Submitted by maugustus t3_zyricz in askscience
As I understand it, Newton posited the gravitational force. Prior to this, what was/were the dominant explanation(s) for why things fell toward earth?
Submitted by maugustus t3_zyricz in askscience
As I understand it, Newton posited the gravitational force. Prior to this, what was/were the dominant explanation(s) for why things fell toward earth?
I'd also add that people more versed in metaphysics thought all things tend to move to their natural state, which for things being on earth
To expand on this, Aristotle believed that all matter was made up of a mix of four different elements: fire, air, water, and earth; in that order. Things wanted to return to their natural place.
The Sun was above the air of the sky because fire was naturally above air. If you created a fire here on Earth, one of the effects was that sparks would rise, and this was seen as the element fire naturally seeking its place above the air.
Rain was element water that got above element air, and wanted to be beneath it. That's why rain fell. Your average objects, like a rock or a piece of metal, would fall because they were made of element earth. Thus they were naturally attracted to earth, and if they find themselves unsupported in element air, they will naturally fall.
This is one of several reasons the heliocentric theory took so long to catch on, despite being proposed as far back as the ancient Greeks. The existing conception of physics described above fits quite nicely with a geocentric universe, but doesn't mesh at all with a heliocentric theory. You need a whole new sort of physics (like gravity) to make sense of that.
Incidentally, this also means that Earth's position at the "center of the universe" in the geocentric theory wasn't quite as special as we sometimes think today. The earth was at the center, but the center wasn't necessarily seen as the "best" spot, it was more at the bottom of the cosmic pile, the place where all the dirt falls down to. The outer regions, aka the heavens, were often considered the "best seats" (due to their association with, well, heaven). There was often thought to be a "Fifth Element" (yes, the movie got its name from this idea) that inhabited the highest reaches away from earth and was what the stars and planets were made of.
This also means that the movement of the planets was seen as a fundamentally different sort of thing than the movement of apples. Apples were following the nature of earth, going toward the center. Planets were following the nature of their element, moving in perfect, ordered circles in the heavens.
It was in Aristotles lifetime that the first greek was born to propose a heliocentric theory. I suggest you learn more about greek physics before you profound such errors.
If you suspend what we obviously know, that was actually a very cleverly thought out theory. Really interesting to see how people thought and understood things back then.
Seems like it’s a good example for how a totally wrong conceptualization of a situation can still be very congruent with what you can observe easily
Yeah, and if we have done it once we are probably doing it again, right now.
Very very true. Nowadays many promonent physicists stake their careers on stuff like String Theory or Multiverse Theory, when neither have any direct evidence to back these up, other than "the math makes sense". That's why it's very refreshing when you hear scientists in places like CERN say "we hope we're wrong because that means we get to make new physics". And also why this year's Nobel Prize for Physics is a big deal: they managed to prove Einstein wrong as well.
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Oh wow thanks! I always wondered why the natural state of stuff was considered near the ground...
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Really interesting, thanks!
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Also in this conception, water is above earth, so if you drop a stone in a lake, it will seek the earth. But wood is made of air and fire (and a little tiny bit of earth), so it floats. And burns....
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The bit about Aristotle is not quite correct, that's a very Newtonian way of describing his theory. He was working within a Teleological framework, basically the idea that everything has a goal, an essence, that it's moving towards. Part of this is that like things move towards like things, so it's the 'earth' element in things that makes it move towards the earth, not due to some force but because that's where it's goal is.
To elaborate. Aristotle believed that the earth element strove to be at the centre of the universe, water strove to be above earth, air above water, and fire above air. There was no concept of a force pulling everything together as in Newtonian physics.
While I do see the philosophical distinction, this is still very Newtonian to me. Very interesting.
It's fundamentally very different. In Newtonian physics there's an attractive force that causes for instance a rock to fall down to the earth. In Aristotelian physics there's no attractive force, but the rock strives towards the earth and therefore falls down towards it.
