Category Archives: stardust

Comet Dust and the History of the Solar System

Comet Wild 2 Dust Studies

The history of the solar system is written on the surfaces of planets and moons, but can also be read in dust particles found in the clouds surrounding comet nuclei. How does this work?  Think back a few billion years, to when the solar system was first forming. We had a cloud of raw materials-gases, ices, and dust. You could (if you were around back then) take samples of that cloud material and do a chemical analysis on them. You’d determine the mix of elements and also the isotopes of those elements. (Think of isotopes as different forms of the same element. Chemists call them different “species.” So, you could have helium-3 or carbon-12 or carbon-13.) Study those isotopes and they can give you a lot of information about the timeline of history that our solar system experienced.

Comets formed pretty early in the history of the solar system, making them treasure troves of information about the chemical makeup of the gas and dust cloud that eventually birthed the rest of the solar system. So, it’s obvious why scientists send spacecraft (like the Stardust mission) to gather up comet dust: they can use it to fill in the gaps of our knowledge about how the solar system formed and what those early materials were. We know the big picture: that the rocky worlds formed close to the Sun, and that the volatile gases and ices that existed there were melted or driven off to the outer parts of the solar system (an icy deep-freeze that made a great home for gases and icy particles). Now scientists are examining the bits of dust that come flying off comets as they come close to the Sun in their orbits. And, those “bits” have interesting tales to tell.

Tiny crystals from the Wild 2 comet, captured by NASA’s Stardust mission, resemble fragments of the molten mineral droplets called chondrules, shown here, found in primitive meteorites. That similar flash-heated particles were found in Wild 2, a comet formed in the icy fringes of outer space, suggests that solid materials may have been transported outward in the young solar system. Photo by: Noriko Kita
Tiny crystals from Comet Wild 2 were captured by NASA’s Stardust mission. They resemble these fragments of molten mineral droplets called chondrules. found in primitive meteorites. That similar flash-heated particles were found in Wild 2, a comet formed in the icy fringes of outer space, suggests that solid materials may have been transported outward in the young solar system. Photo by Noriko Kita/Courtesy University of Wisconsin-Madison.

This week, a group of scientists led by Tomoki Nakamura, a professor at Kyushu University in Japan, publicized their analysis of oxygen isotope compositions of three crystals from the halo of Comet Wild 2. Their goal is to the origins of comet materials. Nakamura and University of Wisconsin-Madison scientist Takayuki Ushikubo analyzed the tiny grains – the largest of which is about one-thousandth of an inch across – using a unique ion microprobe in the Wisconsin Secondary Ion Mass Spectrometer (Wisc-SIMS) laboratory.This spectrometer is the most advanced instrument of its kind in the world.

The researchers were surprised to find oxygen isotope ratios in the comet crystals that are similar to asteroids and even the Sun itself. You have to ask yourself: how can this be, if comets formed well away from the Sun (and asteroids)?

Since these samples more closely resemble meteorites than the primitive, low-temperature materials expected in the outer reaches of the solar system, its entirely possible that heat-processed particles may have been transported outward in the young solar system, and eventually embedded in the icy nuclei of comets.

As you might imagine, this is stirring interest among planetary scientists. The findings complicate what used to be a simple view of solar system formation (that I described above).  What are these minerals doing in a comet that came to the inner solar system from out past the orbit of Pluto?  What sort of migratory patterns did early solar system materials follow? The answers will come from more studies of comet dust, and when they do, these little bits of ancient “stuff” will help revise and clarify the details in the theory of how the solar system grew and evolved. Stay tuned!

Of What Use is a Star?

A friend was telling me about a conversation she had with a family member who criticized her for studying science when “there’s so much more you could do with your life.” My friend asked the family member what the relative thought she should be doing, and the response was about like this: become a doctor, or a nurse—a profession that helps people. Another choice, as the relative suggested to my friend, was to settle down and have kids and forget all about science. When my friend pushed her relative on the subject a bit more, the real truth came out: the relative said that science was against religion and that when you compared the two, religion was always better.

