Astrophysics for NERDSSS hahahahaha ur mom L+Ratio (goodluck on ur exam pookie bear)

Question 1

What is a black body radiator?

Answer 1

A ​perfect emitter and absorber of all possible wavelengths of radiation​.
(Stars are approximated as black bodies.)

Question 2

What is Stefan’s Law?

Answer 2

The power output of a black body radiator is directly proportional to its surface area and its (absolute temperature)^4
(on data sheet)

Question 3

What is Wein’s Displacement Law?

Answer 3

The peak wavelength of emitted radiation is inversely proportional to the absolute temperature of the object.
The peak wavelength of light is released at maximum intensity.
(on data sheet = 0.0029 meters Kelvin)

Question 4

Black Body Curves?

Answer 4

Following Stefan’s Law, as the intensity of the light increases, so does it’s temperature.
Following Wein’s Law, as the temperature increases, so does the peak frequency.

Question 5

How does intensity relate to power?

Answer 5

Intensity in inversely proportional to the distance between star and observer.

I = P / 4πd^2 (NOT on data sheet)

Question 6

How can stars be classified and a proof of procedure?

Answer 6

Into different spectral classes based on the strength of absorption lines, which depend on the temperature of the star because the energy of the particles which make up the star is dependant on its temperature.

Hydrogen Balmer lines are found in the spectra of type O, B and (strongest is) A stars. They are caused by the excitation of Hydrogen atoms from the n = 2 state to higher/ lower energy levels.

If the temperature of a star is too high, the hydrogen atoms may be excited to higher levels or the electrons may be ionised. If the temperature is too low, the hydrogen atoms may not become ionised. In both cases Hydrogen Balmer lines will not be present.

Question 7

Spectral Class - Colour - Temperature range (K) - Prominent Absorption Lines

Answer 7

O - Blue - 25,000-50,000 - He+, He, H
B - Blue - 11,000-25,000 - He, H
A - Blue/White - 7,500-11,000 - H, ionised metals
F - White - 6,000-7,500 - Ionised metals
G - Yellow/ White - 5,000-6,000 - Ionised and neutral metals
K - Orange - 3,500-5,000 - Neutral metals
M - Red - <3,500 - Neutral atoms, titanium oxide

Question 8

How are Hertzsprung-Russell Diagrams set up?

Answer 8

Absolute magnitude on the y-axis ((bottom)15 to (top) -15).
Temperature, logarithmically, on the x-axis.
(maybe a little diagram is needed)

Question 9

How can the Sun be classified?

Answer 9

It is a main sequence star, in spectral class G with absolute magnitude 4.83

Question 10

How will a Sun like star’s evolution trace onto a HR diagram?

Answer 10

1. Once the Main Sequence star uses up all the hydrogen in its core, it will move up and to the right as it becomes a Red Giant. Red Giants are brighter and cooler.
2. Once the Red Giant uses up all the helium in its core, it will eject its outer layers and will move down and to the left as it becomes a White Dwarf. A White Dwarf is hotter and dimmer.

(maybe a cutie pie little diagram is needed)

Question 11

What are the stages of stellar evolution?

Answer 11

1. Protostar: clouds of gas and dust (nebulae) which clump together under gravity. Under gravity and for the conservation of angular momentum, the clumps form a dense centre (a protostar).
2. Main Sequence: gravity is balanced by the energy produced through fusion of Hydrogen into Helium so the star is stable and in equilibrium.
   The greater the mass of the star, the shorter its main sequence period is (they sue fuel more quickly).

3.1 Red Giant (if < 3 solar masses): hydrogen runs out and the temperature of the core increases to begin fusing helium nuclei into heavier elements. The outer layers expand and cool.

4.11 White Dwarf (if <1.4 solar masses): when a Red Giant uses up all its fuel, fusion stops and the core contracts as gravity is now greater than the outwards force.
The outer layers are thrown off forming a planetary nebula around the very dense remaining core.

5.11 Black Dwarf: white dwarfs eventually cool to form black dwarfs.

3.2 Red Supergiant (if > 3 solar masses): a larger scale process occurs. They can fuse elements up to iron.

4.2 Supernova: When all fuel runs out, fusion stops and the core collapses inwards very suddenly and becomes rigid, the out layers then rebound off of the core, launching them out into space in a shockwave (can also cause gamma ray bursts).
As the shockwave passes through surrounding material, elements heavier than iron can then be fused.
Supernovae rapidly increase in absolute magnitude and may release around 10^44 J of energy (which the sun outputs in 10 billion years).