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There's two things Newton did here, one was understanding that things accelerate under a force. For the apple to start falling there needed to be some force acting on it and that force was equivalent to the mass of the object times it's acceleration, which, it put another way, was that the apple was accelerated towards the earth by an amount equivalent to the force acting upon it divided by it's mass.
The second thing was gravity. So what force was acting upon that apple? It was the force of Gravity! That force was proportional to the masses of the two objects divided by the distance between them squared.
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Side note: notice that when you take the force of gravity and divide it by the mass of the object being acted upon, the apple, to find out how it's accelerated, the mass of the apple will cancel out by division; and so it doesn't matter of the gravity of earth is acting on apples or bowling balls, the force is the same!
The first is important because under the Teleological framework things had an innate motion towards some ideal state and from this we can start to appeal to faith to divine what things want to move towards. Under Newton's laws things only move when acted upon by some force being applied to them. The second is important because it defines gravity of massive objects as the force that moves objects towards the ground on earth and what keeps the planets orbiting the sun and the moons orbiting their planets rather than the hand of God or some other ideal. Why is this important? It means we can predict natural phenomena rather than appealing to prayer. We can predict the tides, and predicting the tides was really really useful in an age where shipping was economically critical.
Before Newton there were some attempts to predict the tides but they didn't have anywhere near universal success and so people might as well appeal to faith or superstition as they might anyone else who is only sometimes correct. Newton was reliable in his prediction to a point it became hard to ignore... but we've wandered off OP's question here.
>it doesn't matter of the gravity of earth is acting on apples or bowling balls, the force is the same!
Think you swapped a word here: the *acceleration* is the same - the force is proportional to mass.
Newton wasn't the first to think the Earth was pulling on the apple. He was the first to realize the apple was pulling on the Earth too.
And that the same force from the Earth was pulling on the moon. His was a theory of universal gravitation. Universal is the important idea.
Yeah. People figured out "earth pulls stuff". He blew it open to "all stuff pulls all other stuff"
> His mathematical equations/proofs showed that the same force that made apples fall to the earth was what made the planets move
I wouldn't say "what makes them move"--he understood momentum, and what gave planets their momentum is not defined by his gravitational theory. (I would assume he described the initial velocity as divinely created.) Gravity just describes why they orbit.
Isn’t Einstein’s gravitational theory more accepted now?
General Relativity is regarded as the accurate description and cause of gravitation, but the Newtonian formulation is a very good approximation in most cases.
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This isn't correct beyond a surface reading.
We know that quantum mechanics and general relativity cannot both be correct, because they conflict with each other.
But more probably, it seems like both are incomplete. There's a lot of unexplained stuff in space too - like dark matter, where some people propose a modified set of gravitational laws to explain motions instead introducing dark matter (which has never been measured). Very theoretical of course.
But we also have been completely unable to add any sort of gravity to quantum mechanics at all. The accepted models of QM more or less ignore gravity entirely because its power is negligible at quantum scales anyway.
What we know is that the extremes - extremely tiny scales, extreme velocity, extreme gravity - has complicated laws of nature, which happen to trend towards simpler forms as conditions approach everyday life. But you can't really conclude anything else based on that.
> Some physicists are questioning if General Relativity is totally accurate. It's a great approximation, but Quantum Theory may be an even better description of the Universe.
This is just nonsense. The two theories are describing entirely different things. Describing "the entire universe" is outside the scope of general relativity, which only describes gravity. Meanwhile, describing gravity is outside the scope of most Quantum Theory, and those that do include gravity lead to inconsistencies - or even worse, contradictions.
What’s the difference between inconsistencies and contradictions?
I would be careful taking these kinds of ideas too seriously. This starts to get too close to metaphysics for my liking, and I don't believe any physicist genuinely believes or could verify this if they wanted to. It's akin to quantum woo in my mind.