Putting aside the obvious contradiction that becoming a doctor or a nurse does require one to study science (actually become a scientist of the body), the idea that one can compare science and religion—even without the clearly biased opinion of the relative—seems like comparing apples and rocks. In other words, there’s no comparison.

But, I got to thinking about the subtext of the relative’s concerns (again, aside from the clearly sexist assumption that a woman studying science should really be home having babies, something which I’ve always thought is a choice best left to the woman in question), and I see another meaning here. What the relative might really have been asking is “What good is your science?” In other words, what good is astronomy? What use does it have? To a person unschooled in science, or even afraid of it, those are important questions.

But, they’re also fair questions, provided you don’t go around looking for answers that aren’t biased for or against the study of science. It’s a question that I’m sure lots of government officials and elected representatives ask whenever they see a federal budget that includes so many dollars for astronomy research.

HST Looks at Polaris
HST Looks at Polaris

Let’s drill down a little more, though, and ask “of what use is a star?” That’s something that astronomy helps us discover. And, in uncovering the use of a star, we discover links to … ourselves!

From the surface of our planet, the star looks like a point of light. It might be part of a constellation, a star pattern in the sky.

Polaris (which we all know is the North Star for at least a few thousand more years) helps us determine where north is in the sky, in essence, which direction the north pole of our planet is pointing. If we study Polaris’s light through special instruments (spectrometers or spectrographs), we can tell what its chemical makeup is; that is, what chemical elements are in its atmosphere. We can also find out, as HST did, more information about its companion star.

So, in this case, a star is a pathfinder for directions on our planet, and it can tell us something about itself. As we study more stars, we find that they all seem to have some things in common: they were born in clouds of hydrogen gas, they shine (and we can measure their luminosities and use those measurements to tell us how far away they are), and they have different sizes and colors. The sizes and colors tell us something about their masses, compositions, and their life cycles.

HST studies young stars in nearby galaxy
HST studies young stars in nearby galaxy

The more stars you study, the more you learn about the environments in which they’re born. What are their birthplaces? Gas and dust clouds, called nebulae. We find them throughout our own galaxy, and as the image above shows, we see them in other galaxies, too. Throughout their lives, stars enrich their environments by blowing stellar winds rich with elements into interstellar space. When they die, they recycle themselves. Other stars form from the interstellar gas and dust clouds that are left behind when a star dies. And, some of those stars form with planets around them. In our case, the Sun formed from the debris of ancient, long-gone stars. Without the remnants of star death, our star, and particularly our planet, would not have been possible. And, as you may have heard, life on our planet contains atoms that first existed in stars. As Carl Sagan once said, “WE are star stuff.”

Galaxies themselves form from the coalescence of smaller galaxies (dwarfs) of stars, and each star in those galaxies goes through the same birth, life, and death processes that we’ve observed in our own Milky Way Galaxy.

And, the earliest stars that ever shone, more than 13 billion years ago, lit up the universe in a sort of cosmic “first light” that has been reverberating across the light-years ever since.

The technologies we use to study stars are important. Not only do they let us look to outer space for answers, but in some cases, those machines and the computer chips and sensors they use, also benefit humans in many ways. The most obvious use I can think of off the top of my head is the example of sensors built for the Space Telescope Imaging Spectrograph. It turns out they’re also useful for imaging breast cancers. I find that quite poetic: that technology humans developed to look at light from distant objects is also helping humans, who are, after all, part of the cosmic dance that produces galaxies, nebulae, stars, planets, and humans.

So, of what use is a star? Look at your hand, your arm, the face of your loved one, and tell me how poor the universe would be if stars hadn’t formed, lived, and died, leaving their remains to provide the building blocks of more stars, our planet, and eventually, the life upon it.