ISP 205, Section 3, Fall 1999, Prof. Stein
UNIT I: THE SKY
OUTLINE

Introduction: Tour of the Universe A. Scientific Models or Theories B. Appearance of the sky C. Models of the Solar System D. Motion and Gravity E. Light and Atoms

Introduction: Tour of the Universe

What is in the Universe?

Planets: AST disk: Earth: 11128, 11173; Moon: 11603; Mercury: 10511; Venus: 10778; Mars: 11803, 11806; Jupiter: 12933; Io: 12949; Saturn: 13256.
Jupiter Pluto and Charon
Sun. white light; 10426; Halpha; 1843; X-Ray: 10435
The Sun in H_alpha
Stars. Orion: 7702, 1822; pleiades: 2785
Galaxies: Andromeda (top-view): 717; NGC 4565 (side-view): 721
Andromeda Galaxy (M31)
Clusters of galaxies. Leo: 693; Virgo: 694; Coma: 8333; Pisces: 699

[Movie: Universe, 30 min.]

Sizes

MI (200 mi) = baseball (7 cm)

CA = 2000 mi = 70 cm (3/4 m) away
DC = 400 mi = 14 cm away
Earth (2R_earth=12,800 km) = baseball (2R=7 cm)

Moon (2R_moon=3,400 km) (D_E-M = 384,000 km) = marble 2 m = 7 ft away
Sun (2R_sun=1,400,000 = 1.4x10⁶ km) (D_ES = 150,000,000 = 1.5x10⁸ km)
= 7.7 m ball, 0.8 km away (Harrison Rd)
Sun (2R_sun=1,400,000 = 1.4x10⁶ km) = baseball (2R=7 cm)

Earth (R_Earth = 6,400 km = 1%R_sun) (D_E-S = AU (astronomical unit) = 215 R_sun)
is penpoint 7 m away

Neptune (30 AU) is 200 m away
Pluto (40 AU) is 280 m away (on average)
Nearest Star (alpha Cen, 41,000,000,000,000 = 4.1x10¹³ km = 4.3 LY)
is 2000 km = 1200 mi away (DTW-DEN)
(1 LY = distance light travels in year at speed of 3x10⁵ km/s = 9.5x10¹² km = 10¹³ km)
If the Sun is a grape, the nearest star is 100 mi away
Vega (alpha Lyr) (overhead in Sep) (2.5x10¹⁴ km = 26 LY)
is 7000 mi away (DTW-Shanghai)
Sirius (alpha CMa, brightest *) (8.3x10¹³ km = 8.8 LY)
is 4000 km = 2500 mi away (DTW-SFO)
Betelguese (alpha Ori) (6x10¹⁵ km = 600LY)
is 300,000 km away (Moon)
Milky Way Galaxy (Diam_MW = 1,000,000,000,000,000,000 = 1x10¹⁸ km = 1x10⁵ LY)
diameter is 5x10⁷ km (Venus at closest)
Andromeda Galaxy (20,000,000,000,000,000,000 = 2x10¹⁹ km = 2x10⁶ LY)
is 1x10⁹ km away (Uranus)
Milky Way Galaxy (2R_MW = 1,000,000,000,000,000,000 = 1x10¹⁸ km = 1x10⁵ LY)
= baseball (7 cm) (hard to define, no sharp edge)

Andromeda (local group) (20,000,000,000,000,000,000 = 2x10¹⁹ km = 2x10⁶ LY away)
is 1.4 m away
Virgo Cluster (6,000,000,000,000,000,000,000 = 6x10²⁰ km = 6x10⁷ LY) is 42 m away
Visible Universe (1.5x10¹⁰ LY) is 10 km = 6 mi away (downtown Lansing)

The Big Questions

The fate of the universe?
The origin of the universe?
The death of stars (a bang or a whimper)?
The formation of stars and planets?
Celestial motions (them or us)?

A. Scientific Models or Theories

Reading: Chapter 1 (interlude 1.1)

Model or Theory is a picture in your mind of reality

Goal:: Simplest rule to explain most phenomena
Scientific Models (Theories, Laws):: Isolate relevant experience from distracting or trivial effects; Discern a stable relationship in the flux of events; Express the relationship mathematically.