Also, as the other poster already said, saying "quantum theory" is a better description of the universe is nonsense; they describe entirely different things. Although it is no secret they are incompatible as of now, this just indicates one or both may be incomplete but not entirely wrong.
>Some physicists are questioning if General Relativity is totally accurate.
No physicist has ever thought that GR is totally accurate, not even Einstein. We've known from the very beginning that GR and QM are incomplete.
>The simulation has limits so the extreme edges "break" the rules.
What rules does it break? The universe is under no obligation to obey human intuition.
>It is possible the universe is the same way...
That's absolutely nothing to suggest that it is. We humans evolved to have an intuitive understanding of the world we interact with; therefore, we should expect physics to diverge from our evolved intuition when we go beyond humans scales - namely, the very small, very large, very vast, very hot, very rarefied, etc. Go beyond STP and scales of metres and seconds, and we should expect to hit counterintuitive results.
It would be more indicative of a contrived simulation if we didn't encounter edge weirdness.
Well yes and even a little bit humoristically according to relativity there is no real gravitational force existing between objects. Mass is just bending and curvature of the spacetime. So the bigger object the more curvature on the fabric of spacetime and smaller objects fall in to them, because of the curvature. In the end Newton was actually wrong with gravitation.
It's important to note that Newton also defined the modern concept of 'Force'. The concept does not appear in preNewton works.
The man didn’t have to come up with the idea/notion of some gravitational force. It was the formulaic derivation and idea that multiple seemingly-unrelated phenomena were indeed governed by the same thing which made him a straight thug.
He put numbers to it which required developing calculus and building on Galileo's and Brahe's/Kepler's observations.
The important thing is that he wasn’t trying to work out why apples fell from trees, if there is any truth to the legend at all, he was just inspired, by an apple falling, to come up with gravity.
More people should read “The Structure of Scientific Revolution” by Kuhn. There really are no sudden breakthroughs in science, at least as the general public tends to understand, it’s always some kind of gradual change or a collective buildup of many ideas over periods of time.
When it happens, it’s always evolution. In hindsight the stories are always told like it’s some sudden new idea.
I'd like to add that Newton and his contemporaries founded modern science -- the worldview that there is actually an objectively correct explanation for natural phenomena, and we can work on finding that out through thought and experimentation.
You will have noticed there are still many people today who don't hold that worldview, sadly; but in Newton's time and earlier, this described pretty much everyone outside of a select few, who were often considered heretics, witches, that sort of thing for their troubles .
Truth was what the church said it was and most people didn't have the concept of thinking about why apples fall, they just did. A large part of what Newton is remembered for is the notion of investigating this kind of thing at all .
(NB. My comment is Eurocentric like the question ; attitudes may have differed in other civilization centres ).
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The idea that something falling in a straight line/perpendicular to the earth is the same force that keeps the moon running parallel to it…still so surprising to me that someone (or multiple people) realized that
Newton actually saw a limitation of his theory in the motion of mercury since it requires relativity to explain its motion.
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How profound an effect would simply giving a modern physics textbook to Newton be?
>“earth” element pulled things towards the center of the universe
Actually, in a sense, that seems correct. I don't know much about this stuff, but it sounds like, if it wasn't the mysterious expanding force, all the matter might have a tendency of pulling each other back into the origin of the universe.
Sometimes I wonder how those ancient Greek philosophers predicted so many things. I guess we owe them a lot, and also the Renaissance people, who I heard saved many writings from those ancient times. The whole science sounds like built on them.
There was for a long time the Aristotelian nonsense about objects seeking out their natural resting place, but, by the time of Newton, Galileo had dealt a pretty lethal blow to that. Probably the fairest answer is that we were at the beginning then of a modern scientific understanding of the world, and that a coherent model of what caused things to fall to the ground as we understand it now probably didn't really exist then. I could be wrong-- particularly with respect to the advances that were taking place outside of Europe-- but it seems like science before this period was largely about illustrating a beautiful, rational order ordained by God, rather than finding rigorous models that could explain natural phenomenon: Science was still a branch of philosophy. People like Galileo, Copernicus, Newton, etc, aren't giants simply because they corrected long-running misperceptions about things, but because they introduced a fundamental paradigm shift into how we think about the world and ask questions about it.