5.21 Neutron Star (if 1.4 < it < 3 solar masses): Gravity forces protons and electrons together to form neutrons.
Their density is about 10^17 kgm^-3.
Pulsars are spinning neutron stars that emit beams of radiation from the magnetic poles as they spin.

5.22 Black Holes (if > 3 solar masses): when the core of a giant star collapses, neutrons are unable to withstand gravity forcing them together.
The event horizon is the point at which the escape velocity is greater than the speed of light.
The Schwarzchild radius is the radius of the event horizon.

Question 12

What is a binary system?

Answer 12

A system where two stars orbit a common centre of mass.

Question 13

What are the type of supernova?

Answer 13

Type I: when a star accumulates matter from its companion star in a binary system and explodes after reaching a critical mass.

Type II: the death of a high mass star after it runs out of fuel.

Question 14

What are type 1a supernova and why are they used as standard candles?

Answer 14

Type 1a supernova are Type 1 supernova with a white dwarf (the companion star runs out of hydrogen and expands allowing the white dwarf to accumulate its mass). When the white dwarf star reaches a critical mass, fusion begins and as its mass continuous to increase, the white dwarf explodes.

All types of supernovae occur at the same critical temperature, so they have very similar peak absolute magnitudes, about -19.3, and produce very consistent light curves, maximum peak about 20 days after the steep incline in magnitude (although this is conventionally day 0).

Question 15

Why do scientist believe there are supermassive black holes at the centre of all galaxies?

Answer 15

The stars and gas near the centre of galaxies appear to be orbiting very quickly, so there must be a supermassive object at the centre with a very strong gravitational field attracting them.

Question 16

How do supermassive black holes form?

Answer 16

-The collapse of massive gas clouds while the galaxy was forming.
-A normal black hole accumulating huge amounts of matter.
-Several normal black holes merging together.

Question 17

What does the brightness of Type 1a supernovae show?

Answer 17

The expansion of the universe is speeding up.
If it was slowing down, more distant objects would appear to be receding more quickly​, since expansion was faster in the past.
And objects would also appear brighter than predicted as they would be closer than expected. However, Type 1a supernovae have been seen to be ​dimmer than they were expected to be​, meaning they are more distant than Hubble’s law predicted​. This suggests that​ the expansion of the universe is accelerating ​and it is actually older than Hubble’s law estimates.

Question 18

What is dark energy?

Answer 18

Dark energy​ is described as having an ​overall repulsive effect throughout the whole universe​.

Since gravity follows the inverse square law​, it decreases with distance. But since dark energy remains ​constant​ all throughout the universe, it has a greater effect than gravity and is therefore thought to be ​causing the expansion speed to increase​.

Dark energy​ is ​controversial​ because ​there is evidence for its existence but no one knows what it is or what is causing it​.

Question 19

How does the doppler effect provide evidence for an expanding universe?

Answer 19

The Doppler effect causes the line spectra of distant objects to be shifted either towards the ​blue end of the visible spectrum when they move ​towards the Earth​ or towards the ​red end of the spectrum when they move ​away from the Earth​.

The more distant the object, the ​greater its red-shift, suggesting that the universe is expanding.

Red shift formulae (on data sheet) were derived without taking relativistic accounts into effect.

The z value is also known as the redshift (so is positive for red shift and negative for blue shift).

Question 20

What are spectroscopic binaries?

Answer 20

Binary star systems in which the stars are too close to be resolved.

They can be identified by using the doppler shifts of each star.

Question 21

What are eclipsing binaries?

Answer 21

When the plane of orbit of the stars is in the line of sight from Earth to the system, meaning the stars cross in front of each other as they orbit.

They can be identified by their light curve characteristics. (a wittle diagram pwease) (die in a ditch).

Question 22

What is Hubble’s Law?

Answer 22

Hubble’s Law states that a galaxy’s recessional velocity is directly proportional to its distance from the Earth.

Therefore, the universe is expanding from a common starting point.

Question 23

What’s an estimate of the age of the universe?

Answer 23

v = Hd
1 / H = d / v
1 / H = t
(H needs to be converted into SI units (should be about 15 billion years))

Question 24

What does the Big Bang Theory say and what is some evidence for it?

