More Serious Sirius Business
My post last week was about brilliant Sirius, which turns out to be a double star, comprised of a much brighter Sirius A, and a faint Sirius B. We saw how the motions of these stars, seen in the video below, told us that the Sirius system was 8.6 light years away, and had 20+ times the sun’s luminosity. The motion of Sirius B orbiting around Sirius A takes 50 years to complete. The video below shows a little more than two complete orbits of Sirius B about Sirius A, from approximately 2020 to approximately 2154. The video is a simulation, and presents what you would see if you had a very good telescope aimed at the exact same point in the sky for all that time.
If the telescope is instead aimed at Sirius A, then the motion of Sirius B becomes a textbook case of an orbit—Kepler’s laws of orbital motion in action, as can be seen in the next video. One of those laws says that the mass of an orbiting system is equal to the cube of the system’s average separation divided by the square of the period of the system’s orbital motion.
M = R3 / P2
Here the mass M is in solar masses, the period P is in years, and the separation R is in Astronomical Units or AU (one AU being the distance from the sun to the Earth).
The period is 50 years—that can be directly observed. The separation (between Sirius A and Sirius B) is simply measured by watching Sirius B’s motion and measuring it from one extreme of its orbit to the other (see figure below). This is measured to be about 68 millionths of a radian (see last week’s post for more on radians, triangles, and distances). The average separation is half this, or 34 millionths of a radian.
This image shows Sirius B at approximately the two extremes of its orbit. The distance measures to be about 68 millionths of a radian.
We calculated last week that the Sirius system is 0.5439 million AU away. So, using the same triangle math that we did last week, the average separation in AU is
R = 34 millionths of a radian x 0.5439 million AU = 34 x 0.5439 = 18.49 AU.
Now we calculate the mass of the system:
M = R3 / P2 = 18.493 / 502 = 2.5
So Sirius A and B together measure 2.5 times the mass of the sun. But how much is each star? Is that 2.5 solar masses split evenly between the two? Or does one have more mass than the other? We might expect that to be the case, since A is so much more luminous than B. Well, let’s take another look at the first video, but this time we’ll subtract out the looping effect caused by Earth’s own orbital motion.
The red mark is the barycenter of the system, the common point that both stars in fact orbit. Think of it as the balance point of the system. Note that at any given instant, Sirius B is always about twice as far from the barycenter as Sirius A. If we use the balance analogy, thinking of B and A like two kids on a teeter-totter, Sirius B is about half the mass of Sirius A. So, let’s logic this out.
Sirius B mass + Sirius A mass = 2.5 solar masses
But Sirius A is 2 of Sirius B so
Sirius B mass + 2 Sirius B masses = 3 Sirius B masses = 2.5 solar masses
Sirius B mass = 2.5/3 solar masses = 0.833 solar masses
And then since A is twice B, Sirius A has mass of
2 x 0.833 solar masses = 1.67 solar masses
So now we have the masses of the two bodies. In fact, this was a rough calculation. If you study the orbits of the two stars carefully, you see that they are tilted a bit with respect to Earth, and the tilt at which the orbits are seen alters their shape somewhat, as seen in the last video below. That would change that 68 millionths of a radian measurement above. We could, and really should, do that study of the orbits. However, the “correct” masses of Sirius A and B are in fact 2.0 solar masses for A and 1.0 for B—so our rough calculation is not so far off. Thus we will stop our Sirius business here.
Here you see how we know stuff about stars. From the colors of the stars we can get their temperatures, etc. as discussed in the post of two weeks ago. The way we come to know stuff about stars is we do the observations, and we do the math. After all, we can’t go measure the Sirius system with a tape measure and weigh it with a bathroom scale!
A Serious Sirius Business
Sirius A & B, seen through the Hubble Space Telescope. The arrowed object is Sirius B.
The brightest star* in the sky, Sirius, the Dog Star, was the subject of a nice, short article in the March 2020 issue of Sky & Telescope magazine. The article noted that Sirius is a double star: the Sirius that we point to in the night sky (what astronomers call “Sirius A”) is orbited by a faint companion star (“Sirius B”). Sirius B is most difficult to see through a telescope, owing to the brightness of Sirius A—but it can be spotted, and even photographed.
Sirius is in the constellation of Canis Major, the Greater Dog, near Orion. This image was made using the Celestia app, and the lines you see at upper left are the orbits of the planets, marking the plane of the solar system and the plane of the Earth’s own orbit.
The motion of Sirius B around Sirius A can also be spotted. Observe Sirius with a good telescope over a period of 50 years and you will see Sirius B complete one orbit. The video below shows a little more than two complete orbits of Sirius B about Sirius A, from approximately 2020 to approximately 2154. This video is a simulation made with the app Celestia. It shows what you would see if you had a very good telescope (far better than the Hubble Space Telescope, which took the image of Sirius A & B at the start of this post) aimed at the exact same point in the sky for all that time.
As you can see, the motion is complex! Were you expecting something simpler? If you’ve taken an astronomy class or done some self-teaching, you might have expected something like the video below. It shows what you would see if you had a very good telescope aimed on Sirius A for all that time. It looks like the textbook case of an orbit—Kepler’s laws of orbital motion in action.
What was happening in that first video, with all those crazy motions? Well, it turns out that those crazy motions tell us quite a bit of information about the Sirius system.
First, consider the rapid looping motion of both A and B that you saw in the first video. That is what is called “annual parallax”. It is caused by the motion of the Earth around the sun. As the Earth circles around the sun, that circling motion is reflected in the nearby stars, as seen in the diagram below. This effect is seen only in nearby stars, however; the farther away a star is, the weaker is this effect. This is because the more distant the star, the smaller the size of the Earth’s orbit is relative to that distance.
Annual parallax. As Earth circles the sun, the line of sight from Earth to a nearby star (white dotted line) changes, causing the star to appear to have a looping motion (green curve) against the background of space and the more distant stars as seen over the course of a year. This effect can only be seen in nearby stars, because the farther away the star is from the sun, the narrower the parallax angle (the angle between the two red dotted lines). For most of astronomy’s history, this parallax effect could not be observed, and the failure to observe it was taken as evidence that the Earth was not in motion. Parallax was finally observed in the 1830s by F. W. Bessel—at a time when telescope technology had advanced sufficiently for telescopes to be able to detect it.
If a star is located on the plane of Earth’s orbit, the star’s parallax motion will be back and forth, as seen at left in the figure below. If the star is located straight above the plane of the Earth’s orbit, the star’s parallax motion will be circular, as seen at right. The closer a star is to the plane of the Earth’s orbit, the more back-and-forth and the less circular it will be.
Parallax motion (in green) as seen in a star that lies in the plane of Earth’s orbit (left) and above the plane of Earth’s orbit (right).
The next video shows this motion for the star Pollux in the constellation Gemini (which is near the plane of Earth’s orbit in the sky) and for the star 36 Dra in the constellation Draco (which is far from the plane). Note how Pollux moves back-and-forth, while 36 Dra moves in a circle. Note also how the parallax motion is weaker in 36 Dra than in Pollux, indicating that 36 Dra is more distant than Pollux.
Next let us look at Sirius A and Pollux, seen side-by-side. Now Pollux (left) has a motion weaker than Sirius A (right, which also drifts across the screen because of Sirius B, as we will discuss in due course). So, Pollux is more distant than Sirius A.
In fact, we can do better than just determine that Sirius is closer than Pollux which is closer than 36 Dra; we can in fact determine the distance of each star. As you can see from the parallax figures above (the ones that show the parallax motion in green), parallax movement is just a matter of angles. In a long, skinny triangle, there is a simple relationship between the length D of the longer leg of the triangle, the length S of the shorter leg, and the triangle’s narrowest angle {a}, as seen in the figure below.
S, D, and the angle {a} are related by the equation D = S/a if {a} is measured in radians.
First we measure the size of a star’s parallax motion {a} in units called radians. Just as there are 360 degrees in a circle, there are
2 x Pi = 2 x 3.14159… = 6.28319…
radians in a circle. Then the distance D to that star is calculated via
D = S/a
as in the figure above. But in the case of parallax, S is just the distance from the sun to the Earth. The sun-Earth distance is one Astronomical Unit or one AU. So now we have
D (in AU) = 1/a (in radians)
For Sirius, the parallax is {a} = 1.83846 millionths of a radian, so its distance is
D = 1/1.83846 = 0.5439 million Astronomical Units
or 543,900 AUs. Light takes 8 minutes and 20 seconds (8 & 1/3 minutes) to travel the one AU from the sun to the Earth. Light would then travel from Sirius to Earth in
543,900 x 8 & 1/3 minutes = 4,532,500 minutes.
There are 60 minutes in an hour, 24 hours in a day, and 365.25 days in a year, so
1 year = 60 x 24 x 365.25 = 525,960 minutes.
So, 4,532,500 minutes is
4,532,500 / 525,960 = 8.6 years.
Light therefore takes 8.6 years to travel from Sirius to Earth. Sirius is 8.6 light-years away!
That distance is just the first bit of information we can learn about Sirius from its motions. Parallax is in fact the only direct means we have of measuring the distances to the stars. Using parallax in the same way we did with Sirius, we find that the distance of Pollux is 36 light years, and the distance of 36 Dra is 75 light years.
Once we know how distant Sirius is, we can easily determine how powerful it is by comparing Sirius and the sun and factoring in their distances (see last week’s post for all the details on this). Sirius turns out to have over 20 times the light output power of the sun—that is, over 20 times the luminosity of the sun.
So, we know that Sirius is a star system 8.6 light years away that exceeds the sun’s light output by over 20 times. And we haven’t even messed with the orbit of Sirius B. Next week we will see what else we can learn from the motions of Sirius.
*To any wag who wants to say “Sirius is not the brightest star in the sky, the sun is”, I say “O bother”.
The Summer Stars Speak
This post is based on a series of four posts that originally appeared here in July of 2016.
My posts for the next two weeks will be on the science of learning about the stars through “double stars”, so this is good material to “re-run”.
Look up at the summer night sky. You see stars, of course. There are bright stars like Vega and Arcturus, middling stars like Polaris (the North Star) and Mizar (the star in the “bend” of the Big Dipper’s handle), and faint stars like Rho Leo (an unremarkable star in the constellation of Leo, the lion) and Alcor (the dim companion of Mizar). When we look at these stars, what are we seeing? How do we know what the stars are? You have probably heard that the sun is a star, but are all these stars suns?
Some of the stars of the summer sky as represented by the Stellarium planetarium app.
I have previously discussed in this blog how a person with excellent vision will see stars as small, round dots of differing apparent sizes, or magnitudes. Magnitude means bigness, as this old discussion of the scale of magnitudes indicates:
The fixed Stars appear to be of different Bignesses.... Hence arise the Distribution of Stars, according to their Order and Dignity, into Classes; the first Class... are called Stars of the first Magnitude; those that are next to them, are Stars of the second Magnitude... and so forth, ‘till we come to the Stars of the sixth Magnitude, which comprehend the smallest Stars that can be discerned with the bare Eye....
The idea of magnitude as bigness also shows clearly in this old discussion of the changing magnitude of a “new star” or “nova”:
...from the sixteenth to the twenty-seventh of the same month... it changed bigness several times, it was sometimes larger than the biggest of those two stars, sometimes smaller than the least of them, and sometimes of a middle size between them. On the twenty-eighth of the same month it was become as large as the star in the beak of the Swan, and it appeared larger from the thirtieth of April to the sixth of May. On the fifteenth it was grown smaller; on the sixteenth it was of a middle size between the two, and from this time it continually diminished till the seventeenth of August, when it was scarce visible to the naked eye.
More stars of the summer sky. Note how Stellarium represents the stars as dots of differing sizes. The web page for Stellarium states that Stellarium “shows a realistic sky... just like what you see with the naked eye....”
This system of classifying stars by their apparent sizes dates back to the ancient Greek astronomer Hipparchus, nearly two centuries before Christ. However, following the development of the telescope in the early seventeenth century, astronomers came to realize that the apparent sizes of stars are spurious: Arcturus looks larger than Rho Leo not because of its physical size, but because of its light output and how that light interacts with the eye.
