Some people ask the question "Of what
good is math?" What is the relationship between math and
physics? Well,
sometimes math leads. Sometimes physics leads. Sometimes they come together
because, of course, there's a use for the mathematics. For example, in the
1600s Isaac Newton asked a simple question: if an apple falls then does the
moon also fall? That is perhaps one of the greatest questions ever asked by a
member of Homo sapiens since the six million years since we parted ways with
the apes. If an apple falls, does the moon also fall?
physics? Well,
sometimes math leads. Sometimes physics leads. Sometimes they come together
because, of course, there's a use for the mathematics. For example, in the
1600s Isaac Newton asked a simple question: if an apple falls then does the
moon also fall? That is perhaps one of the greatest questions ever asked by a
member of Homo sapiens since the six million years since we parted ways with
the apes. If an apple falls, does the moon also fall?
Isaac Newton said yes, the moon falls because of the Inverse Square Law. So
does an apple. He had a unified theory of the heavens, but he didn't have the
mathematics to solve the falling moon problem. So what did he do? He invented
calculus. So calculus is a direct consequence of solving the falling moon
problem. In fact, when you learn calculus for the first time, what is the first
thing you do? The first thing you do with calculus is you calculate the motion
of falling bodies, which is exactly how Newton calculated the falling moon,
which opened up celestial mechanics.
So here is a situation where math and physics were almost conjoined like
Siamese twins, born together for a very practical question, how do you
calculate the motion of celestial bodies? Then here comes Einstein asking a
different question and that is, what is the nature and origin of gravity?
Einstein said that gravity is nothing but the byproduct of curved space. So why
am I sitting in this chair? A normal person would say I'm sitting in this chair
because gravity pulls me to the ground, but Einstein said no, no, no, there is
no such thing as gravitational pull; the earth has curved the space over my
head and around my body, so space is pushing me into my chair. So to summarize
Einstein's theory, gravity does not pull; space pushes. But, you see, the
pushing of the fabric of space and time requires differential calculus. That is
the language of curved surfaces, differential calculus, which you learn in fourth
year calculus.
So again, here is a situation where math and physics were very closely
combined, but this time math came first. The theory of curved surfaces came
first. Einstein took that theory of curved surfaces and then imported it into
physics.
Now we have string theory. It turns out that 100 years ago math and physics
parted ways. In fact, when Einstein proposed special relativity in 1905, that
was also around the time of the birth of topology, the topology of
hyper-dimensional objects, spheres in 10, 11, 12, 26, whatever dimension you
want, so physics and mathematics parted ways. Math went into hyperspace and
mathematicians said to themselves, aha, finally we have found an area of
mathematics that has no physical application whatsoever. Mathematicians pride
themselves on being useless. They love being useless. It's a badge of courage
being useless, and they said the most useless thing of all is a theory of
differential topology and higher dimensions.
Well, physics plotted along for many decades. We worked out atomic bombs. We
worked out stars. We worked out laser beams, but recently we discovered string
theory, and string theory exists in 10 and 11 dimensional hyperspace. Not only
that, but these dimensions are super. They're super symmetric. A new kind of
numbers that mathematicians never talked about evolved within string theory.
That's how we call it "super string theory." Well, the mathematicians
were floored. They were shocked because all of a sudden out of physics came new
mathematics, super numbers, super topology, super differential geometry.
All of a sudden we had super symmetric theories coming out of physics that then
revolutionized mathematics, and so the goal of physics we believe is to find an
equation perhaps no more than one inch long which will allow us to unify all
the forces of nature and allow us to read the mind of God. And what is the key
to that one inch equation? Super symmetry, a symmetry that comes out of
physics, not mathematics, and has shocked the world of mathematics. But you
see, all this is pure mathematics and so the final resolution could be that God
is a mathematician. And when you read the mind of God, we actually have a
candidate for the mind of God. The mind of God we believe is cosmic music, the
music of strings resonating through 11 dimensional hyperspace. That is the mind
of God.
Watch the video
Michio Kaku
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