Kepler Galileo and Newton Kepler: determined the motion of the planets. Understanding this motion was determined by physicists like Galileo and Newton and many others. Needed to develop Physics as a science: understand motion, forces, and gravity 1
Galileo and the physics of motion Studies of motion important: planetary orbits, cannonball accuracy, basic physics. Galileo among first to make careful observations, develop concepts velocity, acceleration, effects of friction pendulums, use as clock (Galileo not quite successful) rate at which objects fall do not depend on their mass (ignoring friction) acceleration of falling bodies is a constant 2
Galileo and Motion and Gravity Galileo and many of his contemporaries developed the concept of motion - velocity and acceleration - importance of friction Galileo used inclined planes (Florence museum) and (perhaps) the Leaning Tower in Pisa 186 ft high, 296 steps 3
Speed vs Mass according to Aristotle, heavier objects fall faster then light objects The heavier (green) ball will hit the ground before the lighter (red) ball Experiments showed Aristotle was wrong. Pure thought not the best way to do science 4
Motion: velocity and acceleration MOTION: concepts acceleration = change in velocity either speed or direction. accelation = dv/dt change in velocity per unit time Change in velocity depends on forces exerted. Cause acceleration. Gravity causes downward acceleration 10 m/s vs 20 m/s 10 m/s to right vs 10 m/s down. 5
Speed vs Mass vs Acceleration Experiments done by Galileo and others showed that the heavier (green) ball and the lighter (red) ball hit the ground at the same time Galileo also showed that the gravitational acceleration was a constant 32 ft/sec/sec Theories based on experimental observations are best way to do science. http://nicadd.niu.edu/~hedin/galileo.htm - fake news story Hammer+feather on moon:https://www.youtube.com/watch?v=5c5_doeyafk Or https://er.jsc.nasa.gov/seh/feather.html 6
Newton 1642-1727 : Motion and Gravity Started from earlier concepts and measurements of motion - Kepler s Laws on planetary motion - Galileo determination that acceleration at Earth s surface was a constant independent of mass Developed calculus and so provided mathematical tool to relate acceleration to velocity to position Developed his 3 law s of motion to relate acceleration to the applied force Developed form for gravitational force. Demonstrated it. was universal (same everywhere) 7
Newton s Laws of Motion 1. Body continues at rest in uniform motion in a straight line unless a force is imposed on it. (Inertia) 2. Change of motion is proportional to the force and is made in the same direction. F = ma Force = mass x acceleration acceleration= change in velocity per time If F=0 than a=0 and velocity (and direction) stay the same 3. To every action there is an equal and opposite reaction (action depends on mass and velocity and is related to momentum) For this course be able to apply to Kepler s Laws 8
Forces in Nature Gravity Electromagnetism Strong Nuclear Force Weak Nuclear Force 9
Gravity the first force to be understood was gravity Newton used results from Galileo, Kepler and others on motion on Earth s surface and orbits of the planets gave simple relationship for gravitational force between 2 objects separated by distance R F G mass mass 1 R 2 2 10
Gravity (Newton) There is a force between any two bodies 1 and 2 F = G m 1 m 2 /r 2 with m 1 and m 2 being the masses and r being the distance between 1 and 2 Always attractive Depends on the masses of the two bodies Decreases as the distance increases Is the same force everywhere in the Universe Weakest force but dominates at large distances 11
Gravity Examples Body A on surface of Earth with mass m A F A = G m A m Earth /r 2 Earth If object B has a mass 10 times that of object A, the Force of gravity is 10 times larger on B But F = ma or acceleration = Force/mass so the acceleration due to gravity is = G m Earth / r 2 Earth Does not depend on mass so all objects have same acceleration (ala Galileo). Does depend on mass, radius of Earth G is universal constant 12
Surface Gravity Acceleration due to gravity at the surface of any planet is g = G m planet /r 2 planet different planets, different surface gravity Mars: mass = 0.11 mass(earth) and radius = 0.53 radius(earth) so g(mars) =.11/.53 2 g(earth) or about 40% that of Earth Impacts escape velocity from given planet (or moon) and what type of atmosphere planets have 13
Planetary Orbits Gravitational force between Sun and planets causes orbits with D being the planet s distance from the Sun Force = G m Sun m planet /D 2 orbit as a = F/m = G m Sun /D 2 does not depend on the planet s mass, all objects the same distance from the Sun will have the same orbits. Also true for orbits around other objects (Earth, Jupiter) - means satellites around Earth can have similar orbits even if different masses 14
