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Units 11-20: The Newtonian Revolution and the Discovery of Natural Law

Units 11-20: The Newtonian Revolution and the Discovery of Natural Law. Ptolemy vs. Copernicus: earth in a natural context Tycho Brahe’s observations Kepler and the planetary laws Galileo: the telescope, foundations of mechanics Newton and the foundation of western science

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Units 11-20: The Newtonian Revolution and the Discovery of Natural Law

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  1. Units 11-20: The Newtonian Revolution and the Discovery of Natural Law Ptolemy vs. Copernicus: earth in a natural context Tycho Brahe’s observations Kepler and the planetary laws Galileo: the telescope, foundations of mechanics Newton and the foundation of western science Maxwell and the laws of electromagnetism 20th Century physics; relativity, quantum mechanics

  2. Motions of the Planets • Back in the old days, planets pretty much WERE astronomy. Stars didn’t seem to DO anything, except rise and set. And galaxies, nebulae… invisibly faint and undiscovered. • Greeks LOVED circles. Even made a semi-religion out of them. The Pythagoreans - Insisted the Universe was based on the perfect circle and integer numbers. But…

  3. Jupiter in retrograde loop

  4. Retrograde Motion: About once a year, the planets go backwards! • For fans of simple, uniform, circular motion, this was a problem. • But the Greeks were true scientists – they didn’t sweep inconvenient facts under the rug. How to account for this while preserving the appeal of an earth-centered universe? • There were actually some good reasons initially to favor an earth-centered solar system…

  5. If the Earth were in fact moving around something else… • … we’d see the stars undergoing a reflex motion called “parallax”. • Careful (but crude by today’s standards) observations showed no parallax motion during the year. • So: Either (1) the earth is motionless with respect to the apparently fixed stars, or (2) the stars are so vastly far away that their parallax motion is undetectably small. • The Greeks went with (1). Doh!…. They were wrong! – they should’ve gone with door #2!! • Let’s continue with the historical progression and explore how the earth-centered model persisted for a really unfortunately long period of time…

  6. Ptolemy – Greek (Egyptian) Astronomer 100AD made first decent quantitative model of the planets’ motion • It had the Earth at the center • Accounted for retrograde motion with epicycles. Then needed to offset the center of epicycles. Then needed epicycles on top of epicycles… • Taken literally, it was ugly. But mathematically, it was brilliant!

  7. Ptolemy epicycles scheme

  8. Ptolemy: Dogmatic, or Innovative Mathematical Modeler? • We don’t exactly know. History took his idea and went off in a very bad direction. • But some evidence suggests that he was agnostic on where the center of the solar system was. He just wanted the simplest, most concise calculation device for determining the positions of the planets – BIG success here! • His construction is essentially what we would call today a Fourier de-composition of the motions of the planets, and this is still to this day the most efficient way to calculate planetary positions for many moderate-accuracy situations.

  9. But! Aristarchus ~600BC First Deduced the planets orbited the sun, not the Earth • His reasoning is not known – original writings are lost • Now, the Greeks had no authoritarian religious problem with a sun-centered universe. But, • They reasoned if the earth orbited the sun we should see parallax motion in the stars. They didn’t, and so thought the earth must be at the center… Very unfortunate decision, as luck would have it.

  10. The Ptolemaic Model Became the Official “Truth” for Many Centuries • Why? • What else was going on around ~100AD.......?

  11. The Rise of the Authoritarian Mindset! THAT’s what! • Ptolemy introduced his model at the time of the rise to power of the Christians in western civilization. • The earth-centered model was in line with their belief that the Earth is the center of God’s universe and God’s attentions. It became dogma… to be challenged only at the risk of being “re-educated” in, for example, the dungeons of the Inquisition • Fear is a bad ingredient to introduce into the quest for knowledge. Progress… stopped.

  12. There followed 1,500 years of intellectual stagnation – or worse – in the West • In the 1550’s Nicholas Copernicus challenged the Church with his realization that the motions of the planets could be understood much more simply if all planets revolved around the sun…

  13. Retrograde why

  14. Was it just a matter of symantics as to who got to be called “the center of the solar system?” • Or, is there an observational test which rules one way conclusively? • Enter… Galileo

  15. Galileo

  16. Galileo’s Telescopic Discoveries • Heard about the invention of the telescope by Hans Lippershey in 1610, and immediately ground his own lenses and built the first astronomical refracting telescope. • Got him into MAJOR trouble with the Catholic Church, which pretty much ruled western civilization at this time and for a millenium prior. • He looked through his telescope and saw…

  17. Mountains and Craters on the Moon! • But, the church taught the moon was this perfect orb placed by God to light our nights. How DARE Galileo claim it was scarred with pox marks and mountains like this sinful earth? • Heresy! • Bummer. Well,how about the next discovery…?

  18. Sunspots! • Black spots with irregular borders that grew and changed, much like malignant melanoma (skin cancer). • But, the Church said the sun was this perfect orb placed by God to light and warm our days. How DARE Galileo claim it was scarred by ugly cancerous spots! • Heresy! • Bummer! how about the next discovery…?

  19. Four Moons Orbiting Jupiter! • Orbiting Jupiter?! But the Church taught that the EARTH was the center of the Universe… how DARE Galileo claim these moons circle Jupiter and not us! • Heresy! • Everyone now… “Bummer!”… Galileo is clearly getting in pretty deep. Well, what about the next discovery?