This is perhaps better understood by imagining that one night you and a friend experiment with two identical small LED flashlights, one of which has a weak battery, and the other of which has a very strong battery. Your friend walks two hundred paces directly away from you, then stops, turns on the lights, and aims them both back toward you. The brighter light will appear larger to you than the fainter light, even though both are the same physical size. Try it and see. When it comes to point-like light sources, be they distant flashlights or distant stars, the apparent size you see resides not in the lights but in your eyes.
Thus in the nineteenth century astronomers reworked the magnitude scale so that it wasn’t about size. They came to understand that the light that reaches Earth from a first magnitude star is about 100 times more intense than the light that reaches Earth from a sixth magnitude star. The intensity is measured in power per unit of area—Watts per square centimeter or W/cm2. The magnitude scale is related to light intensity through a factor of 2.5; the light from a (very faint) fifth magnitude star is 2.5 times more intense than the light from a (barely discernable to the eye) sixth magnitude star. A fourth magnitude star (still pretty faint) has 2.5 times the light intensity of that fifth magnitude star and 2.5x2.5=6.25 times the light intensity from the sixth magnitude star. Thus a bright first magnitude star is 2.5x2.5x2.5x2.5x2.5=100* times brighter in terms of intensity than that barely discernable sixth magnitude star.
Why this system? Because the original magnitude scale was based on what the eye sees, and the eye works on a multiplicative scale, not a simple additive one. To see this for yourself, gather up about ten birthday cake candles and turn out all the lights in the room. Look around; it’s dark in the room! Now light one candle. Note how one candle changes things a lot; with one candle you can really see. Now light a second candle, so that two candles are burning. Note how the second candle does make the room brighter, but the change it causes is not as dramatic as the change caused by the first. The third candle causes even less change, the fourth less still, and by the time you go from nine candles to ten you hardly notice the difference. Your eye is not attuned to additive increases in light; each additional candle does not seem to increase the illumination of the room equally, even though each is adding an equal amount of light power. No, your eye is attuned to multiplicative increases in light. Understanding the multiplicative nature of the magnitude scale makes it easier to determine what we are seeing when we look at the stars, and how we know what the stars are.
To know more about the stars, we need to consider what things might affect the intensity of light reaching Earth from a star. These are pretty basic: the distance of the star, and its power output or luminosity. Obviously the farther away a star is, the weaker in intensity its light will be when it reaches Earth and the less bright the star will appear. And obviously a less powerful star will appear less bright than a more powerful star at the same distance.
The relationship between distance and brightness is pretty simple. As light travels away from a star, it spreads out in all directions, like an expanding sphere. The surface area of a sphere is determined by the square of the sphere’s radius. Increase the distance to a star by a factor of 2, and you increase the surface area over which the light is spread by a factor of 2x2=4. Thus you decrease the intensity of the star’s light by a factor of 4, too. Increase the distance by a factor of 10, and you increase the area the light is spread over by a factor of 10x10=100, and you decrease the intensity of the star’s light by a factor of 100.
The gray/black sphere is twice the radius of the blue sphere, and has four times the surface area.
But a change in intensity by a factor of 100 is a change of five steps on the magnitude scale. The star Spica is a summer sky star whose magnitude is about 1.0. A star identical to Spica but ten times farther away from Earth would be five magnitudes fainter—magnitude 6.0. Were it a hundred times farther from Earth, it would be magnitude 11.0 (too faint for the eye to see, but detectable by telescopes). The graph below shows the relationship between distance and magnitude:
How can we determine the distance to a star? Through the parallax angle created by Earth’s motion about the sun, as illustrated below.
The closer the star, the larger the parallax angle, which is usually measured in seconds of arc (just like there are 3600 seconds of time in an hour—60 seconds per minute times 60 minutes per hour—there are 3600 seconds of arc in a degree). The Earth-to-sun distance is one Astronomical Unit, or AU. This chart shows the relationship between distance in AU and parallax angle in seconds of arc:**
Luminosity is a little more complex of an issue than distance, because luminosity itself depends on a star’s temperature and size. Temperature has the bigger effect. As discussed in a previous post, stars give off light in the same way as, and produce the same continuous ROYGBIV rainbow spectrum as, a piece of glowing hot iron or any piece of glowing hot, dense, incandescent material. So we suppose that the star and the iron have much in common. The proportion of colors in the rainbow emitted by an incandescent body depends upon temperature—the hotter a piece of iron (or a star) is, the more it radiates blue and violet light versus red and orange light. Thus as an incandescent body’s temperature rises its color changes from glowing dull red, to glowing orange-yellow, then white, and then even blue-white. The color of an incandescent body then indicates its temperature. The sun is a yellow star. Stars that are redder in color are cooler than the sun. The coolest, reddest stars are only about half as hot as the sun. On the other hand, the hottest, bluest stars are more than twice as hot as the sun.
Not only does the color of light emitted by an incandescent body change with temperature, but the quantity of light changes, too. A piece of iron that is glowing orange-yellow is more luminous than if it is only red hot. This effect is tremendous. Luminosity—the “wattage” of light emitted—goes as the fourth power of temperature, meaning that a star that is twice the temperature of Spica (but the same size) will have 2x2x2x2=16 times Spica’s luminosity! A star the same size as Spica but one tenth as hot would be 10x10x10x10=10,000 times less luminous. Since 10,000 is two factors of 100 (100x100=10,000), and since a change of 100 corresponds to five steps on the magnitude scale, a star one tenth as hot as Spica would be 10 steps down on the magnitude scale, at magnitude 11.0. The relationship between temperature and magnitude is shown here:
Size has a lesser effect on luminosity than temperature. Luminosity follows the surface area of a star, and since surface area of a sphere goes as the square of radius, a star twice the radius of Spica (but the same temperature) would have 2x2=4 times the luminosity. A star one tenth the radius of Spica (but the same temperature and the same distance from Earth), would be 10x10=100 times less luminous—and thus five steps down from Spica on the magnitude scale, at magnitude 6.0. Here is a graph of the relationship between size and magnitude:
We now have everything we need to figure out what these stars we see really are. Let’s begin with Vega. Vega is magnitude 0.0—one step brighter on the magnitude scale than the summer star Spica, which is magnitude 1.0. Vega’s parallax is 0.130 arc seconds. Reading off the parallax chart, we find a parallax of 0.130 arc seconds corresponds to the star being 1,500,000 AU distant (1,500,000 times more distant than the sun).
So suppose Vega were in the place of the sun—that is, suppose somehow we could magically replace the sun with Vega, which would make Vega 1,500,000 times closer than it currently is. According to the magnitude and distance chart, making Vega 1,500,000 times closer would make it about 31 steps of magnitude brighter.
Vega is 0.0, and smaller numbers on the magnitude scale mean brighter (a 1 is brighter than a 5, a 0 is brighter than a 1, a minus 1 is brighter than a 0, a minus 5 is brighter than a minus 1, etc.), so making Vega 1,500,000 times closer would make it a minus 31. The sun, by contrast, is minus 27. So, were Vega in the place of the sun it would be four magnitude steps brighter than the sun. Four magnitude steps means 2.5x2.5x2.5x2.5=39 times the sun’s luminosity. Vega seems to be much more powerful than the sun.
That makes sense. Vega is bluer than the sun, and therefore hotter. In fact, based on its color, Vega should be about 1.7 times hotter than the sun. Judging from the magnitude and temperature chart, being 1.7x hotter would only make Vega about 2 magnitudes brighter than the sun at the same distance.
So Vega must also be larger than the sun. According to the magnitude and size chart, to account for the remaining 2 magnitudes of brightness, Vega must be about 3.3 times the sun’s radius.
Let’s try Arcturus. It has magnitude 0.2, with parallax 0.089 arc-seconds. From the parallax chart we get that Arcturus is about 2,000,000 times the sun’s distance.
If we put Arcturus where the sun is, we make it 2,000,000x closer. According to the charts, that will make Arcturus about 32 steps brighter on the magnitude scale. Were Arcturus where the sun is, it would be magnitude negative 31.8—we’ll just say minus 32. That is five steps of magnitude brighter than the sun at the same distance. That makes Arcturus 100x more luminous than the sun.
But Arcturus is a golden yellow star. It is a little redder, and thus a little cooler, than the sun. Its color tells us that it is about 9/10 the sun’s temperature, so the sun is 10/9 its temperature. Were Arcturus the size of the sun, the sun would be the more luminous, but only by a magnitude or less according to the charts.
Therefore the reason Arcturus would be five magnitudes brighter than the sun were it at the same distance as the sun has to be because Arcturus is larger than the sun. According to the size and magnitude chart, that five magnitude (plus the half or so magnitude due to temperature) difference means Arcturus must be about 14 times the sun’s radius.
So, we have reasoned out that Vega must be about 39x more luminous than the sun, and 3.3x larger (in terms of radius). We have reasoned out that Arcturus must be about 100x more luminous than the sun, and 14x larger. Let’s “check” our answers using the Celestia computer app. Celestia gives the luminosity of stars and can show us what different stars would look like were they in the place of the sun.
According to Celestia, Vega is 49.1x as luminous as the sun, and about 3x as large, while Arcturus is 113x as luminous and 25x as large. So our calculations are in general agreement with Celestia. That’s not too bad, since Celestia’s values are no doubt based the work of astronomers who used more sophisticated and precise reasoning and measurements than these limited charts!
The sun, Vega, and Arcturus as they would appear from a distance of 1 AU (the distance of the Earth from the sun), according to the Celestia app.
There are stars more powerful than Arcturus. Consider Antares, in the constellation of Scorpius.
More stars of the summer sky as represented by the Stellarium planetarium app, including the stars of Scorpius. Antares is at center, slightly toward the top.
According to Celestia, Antares is over 9000x as luminous as the sun, even though it is only about half as hot. The luminosity of Antares is owed to it being so huge that, were it in the place of the sun, the Earth would be deep inside it! Antares is bigger than Earth’s orbit.
Antares is so huge that, were it in the place of the sun, Earth would be inside the enormous red star.
Then there is Rho Leo, which doesn’t look like much in the sky, but that is only because it is so far away. Celestia says Rho Leo is almost 70,000x more luminous than the sun.
Rho Leo (circled).
The sun and Rho Leo as they would appear from a distance of 1 AU, according to the Celestia app. However, Celestia cannot represent the blinding brilliance of Rho Leo’s surface.
Don’t be surprised that so many of the stars visible in the summer sky are more powerful than the sun—luminous stars stand out. There are plenty of sun-like stars out there; they just do not stand out. Consider HIP 80337, a dim star in Scorpius.
HIP 80337 (circled).
According to Celestia, HIP 80337 is very sun-like: same size, same color, same luminosity. Put HIP 80337 in the place of the sun and it would look pretty much the same.
HIP 80337 has about the same parallax as Arcturus, and therefore is about the same distance. When you look at HIP 80337 you are seeing what the sun would look like if it were where Arcturus is.
Now consider Barnard’s Star. It is a summer star, but you cannot see it without a telescope, even though it is not half as distant as even Vega.
The location of Barnard’s star.
Like Antares, it is not very hot, but unlike Antares, it is small. According to Celestia, it is not even one half of one thousandth of the sun’s luminosity. Or consider the star 2MASS J18353790+3259545, near Vega. Celestia says its luminosity is just a tiny fraction of Barnard’s star! Were 2MASS J18353790+3259545 to be put in the place of the sun, it would look so small as to be almost star-like. It would glow red like a piece of charcoal, and provide less light than a full moon. Astronomers believe that small, dim, red stars like Barnard’s and 2MASS J18353790+3259545 comprise the vast majority of stars in the universe—we just can’t see them.
Barnard’s Star, 2MASS J18353790+3259545, and the sun as they would appear from a distance of 1 AU, according to the Celestia app.
So now we know what some of the summer stars are. More importantly, we know how we know what the summer stars are. We see that the sun is definitely a star: HIP 80337 is a star, and the sun and HIP 80337 are pretty similar. But are the stars suns? Antares is giant compared to the sun; Rho Leo is blinding compared to the sun; 2MASS J18353790+3259545 is puny compared to sun. And the differences between these stars and the sun pale compared to the differences among themselves—consider 2MASS J18353790+3259545 versus Antares or Rho Leo. Perhaps the safest thing to say is that there is an incredible amount of diversity among the summer stars.