Process of model building: (similar to everyday problem solving)

1. Have Problem
Observations to explain or conflict between observations and existing model
Define what problem is. Ask the right questions.
2. Generate a New Model/Theory
Use divergent, flexible thinking; brainstorming.
More than one possible solution, weigh pros and cons.
Usually modify old model, occasionally something entirely different.
based on fundamental ideas, previous theories, aesthetics
Choose a model
3. Test Model/Theory - Act on it
Make Predictions
Compare predictions of model with new observations.
How well does model correspond to reality?
Revise model/theory if necessary (-> step 1).

[video: magic hut (start 3m54s)(20 min)]
Criteria for Fruitful, Successful Model
- Relate many observations. Simple, easy to grasp. Few assumptions.
- Makes predictions that agree with experience.
- Solves significant problems.
- Stimulates new investigations.
Limitations
Models are based on limited experience. They are extrapolated to a range of similar situations and are applied in a broader context than that in which they were developed. Sooner or later, advances in experience reach a limit where assumptions are no longer valid. Theories are seen to be too limited or too inaccurate.
Examples:
- sunspots vs. Republicans in Senate (extrapolation)
- sunspots vs. rainfall (limited observations)
- height vs. age (biased observations)
Proof
Can disprove a theory by failure to correctly predict phenomena. Cannot prove a theory correct. Scientists know that none of the theories and models we use are perfect:

The criterion for a good model is its usefulness for the task for which it is used.
Can increase our confidence in it by successes in predicting phenomena.
Activity: surviving in the wilderness

B. Appearance of the sky - what do we see?

Model of Sky -- Celestial Sphere
Reading: section P.2

Problem: location of stars, motion of planets, what holds stars up
Model: Celestial Sphere
ancient - stars on crystal sphere
modern - globe surrounding Earth
Celestial Equator - over Earth's equator, = projection of Earth's equator
Celestial N & S Poles - over Earth's poles, = projection of Earth's poles
zenith - point directly overhead
meridian - line from north celestial pole through zenith to south point on horizon.
[AST disk, celestial equator 9998, Earth 10002, meridian 10003-4]
Use: Coordinate system
Declination - angle N or S or celestial equator (like latitude), measured in degrees
Right Ascension - East-West position on celestial sphere (like longitude). Measured eastward from position where sun crosses celestial equator in spring (vernal equinox), in units of hours:minutes:seconds.
[AST disk: 9983(?), 9995-10000]
[demo: celestial globe]
Twelve Constellations in the Zodiac.
Pisces (S of Pegasus, see in fall) (RA 0 h)
Gemini (near Orion, see in winter) (RA 6 h)
Virgo (near Leo, see in spring) (RA 12 h)
Sagittarius (S of Vega, see in summer) (RA 18 h)
Jan. Sky Map from Abrams Planetarium

Limitations:
All models have limitations.
Need different models for different purposes.
Limitation of Celestial Sphere Model: Third dimension - distance.
e.g. Orion Constellation
The Sun
Reading: section 1.1

(i) Daily Motion, due to Rotation of Earth toward the East on its axis
E->W re. horizon
Time: day determined by rotation of Earth.
[star trails, AST disk 9931, 10070-71]
[Rotating telescope represents Earth, AST disk, step 10090-10105, slow play 10106-10166]
Demo: spotlight and globe
[Rotating Earth from geosynchronus orbit, AST disk, step 11155-11188]
demo: voyager

(ii) Annual Motion, due to orbit of Earth toward East about Sun
W->E re stars.
Path of sun in sky = ECLIPTIC
Seasons: Due to inclination of Earth's axis of rotation with respect to plane of its orbit around sun
Year determined by motion of Earth around sun.
Winter Solstice - about Dec 21. Sun farthest south, rises SE, sets SW. Long night, short day.
Vernal (spring) Equinox - about March 21. Sun rises E, sets W. Equal day and night.
Summer Solstice - about June 21. Sun farthest north, rises NE, sets NW. Long day, short night.
Autumnal Equinox - about Sept 21. Sun rises E, sets W. Equal day and night.
Demo: Motion re stars, spotlight and globe (move Sun then Earth, eg geo vs helio centric)
Demo: light on liquid crystal, dependence of heating on inclination.
[Height of Sun, AST disk 10180-10224]
[slide sequence: sunrise Jan-June]
[Inclination, AST disk 9921,9923-24(solar rays)]
[AST disk 10168-79]
Demo: voyager

Stars

Reading: section 1.1, Appendices: S1-S4 (star maps at back of book)

Constellations: Beyond Earth: Orion 3793, Pleiades 3797, Big Dipper 3801, Hyades 3802, Lyrae 3806, Cygnus 3807, Auriga 3809, Winter 3823

      (i) Recognize Bright stars and their constellations.
          Locate on star map and in sky.
          16 Brightest Northern Hemisphere Stars
          Map of Taurus
      (ii) See different stars at different seasons, 
          because of Earth's orbit about the Sun.
          Night side of Earth faces in different directions.
	    Star Maps:
		January
		February
		March
		June
		September
		December
      Planetarium, star maps

Moon
Reading: sections 1.2-1.3

Daily Motion
Monthly motion: due to orbit of Moon toward East about Earth
Time: month determined by motion of moon around Earth.

