Fourth-Fifth Test

Question 1

Harvard calculators

Answer 1

women who sat around in harvard and did math. famous: annie cannon and henrietta leavitt. both deaf math majors

Question 2

Henry Draper

Answer 2

lived mid 19th century, interested in spectral lines but unsure what they were. had ability to make good spectra. on death wife gave money to harvard to study spectra, spectra discoveries there named after him.

Question 3

star spectral types

Answer 3

Annie Cannon noticed similarities in different stars, designed an A-V sequence. When it was figured out what spectral lines are, cannon rearranged stars onto a scale from hot-cool, 30,000K to 3000K. O B A F G K M.

Question 4

Draper Spectral Classification System

Answer 4

O B A F G K M. From hot to cool, 30,000K to 3000K. 0-9 subtypes. Oh, be a fine girl, kiss me!
division of temperature based on spectral lines.

Question 5

HR Diagram

Answer 5

get apparent mag, get distance and temperature from spectral math filtering. get graph of line going top left to bottom right, hot left on X, bright high on Y. the line is the MAIN SEQUENCE. red giants in top right- low T high brightness, white dwarfs bottom left- opposite.

Question 6

spectroscopic parallax

Answer 6

distance from star derived from spectrographs. astronomers call all distance spectrograph.

Question 7

luminosity variance of stars

Answer 7

Henrietta Leavitt discovered that some stars vary in magnitude regularly, period measured in day. she checked if variation was related to anything useful- it was! luminosity… that is, the higher the period of of the star, the brighter it is.

Question 8

cepheid star

Answer 8

UNCLEAR. a star that exhibits a certain kind of period-luminosity relationship. used as a standard candle to measure distances. including to distant galaxies, because 99% of the distance to a star is the distance to its galaxy.

Question 9

two types of cepheid variables

Answer 9

Type I “classical”, type 2 “w viginis” viginis lower and lefter on graph.

Question 10

stellar nurseries

Answer 10

gas clouds such as orion. gas and dust ejected from supernova, gas collapses, protostars blow gas around, disks form etc.

Question 11

Messier catalog

Answer 11

1781, by messier. Lots of items have messier number.

Question 12

NGC catalog

Answer 12

new general catalog. 1886, more stars.

Question 13

solar system formation

Answer 13

cloud->disk->star-> planets

Question 14

what happens to materials of dying star

Answer 14

5-10% imploded. 90-95% sent out and recycled.

Question 15

making mathematical model of stars

Answer 15

make star into series of concentric circles. assumptions: star is spherical, layers made by concentric circles are same all around. measure Temperature, density, pressure, composition (T1, Ro1, Comp1, P1) of outermost layer with spectral stuff. Use physics to calculate it for each layer going in. Calculus removes the layers and can make it a continuous calculation.

Question 16

once mathematical model exists

Answer 16

star can be evolved in the fourth dimension!

Question 17

first stage of stellar evolution

Answer 17

Very big, low density cloud, density increasing, hot gas rises, cold sinks… strong convection. Temperature stays same, cloud gets smaller, thus smaller brightness.

Question 18

second stage of stellar evolution

Answer 18

density continues to increase, convection gets harder, almost stops, keeps collapsing. temp keeps going up, still getting smaller = dimmer. moves left on graph.

Question 19

third stage

Answer 19

gets hot enough that star IGNITES: hydrogen burns into helium, starts temperature chain reaction. equilibrium between temperature and gravitational pressure. is a star with disk around it that forms into planet

Question 20

collapse of cloud into star

Answer 20

cloud has some natural tendency to rotate. as gravity shrinks it, spins faster to conserve angular momentum. Horizontal force towards center, vertical force towards equator of spin: causes disk with packed middle. spirals up or down.

Question 21

other STAR formation fact.s

Answer 21

clouds of gas often form more than one star, many points of light. can form binary, tertiary stars, star clusters

Question 22

once mathematical model exists

Answer 22

star can be evolved in the fourth dimension!

Question 23

first stage of stellar evolution

Answer 23

Very big, low density cloud, density increasing, hot gas rises, cold sinks… strong convection. Temperature stays same, cloud gets smaller, thus smaller brightness.

Question 24

second stage of stellar evolution

Answer 24

density continues to increase, convection gets harder, almost stops, keeps collapsing. temp keeps going up, still getting smaller = dimmer. moves left on graph.