We have learned how we know what the stars are, and using that knowledge we have seen that while the sun is certainly a star, the summer stars themselves vary wildly in size and in power or luminosity. Among such incredible stellar diversity are many bodies that are very different from the sun. But all this knowledge about the stars came from just three measurements: (1) An annual motion of a star (parallax), (2) The magnitude of that star, (3) The color of that star.
We do not measure the size of a star like we might measure the size of a window with a ruler. We do not measure the distance to a star like we might measure the distance to a friend’s house with our car’s odometer. We do not measure the power output of a star like an engineer might measure the output of a new kind of light bulb. We have never been to a star to make such direct measurements, and we are not likely to go to one in the near future. Rather, we measure movement, magnitude, and color, and from these things we reason mathematically to determine the star’s size, distance, temperature, and luminosity. We reason by analogy—the light of stars matches the light given off by a dense, incandescent object like a piece of hot iron. We suppose that stars and incandescent iron behave in the same basic ways: the luminosity of an iron ball increases as the square of its radius and the fourth power of its temperature, thus so does the luminosity of a star. In short, we suppose that the heavens and the Earth are under the same rule.
If we are wrong about the specific supposition that stars and glowing iron have something in common, we may be very wrong about the sizes and luminosities of stars now, but we can hope to figure things out better in the future. And we can imagine why there might be limits to this sort of supposition. For example, my fellow blogger Brenda Frye has noted that there is a limit to how massive a star can be, and that limit is only about 150 times the mass of the sun. But Antares takes up much, much more than 150 times the volume of the sun. Antares must be a lot less dense than the sun. How much less dense can Antares be before it stops being a “dense, incandescent body,” and the analogy to iron breaks down, throwing off our mathematical reasoning? On the other hand, if we are wrong about the general supposition that the heavens and the Earth are under the same rule, so that in fact maybe the stars are controlled by magic Elves who choose the coloring and brightness and motion of the stars for their own inscrutable Elvish reasons, that would do more than throw off our reasoning a bit. That would mean that we could never hope to know anything about the stars other than their motion, their magnitude, and their color. That would really stink.
Keep this in mind when you look up at the summer stars, or when you hear about how far away a certain star is, or how large or powerful it might be. It is cool, cool, cool to be able to look up at the summer sky and see the stars, and know something about what you are looking at, and to know how you know what you know, and to know why it is even possible to know what you know. There is so much to see and think about in the stars of the summer sky.
*OK, for those of you who multiplied this out and found out that the result is not 100 but 97.66... well, actually the multiplying factor in the magnitude scale is not exactly 2.5, but 2.5118864.... This number is called “Pogson’s ratio,” after N. R. Pogson, the British astronomer who proposed this system in 1856.
**For those who want the math of the parallax-and-distance chart: For the small angles involved in parallax the relationship between parallax and distance is simple:
PARALLAX ANGLE = EARTH-to-SUN DISTANCE / STAR DISTANCE
In terms of AU, this is
PARALLAX ANGLE = 1 AU / STAR DISTANCE IN AU
This formula gives the parallax angle in radian units. There are 57.3 degrees in a radian, and 3600 seconds of arc in a degree, so to get this formula to work in seconds of arc it needs to have those correction factors built in
PARALLAX ANGLE = (1 AU / STAR DISTANCE IN AU) x 3600 x 57.3
This last formula is what is plotted on the chart.
Vatican Observatory Photometry and “The Vilnius Connection”
“Forty Years of Photometry.” That is what is on the cover of the Specola Vaticana/Vatican Observatory’s 2019 Annual Report. If you have not had a look at the report, click here and read through it (and to see Annual Reports going back years, click here). The two gentlemen on the cover are Fr. Richard P. Boyle, S.J. (at right) and Fr. Robert Janusz, S.J. And that cover, and those gentlemen, have a connection to my “origins story” with this Sacred Space Astronomy blog and the V.O.
The Annual Report’s main article starts off by noting that,
Just as this year the world celebrates the 50th anniversary of the Apollo moon landing, so here at the Specola we mark a significant anniversary: 40 years since the pioneering publication of Father Martin McCarthy and his collaborators on stellar photometry, which laid the groundwork for what has become a major thrust of research at the Vatican Observatory. In that paper, Fr. McCarthy described a program that has been carried out over forty years, three continents, several telescopes, and the careers of several astronomers… and is still ongoing.
The article provides a little history about the use of photometry—that is, “the measurement of light”—to learn about stars. The V.O. started doing photometry in earnest in the 1950s, and things gained momentum through Fr. McCarthy’s work. McCarthy ended up serving for several years as commission president of the International Astronomical Union’s (IAU) Commission 25 on “Stellar Photometry and Polarimetry,” and of Commission 45 on “Spectral Classification”. Meanwhile, the article reports,
The beginning of a long term photometric project at the Specola got underway with the urging of its new director, Fr. George Coyne, S.J., who had been appointed in 1978. Coyne, like McCarthy, was also a member of the IAU Commission 25. So was V. [Vytautas] Straižys from Vilnius, Lithuania.
Through this commission, Coyne heard Straižys describe a new system of photographic filters devised in Vilnius which seemed to hold great promise for stellar photometry. Later, K. Nandy (Edinburgh Royal Obs.) and F. Smriglio (Università di Roma “La Sapienza”) also suggested the Vilnius system to Coyne.
When Coyne welcomed a new, young astronomer, Richard Boyle, S.J., to the Specola in 1981, he suggested that Boyle look into this new project. Boyle’s Ph.D. was actually in solar astronomy; but this young and energetic solar astronomer soon began to observe stars other than the sun, at night, using the Vilnius photometric system in collaboration with fellow astronomers in Rome, Vilnius, and Edinburgh....
In 1986 F. Smriglio, R.P. Boyle, V. Straižys, and collaborators published [their] results; this was Boyle’s first paper using the Vilnius Photometric System....
Fr. Boyle has been doing photometric work ever since. And in the mid-2000’s his path and mine crossed (intellectually) in Vilnius. In 2004 I had read an article in Sky and Telescope magazine about Galileo’s observations of a double star, Mizar in the Big Dipper. It was immediately apparent to me that Galileo’s Mizar observation would have created problems for the heliocentric system that he supported. I became interested in the star observations made during Galileo’s time, and began research.
Eventually I wrote a paper about this research, but I was unsure of where to submit it for publication. I had never written about this kind of topic before. Who would consider a paper that included, on one hand, calculations involving “Bessel functions”, and on the other hand, Galileo’s drawing of the Trapezium in Orion? Well, a journal called Baltic Astronomy had published a paper that had been useful to me—about Galileo inadvertently observing Neptune. I had referenced the Baltic Astronomy paper in my paper. So, I decided to send my paper to Baltic Astronomy.
Baltic Astronomy was published in Vilnius, Lithuania. Its editor was an astronomer named Vytautas Straižys. After a referee’s report, Baltic Astronomy accepted the paper! I was very pleased—my first astronomy journal publication since my graduate school days. But there were certain details about the publication process that I was unsure about. I was afraid that if I kept bugging Straižys with questions I would quickly annoy this astronomer from Vilnius. So, I looked to see what authors regularly published in the journal.
The name “Richard Boyle” caught my attention. That sounded like someone I could bug with less chance of unknowingly doing something culturally clumsy. And, Boyle had a degree from St. Louis University. My father got his Ph.D. there. I lived in St. Louis once! Why, this Boyle guy was practically my second cousin twice removed. So, I contacted him for advice.
That was a good move. Boyle knew the ropes, of course. Everything worked out. “On the Accuracy of Galileo's Observations”, by yours truly, appeared on page 443 of Volume 16, Number 3/4 (2007) of Baltic Astronomy. That was my first history of astronomy peer-reviewed publication. Boyle happened to have a paper published on page 459 of that same volume: “A Method to Correct CCD Flatfields for Precise Stellar Photometry”. Also, on page 467 was a paper by a guy named R. Janusz with a V.O. affiliation: “The Commandphot, an Organized and Automated Method for Processing CCD Stellar Observations”. Moreover, on page 451 was a paper “The STRÖMVIL Photometric System: 1996 TO 2006” by A. G. Davis Philip, whose affiliation was “Institute for Space Observations and Union College” but whose paper featured a full-color photo of the Vatican Advanced Technology Telescope (VATT). Unknowingly, I had ended up publishing in a journal that had significant ties to the Vatican Observatory.
Left—Volume 16, Number 3/4 (2007) of Baltic Astronomy. Right—the VATT in the STRÖMVIL paper.
I kept up the research, and I kept submitting papers to Baltic Astronomy. They published five papers of mine between 2007 and 2010. And most of the time, when one of my papers was published, a paper by a V.O. astronomer was published in the same volume. On page 93 of Volume 18, Number 1 (2009) is “Regarding the Potential Impact of Double Star Observations on Conceptions of the Universe of Stars in the Early 17th Century” by Henry Sipes and me. But on page 1 is “Young Stars in the Camelopardalis Dust and Molecular Clouds. V. More YSOs Confirmed Spectroscopically” by C. J. Corbally (Vatican Observatory) and V. Straižys. On page 265 of Baltic Astronomy Volume 19, Number 3/4 (2010) is my “Changes in the Cloud Belts of Jupiter, 1630-1664, as Reported in the 1665 Astronomia Reformata of Giovanni Battista Riccioli”. And on page 225 is “High Velocity Spectroscopic Binary Orbits from Photoelectric Radial Velocities: BD+20 5152, a Possible Triple System” by J. Sperauskas, A. Bartkevičius, R. P. Boyle, & V. Deveikis.
The Baltic Astronomy connection led to further contact with the V.O., and particularly with a V.O. astronomer named Guy Consolmagno. I ended up meeting Consolmagno in Chicago. Later, I invited him to come to Louisville to give a talk at our public library. When I invited him to talk at the library, he was not the Director of the V.O.—but by the time he spoke there, he was. In 2016 Br. Guy invited me to write for this blog, and in 2019 I was named a V.O. Adjunct Scholar.
I have not published in Baltic Astronomy since 2010. Around then I changed the focus of my work, from the sorts of technical analyses that I wrote for Baltic Astronomy to searching the writings of seventeenth-century astronomers for the kinds of historical works that those technical analyses said should exist, and to translating those works so others could read them. But Baltic Astronomy and the Vilnius connection is arguably why you read my posts on Sacred Space Astronomy, and why you can find my face, along with Frs. Boyle and Janusz, in the 2019 Annual Report of the Vatican Observatory that celebrates “Forty Years of Photometry”.
“Forty Years of Photometry” article in the 2019 Vatican Observatory Annual Report
Back Yard Meteor Crater: Jeptha Knob
There is a meteor crater in my back yard! Despite having lived in the Louisville, Kentucky area for thirty years, I only learned about the crater this year, when I took part in the AAS Kentucky Area Meeting 2020 on March 7. One presenter mentioned impact sites in Kentucky, including Jeptha Knob. Jeptha Knob is located half an hour due east of my house. It is just a few miles from Shelbyville, Kentucky, home of one of my college’s campuses. A few years ago, I taught Astronomy 101 at that campus for two semesters, wholly unaware of any nearby crater. However, while I did not know of Jeptha Knob until this year, I did know the name because of the Jeptha Creed distillery in Shelbyville (we make a lot of bourbon here in Kentucky, you know).
Jeptha Knob near Shelbyville, Kentucky
Jeptha Creed distillery in Shelbyville calls attention to the knob’s name.
Last month my wife and I decided to go check out Jeptha Knob—a good “no social contact”, enjoyable, yet professionally constructive thing to do during a pandemic shutdown. According to the Jeptha Creed distillery, the knob was named by Squire Boone and Daniel Boone when they came to explore Kentucky in the late 1700s, and they chose the name after the Biblical warrior from Judges 11, because hunting was plentiful in the area due to a salt lick that attracted buffalo, deer and turkey. Jeptha was a warrior who for some inconceivable reason vowed to God that, were he victorious in battle, he would sacrifice the first thing he saw upon returning to his home—and surprise, surprise, his daughter, his only child, runs out to greet him as he approaches the house (it is not a happy story). Perhaps the Boone brothers thought that if Jeptha had lived on the knob he might have managed to find a wiser choice of something to first see at his house.