  20. Venus Showed All the Phases that the Moon Did! • The Church wasn’t as upset with this. But, they should’ve been – it’s the most fatal of all to the Church’s cosmology, as Galileo knew. Let’s see why, on the white board…

  21. Copernicus’ “De Revolutionabus” was an Underground Hit! • Now the race was on – perfect uniform circular motion, even in the sun-centered model, didn’t reproduce the measured positions of the planets accurately. • What is the True Shape and True Motion of the planets? To answer, we first need GOOD DATA! • Enter… Tycho Brahe

  22. Tycho Brahe – Danish Astronomer of late 1500’s • Discovered the supernova of 1572, showed it was far beyond the planets – the first non-planet to be shown to be something other than fixed and constant. • King of Denmark impressed, gave him an island and money for the best scientific instruments of his day • He read Copernicus, his goal: find the true orbits of the planets. • He was an OUTSTANDING observer. Measured the precise positions of the planets, especially Mars, every clear night for 20 years, with an accuracy of +- 1 arcminute (!) • But he was a mediocre mathematician. No problem – he had the money – he hired one!

  23. Kepler picture

  24. How did Kepler determine the shape of the planetary orbits? He was Very Clever! • Kepler’s data was a table of times and positions of the planets. • He figured, let’s start with a promising planet and once we’ve figured it out we can then streamline the work on the other planets. • Let’s try and decide which would be a good choice for a first planet totackle…

  25. Kepler’s 1st Law • Planets orbits in ellipses, with the sun at one focus • OK… so what’s an ellipse, and what’s a focus??...

  26. Kepler’s 1st law

  27. Drawing an ellipse

  28. Kepler’s 2nd Law • Often called the “Equal Area Law” • The sun-to-planet line sweeps out equal areas in equal times • Pick any time interval you want. The sun-planet radius sweeps through the same area during that time interval, regardless of where it is in the orbit. • This law is an example of a more general rule – Conservation of Angular Momentum

  29. Kepler’s 2nd law

  30. AngMom definition

  31. The Meaning of Angular Momentum • Imagine something moving around an orbit, or maybe around its own axis of rotation. Now imagine how much work you’d have to do to STOP that angular motion. That’s a good feel for its Angular Momentum.

  32. A weblink animation showing an object in a Keplerian Elliptical orbit which can be varied

  33. We’re Now Almost Ready for Newton’s Discoveries… • Newton built on the experiments of Galileo: • Galileo dropped objects from the Tower of Pisa to see how they fell… • --The rate of acceleration of falling objects is a constant. 32 ft/sec per second, or about 10 meters/sec per second. • -- Objects fall at the same rate, regardless of their mass, temperature, color, composition… • --This violated the Church (again! Doh!!) • Measured the rate of swing of pendulums, found it was the same regardless of the amplitude of the swing

  34. More Trouble Making from Galileo: His Experiments • Aristotle taught “gravity – the tendency of heavy things to fall”, and: heavier objects will fall faster than lighter objects. • Is that right? Pretty easy to discover by yourself…

  35. Newton’s 3 Laws of Motion • These are more general than gravity. They’re the basis of the branch of physics called… • Mechanics – how objects move when under the influence of forces

  36. Newton’s 1st Law • The Law of Inertia • An object will remain in it’s same state of motion unless acted on by a force • A revolutionary idea at the time, as Aristotle (the Church’s chosen physics authority) taught “The natural state of motion of an object is to be at rest” • But, the 1st law is really a special case of a more general law…

  37. Newton’s 2nd Law • The acceleration an object experiences is directly proportional to the force acting on it, and inversely proportional to the mass of the object • Acceleration = Force/Mass • In plain English – heavier things are harder to push up to speed, and the harder you push, the faster it’ll accelerate. Your intuition should serve you well here!

  38. Newton’s 3rd Law • Forces between objects are always felt mutually; equal and opposite • Often called the Law of Equal and Opposite Reactions • In plain English… when you push or pull on something, it’ll pull or push back equally

  39. Newton’s Laws of Motion and common observations of the moon allows us to make a good guess at the Law of Gravity • Let’s follow his reasoning. Sit under the apple tree with Sir Isaac and ponder…

  40. Confirmation of the Law of Gravity • Newton realized that if gravity held you and me to the earth, and held the moon in orbit, it was a short jump to infer the planets were held in orbit by gravity from the sun. So… • Kepler’s Laws (which still were unexplained) must be derive-able by pure reasoning from Gravity and the laws of motion. • Not easy – had to discover the branch of mathematics called “calculus” first. That was his summer vacation of 1666.

  41. Kepler’s 3rd Law as Derived by Newton • Kepler’s 3rd Law is P2=ka • Newton’s derivation of this law looked like this… • P2 = 4p2a3/G(m1+m2) • Did somebody goof? Why don’t they look the same???

  42. The Tidal Force • Not really a new force; it’s an aspect of gravity. • Gravity is stronger when closer. So, the near side of an object will feel more attraction than the far side, causing a stretching force. • What will this gradient in gravity do to the earth’s shape?...

  43. springNeap diagram

  44. Tidal Friction… • Now realize the earth is rotating during all this. • How will this affect the orientation of the tidal bulge?

  45. Tidal advance

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