(i) Phases
Moon Phases+diagram
Illuminated side faces sun. View it from Earth, see different fraction of illuminated side depending on position in orbit.
Times of rising and setting at different phases.
[Earth, Moon, Sun diagram, AST disk 9940, phases 9941-9949]
[Phases: BE 3709-3728, 3733-3740, 3742-3748]
Activity: spotlight, tennis and Ping-Pong balls

(ii) Eclipses
Solar - moon between sun and Earth, casts shadow on Earth
Lunar - Earth between sun and moon, casts shadow on moon
Moons orbit tilted 5^o from the ecliptic. Twice a year point where moons orbit crosses ecliptic located on line between sun and Earth, so sun, moon and Earth can lie on straight line
[Video: July 91 eclipse.]
[Solar, AST disk 9965-71]
[Lunar, AST disk 9958, 9960-64, BE: 3784]
[Earth, Moon, Sun diagram, AST disk 9957]
Activity: spotlight, balls
the Planets
Reading: section 1.4

Daily motion - East to West with respect to the horizon
Annual motion - generally East with respect to the stars, near the ecliptic.
Retrograde motion - part of each year moves West with respect to the stars
[retrograde motion Mars: AST disk 9904, slow play 10277-10288]
Demo: voyager
Planetarium

Venus & Mercury - always near Sun
Mars, Jupiter and Saturn - anywhere along ecliptic
Brightness not uniform - brighter and fainter
Motion not uniform - faster and slower compared to the stars
Planetarium

Orientation: N,S,E,W
planetarium, streets, equator, poles
Bright Stars and Constellations
Moon
[Activity: identifying stars on map, locate Moon]
Coordinates
Daily Motion
Annual Motion (Stars, Sun)
Motion of planets re stars,
direct and retrograde motion
Geocentric & Heliocentric views - Orrery
[Activity: path of Mars re stars]

Summary of Observed Motions

C. Models of the Solar System

Ptolemaic Model
Reading: section 1.4

Observations: daily and annual motions of the Sun, Moon, and planets. Eclipses. No stellar parallax.
Fundamental ideas: Heavens are perfect. Perfect geometry is circle and spheres.
Problem: predict planetary positions and motion
Model: Geocentric. - Sun, Moon and all planets move around the Earth on circles.

Natural motion of heavenly bodies is Uniform Circular Motion
Observed motions can't be explained by simple geocentric model, need complex model of epicycles, eccentric and deferent
Deferent - Daily motion E-> W, and Motion W-> E re stars
all heavenly objects whirl around Earth E->W daily.
Planets move slower along deferent than stars
Epicycles - Retrograde motion
Planet moves around epicycle, center of epicycle moves along deferent.
When planet is moving backwards along inner part of epicycle ->retrograde motion
Venus and Mercury
Centers of epicycles lie on Earth-sun line.
Size of epicycles determined by greatest distance from sun.
Mars, Jupiter and Saturn
Radius of epicycles align with Earth-sun radius in order to make retrograde motion occur when planet opposite the sun, but anywhere on deferent.
Size of epicycle determined by size of retrograde loop. Decreases from mars -> Jupiter -> Saturn.
Eccentric - Non-uniform motion
Earth offset from center of deferent circle.
Planets appear to move faster when closer to Earth, slower when farther away
Equant - non-uniform motion
motion along deferent not uniform. Appears uniform when viewed from point offset from center of deferent opposite to eccentric

[Diagram, AST disk 6979, detail 6980, book plate 9906, diagram 9907]
[Geocentric view, AST disk, side 2, chapt 32]
[Deferents & epicycles, Mechanical Universe prog 9, chapt 18, Almagest chapt 19]
[Ptolemaic and Tychonian models, Mechanical Universe, prog 21, chapt 8 (15131)]