The top of the knob is the highest point in the region: 1200 ft. There are no comparable peaks for tens of miles in any direction. Geologists think that the knob is probably the central peak of an impact crater. They are not certain. Gravity surveys, magnetic surveys, the detection of iridium in the knob, certain folds in the rocks, and other things suggest to them that Jeptha Knob has an “exogenetic origin” from a “hypervelocity impact”. However, “many of the accepted criteria required to define impact structures have not been observed at Jeptha Knob”. Any crater rim has long since eroded away.
Having never been to an impact site before, I had no particular expectations for the knob when we went there. However, to my non-geologist’s eye, the terrain certainly seemed to be more rugged and folded than the usual hills in the region. That said, the difference was not great enough for the average person to really notice any difference; a person would have to be looking for it. Indeed, the abundant wildflowers on the knob would more likely catch the attention of visitors who have eyes for natural things than would the lay of the land.
Wildflowers on Jeptha Knob (from left to right): Larkspur and trillium, anemone, Dutchman’s breeches, phlox, and Jack-in-the-pulpit
Nevertheless, there was something very cool about being on the central peak of an impact crater. Even if it was an eroded crater, and even if geologists are still a bit uncertain about whether it truly was caused by an impact, it was a neat place. It is almost in my backyard, so I'll be happy to accept it as an impact crater.
And while the crater is almost in my back yard, quite a few backyards are actually inside the crater! The area around Shelbyville has many new homes built on old farms. Farm acreage with road frontage becomes home sites; the back acreage often returns to forest. This is true on the knob itself; there were new homes built right up on the peak of the knob. I wonder if the folks who live in these homes know that their woodsy back yards lie inside a meteor crater.
Looking up at the top of the knob (home to many antenna towers)
The view from the top, looking north
Left and center: geologists’ maps of the impact site (from “The Jeptha Knob Cryptoexplosive Structure, Shelby County, Kentucky”, 42nd Annual Meeting of the American Institute of Professional Geologists, 2005). Right: an interesting graphic from a University of Kentucky website about the knob.
Topographic map of the knob
Homes and young woods on the knob
Science Hill in Shelbyville. A historical marker in front of this building states that from 1825 to 1939 it housed one of the foremost college preparatory schools for girls in the United States. It has been a restaurant now for many years. However, while the interesting name of the place might suggest a reference to the interesting geology of Jeptha Knob, the school predated by seventy years the first geological study of the knob.
I taught two semesters of astronomy here at my college’s “Shelby Campus”, unaware that I was teaching just a few miles from an impact crater.
Galileo and the Science Deniers – a Review
Christina of Lorraine had astronomy questions for Fr. Benedetto Castelli, so she sat him down to get answers. The conversation occurred in December of 1613, and arguably Christina’s questions set the entire “Galileo Affair” into motion. Mario Livio opens his new book, Galileo and the Science Deniers, with that conversation between the mother of the ruler of Tuscany and one of Galileo’s friends. Livio says he wrote a book about Galileo because—
very few of the known biographies [of Galileo] were written by a research astronomer or astrophysicist. I believe, or at least hope, that someone actively engaged in astrophysical research can bring a novel perspective and fresh insights even to this seemingly overworked arena.
He also says he wrote it because he sees a connection between the Galileo story and the unscientific and anti-scientific attitudes present today in the broader world beyond working scientists (p. xv). Those are great reasons to write a book about Galileo. That broader world would surely benefit from a scientist’s look at Galileo’s work. Unfortunately, Livio leaves his scientist’s outlook elsewhere. Rather than providing a novel perspective, he re-tells an old tale that contributes to the very problem of science denial that he deplores in his book.
The problems with Galileo and the Science Deniers start in the first sentences of the book, with Christina and Castelli. Livio describes Christina questioning Castelli about the discoveries that Galileo had made since 1609 with his telescope, and pressing Castelli regarding whether the Earth moves, given that a moving Earth seems contrary to the Bible. Castelli, though intimidated by the prospect of arguing with royalty, politely and respectfully stands his ground. We know all this because Castelli described it all to Galileo in a letter of December 14, 1613, which still exists.
Christina of Lorraine is then the first in a long line of characters in Livio’s book who, for reason of what was in the Bible, opposed Galileo and his promotion of the heliocentric system of Copernicus. To Livio, Christina and company are Science Deniers who reject science for scripture. At one point (p. 115-116), Livio writes that such people—
were asking Galileo to give up convictions that had been forged on the basis of painstaking scientific observations and brilliant deductions, only because they appeared to contradict some ancient, vague, poetic texts—and only when those texts were interpreted literally rather than figuratively.... Should he have abandoned what he regarded as the only possible logical conclusions in favor of what amounted to a seventeenth-century version of political correctness?
Livio continues, noting that Galileo—
did his best to prove that, while interpretations of scripture could be reformulated in alternative ways so as to agree with what nature was presenting, facts were facts.
Yet, Christina of Lorraine and those of like mind did not disagree with the facts. Christina had a wingman in her conversation with Castelli—one Professor Boscaglia from the University of Pisa. Boscaglia emphasized to her that everything Galileo had discovered was true. However, he and Christina still both urged that the Earth does not move, both noting that a moving Earth is contrary to the Bible.
Livio relays all this. He describes how, following Galileo’s first publishing his discoveries in his 1610 Starry Messenger, some people did claim that Galileo was talking nonsense. Martin Horky, in particular, was most insulting in this regard. Yet by April of 1611 such claims were gone. A team of astronomers from the Society of Jesus verified Galileo’s discoveries, discoveries that showed that Jupiter had moons circling it, that Venus circled the Sun, and so on. Even Horky came around. Such is the power of reproducibility in science; everyone, even Horky, could eventually repeat Galileo’s observations and confirm his results.
But those observations of moons circling Jupiter, or Venus circling the Sun, did not show that Earth moved. Those discoveries were fully compatible with the ideas of Tycho Brahe, who Livio also discusses. Brahe envisioned the Sun, Moon, and stars circling an immobile Earth, while the planets circled the Sun. Tycho’s geocentric system and Copernicus’s heliocentric system were mathematically and observationally identical, insofar as the Sun, Moon, and planets were concerned.
Therefore, Christina and Boscaglia could accept that everything that Galileo had discovered was true—facts were indeed facts, after all—but not accept the Earth’s motion. They were not Science Deniers. The existence of Jupiter’s moons had been established through reproducible observations; Earth’s motion had not. Meanwhile, the Bible says (Eccl. 1:5),
The sun rises and the sun goes down; then it presses on to the place where it rises.
That might be poetic, and it might be ancient, but it is not vague. Sure, one might say that the Bible just speaks to things as we see them—after all, we do in fact see the Sun rise in the East, set in the West, and rise again in the East. But absent compelling argument for Earth’s motion, Christina, who Livio describes as a “singularly religious woman” (p. 148), would have no reason to prefer a less literal interpretation of the Bible.
Meanwhile, there were certainly compelling arguments for Tycho’s ideas.
Livio mentions the case of Cesare Cremonini, a staunch defender of the ideas of Aristotle. Cremonini, says Livio, refused to as much as look through a telescope. He was an atheist, so the words of the Bible would not have concerned him. But, as Livio reports (p. 98),
Cremonini wanted something deeper than what had been revealed by Galileo’s observations. He noted, for instance, that if the Moon was indeed a terrestrial-like body, as Galileo’s findings had implied, it should have fallen toward the Earth.
In terms of the scientific knowledge of the time, Cremonini was right. Terrestrial bodies fall down, they do not hang in the sky. Drop or throw a rock; it falls to Earth. The physics of the time, which was the geocentric physics of Aristotle, explained the motions of celestial bodies by assuming they were made of a substance not found on Earth, a substance that naturally stayed up in the heavens and moved in circles, as opposed to a rock which naturally fell toward the center of the Earth and stopped. Livio understands this, writing—
In the absence of a theory that could explain why this was not happening (a situation that lasted until Newton [decades after Galileo]), Cremonini was not prepared to give up Aristotelian views.
There were no physics to explain the motion of either the Moon or the Earth in the heliocentric system. By contrast, in Tycho’s system, the basic geocentric structure of Aristotelian physics remained intact. Tycho said that his system violated neither the laws of physics nor the words of the Bible.
Physics was one compelling argument for Tycho’s system. Another was the stars. In Tycho’s system the stars lay just beyond Saturn, whereas in the heliocentric system, they had to be very distant in order to explain why Earth’s motion was not reflected in them. But, as Livio writes (p. 65), given that vast distance,
one could then estimate the size that the stars had to be in order for them to be seen with their apparent dimensions observed with the naked eye. Those expanses turned out to be even larger than the diameter of the entire solar system, which seemed highly implausible. Consequently, Brahe concluded that the Earth could not be orbiting the Sun.
By contrast, in Brahe’s system stars were of reasonable size, comparable to the Sun and larger planets. Unfortunately, Livio presents this star size argument, but he never discusses it further. He just states that,
[Galileo] concluded that the apparent dimensions of stars as seen with the naked eye did not represent real physical sizes—they were just artifacts.
And here Livio fails to provide the broader world with a scientist’s perspective and insight; he leaves be the scientific problem of star sizes. In fact, while Galileo thought that the apparent dimensions of stars as seen with the naked eye did not represent real physical sizes, he thought that their apparent dimensions seen with the telescope did. He reported on those dimensions in various works that Livio cites: the sunspots letters, the reply to Francesco Ingoli, the Dialogo. Other astronomers, such as Simon Mayr, who Livio discusses, noted the telescopic dimensions of stars and the problems they posed for heliocentrism. Christoph Scheiner, another astronomer in Livio’s book, succinctly put it this way: if the orbit of the Earth cannot be detected in a heliocentric universe, but the size of a star can be, then the star must be larger than Earth’s orbit. Brahe’s stars problem did not go away; indeed, it was reinforced by the telescope.
Thus there were scientific arguments against heliocentrism that made the geocentric Tychonic system compelling. Scientists such as Mayr and Scheiner embraced that system, rejecting Earth’s motion, just like Christina of Lorraine. The reader might hope that a book written by an active scientific researcher would explore what these scientists had to say, discuss the dynamism and complexity of the scientific arguments of the time, and help the reader understand those arguments—but Galileo and the Science Deniers does not do that. Indeed, Livio portrays Mayr as not even understanding what Jupiter’s moons were (p. 69)—
Mayr may have independently detected the satellites [of Jupiter] before Galileo, but he failed to understand that the moons were orbiting the planet.
But Mayr certainly did understand that. He himself reported that—
by degrees [I] arrived at the following view, namely, that these stars moved round Jupiter, just as the five solar planets, Mercury, Venus, Mars, Jupiter, and Saturn revolve round the Sun.
In fact, Mayr was able to show mathematically that the observed motions of the moons indicated that Jupiter circled the Sun and not the Earth. Yet Livio misses this and misrepresents Mayr’s views. Note that Mayr does not include Earth among the planets—he subscribed to the Tychonic system, in which Earth did not move.
Scheiner also subscribed to the Tychonic system. And it was Scheiner, not Newton, who first proposed a physical explanation for how an Earth-like body could be in an orbit. Livio misses this scientist’s work, too. Scheiner envisioned an orbit being a perpetual falling action, much like Newton, but Scheiner was decades before Newton. Scheiner said his orbit theory would not really help the Copernican system, because heliocentrism had too many other problems. One of those, he said, was the star size issue. But another was the problem of falling bodies: how can objects fall straight down on a rotating sphere? The Earth is not like a cabin on a ship, in which everything moves together, like Galileo said (and Livio relays). On a rotating sphere, things move at different speeds—fastest at the equator, slowest at the poles, etc. Scheiner was right. Things can’t fall straight down on a rotating sphere. Anti-Copernicans envisioned what we now call the “Coriolis Effect”, long before the Coriolis for whom it is named. But they envisioned it as a scientific argument against Earth’s motion—its seeming absence showing Earth’s immobility.