They didn't have good math either. Newton (and others) made up calculus, but not just that.
Even the abstract notation of polynomials and equations, by using letters to represent variables, was kind of new in Newton's time. This was due to Viete, in XVI century, and I would guess it was one of most important inventions for math and science ever.
Imagine how it was to study equations by saying "the double of the square of a quantity plus three times the same quantity is equal to 5"
I got into physics because of Einstein, but I'm pretty well convinced Newton now was the real boss. If he were here today, he'd still be making groundbreaking contributions. Also worth mentioning his eureka moment was not realizing gravity was responsible for apples falling to the ground, but realizing that one and the same thing could explain that, the orbits of planets and ocean tides. The popular picture we have of him doesn't do him any justice at all.
Newton wasn’t they only person working on Gravity. Robert Hooke (and others) developed a lot of the theoretical backing for Gravity. He just didn’t know Calculus so he couldn’t connect theory to observations. Imo, the popular picture of Newton is largely of his own design; he used his position of power to take credit for things like Calculus and Gravity and downplay those who help contribute.
Gravity like most discoveries wasn’t divined in a single moment by a single person but was dozens of astronomers, physicists, and mathematicians asking questions and pushing the boundaries of our understanding. Newton once said he was standing on the shoulders of giants because he couldn’t have made the discoveries he did without those before and around him.
That's actually a fair point, and, I'll admit, I occasionally fall into the habit of believing in the light of a single genius still: That's pretty much never true. Thank you for the correction.
"If I have seen further, it is by standing on the shoulders of giants." - Newton
Newton was the one who really pulled everything together in a fundamental way. Barrow (his advisor) developed a lot of Calculus as did Fermat and Descartes before him and Barrow suspected the fundamental theorem of Calculus but it was Newton who proved it (to the standards of the day) and that was the key to confidently solving differential equations. While the problems of differentiation and integration are what we think of as Calculus that's not really what it's about, it's really about solving differential equations and that's what Newton advanced and then applied to problems of physics of the day.
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> objects seeking out their natural resting place
Isn’t this what gravity is anyway?
IIRC the Aristotle viewpoint was something like, all things are pulled towards the center of the universe, with different elements floating on top of others in the order: earth < water < air < fire (sun) < aether (cosmos).
If you're a video gamer, I highly recommend checking out Odyssey - The Story of Science, an educational game which goes into detail about the "what"s and "why"s of what people believed about the cosmos before modern times, and how each of those theories was disproven.
Not really pulled, more like, each element has its natural place, and it’s essence is to find its proper place. There was no force to do the pulling or floating, it was instead an essential property of a the element itself to organize in this way.
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Best understanding of gravity that exists today is it's a warping of space and time around a massive object that causes objects moving around it to deviate from straight line motion when seen from an observer far away. Not sure how you could massage that into an Aristotelian explanation. I'm also not an expert of Aristotelian physics, which is why I left it at that, but one of the consequences I understand from it was that heavier objects should fall faster than lighter ones, which is the thing Galileo disproved.
That's not Newton's gravity, that's Einstein's relativity. Newton's simply posited that massive objects pulled things to them, not that they warped space-time.
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Well, not just gravity but everything seems to seek its lowest energy state.
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Your question is the wrong way round. The concept of gravity being the force that makes apples fall is ancient. Before Newton, we knew that gravity makes the apple fall, but we didn't know what held the earth, moon and sun in a stable system.
What Newton did was to extend idea of gravity to the heavens. He did this by realising, and then mathematically proving, that the thing making apples fall is the same thing that holds the sun, moon and earth in a system.
This is what it was called 'universal gravitation'.
Or to put it another way: Newton realized that as the apple fell to the earth, the earth also fell towards the apple!