Tests:
Predicted planetary positions and motions. Accurate to a few moon diameters. Tycho Brahe upset that predicted conjunction of Jupiter & Saturn off by a month.
No observable parallax. Earth doesn't appear to move.
The geocentric model explains all the basic motions and observations made with the naked eye.
Copernican Model (1473-1543)
Reading: section 1.4, 1.5
[Portrait, AST disk 6995,6]

Observations: Same as before: daily and annual motions of the Sun, Moon, and planets. Eclipses. No stellar parallax.
Fundamental ideas: Sun is at center. Perfect geometry of circles and spheres.
Problem:
Aesthetics - Ptolemy did not use uniform circular motion (equant)
Model: Heliocentric - all planets, including Earth, orbit the sun.
Planets closer to sun move faster
Retrograde motion: faster moving inner planet overtakes and passes slower moving outer planet.
[AST disk, diagrams 9912,13, model 6997, book 6998]
[Geocentric view, AST disk, side 2, chapt 33]
[Copernican model, Mechanical Universe, prog 21, chapt 9-10 (17000, 17141-17190)]
Tests:
Accuracy of predicted planetary positions unchanged.
Phases of Venus -> Venus orbits sun (Galileo, 1565-1642) [portrait, AST disk 7025,6] [Robbins et al. Fig 5-19.]
Sunspots, moon mountains -> heavens not perfect
Tycho Brahe (1546-1601) observed new bright star in Cassiopeia (supernova).
Showed no parallax -> so farther than moon -> star -> stars change;
Observed comet, showed crossed orbits of Jupiter and Mars, so no crystal spheres.
[Portrait, AST disk 7004,5, observatory 7008, instruments 7012, slides of Hven]
Stellar parallax observed 1838 (Friedrich Bessel 1784-1846)

Problems:
Why do objects fall straight down on spinning Earth?
How are atmosphere and moon carried along by moving Earth?
Galileo observed moons of Jupiter carried along with Jupiter
No parallax (stars very distant, parallax very small, first observed by Bessel in 1838)
[AST disk 7032].
Video: Mechanical Universe, program 4, chapter 19 (How things fall)
[parallax, AST disk: 9918]

Appeal -
Aesthetic: Simple natural explanation of retrograde motion - inner planets move faster, so overtake outer planets. Explains why always at opposition. Symmetry of nested orbits.
More universal, Earth like other planets.
Repugnance -
Earth not unique

Philosophy - Earth not unique! Revolutionary! (Origin of meaning of word is name of Copernicus book, "On the Revolutions of the Heavenly Spheres")
Keplerian Model (1571-1630)
Reading: sections 1.5-1.6
[portrait, AST disk 7019,20]

Observations: Tycho Brahe's observations of Mars and other planets
Problem:
Observations of planetary positions by Tycho Brahe (1546-1601) much more accurate ( ~1/8 moon diameter). Inconsistent with Copernican model.
[conflict observations and models, Mechanical Universe, prog 21, chapt 2 (4500)]
Model:
a. Elliptical planetary orbits

ellipse

b. Non-uniform speed around orbit
c. P²(yr) = a³(au), planet's period is related to its distance from sun
[ellipses, Mechanical Universe, prog 21, chapt 3-4]
[diagram, AST disk, 9914,5]
[3 laws, Mechanical Universe, prog 8 22, 25 (3 laws)]
[Mechanical Universe, prog 21, chapt 12 (Earth's orbit), 13,14 (Mar's orbit)]
Tests:
Derived for Mars, test with other planets and comets.
Much more accurate predictions of planetary positions.
Philosophy:
Non-uniform planetary motion. Not natural motion. Need a force.
Appeal:
Accuracy.
Universality - all orbiting bodies (planets and satellites) have same properties.
Comparative Summary of Solar System Models

D. Motion and Gravity

Reading: section 1.7, MP 1.1

Ptolemy, Copernicus and Kepler's models were descriptive and geometric. They did not explain. Newton developed an explanation.

[Newton portrait, AST disk 7034]

Newton's Law of Motion (1642-1727)

Motion only with respect to something
Velocity
Speed=distance traveled in given time
Velocity=speed in given direction=distance traveled in given direction in given time
distance = velocity x time (e.g. mi/hr x hr = mi)
Acceleration=change in velocity in given time
speed up, slow down, turn
Acceleration is intrinsic, need refer to nothing else.
[Inclined planes, Mechanical Universe, program 4, chapt 25-26]

Newton's Law of Motion
acceleration = force / mass

Force = push or pull
Mass = inertia, resistance to change of motion. Depends on amount of matter, not size.

