Gregor Mendel started in the research that eventually would uncover the four fundamental laws of inheritance when he noticed that some traits in pea plants seemed to skip a generation. Percy Spencer was messing around with vacuum tubes, and noticed that in a certain configuration, they caused a chocolate bar in his pocket to melt -- further inquiry led to the invention of the microwave oven. French physicist Henri Becquerel discovered radioactivity when he accidentally ruined some photographic plates with what turned out to be a chunk of uranium ore. Alexander Fleming saved countless lives with the discovery of penicillin -- found because he wondered why a colony of mold on one of his culture plates seemed to be killing the bacteria near it.
I consider myself at least a little above average, savvy-wise, but I don't have that ability -- to look at the world and think, "Hmm, I wonder why that happened?" Mostly I just assume "that's the way it is" and don't consider it much further, a characteristic I suspect I share with a lot of people. In this vein, here's some research about something I've known about since I first started reading junior books on astronomy, when I was maybe ten years old, and never thought was odd -- or even worth giving any thought to.
There's a strange gap, something astronomers call "The Great Divide," between Mars and Jupiter. The distance between Mars and Jupiter is over twice as great as the diameter of the entire inner Solar System. In that gap is a narrow band called the Asteroid Belt -- and not a hell of a lot else.
Even more peculiar, when you think about it (which as I said, I didn't), is why inside of the Great Divide all the planets are small, dense, and rocky, and outside of it the planets are low-density gas giants (I do remember being shocked by the density thing as a kid, when I read that Saturn's overall density is lower than that of water -- so if you had a swimming pool big enough, Saturn would float).
[Image is in the Public Domain courtesy of NASA/JPL]
Well, it looks like the physicists may have explained the Great Divide in our own Solar System and the compositional difference of the planets on either side of it in one fell swoop. A team from the Tokyo Institute of Technology and Colorado University has found that the Great Divide may be a relic of a ring of material that formed around the early Sun, and then was pulled apart and essentially "sorted" by the gravitational pulls of the coalescing planets.
The authors write:
"Young stellar systems were often surrounded by disks of gas and dust," said Stephen Mojzsis of Colorado University, who co-authored the paper, which appeared in Nature. "If a similar ring existed in our own Solar System billions of years ago, it could theoretically be responsible for the Great Divide, because such a ring would create alternating bands of high- and low-pressure gas and dust. Those bands, in turn, might pull the Solar System's earliest building blocks into several distinct sinks -- one that would have given rise to Jupiter and Saturn, and another Earth and Mars.
"It is analogous to the way the Continental Divide in the Rocky Mountains causes water to drain one way or another. That's similar to how this pressure bump would have divided material in the early Solar System... But that barrier in space was not perfect. Some outer Solar System material still climbed across the divide. And those fugitives could have been important for the evolution of our own world... Those materials that might go to the Earth would be those volatile, carbon-rich materials. And that gives you water. It gives you organics."
And ultimately, it gives the Earth life.
Now, it bears keeping in mind that we can't generalize from this to other star systems. There have already been dozens of "hot Jupiters" discovered, gas giants that orbit close in to their host star; the wonderful astrophysicist Dr. Becky Smethurst mentioned just last week in her monthly "Night Sky News" video the discovery of an ultra-low-density "super-puff planet" that orbits so close that the physicists are scratching their heads trying to explain how the planet's light, fluffy atmosphere doesn't get blown away entirely. But the Mojzsis et al. paper seems to have taken a big step forward in explaining the configuration of planets in our own immediate neighborhood.
We propose... that the dichotomy was caused by a pressure maximum in the disk near Jupiter’s location... One or multiple such—potentially mobile—long-lived pressure maxima almost completely prevented pebbles from the Jovian region reaching the terrestrial zone, maintaining a compositional partition between the two regions. We thus suggest that our young Solar System’s protoplanetary disk developed at least one and probably multiple rings, which potentially triggered the formation of the giant planets.And once the process started, it accelerated, pulling dense, rocky material inward and lightweight, organic-chemical-rich material outward, resulting in a gap -- and an outer Solar System with gas giants surrounding an inner Solar System with small, terrestrial worlds.
"Young stellar systems were often surrounded by disks of gas and dust," said Stephen Mojzsis of Colorado University, who co-authored the paper, which appeared in Nature. "If a similar ring existed in our own Solar System billions of years ago, it could theoretically be responsible for the Great Divide, because such a ring would create alternating bands of high- and low-pressure gas and dust. Those bands, in turn, might pull the Solar System's earliest building blocks into several distinct sinks -- one that would have given rise to Jupiter and Saturn, and another Earth and Mars.
"It is analogous to the way the Continental Divide in the Rocky Mountains causes water to drain one way or another. That's similar to how this pressure bump would have divided material in the early Solar System... But that barrier in space was not perfect. Some outer Solar System material still climbed across the divide. And those fugitives could have been important for the evolution of our own world... Those materials that might go to the Earth would be those volatile, carbon-rich materials. And that gives you water. It gives you organics."
And ultimately, it gives the Earth life.
Now, it bears keeping in mind that we can't generalize from this to other star systems. There have already been dozens of "hot Jupiters" discovered, gas giants that orbit close in to their host star; the wonderful astrophysicist Dr. Becky Smethurst mentioned just last week in her monthly "Night Sky News" video the discovery of an ultra-low-density "super-puff planet" that orbits so close that the physicists are scratching their heads trying to explain how the planet's light, fluffy atmosphere doesn't get blown away entirely. But the Mojzsis et al. paper seems to have taken a big step forward in explaining the configuration of planets in our own immediate neighborhood.
All based on an observation most of us knew about, and very likely few of us had ever thought to question.
All of which brings to mind the wonderful quote by Hungarian biochemist Albert von Szent-Györgyi -- "Discovery consists of seeing what everyone has seen, and thinking what nobody has thought."
All of which brings to mind the wonderful quote by Hungarian biochemist Albert von Szent-Györgyi -- "Discovery consists of seeing what everyone has seen, and thinking what nobody has thought."
****************************************
