Astrophysics (M5)

Question 1

Luminosity

Answer 1

The total radiant power output of a star
Symbol: L
Unit: W

Question 2

Hertzsprung-Russel diagram

Answer 2

A graph showing the relationship between the luminosity of stars in our galaxy and their average surface temperature, with temperature increasing from right to left.

Question 3

Planetary nebula

Answer 3

The outer layers of a red giant that have drifted off into space, leaving the hot core behind at the centre as a white dwarf.

Question 4

White dwarf

Answer 4

A very dense star formed from the core of a red giant, in which no fusion takes place.

Question 5

Singularity

Answer 5

The region in a black hole where the volume tends towards zero. A place where matter is compressed down to an infinitely tiny point.

Question 6

Electron degeneracy pressure

Answer 6

A quantum-mechanical pressure created by the electrons in the core of a collapsing star due to the Pauli exclusion principle.

Question 7

Neutron degeneracy pressure

Answer 7

Created by collapsing start being so dense that electrons and protons are fired to form neutrons. This balances the gravitational force collapsing the star.

Question 8

Chandrasekhar limit

Answer 8

The mass of a star’s core beneath which the electron degeneracy pressure is sufficient to prevent gravitational collapse.
1.44 solar masses

Question 9

Supernova

Answer 9

The implosion of a red supergrass at the end of its life, which leads to subsequent ejection of stellar matter into space, leaving an inert remnant core.

Question 10

Black hole

Answer 10

After a star has gone supernova, if the core has a mass greater than about 3 solar masses, the gravitational collapse continues to compress the core. The result is a gravitational field so strong that its escape velocity is greater than the speed of light.
Super- massive black holes with several million solar masses are thought to be at the centre of most galaxies.

Question 11

Neutron star

Answer 11

If the mass of the core after a supernova is greater than the Chandrasekhar limit, the gravitational collapse continues, forming a neutron star.
Made almost entirely of neutrons
Can be very small - 10km in diameter
Typical mass of about 2 solar masses
Density similar to an atomic nucleus - 10^17 kgm^-3

Question 12

Red giant

Answer 12

Evolve from main sequence stars with 0.5-10 solar masses.
When fuel runs out in a main sequence, fusion stops so gravity is greater than radiation and gas pressure. Core begins to collapse and pressure increases.
Fusion starts in a shell around the core

Question 13

Red supergiant

Answer 13

A massive star in the last stages of its life before it implodes in a supernova.
Mass 0.5-10 solar masses
Heat of core means helium nuclei move fast enough to overcome electrostatic repulsion and fusion starts.
Heavier elements form in layers around the core.
Inert iron core is unstable.

Question 14

Planet

Answer 14

An object in orbit around a star with 3 main characteristics:
~mass large enough for its own gravity to hive it a round shape
~no fusion reactions
~cleared its orbit of most other objects

Question 15

Solar system

Answer 15

Our solar system contains the Sun and all objects that orbit it. It is one of many.
In 2014 over 1100 other solar systems had been discovered.

Question 16

Galaxy

Answer 16

A collection of stars and interstellar dust and gas. On average a galaxy will contain 100 billion stars, a significant proportion of which have their own solar system.

Question 17

Planetary satellite

Answer 17

A body in orbit around a planet. This includes moons and man-made satellites.

Question 18

Comet

Answer 18

A small, irregular body made up of ice, dust and small pieces of rock.
Few hundred metres to tens of km across.
All orbit the Sun mainly in highly eccentric elliptical orbits.
As they approach the Sun, some develop spectacular tails.

Question 19

Asteroid

Answer 19

An object too small and uneven to be a planet, usually in a near-circular orbits around the Sun and without the ice present in comets.

Question 20

Fusion

Answer 20

A process in which two smaller nuclei join together to form one larger nucleus.

Question 21

Radiation pressure

Answer 21

Pressure from the photons in the core of a star which acts outwards to counteract the pressure from the gravitational force pulling the matter inwards.

Question 22

Gas pressure

Answer 22

In stars, the pressure of the nuclei in the star’s core pushing outwards and counteracting the gravitational force pulling the star inwards.

Question 23

Nebulae

Answer 23

A cloud of dust and gas (mainly hydrogen) often many hundreds of times bigger than our solar system.

Question 24

Protostar

Answer 24

A very hot, very dense sphere of condensing dust and gas that is on the way to becoming a star.

Question 25

Main sequence star

Answer 25

The main period on an HR diagram in a star’s life during which it is stable.