Kepler s Laws Kepler s Laws can all be derived from Newton s laws of motion and force of gravity gravity causes elliptical orbits where planet moves faster when closer to the Sun as force of gravity is larger there Third Law actually D 3 =(Msun + Mplanet) x P 2 D=distance from Sun and P=period weaker force further away gives longer period As mass Sun much larger can mostly ignore mass planet (but Sun does move slightly due to planet s pull) 15
Orbital Periods Study orbital preriods get masses - planets around Sun Sun s mass - Jupiter s moons around Jupiter Jupiter s mass Also used for stars (more on this later) - two nearby stars orbiting each other their masses - an exoplanet orbiting a star will cause the star to wobble a bit can give mass of exoplanet see some animations at (from wikipedia) http://nicadd.niu.edu/~hedin/162/center.html 16
Planetary Orbits Trojan points have stable points in planetary orbits - also called Lagrange points 17
Trojan points of Jupiter One asteroid found at Earth s Trojan point. See 162 webpage 18
LIGHT Visible light, infrared, UV, radio are all types of Electromagnetic Radiation. They differ by having different frequencies different colors EM Radiation is caused by accelerating electric charge (usually electrons since they are the lightest) Being accelerated Photon radiated (light) Electron emits light Electron absorbs light 19
Electromagnetic Force There is a force between any two bodies 1 and 2 F = Cq 1 q 2 /r 2 with q 1 and q 2 being the charges and r being the distance between 1 and 2 Both attractive and repulsive Depends on the charges of the two bodies Decreases as the distance increases Is the same force everywhere in the Universe Stronger than Gravity but average charge usually equal 0 Electricity and Magnetism are different aspects of the same force 20
Electromagnetic Force Example: Rubbing a balloon on your hair or a cat builds up excess electrons on the balloon which can then stick to a wall, or even better, to a cat 21
Light is a bunch of photons EM radiation or EM waves wavelength (l) = distance between waves Period = time between wave peaks Frequency (n) 1/period = how rapidly wave is changing So 60 Hz = 60 Hertz = 60 beats per second is the same as a period of 0.016 seconds Can use either wavelength or frequency to characterize light frequency proportional to energy E = hf velocity = wavelength X frequency sound = 1 mile/5 seconds light = 1 mile/5 microseconds = 300,000 km/sec 22
high energy high frequency low energy low frequency 23
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Continuous Spectrum Radiation of light due only to Temperature of object All frequencies Peak of frequency spectrum depends on Temperature wavelength max = 3,000,000/T with wavelength in nanometers and T in Kelvin Total energy emitted E = sigma x T 4 sigma=constant 25
Temperature Temperature Velocity Energy At higher Temps higher velocities more acceleration of electrons more light emitted Kelvin Scale Absolute 0 = 0 0 K = -273 0 C = -459 0 F at high T Kelvin and Centigrade about same 26
EXAMPLES normal, incandescent light bulbs T=5000K people T=300K infrared campfires, stoves T=600-1000K, start to glow red low energy photons high energy 27
Discrete Spectrum spikes at specific frequencies Depends on which atoms are present Examples include fluorescent or Neon or Mercury lights Can be used to identify chemical composition of objects (spectroscopy) 28
Atoms and Energy Levels emission lines can tell one atom from another in this case Hydrogen from Mercury from Neon 29
Atoms and Energy Levels An atom is a nucleus surrounded by electrons held together by the electromagnetic force Electron can be in different energy states Changes in energy states (Quantum Leaps) produce discrete spectrum 30
Hydrogen Simplest atom just one electron and one proton heavy hydrogen or deuterium adds one neutron to the nucleus 31
Atoms and Energy Levels 32
Hydrogen lines For Hydrogen, the lines in the visible spectrum are transitions to the n=2 (Balmer) Those to the n=1 are in the UV (Lyman series) 33
Transitions between different atomic energy states either emit or absorb light The energy of the light (the photon s frequency) is equal to the difference between the atomic energy states Pattern of photon frequencies tells what atom is emitting the light E(photon) = hf H = Planck s constant F = frequency 34
How fluorescent light works Tube filled with Mercury and Argon gas Initial HV heat up gas Argon plasma moves electrons in Mercury to higher energy levels electrons fall to lower energy levels and emit UV light UV light absorbed by phosphor coating on walls and is reemitted at lower energy, with mix of colors that appears white 35