Question 25

gestation times of different stars

Answer 25

100 solar mass stars born in 10k yrs, solar mass one million, 10^8 years for much smaller. they also die in related amounts of time.

Question 26

collapse of cloud into star

Answer 26

cloud has some natural tendency to rotate. as gravity shrinks it, spins faster to conserve angular momentum. Horizontal force towards center, vertical force towards equator of spin: causes disk with packed middle. spirals up or down.

Question 27

other STAR formation fact.s

Answer 27

clouds of gas often form more than one star, many points of light. can form binary, tertiary stars, star clusters

Question 28

accretion theory

Answer 28

one idea of how planets form. in cloud orbiting protostar, molecules stick together chemically. those then start sticking together gravitationally. kepler’s third say that each little orbiting body orbits at different velocities, tug and stick to each other

Question 29

moon formation

Answer 29

maybe further accretion disks, maybe giant impact- he doesn’t like this

Question 30

minimum mass for H fusion

Answer 30

1/12th solar mass

Question 31

neutrino telescoping

Answer 31

would be able to see core of sun, as light takes 10^5 years of reabsorption and emission to get out. use perchrolo ethylene with helium bubbling at first, that cannot detect all kind of neutrino, now look for light flashes in a pool of water, can detect all three. blurry map of sun made. deep underground to remove noise from other solar particles.

Question 32

solar neutrino flux problem

Answer 32

solar neutrinos detected did not match predictions not enough of them. Answered by neutrinos changing flavor as they travel, between electron, muon, and tao. before solution: sun’s core off? black hole at center w/ sun sustained by rotation around it?

Question 33

hydrogen fusion process

Answer 33

2H fuse into He2, then one more H to become He3, etc, double chains, get the slide.

Question 34

4H fusion equation

Answer 34

4H -> 1He4 + 2 gamma rays + 2 positrons + 2 neutrinos

Question 35

neutrinos

Answer 35

“little neutral ones”. predicted 1930 when EM was not being conserved. Seen in 1942. Mass, not electric charge was missing, hence neutralness. almost impossible to detect, 10^13 through hand every second. half would survive ten lightyears of lead!

Question 36

death of star

Answer 36

massive: red giant layers fall back in, process repeats of fusing heavier elements up to iron. iron is boundary between exothermic fusion and fission, no more fusing it. explodes in supernova maybe.
smaller: stops burning helium, becomes size of earth but one solar mass, radiative heat, fades eventually to black dwarf.

Question 37

lifetimes of stars

Answer 37

10^0 - life of biggest star.
10^10 - life of sun
10^11 - life of bigs:moreth

Question 38

solar neutrino flux problem

Answer 38

solar neutrinos detected did not match predictions not enough of them. Answered by neutrinos changing flavor as they travel, between electron, muon, and tao.

Question 39

neutrino observatories

Answer 39

South Dakota goldmine, super kumioandi in japan, IceCube array in antarctica

Question 40

serious star system

Answer 40

1844 serius B predicted from A wobbling, observed 1962, spec isolated 1915. problem: it was insanely dense!

Question 41

serius b density properties

Answer 41

1 solar mass, size of earth. 150lb person becomes 75 billion tons, AA battery (1/20lbs) becomes 250 million tons. one teaspoon of white dwarf material is 20 tons on earth. 1 mil grams/cm^3

Question 42

why white dwarfs are stable

Answer 42

Pauli Exclusion principle, heisenberg uncertainty principle. deltaX * deltaP > a constant. change in movement times change in momentum must remain greater than a certain constant. thus, as movement decreased, momentum increases, thus creating the quantum pressure needed to counter the force of gravity. “electron degenerate gas pressure”

Question 43

lifetimes of stars

Answer 43

10^0 - life of biggest star.
10^10 - life of sun
10^11 -

Question 44

white dwarfs general facts

Answer 44

white dwarf. what happens to them?

Question 45

old vs new cluster of stars

Answer 45

old: clustered at bottom of HR, everything above has died. Lots of red giants shrinking to white dwarfs. in young cluster, lots of ones at top.

Question 46

Sirius star system

Answer 46

1844 serius B predicted from A wobbling, observed 1862. 1915 observed with spectral lines.

Question 47

Sirius b density properties

Answer 47

1 solar mass, size of earth. 150lb person becomes 75 billion tons, AA battery (1/20lbs) becomes 250 million tons. one teaspoon of white dwarf material is 20 tons on earth.

