Everything Everywhere Daily: History, Science, Geography & More - Fantasy Nobel Prizes: Isaac Newton
Episode Date: March 27, 2021Isaac Newton is one of the most important scientists in the history of the world. His discoveries have impacted almost every aspect of physics, and a huge part of the first two semesters of any physic...s course is dominated by his discoveries. It raises an interesting question: If Nobel Prizes were given out when Newton was alive, how many would he have won? Join me as I play fantasy Nobel Prizes with Sir Isaac Newton on this episode of Everything Everywhere Daily. Learn more about your ad choices. Visit megaphone.fm/adchoices
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Isaac Newton is one of the most important scientists in the history of the world.
His discoveries have impacted almost every aspect of physics,
and a huge part of the first two semesters of any physics course is dominated by his discoveries.
It raises an interesting question, however.
If Nobel Prizes were given out when Newton was alive, how many would he have won?
Join me as I play Fantasy Nobel Prizes with Sir Isaac Newton on this episode of Everything Everywhere Daily.
What if your perceptions about the past,
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In a previous episode, I went over the number of Nobel Prizes that Einstein could have won or should have won,
assuming they gave out posthumous awards. This was a relatively easy exercise insofar as Einstein actually did win a Nobel Prize,
and I was able to limit to the discussion, mostly to things that did win a Nobel Prize, but Einstein just didn't get credit.
For Newton, this exercise is much more difficult.
Isaac Newton died in 1727, and the first Nobel Prizes weren't given out until 1901.
Moreover, the world of science was really different in the 17th century compared to what it was in the early 20th century.
Newton was making discoveries in very basic things compared to later discoveries.
He was, in fact, picking the low-hanging fruit in the world of physics.
Nonetheless, it was Newton that did it.
he laid the foundation on which science is still being taught today.
So, because this is such a theoretical exercise,
I'll define something as Nobel Prizeworthy
if it's a discovery that was a significant advance in science,
or if it allowed for significant advancements in science.
Because I'm doing this almost 300 years after Newton's death,
I have the benefit of hindsight to see which of his advancements have stood the test of time.
Let's start with one of Newton's biggest accomplishments,
and the one which might cause the most controversy in this discussion, calculus.
As I noted in my previous episode on Who Invented Calculus, Newton certainly invented calculus
independently, but he never publicized it. The controversy lies in the fact that there is no
Nobel Prize for Mathematics. However, there have been prizes given out for the development
of techniques that allowed science to advance. For example, the 1993 Prize in Chemistry was given
to Kerry Mullis for his development of the Polymeries chain reaction technique for DNA replication.
The PCR technique was vital for the advancement of all genetic science.
So in that vein, we'll give Newton a Nobel Prize for calculus, as all subsequent physics
is dependent on calculus.
Nothing else would really exist without it.
It's that important.
This isn't just solving a mathematical problem like Fermaz's theorem.
It was developing an entire branch of mathematics.
And for the record, he'll share this theoretical Nobel Prize with Gottfried Leibniz,
who is considered the coadventure of calculus.
In the same vein, we'll give Newton a second Nobel Prize for the development of the reflecting telescope.
Every single optical research telescope built in the last 100 years is a reflecting telescope.
And I'll refer you to my previous episode on telescopes.
The Hubble telescope, the Kek telescope, the Grand Telescope of Canarias,
have all been reflecting telescopes.
All extrasolar planets have been discovered with reflecting telescopes.
Every planet and planetoid in the solar system was discovered with a reflecting telescope.
Basically, modern astronomy doesn't exist without Newton's reflecting telescope,
so you have to give Newton Nobel Prize number two.
Now we can start getting into his actual scientific discoveries,
and the first thing you have to recognize are his three fundamental laws of motion.
His first law is the law of inertia.
His second is the equation force equals mass times acceleration.
His third law states that every action has an equal and opposite reaction.
There's a lot more to it, but that's the summary of the three laws.
That these are fundamental is beyond no doubt.
The real question is, how many prizes do we award?
I think the answer is three, and I've gone back and forth on it.
Each of these is so fundamental that any one of them had they been discovered by
someone else would have put that person in the history books.
So I'll award Newton three more Nobel Prizes for his three fundamental laws,
because they are quite simply fundamental.
The next theoretical Nobel Prize would be awarded for his work on the theory of gravity.
Newton basically laid down the understanding of this thing called gravity.
He made sense of the observations made by Galileo, Kepler, and Copernicus.
As he described it, quote,
every particle of matter attracts every other particle with a force along a straight line joining them,
and it is directly proportional to their masses,
while inversely proportional to the square of the distance between them.
Again, this one is incredibly obvious,
and it would be theoretical Nobel Prize number six.
Next would be Newton's groundbreaking work with light.
Newton's work with light was mostly experimental.
His biggest discovery was that light was made up of different
colors. He was able to separate white light into colors with a prism and then recombine them
back into white light. His work with light probably wasn't quite as foundational as his work
with gravity and motion, but it was still extremely important and for the 17th century was
revolutionary. So that's seven Nobel Prizes so far. Number eight would be for Newton's Law of
Cooling. His law of cooling states, quote, the rate of heat loss of a body is directly proportional
to the difference in temperature between the body and its surroundings.
This law of Isaac Newton laid the foundation for the entire study of thermodynamics.
Theoretical Nobel Prize Nobvreys number nine would be given for the explanation of Newtonian fluids.
Newtonian fluids are fluids like water.
A Newtonian fluid's viscosity remains constant no matter the amount of shear applied at a constant temperature.
A non-Newonian fluid changes its viscosity when a force is applied.
You can find great videos on YouTube of people walking quickly across non-Newtonian fluids like cornstarch mixed with water.
The initial force of a step on it causes the viscosity of the fluid to increase very briefly,
allowing you to walk over it if you walk quickly.
If you stand still, then you'll just sink.
The fact that these are called Newtonian and non-Newtonian fluids should give you an idea as to the importance of Isaac Newton's contribution.
He probably would not be awarded this prize by himself.
There are many other scientific fields that Newton influenced, but it's hard to grant him a prize because he didn't actually do anything in those fields.
For example, there are laws in electricity and magnetism, which are very similar to Newton's gravitational equation.
They were clearly inspired by Newton, but Newton didn't actually do anything with electricity or magnetism.
Likewise, he was the first person to theorize an artificial satellite, but it was really just an application of his gravitational theories.
There is, however, one more Nobel Prize that he probably would have earned.
The final Nobel Prize, however, isn't for science.
It would be in economics.
Newton didn't spend most of his life working on all the scientific discoveries I listed.
He spent most of his life working on things like alchemy and trying to decipher biblical prophecies.
He also had a very prestigious job for over 30 years as the head of the royal mint.
At the time, England and other countries had a problem with coin clipping.
This is where people would shave off the edges of a coin.
They would keep the shavings, which were made of the same precious metal,
and then try to pass on the slightly smaller coin.
Newton oversaw a new coinage system in England, where the coins had milled edges.
These are small serrations on the edge of a coin.
Many coins still have these today, including the U.S. quarter and dime.
The edges ensured that if anyone tried to clip the coin, it would be very obvious because the milled edges would be removed and the coin would become smooth.
This might not sound like a big deal right now, but for the 17th century, it was a huge deal.
It was a landmark in stopping coin debasement and inflation.
So, 10 potential Nobel Prizes is pretty good.
It's one less than what I gave Einstein, but I can't think of many people who would be awarded more things.
theoretical Nobel Prizes than Sir Isaac Newton.
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