Examples: cars, balls, rockets
Demo: pucks on air table
Demo: pull cart with weights using spring
Orbital Motion: direction changes (speed also changes slightly) -> need force!
[velocity, acceleration and force, Mechanical Universe, program 6, chapt 13 (good animation)]
Example: cars turning corners
Newton's Theory of Gravity
Planet's motion in its orbit is accelerated (direction and magnitude of velocity changes). Force is needed. Newton said force is gravity:

Source of Gravitational Force is Mass.
Every object attracts every other object by force of gravity.
More Mass -> stronger gravity.
Larger Distance -> weaker gravity.

F_gravity = G M m / D²

[AST disk: F toward center 7087, F on planet 7088]
[Mechanical Universe, program 8, chapt 28-29 (force of gravity)
Show: Ratios and Exponents
Interactive Physics II (PC): falling, orbiting bodies with Motion Activity
Tests
Acceleration of Moon. (Know acceleration = F/m at Earth's surface, Know distance to Moon, Calculated acceleration at Moon's distance, Compare actual acceleration found from period and distance) [Mechanical Universe, program 8, chapt 38-43, Newton's prediction 40; Moon's acceleration 41-42; circular motion, a=v²/r, prog 9 chapt 21-26]
Solved problems of Copernican system: objects fall straight down, atmosphere stays with planet, moon stays with planet [Mechanical Universe, prog 4, chapt 34-36, (falling ball)]
Orbits of comets, spacecraft, Neptune and Uranus. (Laplace 1800 calculated Uranus orbit)
Derivation of Kepler's laws. Used to determine masses.
Discrepancy: Mercury, high speeds
Philosophy:
Mechanical Universe.
Given knowledge of where everything is and how it is moving now, and enough computer power, you can calculate everything that will happen in the future.
Appeal:
Universal -- all motion, terrestrial as well as celestial
Accurate predictions.
Aesthetic -- simple, few assumptions
Application: Determining masses Reading: p 38
Can only determine masses of astronomical bodies where there are at least two bodies orbiting around each other.
Can measure line of sight velocity by Doppler shift
Can measure period

Derivation of Kepler's Third Law (optional)
Start with Newton's equations of motion and gravity
a = F/m and F_gravity = GMm/D²
Substitute F_gravity for the force in the equation of motion.
a = GMm/D² * 1/m = GM/D²
(Note: acceleration independent of mass of accelerated body)
a = change in velocity / time = v/t
v = distance / time = D/t
a = D/t²
D/t² = GM/D²
Solve for M: multiply by D² and divide by G
M = D³/Gt² (Kepler's Third Law)
Kepler's Third Law in Solar System Units
is
M₁ [M_sun] + M₂ [M_sun] = D[AU]³ / P[yr]²
where
M₁ = mass of body 1, in units of mass of Sun
M₂ = mass of body 2, in units of mass of Sun
D = radius of nearly circular orbit (= semi-major axis of ellipse in general) in AU (Astronomical Units)
P = period of orbit in years
Must convert distances to AU
Must convert times to years
If given other information must determine Distance and Period
e.g. d=vt, t=d/v, where here distance = circumference of orbit not its radius.
If one mass is much less than the other, it can be neglected.
Work problem in class: Mass of the Earth
Reading: p 38, Problem 2, p41
Energy
Reading: MP 2.1 (p 57)

Energy = ability to do work
Kinetic energy = energy of motion
Potential energy = work a force could do
Energy is conserved:

Kinetic Energy + Potential Energy =Total Energy = constant
1/2 m v² - GMm/D = E = constant

E_Total = 0 at infinit separation. As fall the KE increases (speeds up), so the PE must decrease (become more negative) to keep the total energy = 0 (constant).

Demo: pendulum
If Energy is conserved, how do things get started, or once moving how do they step? Work transfers energy.
[Video: Ring of Truth: Change 2297-3412 (Toure de France, energy conservation)]
Applications:
Do work to change speed, not to turn
Bound orbit: total energy < 0.
Unbound orbit: total energy > 0.
Escape velocity: speed required to escape to infinity.
Einstein's Theory of Motion and Gravity (Optional)
Reading: MP 13.1, MP 13.2, interlude 13.1

Problem:
Speed of Light the same for all observers.
orbit of Mercury: axis precesses

All objects fall at same speed: inertial mass = gravitational mass

Demo: air track
Video: Mechanical Universe, program 25, chapter 25-27

New Model:
Laws of Physics the Same for all freely moving observers.
Speed of Light the Same for all observers.
Can Not Distinguish between Gravity and Constant Acceleration by some other force.