The nuts and bolts of good scientific arguments against Earth’s motion should interest, and be understandable to, a scientist. Translations of Mayr’s and Scheiner’s work exist but are not in Livio’s Bibliography. Anti-Copernican scientific arguments undermine the very title of Livio’s book, as they further drive home the point that Christina, Mayr, Scheiner, and so on were hardly Science Deniers. Still, Livio gives little space to such arguments.
He gives no space at all to the flaws in Galileo’s own scientific arguments. As mentioned above, Livio overlooks Galileo’s statements about the dimensions of stars in several places. But he also misses that Galileo even claimed in the Dialogo to be able to split the telescopic disk of a star with an obstructing marker set up in the distance. That is impossible. The disk-like images of stars that Galileo claimed to see were indeed artifacts of the telescope. Being formed inside the telescope, they could not be split by something outside. A working astronomer, with experience in using telescopes, might have noticed and discussed this bogus claim, something that a historian might not catch, but Livio does not catch it either.
And Livio overlooks something else. Galileo argued that the tides of the oceans were evidence for Earth’s motion. The double motion of Earth rotating about its own axis while revolving about the Sun creates a daily variation in the speed of Earth’s surface which, Galileo said, causes the oceans to slosh back and forth in their basins, creating the tides. Livio refers to both Galileo’s 1616 tides discourse to Cardinal Orsini, and to his 1632 tides discussion in the Dialogo, but Livio misses a key difference in the two. If the daily surface speed variation drives the tides, that should produce a single high and a single low tide each day, with 12 hours between high and low. But Galileo noted that the tides in the Mediterranean Sea have 6 hours between high and low. He said that while the speed variation drives the tides, tidal periods in specific places were influenced by the characteristics of the local ocean basin, as the water surge was reflected back and forth within that basin, thus explaining the 6 hours as being characteristic of the Mediterranean only. And, in the 1616 discourse, Galileo claimed that the Atlantic Ocean tides observed in Lisbon, Portugal showed the full 12-hour period, in agreement with his theory. But in 1619 Galileo was informed (by Richard White of England, who wrote about it) that this claim was in error; tides are 6 hours at Lisbon. Under Galileo’s theory, the Atlantic tides should have a different period from the Mediterranean. Arguably, the Lisbon tides falsified Galileo’s theory; at the very least they strongly challenged it. Yet in 1632 Galileo presented the tides theory again, with one big change from 1616: he omitted mention of Lisbon and the Atlantic tides. In 1632 he put forward his tides theory, the thing he originally intended to be the title feature of the Dialogo, his big argument for Earth’s motion, simply omitting an important but inconvenient fact. It seems facts were not always facts. Despite being a working scientist, Livio misses this.
Christina of Lorraine may not have raised all these specific problems with Galileo, but others who opposed him did. Francesco Ingoli, who played a role in the censoring of Copernicus’s work in 1616, and Melchoir Inchofer, who played a role in the rejection of the Dialogo in 1633, each noted the star size problem in their writings. Zaccaria Pasqualigo, also involved in the actions of 1633, cited the issue of tidal periods.
Galileo and the Science Deniers is therefore wrongly titled. Christina of Lorraine and those like her were not Science Deniers. They chose, from between two theories that fit the new telescopic discoveries (Copernicus’s heliocentrism and Brahe’s geocentrism), the one that fit the Bible—and that fit the known laws of physics. They did not refuse to acknowledge established scientific fact.
Galileo responded to Christina’s challenge by focusing on the Bible. He responded to Castelli’s letter of December 14 with a letter of December 21 back to Castelli, and later with a larger letter to Christina herself. These letters are considered masterful discussions of science and religion, full of words like—
Holy Scripture and nature both equally derive from the divine Word, the former as the dictation of the Holy Spirit, the latter as the most obedient executrix of God’s commands
—and so on. But arguably Galileo’s words said little to a person who accepted the telescopic discoveries as true and was drawn to Tycho’s ideas for scientific reasons as well as religious ones. And those words were about religion. The letter to Castelli became in 1615 the subject of a complaint lodged against Galileo with the Inquisition. And thus “The Galileo Affair”, and its sorry story of religious politics, personality, and pettiness was off and running. Livio’s book is mostly about that, not about science or science denial, despite Livio’s occasional references to modern science denial.
To be clear, the fact that “The Galileo Affair” was about politics, personality, and pettiness, rather than denial of what was seen through a telescope, does not alter the fact that the Church did Galileo wrong. However, I live in the Archdiocese of Louisville, Kentucky, established in 1808 as the Diocese of Bardstown, Kentucky. It was the first inland diocese in the United States, and Kentucky was a slave state. A slave market existed in Louisville, within blocks of the cathedral. Bishops and religious orders and many others in the Catholic Church, officials and non-officials alike, bought in to the corrupt local culture and themselves kept people in slavery. In recent decades there has been much Catholic apologizing for this. Doing people wrong is something human beings and human institutions do: my city; my state; my country; my Church. What makes the Galileo case stand out is that it was supposedly about “science”, and “facts”. Absent someone rejecting scientific discoveries, “The Galileo Affair” falls well behind slavery in the line of Church wrongs—just a case of the Church cruelly bullying a well-connected old guy, who himself bullied opponents like Mayr and Scheiner with the harshest language.
A memorial in the cemetery of the Sisters of Loretto at the Foot of the Cross, west of Springfield, Kentucky, that stands on the site of the graves of those African-Americans who were enslaved by the sisters.
Given that Galileo and the Science Deniers does not provide the sorts of novel perspective and fresh insights (especially as regards the science of the time) that a scientist might offer, and given that “The Galileo Affair” is indeed an overworked arena, why then does this book exist? It provides no ringing endorsement of freedom of thought, or freedom to be wrong. Livio writes that the big lesson from the Galileo Affair is that (p. 200)—
no officialdom, be it religious or governmental, should have the authority to impose punishments on scientific, religious, or any other type of opinions (whether correct or incorrect)…
—which sounds good, but then he adds this:
as long as those neither harm, nor incite others to harm, anybody else.
Since Livio also notes that Pope Urban VIII maintained that Galileo’s ideas were “not only false, but also perilous to humanity [p. 211]”, presumably the bullying of Galileo might be acceptable under the “harm” clause.
No, the book seems to exist to tell a tale of a hero. Consider two items from Galileo and the Science Deniers. One is Livio’s discussion of a copy Galileo made of the December 21 letter to Castelli (the one that was sent to the Inquisition). Livio writes (p. 110):
Probably aware that the letter, which Galileo wrote to Castelli rather hastily, could spell trouble, Galileo produced a slightly revised version, in which he more thoughtfully and cautiously presented the theological issues. He then sent the letter with an explanation to his friend the Florentine monsignor Piero Dini. Galileo asked Dini to show the letter to the Collegio Romano mathematician Christoph Grienberger and, if appropriate, also to Cardinal Bellarmino....
But what Galileo told Dini is that he was sending him a copy of the letter to Castelli “in the correct version as I wrote it”, stating that he suspected that “perhaps whoever transcribed it [the copy sent to the Inquisition] may have inadvertently changed some word”. Galileo presented the “revised” version to Dini as being the original version. Indeed, historians have long been in the dark as to what really was the original version. Only in 2018 was Galileo’s subterfuge discovered, when the original letter in his own hand, with his marks for the revision for Dini, was found mis-filed in a library. There was no transcription error in the version sent to the Inquisition. Thus in Livio’s tale a lie told to a friend to release a milder version of the letter becomes a revision sent to the friend with explanation.
The second item is Livio’s willingness to portray Galileo’s opponents in really poor terms. Simon Mayr’s understanding of Jupiter’s moons is not in Galileo and the Science Deniers, but Galileo’s labelling him a “poisonous reptile” and “an enemy not only of me, but of the entire human race” is (p. 69). Livio invokes “horrifying memories of totalitarian regimes past and present” in regards to the Inquisition (p. 191), and writes that
Cases such as those of self-exiled dissident Saudi Arabian journalist Jamal Khashoggi and Russian defector Alexander Litvinenko, both murdered by their native countries’ governments, immediately come to mind.
Galileo’s opponents are poisonous reptiles indeed.
Granted all this, and granted the book’s lack of interest in the scientific debate of the time, Galileo and the Science Deniers simply retells a tale about a hero. Livio does that well. He does not overlook the hero’s personality flaws; the book is not a hagiography. But he does overlook the hero’s scientific errors. The hero who omitted crucial facts in presenting his tides theory is logical and brilliant. His opponents’ interest in and acceptance of science is overlooked. Thus, there is the hero and his friends, and there are the bad guys—enemies so bad that the murder of Jamal Khashoggi comes to mind.
That is a shame, because science today does not need another version of this tale. Livio is right about the problem that science denial poses to science; his point there is important and right on the target. But science denial always involves tales of conspiracies on the part of big bad institutions to cover up the truth revealed by the lone hero, or the scrappy rag-tag band of heroes. As Bob Garfield of NPR’s “On the Media” very recently put it, “a victim, someone who has been silenced by ‘The Man’, a martyr to truth-telling... is a recurring theme in the conspiracy genre”. I have said many times on this blog, if we want to strike a blow against science denial, we need to stop retelling the hero tale—clearly the previous 40,000 retellings have not done any good. We need instead to tell how science really worked during the debate over Earth’s motion, and still works now, and how complex, dynamic, and interesting that debate was. We need to give Christina of Lorraine her due. We will not combat science denial and its associated conspiracy theories by telling people, contrary to the historical record, tales of how the very birth of modern science was marked by rejection of facts and a big conspiracy to hide The Truth. We will combat science denial by showing how vigorous scientific debate over a universally accepted set of facts was present at the very birth of modern science, as it often is in science today. Galileo and the Science Deniers does not do this, despite its author being a scientist. It retells a tale that is central to the genre of conspiracy and science denial, and so it will in all likelihood contribute the very science denial problem it purports to help solve.
You-Know-Who, the Coronavirus, and Science Denial Hypocrisy
I saw a banned film this week! And it led to you-know-who!
If you read this blog, you are likely familiar with NPR’s “Science Friday” show. You might have listened last Friday, May 15, and heard the segment called “Fact Check My Feed: Finding The Falsehoods In ‘Plandemic’”. For those of you who do not follow “Science Friday”—and who somehow have managed to miss all the rest of the hubbub over this—“Plandemic” is a video, a short film, if you will. It primarily consists of an interview with a scientist named Dr. Judy Mikovits. Mikovits has renegade ideas regarding the coronavirus, vaccines, and the medical world. Of course, your cousin Joey has renegade ideas about these things, too. But Mikovits is co-author of a book called Plague of Corruption that has a foreword by Robert F. Kennedy, Jr. (a prominent figure in the anti-vaccine movement) and that has been the top seller on Amazon recently.
I wanted to see the video before writing this post, but “Plandemic” has been banned by the big internet companies, and someone hacked its web page (which now—or at least when I looked for it—features a short statement, replete with a few common crudities, asserting that Mikovits is crazy). It took some work to find the film. But I found it. And I watched it. I believe this is the first time I have ever watched a banned film.
When I was growing up in Owensboro, Kentucky, there was a drive-in movie theater that liked to show “banned” films—typically B-grade horror flicks loaded with gore; the kind made by a guy whose cousin works at the local butcher shop and can get hold of lots of offal for “special effects”. The drive-in would advertise movies “banned in 30 countries” and promote a “free barf bag with each ticket purchased”. This classy operation was located over a mile from my house, but because the ground between it and home was low, and mostly fields, from my back yard on summer evenings I could see the screen flickering in the distance. I would sometimes use my telescope to try to see what was showing. But seeing the screen one-eyed through the eyepiece, half-blocked by trees, image inverted, with no sound, was pretty much pointless. My eighth-grade self could never really make out anything, could never really brag to my friends that I had seen one of those banned movies. Had that younger, telescope-peering self known that this video of two middle-aged people talking would be my first experience with banned film, he would have been very, very disappointed indeed.
But my present, historian-of-science self is not disappointed at all. He loves this. Why? Because it was a “science” thing that was being banned. And banning a science thing, of course, means that talk of you-know-who is just around the corner.