Question 48

why white dwarfs are stable

Answer 48

Pauli Exclusion principle, heisenberg uncertainty principle. deltaX * deltaP > a constant. change in movement times change in momentum must remain greater than a certain constant. thus, as movement decreased, momentum increases, thus creating the quantum pressure needed to counter

Question 49

Chandrasekar limit

Answer 49

1.4 solar masses. after that, degenerate electron motion gets relativistic- can’t hold up, no stability. developed 1930.

Question 50

white dwarfs

Answer 50

<1.4 solar masses. takes 2x age of universe for leftover heat to radiate away, becoming black dwarves, none exist yet.

Question 51

light leaving star

Answer 51

light (photos) made in core from energy of fusion. because of density of interior of star, takes 10^5 (10,000) years to get out of the star. mathematically: a random walk. imagine drunk person leaving bar and taking one equal step at a time home. Math says that you WILL get there eventually. this is the path light follows as it is absorbed and re-emitted repeatedly.

Question 52

spectral line broadening

Answer 52

spectral lines from a star broadened by properties such as temperature, rotation/turbulence (producing red and blue shifts). Using a densitometer, see darkness of spectral line. Each broadening effect has a different signature, use mathematical curves to remove these bit by bit- getting data from each time.

Question 53

what can get from spectral line curve analysis

Answer 53

Temp ±50°
gas pressure+density
chemical abundances
rotational velocity
mag field strength+direction
expanding gas shell
radial velocity from earth

Question 54

red giant mass loss

Answer 54

can red giants lose enough mass to become white dwarves? big stars have to lose 98.6% of their mass. in casting off outer layers, stars lose a ton but losing 90% is rare. thus, they become SOMETHING MORE

Question 55

light echo

Answer 55

light appears to be leaving a nebula faster than light, its not, just geometry and different angles??

Question 56

Joclyn Bell

Answer 56

1967 PhD candidate under Anthony Hewish. Looking for an easy way to find quasars, which scintillate. Instead discovered radio pulses with regular period.

Question 57

pulsar discovery process

Answer 57

Bell told to go back to quasars! At first thought that pulsars were man made, then they started varying sidereal (4 min off) meaning they were outside solar system.

Question 58

how to discover pulsar

Answer 58

distance radio comes in as point source, narrow compared to cone-like planet. at the time, telescopes “integrate” radio signals, building them over time. This loses the pulsar data. Bell rented a field south of london built up-pointing antennas with 2x4s.

Question 59

two early ideas for pulsars

Answer 59

Fastly rotating main sequence with a hotspot- with period of one sec, would fall apart. Two binaries working together- speed required would mean they’d merge. white dwarfs also would fall apart.

Question 60

pulsar

Answer 60

rotating neutron star, left over after stellar explosion. size of burlington, 10km across. period of 1.3 millisecond to 10 seconds. .

Question 61

synchrotron emissions discovery

Answer 61

a basic particle accelerator that synchronizes magnets with charged particles going around. researchers discovered that with a super-strong magnetic field, charged particles traveling at relativistic speeds emit blazes of light. a quantum effect, not a thermal emission

Question 62

oppenheimer-volkoff

Answer 62

same as chand limit for white dwarves, but for neutron stars. limit is 1.4 (2 now) to five solar masses (upper limit). not sure how that bloody works! neutron stars only on small part of diagram.

Question 63

how neutron stars form

Answer 63

collapsing stars >1.4 solar masses shrink past white dwarf density, pauli exclusion causes electrons and protons to fuse into neutrons. they find their own equilibrium like white dwarfs do = heisenberg delta x, delta p.
“nucleon degenerate gas pressure”

Question 64

neutron star weight properties

Answer 64

150lbs Earth = 75 trillion trillion tons = 75*10^24 tons.

1/20lbs Earth = 25 billion trillion tons + 25*10^21

Question 65

pulsar model

Answer 65

super spinning neutron star. magnetic axis off slightly. off axis and rotation speed taken down from orig star when star collapses. atmosphere around it, slimmish jet from pole.

Question 66

“atmosphere” of pulsar

Answer 66

no pauli exclusion pressure on e- and p+ on outside of thing, they don’t form neutrons strong magnetic field + relativistic speeds = SYCHROTRON EMISSION!
as pulsar rotates, emitting part hits earth. width of emission cone is duration of pulse.

Question 67

loss of spin for pulsars

Answer 67

angular momentum goes down, some energy is radiated out by the jet. loses .000005 seconds in four years, measured by mean julian year- exactly 24hrs.