Predictions:
Light is attracted by gravity: Bending of Light by the Sun Video: Mechanical Universe, program 25, chapter 29
Energy = Mass (E=mc²): move faster -> more energy -> more mass

-> more inertia, can't exceed the speed of light

Time dilation -- time slows down when moving
Gravity is Geometry: Mass warps space-time. Warped space-time controls how objects move.

Tests:
Orbit of Mercury, lifetimes of cyclotron particles, displacement of stars close to Sun, increase of inertia as speed increases.

Matter emits light. This light carries information about the matter that emitted it. Most of our information about the universe comes from light we receive. We need to analyze that light to determine the properties of the matter that produced it. To do this, we need to understand the nature of light and its interaction with matter.

Reading: Chapter 2

1. Light

How do we see?

An object must give off light, and our eye must receive the light, in order to see the object.
That light can be emitted by the object (e.g., a lightbulb or the Sun)
Or, light from another source can be reflected off the object (a pen reflecting a lightbulb or the Moon reflecting sunlight)
If there is no light, can't see an object

Light is an Electromagnetic Wave.

Reading: sections 2.1, 2.2

changing electric and magnetic force.
wavelength (lambda) = distance between waves;
period (P) = time between waves;
frequency (f) = number of waves per unit time: Demo: weighted rope; Analogy: Buses; [BE: 1747 (wave)]; Mechanical Universe, Program 40: chapt 4 - light waves; 10 - Newton; 11 - Huygens; 12-15 - waves; 17 - lines of force; 19 - oscillating charge; 40 - telescope

Light is a Stream of Photons

Reading: section 2.6

Higher Energy Photons = Shorter Wavelength Light: e_photon = hf = hc/lambda

Spectrum of Light

Reading: section 2.3, Figure 2.8

   x-rays      (< 20 nm)         (high energy, short wavelength)
   ultraviolet (20 nm - 0.4 microm)
                  blue      \
                  green     |
   visible        yellow    }    lambda = 0.4-0.7 micrometers
                  orange    |
                  red       /
   infrared    (1 microm - 1 mm)
   microwave   (1 mm - 1 cm)
   radio       (> 1 cm)           (low energy, long wavelength)

[Examples: AST disk: radio 470, MW 471, visible 473, UV 474, XR 475]

2. Atoms

Reading: section 2.6

Matter is made of atoms.

Atom - Different atom for each element.

Nucleus orbited by Electrons.

Nucleus - Composed of protons (+ charge) and neutrons (0 charge).

: Contains most of atoms mass.

Electrons (- charge) - Orbit nucleus, attracted by electric force.

Electric Force -

: Produced by charge,; Opposite charges attract, like charges repel.; Decreases with distance

Element determined by number of protons in nucleus

(H has 1 proton, He has 2 protons, C has 6 protons).

[BE: 1764 (He atom)]

Crude Model - atom = solar system

If person = proton or neutron, electron = cotton candy orbiting 100 km (60 mi) away (Flint).

If nucleus = raisin, electron=400 m away, next atom 2.5-25 mi away.

If sun = 3 ft diam ball, Earth=raising 100 m away, nearest star=distance to Sun

Electrons can only orbit nucleus at certain allowed distances.

Electrons in smaller orbits have lower energy than electrons in larger orbits. (Takes energy to move electron from small to large orbit against pull of electric force.)

Neutral Atoms - number of electrons = number of protons.

Usual state at low temperature.

Ions - some or all of electrons have been knocked out of atom.

Usual state at high temperature.

[BE: 1765 (He ion)]

States of Matter

Gas - atoms move around freely. Interact (exert electric force on each other) only during collisions.
Liquid - atoms move around, but not freely. Always exerting electric force on each other.
Solid - atoms held in place by electric force. Can only vibrate about fixed position.