Answer 24

That the universe started with a huge explosion from a singularity that was infinitely small and infinitely hot.

When this happened , high energy radiation would have been produced. As the universe expanded and cooled, the radiation would have lost energy and been red shifted. Its remains are CMBR.

During the early stages of the Big Bang, nuclear fusion would have converted hydrogen nuclei into helium nuclei, before the universe cooled and nuclear fusion would have stopped. The fact that the relative abundance of H:He is 3:1 is more evidence for the Big Bang model of the universe.

Question 25

What are quasars?

Answer 25

Quasars are active galactic nuclei (a supermassive black hole surrounded by a disc of matter which causes jets of radiation to be emitted from the poles as it falls into the black hole.

They are characterised as having the following features:
-large optical red shifts
-extremely powerful light outputs
-not much bigger than the sun in size

Quasars are thought to be some of the most distant measurable objects in the known universe.
The inverse square law shows that quasars can have the same energy output as several galaxies.

Quasars have much greater radio emissions than stars.

Question 26

What are exoplanets?

Answer 26

Planets that orbit other stars which are not within our solar system.

Question 27

How can exoplanets be detected?

Answer 27

Since they tend to be obscured by the light of their host stars they can either be detected by:

(1) The radial velocity method (or wobble effect): works on the same method used to detect spectroscopic binaries. The effect is most noticeable with ​high-mass planets since they have a greater gravitational pull on the star. The line spectrum of the star is blue-shifted when it moves towards the Earth, then red-shifted when it moves away. This shows that there is something else near the star that is exerting a gravitational force on it – the exoplanet. The​ time period (T)​ of the planet’s orbit is​ equal to the time period of the Doppler shift​.

(2) The Transit method: this involves observing the ​intensity of the light output​ ​of a star. If a planet ​crosses in front of a star, the intensity dips slightly. If the intensity of a star dips ​regularly​, it could be a sign that there is an exoplanet orbiting it. If there are variations in the regularity of the dips, there may be several planets orbiting the same star which have a gravitational effect on the transiting planet.

The ​size​ and the​ orbital period​ of the planet can be determined from the ​amount​ that the intensity falls by and the ​duration​ of the dip respectively. However, the application of this method is limited since it ​only works if the line of sight to the star is in the plane of the planet’s orbit​, which is ​more likely for planets with small orbits​. This is because most orbits are ​inclined​ (do not pass in front of the star when observed from the Earth), and smaller orbits mean that parts of the planet are more likely to cross in front of the star and block some of its light.

(a diagram of the intensity dipping)

Question 28

What is luminosity?

Answer 28

Rate of light energy released/ power output of a star?

Question 29

What is intensity?

Answer 29

The power received from a star (its luminosity) per unit area, measured in Wm^-2.

It is the effective brightness of an object.

Question 30

What is the apparent magnitude, m, of an object?

Answer 30

How bright the object appears in the night sky.

Question 31

What is the Hipparcos scale?

Answer 31

A logarithmic scale which classifies astronomical objects by their apparent magnitudes. 1 is the brightest, 6 is the faintest. The intensity changes with a ratio of 2.52 (a magnitude 5 star is 2.51 times brighter than a magnitude 6 star).

Question 32

What is the absolute magnitude, M, of an object?

Answer 32

Its apparent magnitude if it were 10 parsecs away from the Earth.

Question 33

What is parallax?

Answer 33

The ​apparent change of position of a nearer star in comparison to distant stars​ in the background, ​as a result of the orbit of the Earth around the Sun.​ The property is measured by the ​angle of parallax (θ)​. The greater the angle of parallax, the closer the star is to the Earth.
(a little diagram)

Question 34

What is 1 Astronomical Unit?

Answer 34

The average distance between the centre of the Earth and centre of the Sun.

Question 35

What is one Parsec?

Answer 35

The distance at which the angle of parallax is 1 acrsecond (1/3600th of a degree).

The distance at which 1 AU subtends an angle of 1 arc second.

Question 36

What is a Light Year?

Answer 36

The distance that an EM waves travels in a year in a vacuum.

Question 37

What does a convex lens do?

Answer 37

It focuses incident light

Question 38

What does a concave lens do?

Answer 38

It spreads out incident light.

