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A short presentation about Newton and his Gravity.
Citation preview
1/17/13
1
Standard units of mass, length and 7me
Kilograms (kg) Meters (m) Seconds (s)
Astronomical masses and distances are o?en very large, e.g. the mass of the Sun is:
2,000,000,000,000,000,000,000,000,000,000 kg
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Frequently use the mass of the Sun as a convenient unit of mass:
Sun itself has mass 1 MSun Most massive stars are about 100 MSun Milky Way center black hole 4.5 million MSun
For distance use light year the distance light travels in one year, or parsec:
1 parsec (pc) = 3.26 light years
Recall three squared is wriTen 32 = 9, three cubed is 33 = 27 etc
Write large or small numbers as powers of 10:
10 = 101
100=10x10=102
1,000=103
1,000,000=106
2,000,000=2x106
number of zeroes following the rst digit
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Recall three squared is wriTen 32 = 9, three cubed is 33 = 27 etc
Write large or small numbers as powers of 10:
0.1=1/10= 10-1
0.01=10-2
0.001=10-3
0.002=2x10-3
number of zeroes preceding the rst non-zero digit
1 MSun = 2 x 1030 kg 1 parsec = 3 x 1016 m
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Nicolaus Copernicus (1473-1543) planets orbit the Sun, not the Earth
Johannes Kepler (1571-1630) planetary orbits are not circles, but ellipses, described by simple laws
Galileo Galilei (1564-1642) discovered the moons of Jupiter orbital mo7on is universal
Forces cause accelera.on
F = maGravity is a force: same force on Earth extends to the Moon explains the Moons orbit about the Earth gravity also explains planetary orbits
Gravita7onal forces: propor7onal to mass: 2 x m = 2 x force decrease with distance squared: 2 x d = force
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d
M m
F = GMmd2
G is Newtons gravita7onal constant: measures how strong gravity is
Newtons theory of gravity is unbelievably successful
Explains the mo7ons of the planets almost perfectly, used to model spacecra? trajectories, collisions between galaxies
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Features of Newtonian gravity
Mass is used to refer to two (in principle) dis7nct concepts
The strength of the gravita7onal forces a body creates
How resistant it is to being accelerated by a given force (its iner7a)
Features of Newtonian gravity
Mass is used to refer to two (in principle) dis7nct concepts
A gold bar and a lead bar that have an iner7al mass of 1 kg produce the same gravita7onal forces too
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Speed of light
Ole Roemer (1676) es7mates the speed of light by 7ming transits of Jupiters moons
Light has to travel extra distance, transit appears late
Speed of light
Modern value:
~182,000 miles / s ~300,000 km / s 299,792,458 m / s
(Roemer was about 20% o the right value)
In Newtonian gravity, the speed of light, denoted as c, has no special role force between Earth and Sun, say, is communicated instantaneously
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Escape velocity
Forms of energy before Einstein included: kine7c energy (associated with mo7on) thermal energy poten7al energy (with posi7on)
Conserved: sum remains the same
Escape velocity is smallest v that gives enough energy for a body to escape to very large distance (innity) without falling back under gravity
Escape velocity
R
v
Launch a projec7le, mass m, with velocity v, from surface of Earth (distance R from center of Earth)
Kine7c energy = m v2
Gravita7onal poten7al energy
= GMEarthm
R(nega7ve: if I fall toward Earth kine7c energy increases, poten7al energy must become more nega7ve to conserve energy)
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Escape velocity
If Kine7c + Poten7al energy = 0 (or more), escape
12mv
2 GMEarthm
R = 012mv
2 =GMEarthm
R12 v
2 =GMEarth
Rv 2 = 2GMEarthR
v = 2GMEarthR
For the Earth, the escape velocity is 25,000 mph or 11,200 m/s
Dark Stars
Imagine light was just like a projec7le launched with some speed c (the speed of light!) from a star of mass M. How compact would the star be to trap the light?
vesc =2GMR set equal to c
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Dark Stars
vesc =2GMR set equal to c
c = 2GMRc 2 = 2GMRR = 2GMc 2
a star smaller than this would be a dark star, even light cannot escape
Dark Stars
John Michell (1784)
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Dark Stars
How big is this? For an object the mass of the Sun, the cri7cal radius is:
R = 3 km
R = 2GMc 2very small because c is so large
Dark Stars
This argument depends on seeing light as par7cles that respond to gravity just like regular projec7les
Experiments at the start of the 19th century convinced physicists that light was instead a wave
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Dark Stars
Michells crude concept of a black hole (and, as it turns out, correct es7mate of what we now call the Schwarzschild radius), was forgoTen