Temperature measures motion of atoms (and molecules, nuclei, electrons).
hotter = move faster
kT = 1/2 mv²

3. Emission and Absorption of Light

Reading: sections 2.4, 2.6

Photons are emitted and absorbed when electrons are accelerated and change their energy.

i. Thermal (Blackbody) Radiation
Reading: section 2.4
Hotter -> Bluer (higher energy photons)

move faster, more violent collisions
e_photon = kT, lambda_peak = 3x10^-3 m/T(K)

Hotter -> Brighter (more photons)

move faster, more collisions
F = sigma T⁴

Bigger -> Brighter (more photons)

more atoms, electrons
Luminosity = Flux x Area

Demo: bulb, reostat (images: cool, warm, hot, hottest)

Planck spectrum, AST disk 498-499]
Planck spectrum, BE: 1766-1768]

ii. Emission and Absorption by gas atoms

Reading: section 2.6
A photon (electromagnetic radiation) is emitted or absorbed when an electron changes its energy. [An electron can also change energy in a collision.]

An electron orbiting the nucleus of an atom is continually accelerated, so should radiate, but doesn't.
Origin of quantum mechanics

Only certain orbits (energy levels) are allowed an electron in an atom.

Energy levels of atoms (elevator analogy).

Electron energy decreases (jumps to smaller, lower energy, orbit) -> emit a photon
Absorb a photon -> electron energy increases (jumps to larger, higher energy, orbit)

Photon Energy = Change in Electron's energy

To be absorbed, photon must have just the right amount of energy to make the electron jump to a higher energy, larger orbit.

Demo: salts in flame, discharge tubes
[AST disk: 500]
[Atomic levels & transitions: Ring of Truth, Atoms: 4507-5020, 1h24m10s]
[Mech. Univ. prog. 49: Atoms, chapt 20, orbiting e^- radiates, spirals in; 22-Planck; 24-Bohr model, emission & absorption; 26-sizes of orbits & energy; 27-frequencies of emission and absorption]
AST disk: Hg, Na vapor lamps graph of intensity 559-576]

Continuous, Emission and Absorption spectra
Reading: section 2.5

4. Doppler Shift

: Light from approaching source is shifted blueward, light from a receding source is shifted redward.; bus analogy

5. Telescopes and Detectors

Most astronomical information comes from light we analyze.

a. Telescope

Reading: section 3.1

Like lens of eye

Functions

: i. Collect Photons (primary) L = F x Area; ii. Resolve close objects Theta_min = lambda/diameter; iii. Magnify objects

[Light gathering: AST disk 539]

Location: mountain tops - air absorption, seeing, lights

[BE: 1745 (atmos. transmission)]

Demo: spot aimed at board; rays and mirrors on black board; laser beam in smoke box.

[Historical: AST disk: Gallileo 7028; Herschel 7043,44; Ross 7046]

[Schematic: AST disk: examples 563-576; refractor 568-570; reflector 571-576; prime 7061; cassegrain 616, 7310 ...]

[Photographs of telescopes: AST disk: 581-84, 546, 618]

[AST disk:

: Lick: 7310 (construction diag), 11 (telescope), 16-22; Mauna Kea: 7775-83 (diagram and details); Palomar: 8663-69, telescope 8693, prime 8700-06, coude 8707-10; Mt. Wilson: 7805-11, construction 7861-7903, mule rd 7849; VLA: 8489,96 control, 8480 size, 8503 see through]

Keck video

b. Detectors

Reading: section 3.3

Functions

: i. record photons over a long time (integrate); ii. convert data to permanent medium; iii. Wider range of wavelength sensitivity

i. Photograph

: (about 2% efficient, small dynamic range 10², non-linear-so hard to calibrate)

ii. Electronic detectors (light meter, CCD)

: more efficient 80%, linear, large dynamic range 10⁵,

[AST disk: phot exposure 540-544, Photometer, 600, 603, CCD 622-23]

[AST disk: 577-607, 608-618, 619-625]

c. Spectrograph

Separates light by energy (wavelength, color)

[AST disk: spectrograph diag 608, stellar spectra plate 618, H spectrum 6700, solar spectrum 6739]

Links to other resources on the Sky

Abrams Planetarium Knowing the Sky (UCSD) The Constellations and their Stars (UWisc) The 26 Brightest Stars (UWisc) Galileo Galilei Sky and Telescope Magazine On Line Sky Maps

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This page will be updated continually throughout the course.
Updated: 1999.10.18 (Monday) 12:23:32 EDT
Visions of the Universe

Bob Stein's home page, email: steinr@pilot.msu.edu

ISP 205, Section 3, Fall 1999, Prof. Stein UNIT I: THE SKY OUTLINE