Question 39

What is the principal axis?

Answer 39

The line passing through the centre of the lens at 90° to its surface.

Question 40

What is the principal focus, F?

Answer 40

The point where the light converges or appears to come from.

Question 41

What is the focal length, f?

Answer 41

The distance between the centre of the lens and the principal focus.

Question 42

What is a real and virtual image?

Answer 42

Real image: formed when light rays cross after refraction, can be formed on a screen.

Virtual image: formed on same side of the lens.

Question 43

What is the lens formula?

Answer 43

1 / u + 1 / v = 1 / f
where u is the distance of the object from the centre of the lens
where v is the distance of the image from the centre of the lens
where f is the focal length of the lens

Question 44

What is the power of a lens?

Answer 44

A measure of how closely a lens can focus a beam that is parallel to the principal axis (how short the focal length is).
Measured in Dioptres (D) and is equal to 1 / f

Question 45

When can the magnifying power of a telescope by written in terms of focal lengths of the lenses?

Answer 45

When the two angles are both less than 10°

Question 46

Refracting telescopes (complete with a little diagram)

Answer 46

Refracting telescopes​ are comprised of ​two converging lenses​:

(1) The ​objective lens​: which ​collects light​ and creates a ​real image​ of a distant object.
This lens should have a ​long focal length​ and be ​large​ so as to collect as much light as possible​.

(2) The ​eyepiece lens​: which ​magnifies the image​ produced by the objective lens so that the observer can see it. This lens produces a ​virtual image at infinity​ since the light rays are parallel. This ​reduces eye strain​ for the observer as they do not have to refocus every time they look between the telescope image and the object in the sky.

Question 47

What is normal adjustment?

Answer 47

When the distance between the lenses is equal to the sum of their focal lengths.

This means the principal of focus (F) for the two lenses is in the same place.

Question 48

Little diagrams of reflecting telescopes?

Answer 48

Reflecting telescopes come in several configurations, but the most common of these is the Cassegrain reflecting telescope​. This involves a ​concave primary mirror​ with a ​long focal length ​and a s​mall convex secondary mirror​ in the centre. The convex mirror ​allows the Cassegrain to be shorter​ than other configurations, such as the Newtonian reflecting telescope which utilises a plane mirror instead. The light is collected and focused onto an eyepiece lens.

The mirrors in a reflecting telescope are often a very thin coating of aluminium or silver atoms that are deposited onto a backing material, so they can be as smooth as possible and minimise distortions.

Question 49

What are the causes and effects aberrations?

Answer 49

(with little diagrams of course)

(1) Chromatic aberrations: caused by light of different wavelengths diffracting by different amounts and produces an image with coloured fringing with the effect being most noticeable for the light passing through the edges of the lens. It does not affect reflecting telescopes.

(2) Spherical aberrations: caused by the curvature of a lens or mirror focusing light rays at edge to different positions. The effect is more pronounced in lenses with large diameters and can be avoided by using parabolic objective mirrors in reflecting telescopes.

Question 50

How can the aberrations be minimised?

Answer 50

By use of achromatic doublet, which is a convex lens of crown glass and concave lens made of flint glass cemented together in order to bring all rays of light into focus in the same position (+ diagram).

Question 51

What are some disadvantages of refracting telescopes and advantages of reflecting telescopes?

Answer 51

-Large magnifications require a large diameter objective lens with a long focal length made of glass which must be pure and free from defects.
-Large composite primary mirrors can be made from lots of smaller segments and can be very thin.

-Large lenses can bend and distort under their own weight and can be difficult to manoeuvre and support as they can only be supported from their edges.
-Mirrors are not as heavy as lenses so they are easier to handle and manoeuvre ad can be supported from behind.

-Chromatic and spherical aberration both affect lenses.
-Mirrors are unaffected by chromatic aberration, and the eyepiece can be corrected with a chromatic doublet, and spherical aberrations can be prevented by using parabolic mirrors.

Question 52

Radio telescope:

Answer 52

Ground based -but in isolated regions to avoid interference from nearby radio sources. The simplest are parabolic dishes which focus radio waves onto a receiver (diagram).

Question 53

What are the similarities and differences between radio and optical telescopes?