From the web page of “On the Media”. Mikovits is seated.
Also on Friday the 15th, NPR’s “On the Media” show devoted a segment to “Plandemic” and its banning. Noting the #1 rank Mikovits’s book had achieved on Amazon, the show’s host Bob Garfield remarked (at about 8 minutes in to the segment),
One of the things that makes this video, I guess, effective is that Mikovits is portrayed as a victim, someone who has been silenced by “The Man”, a martyr to truth-telling, which I guess is a recurring theme in the conspiracy genre.... The more that the social media platforms take down the video, the more juice it has among its potential audience. They are boasting of how great it is that Facebook and Google are playing to the stereotype of powerful institutions.
Powerful institutions suppressing a renegade scientist. A martyr to The Truth. Surely you-know-who’s name is coming—it’s just a matter of when. And indeed, Kennedy’s foreword to Plague of Corruption opens with...
[Wait for it!]
And yet, it moves!
You-know-who has arrived.
Kennedy continues:
Galileo whispered those defiant words in 1615 as he left the Roman Inquisition tribunal before which he repudiated his theory that the Earth—the immovable center of the Universe according to contemporary orthodoxy—revolves around the sun. Had he not recanted, his life would be forfeit. We like to think of Galileo’s struggles as the quaint artifact of a dark, ignorant, and tyrannical era where individuals challenged government-anointed superstitions only at grave personal risk. Dr. Judy Mikovits’ story shows that stubborn orthodoxies anointed by pharmaceutical companies and corrupt government regulators to protect power and profits remain a dominant force in science and politics.
If this all just seems too scripted, right down to Kennedy getting the date wrong, well, it gets better. On that same Friday, May 15, “Science Friday” aired another segment, “Galileo’s Battle Against Science Denial”. This was an interview with astrophysicist Mario Livio, whose new book Galileo and the Science Deniers is just out from Simon and Schuster. I have just obtained a copy and begun to read it, but as the title indicates, the thrust of the book is to compare those who opposed Galileo to science deniers today. Those who opposed Galileo being, of course, Catholic Church flunkies. Interestingly, in his interview Livio echoes Kennedy to some extent, citing business and government interests as being part of what drives modern rejection of science, but Livio at least does not repeat the idea that Galileo said, “And yet, it moves!” NPR, apparently going for the “Plandemic” Trifecta this past week, also featured Livio and a discussion of “Plandemic” together on their May 19 episode of the show “The 1A”. Livio here remarked (about 2 minutes into the show) that those who rejected science in Galileo’s time were motivated by a literal interpretation of scripture, mentioning the Catholic Church and noting that “they tried to deny what he was saying”.
Of course, the fact is that those who opposed Galileo were not ignorant and not science deniers. Galileo was not—
punished when he proved
that the sun was sitting still
and the earth’s the one that moved.
He was not forced to recant what he could see with his own eyes. No one denied his discoveries. As I have discussed many times on this blog, Galileo’s opponents were not rejecting science or refusing to acknowledge obvious data in the name of religion, money, or whatnot. They had science on their side—the science of Tycho Brahe, the top astronomer of the time. Telescopes and Earth-bound experiments seemed to support Brahe’s ideas. The Copernican theory at that time had some weird features. Scientists today who take the time to look at the evidence available in the early seventeenth century and look at it through early seventeenth-century eyes will agree that the science was not with Galileo. (Needless to say, I do not think Livio has looked at things through early seventeenth-century eyes, but I will let you know for sure when I have read the whole book.) Those who condemned heliocentrism were not rejecting science for religion. They were rejecting science for science—condemning ideas that they believed were scientifically untenable (“foolish and absurd in philosophy”) and that were also counter to scripture (“and formally heretical”).
“Science Friday”’s two May 15 segments and “The 1A”’s May 19 show both illustrate a certain perverse hypocrisy of those of us in the science world. We promote this Galileo myth of the victim, the scientist silenced by “The Man”, the martyr to truth-telling. We are so attached to this nineteenth-century narrative that we just keep repeating it, even when historians of science have long since abandoned it. It is our contemporary orthodoxy, which we accept regardless of historical evidence to the contrary. And thus, we regularly reinforce one of the foundations of the science rejection conspiracy genre. And with the very same breath in which we do all this, we proceed to complain about science rejection conspiracy theories, and go through the motions to “fact check” their “falsehoods”. We are like the gardener who busily fertilizes the roots of some tough weed, while complaining vociferously about the weed, and plucking off some of its leaves here and there.
If we would be rid of the weed, we must dig it up by its roots. We can’t combat conspiracy theories about powerful institutions suppressing the truth in science when we constantly promote the Galileo myth about powerful institutions suppressing the truth in science at its very moment of birth! Attack the weed of conspiracy theory at its Galileo myth root. Provide a proper understanding of The Galileo Affair. Show how science actually worked in the seventeenth century, and how it actually works now. And then Kennedy might have to look hard for some other martyr figure to point to and get the date wrong. And it might be a whole lot harder to turn a book about conspiracy in science into a best-seller.
I am not going to hold my breath waiting on this. Sometimes it seems to me that science denialism is something we in the science world are all too willing to live with. We may complain about it, but in truth we are happy to have it, so long as we can ignore historical evidence and cling to our cherished orthodoxy about Galileo and how his ideas got banned by The Man, y’know, because, even though he proved that the Earth goes around the sun, y’know, that wasn’t what was in The Bible. And They could see the Earth moving right through one of those telescopes he invented, but They wouldn’t admit it. So They got him, y’know, and They broke him. Burnt him at the stake! But as he was going up in flames, he yelled “And yet, it moves!” So he showed them in the end, if y’know what I’m saying.
I guess maybe it gives us something to bond over with cousin Joey.
Kennedy’s foreword. The date he wants is probably 1633, not 1615.
Science and Water, Then and Now
You find science everywhere. During the early eighteenth century Spanish Franciscans established a series of missions along the San Antonio River in what is now the U.S. state of Texas. They ministered to the native Coahuiltecan people who lived there. The San Antonio Missions are today active Catholic churches in the Archdiocese of San Antonio, while also being part of the San Antonio Missions National Park, and a UN World Heritage Site. Thus, the missions are still there. And, as a film that introduces visitors to the San Antonio Missions emphasizes, so are the Coahuiltecans who built the missions with the Franciscans; their descendants live all over the area.
Artist’s conception of mission life, from a National Parks brochure on the San Antonio Missions.
One of the missions, Mission Nuestra Señora de la Purisima Concepción de Acuña, appeared in this blog last year (click here for that post) because the sun illuminates that church in an interesting way every Feast of the Assumption. However, as I noted in that post, while arranging that sort of illumination would have been an interesting scientific exercise, it would not have involved complex astronomical calculations. A more complex bit of science to be found at the missions is a very practical science that is still put to work in the San Antonio area today. That is the science of water management.
To irrigate the mission farmlands, the Franciscans and Coahuiltecans built dams, reservoirs and miles of open channels or acequias to carry the water from the reservoirs to the farmlands under the action of gravity alone. Getting water from one place to another in the area’s hilly terrain without the use of pumps required skill at mapping out the contours of the land and being able to determine a proper grade to follow around the hills. The grade would have to be steep enough for the water to flow sufficiently, but not so steep as to make the water rush too rapidly and erode the channels. This grade would have to be maintained as the channel was routed around hills.
In a slope, there is a certain amount of vertical drop (orange arrow) for every amount of horizontal distance (yellow arrow). A steeper grade has a greater drop for the same horizontal distance.
To get water from a reservoir behind the Espada Dam on the San Antonio River to the mission fields, the builders had to send the irrigation water above a natural stream. For that they built a stone aqueduct in the early 1740s—the only such structure in the U.S., according to a plaque at the aqueduct.* The acequia system served to provide water for farmers all the way into the 1950s. Some of that 250-year-old system still survives today, and still irrigates fields in the missions.
Illustration of the acequia system around Mission San Juan and Mission Espada, south of San Antonio, Texas.
While the mission acequia system itself may be less important than it once was, San Antonio still relies on a complex water management system—an acequia system of sorts. Visitors to downtown San Antonio can stay at hotels, eat, walk, and ride boats along the picturesque San Antonio River. But that river today is really just the product of the science of water management—its water level and flow are controlled by dams and a big underground bypass tunnel. When the river floods, the water is sent through the tunnel to bypass the vulnerable downtown. When there is low water in the river, the water is recycled through the tunnel—pumped back up to maintain the flow and level through the downtown. It is pretty complicated stuff. No doubt the Franciscans and Coahuiltecans who built the original acequias and aqueduct would be impressed. But they would understand how it all works, and the calculations that needed to be done to build it. The physics of water flow is the same now as it was then.
Check out all the water works, past and present, in the photos below.
Acequia water channels in action.
Mission San Juan, exterior and interior.
Various views of the aqueduct (that’s me in the center one), still carrying water over water.
Mission Espada.
Carrying water in a more modern manner: Left—downtown San Antonio around the San Antonio River. Right—part of the works that makes the river what it is.
The river looks very different downtown (left), where it is dammed and controlled, than it does south of town, where it can be seen as the small stream it really is (center). At right is the river in the 1950’s, prior to being reshaped.
Left—a map showing how the river once ran, compared to its man-made channel through downtown San Antonio now. Center—a diagram of the flood control tunnel. Right—the outlet of the tunnel in normal flow (top) and during a flood in May 2013 (bottom).
*All information on the acequias, aqueduct, and San Antonio River water management system, as well as diagrams, maps, and certain photos, comes from informative plaques along the river and in the missions.
Astronomy in Art & Architecture: R. A. Rosenfeld’s Astronomical History Christmas Cards
Greetings, Readers of Sacred Space Astronomy! Check out the astronomical art below. These are cards made by Randall A. Rosenfeld, who is the archivist for the Royal Astronomical Society of Canada. I’ve been fortunate enough to be on Randall’s Christmas mailing list for some years now, and have built up this small collection of original astronomical artwork as a result. He graciously gave the OK for me to share them with Sacred Space Astronomy readers. These scans do not look nearly as good as the originals, because the originals feature cool stuff like stars colored with metallic ink. A scan just will not capture that sort of thing.
Many of these illustrations are based on material found in historical books on astronomy. I have included links to the originals in many cases. Click on those links if you have time. I think that you will be glad that you did.
The card above is the most recent one Randall has sent out. It depicts the first documented instance of the use of a telescope for astronomical observation in what is now known as Canada, during a lunar eclipse on January 30-31, 1646. The astronomer who did the observation is a Catholic priest (and a Jesuit) so this is of course most appropriate for Sacred Space Astronomy. The astronomer is Fr. Francesco-Giuseppe Bressani, S.J. (1612-1672), at Sainte-Marie among the Hurons.
Randall writes:
There are no surviving contemporary images of Fr. Bressani. Well, if members of religious orders are encouraged to use founders as models, the iconography of a founder can provide a fitting model for a member without a surviving iconography. So, if you detect something slightly Ignatian about his appearance, you wouldn’t be wrong! His telescope is based on surviving French and Italian examples from earlier mid-century, and the method of mounting is that illustrated in works such as Hevelius’ Selenographia copper engraving between pages 40 & 41, and his Machinae coelestis copper engraving between pages 382 & 383. The lantern is based on Jan Collaert’s image (ca. 1600) of Amerigo Vespucci doing some nocturnal navigation. On Fr. Bressani’s table are a few mathematical instruments, in homage to the images of Clavius and Scheiner. The position of the Moon is as it would be near total eclipse from Sainte-Marie among the Hurons, as is its place among the few background stars depicted. The less than optimal sky with clouds is recorded in his observations. It is not recorded where at the settlement he observed, so I have placed him within the present reconstructed site.
The card below Randall sent to go along with the 2017 solar eclipse. It is too bad the metallic ink does not show up better in this scan. He says this card was inspired by eclipse figures in the copy of Cyprianus Leovitius’ 1555 Eclipses luminarium held by the Bayerische Staatsbibliothek.
Sticking with the theme of things passing in front of the sun, we see below a card featuring a transit of Venus. Rosenfeld made this one in 2010, anticipating the 2012 transit of Venus. He writes that it is probably like the arrangement Jeremiah Horrocks (1617 -1641) used to observe the 1639 transit of Venus (the first known observation and recording of a Venus transit).