Question 26

Evolution of the universe (earlier)

Answer 26

0: time and space are created, the universe is a singularity

10^-35: Universe expands rapidly, incredible acceleration. No matter just EM radiation in the form of high energy Gamma rays. Temp=10^28

10^-6: First fundamental particles gain mass through the Higgs boson.

10^-3: Quarks combine to form hadrons.

1: Creation of matter through pair production stops once the temperature has dropped to about 10^9 K.

100: Protons and neutrons fuse together to form small nuclei eg helium. Expansion is so rapid that heaviest element is lithium. 25% of matter is primordial helium.

Question 27

Evolution of the universe (later)

Answer 27

380,000: Universe cools enough for atoms to form. EM radiation from this stage is now CMBR

30 million: First stars appear. Nuclear fusion in these stars allows elements beyond lithium to form.

200 million: The Milky Way forms as gravitational forced pull clouds of hydrogen and existing stars together.

9 billion: The solar system forms from nebulae left by a supernova. Planets form 1 billion years after the sun.

11 billion: Primitive life on earth begins 1 billion years after its creation

13.7 billion: Around 200,000 years ago the first modern humans evolve. Temperature is 2.7 K.

Question 28

Dark matter evidence

Answer 28

Velocity of stars in galaxies does not decrease further from the centre as predicted.
This can be explained if the mass of the galaxy is not concentrated in the centre but most visible mass is.
There must be another type of mass that we cannot see. 27% of the universe must be dark matter.

Question 29

Dark energy evidence

Answer 29

~All type 1A supernovae have the same luminosity so the distance can be measured using its intensity.
~Luminosity also measured from the dappled effect and they are not the same - dimmer than expected therefore further than expected.
~They are accelerating so there must be a resultant force
~This must mean there is energy supplying that force

Question 30

How to use the Doppler equations

Answer 30

Lambda and f are the values calculated in a lab.
Equation can only be used for a galaxies moving at far less than the speed of light.

Question 31

Age of the universe

Answer 31

Age (in seconds) = 1/H0

Question 32

Parsec

Answer 32

The distance at which a radius of 1 AU subtends an angle of one arcsecond (1/3600 degrees)

Question 33

Astronomical unit

Answer 33

1AU = 1.5x10^11

Question 34

Intensity of a star

Answer 34

I = P/A = L/A = L/4piD^2

Question 35

Wien’s law as a ratio

Answer 35

m1/m2 = T2/T1

Question 36

Homogeneous

Answer 36

Uniform in terms of the distribution of matter across the universe when viewed on a sufficiently large scale.

Question 37

Isotropic

Answer 37

The same in all directions - for example the universe appearing the same to any observer regardless of position.

Question 38

CMBR

Answer 38

Cosmic Microwave Background Radiation. Likely caused by and therefore evidence for the big bang. Gamma radiation from big bang stretched with universe expansion so now microwaves.
Temperature of 2.7K

Question 39

Hubble’s law

Answer 39

The recessional speed v of a galaxy is almost directly proportional to its distance d from Earth.

Question 40

Hubble equation

Answer 40

v = H0d

Question 41

Cosmological principle

Answer 41

The assumption that, when viewed on a large enough scale, the universe is homogeneous and isotropic, and the laws of physics are universal.

Question 42

Satellite

Answer 42

A body orbiting around a planet

Question 43

Geostationary satellite

Answer 43

One that remains in the same position relative to a spot on the Earth’s surface by orbiting in the direction of the Earth’s rotation over the equator with a period of 24 hours.

Question 44

Derivation of speed of a satellite

Answer 44

F = mv^2/r = GMm/r^2
v = root(GM/r)

Question 45

Kepler’s first law

Answer 45

The orbit of a planet is an ellipse with the Sun at one of the foci.

Question 46

Kepler’s second law

Answer 46

A line segment connecting a planet to the Sun sweeps out equal areas during equal intervals of time.

Question 47

Kepler’s third law

Answer 47

The square of the orbital period T of a planet is directly proportional to the cube of its average distance r from the sun.

Question 48

Emission line spectra

Answer 48

Each element produces a unique emission line spectrum because of its unique set of energy levels.

Question 49

Continuous spectra

Answer 49

All visible frequencies of wavelengths are present. The atoms of a heated solid metal (eg a lamp filament) will produce this type of spectrum.

Question 50

Absorption line spectra

Answer 50

This type of spectrum has a series of dark spectral lines against the background of a continuous spectrum. The dark lines have exactly the same wavelengths as the bright emission spectral lines for the same gas atoms.