Answer 53

Similarities:
-both intercept and focus oncoming radiation to detect its intensity.
-both can be moved to focus on different sources of radiation, or to track a moving source.
-the parabolic dish of a radio telescope is very similar to the objective mirror of a reflecting telescope.
-both can be ground based.

Differences:
-radio telescopes need to have much larger diameters to achieve the same quality/ have the same resolving power (so they end up having larger collecting powers).
-radio telescopes are simpler and cheaper, a wire mesh can be used instead of mirrors so long as the mesh size is less than the wavelength/20.
-radio telescopes move across an area to build up an image.
-radio telescopes experience a lot of man made interference (like form radio transmissions), optical telescopes experience a lot of natural interference (like from weather, (and light pollution))

Question 54

Infrared telescopes?

Answer 54

They consist of​ large concave mirrors​ which focus radiation onto a detector.
Since all objects emit infrared radiation as heat, they must be ​cooled to ​almost absolute zero​ by liquid nitrogen. They also must be ​well shielded​ to avoid thermal contamination​ from nearby objects as well as its own infrared emissions.
Infrared telescopes are used to observe ​cooler regions in space​. However, the ​atmosphere absorbs most infrared radiation​ so these telescopes must be space based and accessed remotely​ from the ground.

Question 55

Ultraviolet telescopes?

Answer 55

The ozone layer blocks all ultraviolet rays that have a wavelength of less than 300nm​, meaning UV telescopes also need to be space​ based.
These telescopes utilise the ​Cassegrain configuration​ to bring ultraviolet rays to a focus. The rays are detected by ​solid state devices which use the photoelectric effect to convert UV photons into electrons, which then pass around a circuit.
UV telescopes can be used to observe the ​interstellar medium and star formation regions​.

Question 56

X-ray telescopes?

Answer 56

Since ​all X-rays are absorbed by the atmosphere​, these telescopes​ ​need​ to be in space​ to collect data.
These rays have such high energy that they would just pass straight through normal mirrors. This means that X-ray telescopes must be made from a combination of parabolic and hyperbolic mirrors​, all of which must be extremely smooth. The rays enter the telescope, skim off the mirrors, and are brought into focus on CCDs which ​convert light into electrical pulses​.
They can be used to observe high-energy events and areas of space such as ​active galaxies, black holes and neutron stars​.

Question 57

Gamma telescopes?

Answer 57

These telescopes do not use mirrors at all as gamma rays would just pass straight through. Instead, they use a ​detector made of layers of pixels​. As the gamma photons pass through, they ​cause a signal in each pixel they come into contact with​.
These telescopes are used to observe things such as ​gamma ray bursts (GRBs), quasars, black holes and solar flares​.

Question 58

What are the types of GRBs?

Answer 58

(1) Short-lived​ -​ ​these last anywhere ​between 0.01 and 1 second​, and are thought to be
associated with merging neutron stars (forming a black hole), or a neutron star falling into a black hole.

(2) Long-lived​ -​ these can last ​between 10 and 1000 seconds​, and they are associated with
a ​Type II supernova​

Question 59

What is collecting power?

Answer 59

A measure of the ability of a lens or mirror to collect incident EM radiation. It is directly proportional to the area of the objective lens.

The greater the collecting power, the brighter the images produced by the telescope.

Question 60

What is the resolving power?

Answer 60

​The ability of a telescope to produce separate images of close-together objects​. For an image to be resolved, the angle between the straight lines from Earth to each object must be at least the ​minimum angular resolution (θ)​, where θ is in ​radians and given by the Rayleigh Criterion.

Question 61

What is the definition of the Raleigh Criterion?

Answer 61

Two objects will ​not be resolved​ if any part of the central maximum of either of the images falls within the first minimum diffraction ring of the other. (Think electron diffraction patterns)

Question 62

What are charged-coupled devices?

Answer 62

An array of light-sensitive pixels, which ​become charged when they are exposed to light by the photoelectric effect.

Question 63

What is quantum efficiency?

Answer 63

The percentage of incident photons which cause an electron to be released.

Question 64

How do CCDs and the eye compare?

Answer 64

Quantum efficiency: about 80% to about 5%

Spectral range: IR, UV, and visible to only visible

Pixel resolution (total number of pixels used to form an image: about 50 megapixels to about 500 megapixels

Spatial resolution: 10 micrometers to 100 micrometers

CCDs create images which can be shared and stored.
The eye is simpler to use and needs no additional equipment.