Here is another featuring the moon (below). This one Randall based on an illustration from Johann Leonhard Rost’s 1723 Atlas portatilis coelestis.
The card below is in honor of the 150th anniversary of the December 1, 1868 founding meeting of what eventually became the Royal Astronomical Society of Canada. Randall writes:
Some of the material details allude to this; the chart tacked to the wall behind the table is copy of Steiler's 1860s version of Beer & Madler's famous lunar map (1837); the calendar is a dead give away(!); the portable inkwell, quill, and quill knife are copied from those of the 1860s; the paper on the desk has the beginning of the account of that first meeting; and the globe of Mars adds a bit of colour. The globe is a bit of a temporal cheat; Martian globes with canali don’t show up till several decades later, but its inclusion is a way of getting a little colour into the image. And it refers to the all-too-many amateurs in the RASC as elsewhere who were overly influenced by Lowell and Flammarion in the 1890s-1920s in what they affected to see at the eyepiece [namely, Martian “canals”].
The backs of the cards tend to feature some astronomical theme, with woodland creatures (always including a hedgehog). Below left is an example. It features a hedgehog in a rondel, patterned after images of St. George. Below right is the back of the Fr. Bressani card, and it has more astronomical references. Rosenfeld:
On the reverse of the card devoted to Fr. Bressani, the conversation of the hedgehog and beaver is concerned with time. The Beaver is acting as his own [sundial] gnomon, and he’s holding an 18th-century pair-cased watch. The hedgehog hopes it hasn’t arrived late (one of my traits), while it is revealed that a nuthatch of their acquaintance has made off with the printed equation of time that goes with the sundial. The hedgehog then cheerfully announces that they’re received a letter from “honest” George Graham, FRS (1673-1751), the superb clock and astronomical instrument maker who made the Rev’d Edmond Halley’s quadrant at Greenwich, and the Rev’d James Bradley’s zenith sector with which he discovered the aberration of light and the nutation (wobbling) of the Earth’s axis. All of which makes about as much sense as the average 18th-century opera libretto. But it allows me to have a bit of fun with the history of astronomy.
Rosenfeld’s background includes a first degree in medieval studies from St. Michael’s College in Toronto, then a M.A. in medieval studies at the Centre for Medieval Studies there, then a M.S.L. at the Pontifical Institute of Mediaeval Studies in Toronto. So… no degrees in astronomy, or art, or archiving! But he does have an asteroid: 283990 Randallrosenfeld (2004 SG2). And as for why he does the cards, Randall writes:
I’ve always liked the illustrations in astronomical incunabula, and their successors into the early-modern period and beyond, and thought it’d be fun to do my own versions as Christmas cards inspired by their iconography and style. The research before putting pen to paper can be interesting. And the time spent colouring them provides a spot of concentrated peacefulness at the end of Advent.
And that word “incunabula”? It refers to early printed books (from before 1501), like the Gutenburg Bible. So now you have seen some cool art, and, if you followed the links, you have had a look at some cool books from astronomy’s history.
Click here for all Astronomy in Art & Architecture posts.
Cutting Up: Math through Eyes of a Mathematician
Photo from Notre Dame.
Over time I have had the pleasure of introducing to readers of Sacred Space Astronomy guest bloggers who are scientists, bishops, and worship directors. Now I am pleased to introduce a mathematician. Jeffrey Diller is Professor of Mathematics at the University of Notre Dame (currently on leave, having finished up a term as chairperson of the Department of Mathematics there). He studies dynamical systems that arise in a complex analysis context. He also teaches: he was awarded the Fr. James L. Schilts, C.S.C./Doris and Eugene Leonard Teaching Award at Notre Dame in 2012, the Joyce/Kaneb Award for Undergraduate Teaching in 2015, 2008, and 2003.
Since I have been running a series of posts on the topic of mathematics, I wanted a mathematician to give a mathematician’ s perspective on what is great, and what is appealing, about mathematics. Jeff tells me that he became interested in the topic of this post in part out of his recent experience as coordinator for his kids’ middle school math club.
I have known Jeff since my freshman year in college (we shared a dorm room; I once won a cheap burger off him by checkmating his king on a specific square). He is the godfather of my younger son, and I am the godfather of his youngest son. He lives in South Bend, Indiana, with his wife and three sons.
Jeffrey Diller, 29 Jan 2020
The idea of cutting up and reassembling geometric figures for fun and profit goes way back in mathematics. For instance, there is my favorite argument for why the Theorem of Pythagoras is true. Here it is in purely pictorial form:
If this picture seems unfamiliar, then you owe it to yourself to spend a little time understanding what it says. This video might help:
Done? Then let’s move on to related problem. I get out a piece of paper and draw on it an equilateral triangle (i.e. one where all three sides have the same length). Then I hand you the paper and a scissors and ask you to cut up the triangle, along straight lines only, and reassemble the pieces into a rectangle. Can you do it? In fact yes, by mountaintop removal, as illustrated by the next picture.
A substantially more difficult problem is to cut up the triangle into pieces that can be reassembled into a perfect square. This time I leave you to think about how, observing only that the square you get should have exactly the same area as the triangle you started with.
These are particular instances of what are known generally as ‘scissors congruences’. Recall that a polygon is a two dimensional plane figure whose edge is a finite collection of straight line segments. We say that one given polygon is scissors congruent to another if it can be cut up into smaller polygons which can then be reassembled into the second given polygon. It turns out that two polygons are scissors congruent as long as they have the same area, though it is somewhat challenging to explain how in general and even more so to figure out how few cuts one needs to turn one polygon into the other. If you’ve ever messed with ‘Tangram puzzles’ (below), then you have some experience with scissors congruences.
Any good problem is worth generalizing, so if you are of the mathematical persuasion you might wonder what happens when you go from polygons in the plane to flat-sided three dimensional shapes (polyhedra) in space. If two polyhedra have the same volume are they scissors (machete?) congruent? The eminent German mathematician David Hilbert raised this question around 1900 in a notorious list of notable unsolved problems. His student Max Dehn answered it a year later: a perfect cube cannot be dissected into polyhedral pieces that admit reassembly into a triangular pyramid with all sides equal (a regular tetrahedron)—even if the cube and the tetrahedron both have volume 1.
In a little more detail, what Dehn did was to first give a recipe for combining all the angles in any polyhedron into a sort of weighted total angle and then show that this total angle isn’t changed when you cut the polyhedron up into pieces and reassemble them. Finally, he computed the total angle for the cube and the tetrahedron and showed that they were different. QED...
More than half a century later, mathematicians complemented Dehn’s result by showing that when different three-dimensional polyhedra have the same volume and the same ‘Dehn total angle’, they must be scissors congruent. That is, there is no other obstacle, beyond volume and Dehn’s total angle, to cutting up one in order to turn it into the other. Later still, researchers established a similar fact about four dimensional shapes, even in spaces that are in some sense curved one way or another.
A simple geometry problem has turned out to be the entrance to a rabbit hole, and even after much exploring, we haven’t come close to mapping out the depths of it. Analogues of scissors congruence have have been developed and shown relevant for problems quite remote from plane polygons. Just this year, two young mathematicians, Jonathan Campbell and Inna Zakharevich, made substantial new progress in the subject (click here for an article about their work; click here for the work itself), tying scissors congruence to a vast theoretical edifice known as homotopy theory.
Mathematics is like this. Attention given to simple puzzles is rewarded with access to an entire universe, neither entirely apart from nor entirely like our everyday world. Often enough, mathematics has been profitably applied to solve practical problems. But beyond any application there is also the sense that accompanies each leap in our mathematical understanding, each moment when a previously vague intuition about a problem crystallizes into something palpable and logically inevitable, of “arriving home and knowing the place for the first time.”
This post is part of a series of posts on Pi, infinity, and other things mathematical. Click here for the series.
A Tale of Two Cities (and two churches, and two hotels, and an observatory)
In 1934 Our Lady of Lourdes Church in West Baden Springs, Indiana was deemed structurally unsound, was pulled down, and was not rebuilt. A forest grows now where the church once stood. Revolving around Lourdes and its sister church, Our Lady of the Springs (still standing a mile or so down the road in the town of French Lick), is an interesting story about building a world we can live with. This story does involve some elements of what we usually think of as science—a Jesuit-run astronomical observatory is part of the story!—but it is mostly about science as considered more broadly: science as the process of looking carefully at the world around us and trying to measure it and to understand it and the rules by which it works, and to come up with ideas about it, on its terms, not on ours. It is a fascinating story, and one that may give us some good ideas for the future. But it is complex, not short, and best told with lots of pictures; so bear with me in this post, O Readers of Sacred Space Astronomy.
Left: Our Lady of Lourdes Catholic Church. Center: Pre-1930 aerial view of Lourdes (arrowed) and the West Baden Hotel, with a present-day view below. Right: Pre-1930 photo showing the church (arrowed) and the hotel, with present-day view below.
The “Springs Valley” in Indiana is a unique place. It is home to two very small towns—West Baden Springs (population under 600), and French Lick (population under 2000)—and two large, impressive hotels: the West Baden Springs Hotel and the French Lick Hotel. The existing hotel buildings date to the early 20th century, but since the mid-19th century hotels have existed on the spots these hotels occupy, thanks to a natural resource: the mineral springs in the Valley. Both hotels experienced decline; West Baden fell into partial ruin at one point. Both have experienced revival in the 21st century. Both are now fully restored, thanks to the actions of Indiana preservationists and investors; and at least up until the pandemic shutdown last month both had been operating quite gloriously, thanks to the establishment of a casino in French Lick (or “re-establishment”, as gambling was common in the area up through the first half of the 20th century). The Springs Valley towns are not part of a larger metropolitan area. Indeed, the Valley is surrounded on three sides by U.S. National Forest land. Therefore, while the hotels and casino are not the only economic engines in the area, they are big ones.
A key thing that makes the Springs Valley unique, then, is that in it are two small towns built around a vigorous economic infrastructure that dates to the early 20th century and before. Over time the Springs Valley has experienced economic highs and lows like much of the United States (and like other countries, too, I am sure). The U.S. is full of places where these highs and lows have involved jobs leaving and moving to sunbelt states, or to another country, or to a suburban industrial park. The result is often that the original structure of these places becomes hollowed out because of the economic lows. Sometimes that is re-built in other forms when an economic high arrives, but often no economic high ever arrives to match what once was, and the places remain hollowed out. In the Springs Valley, however, the jobs left—but then came back, right to the very same place.
Left: Our Lady of the Springs Catholic Church in French Lick. Right: A street view of French Lick. Arrows indicate Our Lady of the Springs and the French Lick Hotel.
Cornerstone of Macke Hall of Our Lady of the Springs. This photo is included because Br. Bob Macke, S.J. is an astronomer at the Vatican Observatory and a writer for this blog, and this stone honors Fr. Francis Macke, S.J. Any relation?
For all these reasons, a map of the Valley today looks a lot like a map made in 1951. There are differences. For example, the 1951 map labels the current West Baden Hotel as “West Baden College”. But the Springs Valley is a place that retains much of what was attractive about American towns in the mid-20th century. It is a pedestrian-friendly place of neighborhoods, where a family can live, work, shop for groceries, go to church (to Our Lady of the Springs if they are Catholic, but there are a number of other churches as well), visit a public library or their children’s schools (Springs Valley High School, famous as the home of basketball legend Larry Bird, is right in the middle of French Lick), and meet both familiar faces and new ones—all within a distance easily covered by a walk, or a short bike ride, or a quick hop on a trolley bus (or even a trolley—a restored one runs on rails between the two hotels). Here a kid can go to school, stay after for sports or a club, then stop by the library to say hello to a group of friends who are playing a group game on the computers there, then swing by Mom’s workplace to bug her, and then go home, all safely on foot.
Left: 1951 map of the Springs Valley. Right: Present-day satellite view.
Yet a closer look at that 1951 map reveals something remarkable: these sorts of neighborhoods in the Springs Valley are disappearing. Parts of both towns that in 1951 were full of homes are today full of grass—even places with a fine view of the Valley, or located a short walk from Our Lady of the Springs or the Valley schools. This phenomenon is not just something inferred from an old map—it can be seen directly, in Google Street View.