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His proof was deriving equations that at the time sufficiently let you describe both behaviours.
Another point here: there was a fairly widespread belief that the moon, stars and planets were not affected by gravity in the same way as “an apple”. The concept of spherical (as in heavenly) material being fundamentally different was still considered roughly accurate. What Newton did using the new calculus (not getting into who came up with calculus in the first place) was provide a physical and mathematical model that would allow for an apple falling, and a moon stating in orbit, without positing that the moon behaved fundamentally differently.
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If you don't get an answer here, you can also try /r/askhistorians, /r/historyofscience, /r/historyofideas or perhaps /r/philosophyofscience
Science is today not about why it's about how . That's a huge difference and the split started around that time. This split is what allowed modern science to exist before this there would be great discussions about why a stone should move where . Newton s work is all about measuring and equations, why something falls whether it's God's will or the Natural resting place of the stone doesn't matter so you can move on to measuring how fast or how predictable which is way more useful
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Newton formally linked the ideas of mass, acceleration, and weight, as well as the idea that weight and force are the same thing, and also linked force to the idea of changing momentum. He did all of this within a unifying theory of mathematics that relied on his fancy new tool that we would call calculus.
Now, there were other scholars in his day that had achieved bits and pieces of this already, but he brought it all together under a single unifying scheme and added significant portions of mathematical analysis to it (that allowed us to make novel predictions about the world and other worlds), so he's the one we remember. (It also helps his fame in the Western world that he wrote it in Latin, which was the scholarly gold standard of the day)
But the truth is we more or less understood how gravity works (mechanically, that is) since roman times, and newton didn't answer the "why" for us really anyway. What Newton really did was give us a formal mathematic definition of gravity that could be applied robustly to most physical situations humans can observe under one very large tent of mathematics. He allowed us to agnostically apply one set of laws to a whole host of situations that were not obviously connected. This, more than anything else, was his contribution to science.
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in newton's time, astronomers had figured out that the earth and other planets go around the sun.
what they didn't understand is why. obviously the sun illuminated the planets, but what made the planets go around it? one illustration showed angels pushing the planets in their orbits. another idea was maybe the sun was magnetic. newton's revelation was that gravity, which made apples fall, was the same force that made the planets orbit the sun.
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Apples fall because they're ready to fall, and they're heavy. The glass fell because it was heavy, and it was on the edge of something and got shaken or pushed off. No further explanation needed in the minds of 99% of people. Feathers fall slowly because they're so light the air blows them around first. Things fall towards the ground because the ground is the stopping point for everything. Imagine if things fell towards the sky or the nearest tree. The world just wouldn't work. Therefore, they fall to the ground.
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Newton did you not prove gravity made apples fall. That's only half of the story... What he DID show is that the same force that makes apples fall is (partly) the same force that keeps the moon up in the sky. He ended up explaining that the mass of things and the distances between them determine how gravity affects them....
The key to Newton wasnt just the theory, but the math that supported it. People used to say lots of different things about all sorts of Natural phenomena. Often with things like "Its Gods Will" Or some other divine or supernatural explanation.
Well, in scientific language the maths *is* the theory. You mean "not just the hypothesis", right?
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Navvana t1_j2820m2 wrote
The answer will depend on how far back you want to go.
Way back with Arisistotle it was basically thought that the “earth” element pulled things towards the center of the universe.
From there many individuals separately began to describe this attractive force that pulled stuff to the earth, and even began to calculate/quantify it.
So it’s not really true that Newton came up with the idea of a “gravitational force” in the sense of some sort of law of nature that made apples fall from trees.
What Newton did was develop a law of universal gravitation that could actually be applied to everything. At least everything up until we started seeing relativistic effects.
His mathematical equations/proofs showed that the same force that made apples fall to the earth was what made the planets move, and that the force was at least correlated with mass. Prior to Newton the two were not unified, and many thought they were separate phenomena.