The 1951 map of West Baden Springs (left) shows a row of homes on the portion of the street indicated between the two arrows, but today those homes are mostly gone, and in their places are grassy lots (center). The homes remain intact on the portion of the street south of the lower arrow on the map (right).
This intersection in the photo (left) is indicated by the white arrow on the 1951 French Lick map (right). Were this photo taken in the mid-20th century, there would be a dozen more homes in the picture. This is just around the corner from Our Lady of the Springs (blue arrow on the 1951 map) and just a few blocks from the French Lick Hotel.
So why the disappearance of homes? I am not an expert on the area—only an occasional visitor. However, maps are data. Historical records like photographs (or payrolls or court documents or baptismal records) are data. Google Street View is data. So, taking a broad view of science as being looking at data on the world in order to understand the real world as it is, what follows is a “hypothesis” to explain the disappearing homes:
Google Street View images of the primary street in West Baden Springs show the disappearance of homes over a decade. The image on the left is from October 2008; the image on the right is from May 2018.
Another pair of Street View images of the same street, but at a different address. The arrows indicate the same home in both images.
The disappearing homes are the tail end of a long economic decline. Their disappearance is of the same sort as the disappearance of Our Lady of Lourdes. Lourdes had been built by Lee Wiley Sinclair, the owner of the West Baden Hotel that existed at the turn of the 20th century. The arrival of a rail line into the Valley in 1887 had caused the area to boom. Sinclair decided the hotel needed to have a Catholic church overlooking it, and in 1898 began construction on Lourdes (whose name was presumably chosen as appropriate for the “Springs”). The hotel burned to the ground in June 1901, but by December of that year Sinclair was constructing the remarkable circular brick-and-steel domed structure (the largest dome in the world for five decades) that stands today. It was quite the place, but the Great Depression brought an end to it. The owner of the hotel at that time, Ed Ballard, ended up giving the hotel to the newly-established Chicago Province of the Society of Jesus. The Jesuits turned the hotel into a seminary, called West Baden College. They even built a small astronomical observatory there. But just as the Jesuits were taking ownership, Lourdes was deemed to be structurally unsound, owing to water and erosion problems, and had to be pulled down.
Left to right: Jesuits at West Baden College; a section of the hotel, converted into a chapel for the college; that same section now serving as the front desk area of the hotel.
Left: The West Baden College observatory today. The dome has been removed and replaced with a conical roof. The structure is not being used as an observatory and has no instrument. Center: The observatory was abandoned after West Baden College closed in the 1960s. The dome, while in ruins, is obvious in this older photo. Right: the observatory and the West Baden Hotel today. The observatory was likely the project of Fr. Joseph R. Habes, S.J.; Fr. Habes wrote two articles for Sky & Telescope magazine, one in September of 1943, entitled “Saluting an Astronomer”, and one in October 1944, “Aristotelian Cosmology or A Romance of Manhattan”. He is identified in these articles as being from West Baden College. The observatory might have been outfitted with a 5” refractor. An Astromart advertisement from some years ago features “an old brass 5-inch F-15” for sale that had been “found in the attic at an old hot springs resort in Baden Springs, Indiana, that had been taken over by the Jesuit priests”. (The springs are not hot.) The advertisement says the telescope was found by a Fr. Carrera, “a priest who used to be at John Carroll University” who the seller believed was “still on the staff of the Vatican Observatory”. The observatory building is not large; it would be about right for a telescope of that size.
The Catholic connection to this hotel is surely an interesting story. Here was a Catholic church sitting above a popular, high-end hotel, at a time when the Ku Klux Klan was powerful in Indiana, and in the Springs Valley area. Luke E. Hart, a member of the Knights of Columbus (he would go on to lead the Knights a few decades later), while taking a train to French Lick in 1923, saw area roads lined with automobiles full of people returning from a huge Klan parade. The parade was in the town of Orleans, Indiana, located less than a dozen miles northeast of the Springs Valley. “The lights of the automobiles lit up the roads for miles and made quite an impression on the travelers on our train,” he wrote. He estimated that a thousand automobiles were on the road—this in a time when automobile ownership was not so common. No doubt this sort of Klan support was very intimidating to Hart, for the Klan was not just racist, but strongly anti-Catholic, anti-immigrant, and anti-Knights of Columbus. The area south and west of the Springs Valley is heavily Catholic, with Catholic churches dotting the farmland every few miles; definitely not Klan territory. The Valley seems to have sat on a cultural dividing line of sorts. Perhaps the construction of Lourdes (Sinclair was not Catholic himself), and the gift of the hotel to the Jesuits, were not matters of whim. I have not found any information on this, however.
In the mid 1960’s the Jesuits moved their seminary to Chicago, and the domed building became a campus of what is now Northwood University. Then in the mid-1980’s Northwood moved out. The building stood empty. Like Lourdes before it, it became structurally unsound—a whole section of it collapsed in 1991. But unlike Lourdes, it was not pulled down. It was eventually saved, and rebuilt, and since 2007 has been a functioning, high-end hotel, restored to full glory, but also fully modern.
The collapsing West Baden Hotel building—1991.
But for almost two decades the Springs Valley boasted a crumbling hulk instead of an economic engine. My hypothesis regarding the disappearing homes is that many homes suffered “deferred maintenance”, or were abandoned, despite being right around the corner from church, or having a fine view. They deteriorated beyond repair, and were pulled down, like Lourdes.
Left: The view of the Valley from the town of West Baden Springs (but note the many grassy lots). Right: The home with that view.
But Lourdes was not simply turned into landfill rubble. Its bricks and windows were re-used in the construction of St. Raphael Church, located in the town of Dubois (population under 500), a dozen miles southwest of the Springs Valley. St. Raphael boasts some very nice windows, thanks to re-use.
St. Raphael Catholic Church in Dubois, Indiana (left). Note the round window, visible in the photo of Lourdes (right).
Windows in St. Raphael. The one at left is the same window seen in the previous images.
And in a sense, re-use of existing resources is a central theme in this story. The West Baden Hotel was re-used—becoming two different colleges before becoming a hotel again. The economic infrastructure of the Valley has been re-used. Those now-grassy lots can be re-used, to again become neighborhoods for families who will be able to live, work, go to school, bug their parents, shop for groceries, meet familiar faces and new ones, and so forth. The Valley is not a “throw-away” society, or at least it is less of one than many places in the U.S. And sometimes not throwing everything away has benefits, such as some rather awesome windows in a church that probably would not have them were it not for re-use.
It is this re-use that points us to a world we can live with. We human beings do not make the rules by which the world runs. We can build in an unsound manner. We can build a church on an erosion-prone hillside, for example. But we will have to deal the consequences of doing so, of ignoring those rules. This is not a new idea:
Everyone who listens to these words of mine and acts on them will be like a wise man who built his house on rock. The rain fell, the floods came, and the winds blew and buffeted the house. But it did not collapse; it had been set solidly on rock. And everyone who listens to these words of mine but does not act on them will be like a fool who built his house on sand. The rain fell, the floods came, and the winds blew and buffeted the house. And it collapsed and was completely ruined.
But while we do not make the rules, through science we can aim to learn the rules (and not only through science), and to live with them. We can figure out how to build soundly things and communities that will serve well through changing times.
In the 21st century it seems that we have built much that is unsound. A result of this is that we have people that are mentally and physically unsound. Science and the media tell us of rising suicide and addiction rates, and falling life expectancies (and that was before COVID-19). We cannot easily measure those things for ourselves, until the problems become very dramatic, as they have for many people. Then we see them for ourselves. Science also tells us that the planet, too, is unsound as regards climate. Again, we cannot easily see this for ourselves, but if the science is right then in due course the problem will become sufficiently apparent that there will be no debating it. When a sizeable majority of people become personally convinced that a problem is real, to the point where they are wanting to act for the good of their grandchildren and children and themselves—not to just talk, or to vote for someone (who promises that government or big corporations will address this issue), but to take personal responsibility and act to change their own habits to address the problem—when that happens, the world will change, and quickly, as it has in recent months.
However, it would help to have an attractive model of what change might look like—of how to do things differently, but in a way that makes a change of habits look not so bad, and indeed, maybe even appealing. In this regard we might be served well by looking to a place that has figured out how to re-use existing resources and infrastructure, rather than to abandon the old and build anew elsewhere; to a place where a family can live, work, go to school, etc. within a short, safely navigable distance—allowing for a good life with less waste of resources, and less impact on the planet. My point here is not to return to the past (the 2020s need neither the coal-burning train engines nor the massive Klan rallies of the 1920s), nor is it to idealize a community (a casino is not something welcomed by all). My point is that it is possible to do things differently, in a way that has its appeal—a way that might suggest to us that changing our habits and getting on with the process of learning how to do things soundly, to do things in ways that we can live with, and that conform to the rules by which the world works, might not be so bad. The area that built and lost Our Lady of Lourdes is not the only place that can serve as a model for this, surely, but it is one place.
A statue of St. Ignatius (left) currently stands on the foundation of the old Lourdes church, overlooking the West Baden Springs Hotel (right).
A Lourdes plate in the French Lick West Baden Museum.
Information and photos for this post came from exhibits at the French Lick West Baden Museum and from the book Risen from the Ashes: The History of the West Baden Springs Hotel (Patrick O’Bryan, 2016).
Remote Access
The largest Herschel Telescope, built in the late 1780’s.
We are separate now. To slow this virus that plagues us, we maintain a “social distance” from whomever we can. We communicate remotely, through electronic technology.
Astronomers like me have used such technology for decades. Two centuries ago, we worked at our telescopes with our eyes. That is how William and Caroline Herschel worked. The brother-sister team built some of the first really large telescopes, and used them to advance astronomical knowledge significantly—all through eyeball work, done right at their telescope.
But today astronomers are often well separated from telescopes. Modern telescopes are located on remote mountaintops, or even in space. What they see is detected and communicated electronically to astronomers who can be quite remote from them.
This remoteness has brought about great gains in astronomical knowledge. Consider all that has been learned by the Hubble Space Telescope, which has been keeping its distance from us, in orbit around Earth, for three decades. Consider another, smaller orbiting space telescope, the Kepler satellite, which has discovered so many “exoplanets” (planets orbiting other stars).
But that same remoteness has brought about losses, too. William Herschel was the first to ever discover a planet: Uranus. He saw it in a telescope, but could also point out its location in the sky. Modern astronomers who see space telescope images on a screen sometimes can’t even point out the planet Saturn, visible up in the night sky. Students in school see lovely images of Saturn on screens, but they generally can’t find it in the sky either—and they are often both unaware that they can actually look up and see Saturn with their own two eyes, and unaware that they can never look up and see an exoplanet.
The wonder of remote communication technology led us to gain knowledge of exoplanets, which no one may ever truly see, but lose knowledge of planets in our own solar system that we can see, marvel at, and delight in our own personal discovery of. That trade-off may be worthwhile to astronomers, who may never care to see an object in person provided it presents an interesting problem for our study. But today, as we all sit separated from one another, do we find that seeing friends, family, coworkers, and our church community online is the equal of seeing them in person? Is a concert, a play, a ballgame, the outdoors, a hug, or the Easter Vigil still the same when experienced through a screen? After this virus is past, will all our best schools continue remote-only education, never going back to in-person classes, because school online is just so much better?
The Hubble Space Telescope, launched into orbit in the late 1980’s.
Remote communication may make space telescopes possible, but so often a screen is no equal to being there. When the virus is over, and we are no longer forced into separation, we will then have the opportunity to stop choosing separation—stop choosing to relegate so much of our lives to screens—and to value more our in-person hugs, plays, games, schools, and churches. And may we also value more things like being able to find the planets with our own two eyes, and watch them move through the sky as the weeks pass, and share our discoveries with someone, in person, who can see them with us. Separate is rarely equal, and ideas we study on a screen rarely compare to things we experience in person.
This post is a version of my April 16“Science in the Bluegrass” column for the The Record newspaper of the Archdiocese of Louisville, Kentucky.