Astronomy

Question 1

Principal Axis

Answer 1

The straight line through the centre of the lens perpendicular to the lens

Question 2

Converging Lens

Answer 2

Convex lens which makes parallel rays converge to a focal point/principal lens

Question 3

Diverging Lens

Answer 3

Concave lens which makes parallel rays diverge. The point where the rays appear to come from is the principle focus/focal point

Question 4

Focal Length

Answer 4

Distance between centre of the lens to the focal point

Question 5

Focal Plane

Answer 5

The plane of each side of the lens perpendicular to the principal axis containing the principal focus

Question 6

Real Image

Answer 6

With the object at different distances beyond the principal focus of the lens, the position of the screen is adjusted until a clear image of the object is seen on the screen. The image is described as a Real Image because it is formed on the screen where the light rays converge

Question 7

Virtual Image

Answer 7

With the object nearer to the lens than the principal focus, a magnified image is formed. The lens acts a magnifying glass. But the image can only be seen when you look into the lens from the other side of the object. The image is called a Virtual Image because it is formed where the light rays appear to come from.

Question 8

Magnifying Glass

Answer 8

The image is virtual, upright and larger than the object; only seen by viewing it through the lens

Question 9

Normal Adjustment

Answer 9

When a telescope is adjusted so the virtual image seen by the viewer is at infinity;
Normal adjustment is when the distance between the objective and the eyepiece is equal to their focal lengths added together.

Question 10

Angular Magnification

Answer 10

The ratio of the angle subtended at the eye by the image formed by an optical instrument to that subtended at the eye by the object when not viewed through the instrument.

Angular magnification = focal length of objective/focal length of eyepiece

Question 11

Collecting Power

Answer 11

The amount of light a telescope collects (which is proportional to the square of the objective diameter)

Question 12

Spherical Aberration

Answer 12

Optical effect that occurs when incoming light rays focus at different points due to the surface geometry of the mirror

Question 13

Chromatic Aberration

Answer 13

Optical effect that occurs when the refraction of different wavelengths of light through a lens fails to converge at a single point

Question 14

Angular Separation

Answer 14

The angular difference between two objects

Question 15

Rayleigh Criterion

Answer 15

Resolution of the images of two point objects is not possible if any part of the central spot of either image lies inside the first dark ring of the other image.

Question 16

Minimum Angular Resolution

Answer 16

θ = λ/D

Question 17

Charge Coupled Device (CCD)

Answer 17

Integrated circuit etched onto a silicon surface forming light-sensitive elements called pixels

Question 18

Parallax

Answer 18

The apparent displacement of an observed object due to a change in the position of the observer

Question 19

Astronomical Unit (AU)

Answer 19

Mean distance between the centre of the Sun to the Earth

1 AU = 1.496x10^11 m

Question 20

Parallax Angle

Answer 20

The angle subtended to the star by the line between the Sun and the Earth

Question 21

Parsec

Answer 21

1 Parsec (pc) is the distance to a star at which 1 astronomical unit subtends an angle of 1 arcsecond (3.08x10^16m)

Question 22

Intensity

Answer 22

Light energy per second per unit surface area received from a star at normal incidence on a surface

Question 23

Hipparcos Scale

Answer 23

First classification of stars in six magnitudes of brightness; a star with magnitude 1 being one of the brightest in the sky, and a star of magnitude 6 being just visible to the human eye

Question 24

Apparent Magnitude (m)

Answer 24

A number that is a measure of its brightness as seen by an observer on Earth. The brighter an object appears, the lower it’s magnitude value. (The Sun, at apparent magnitude of −26.7, is the brightest object in the sky)

Question 25

Absolute Magnitude (M)

Answer 25

The magnitude the star would have if it was placed at a distance of 10 parsecs from Earth (The Sun has an absolute magnitude of 4.83)

Question 26

Inverse Square Law

Answer 26

I ∝ 1/d^2

Intensity ∝ 1/(distance from Earth)^2

Question 27

Black Body Radiation

Answer 27

A Black Body is a body that is a perfect absorber of radiation (absorbs 100% of incident radiation of all wavelengths). The thermal electromagnetic radiation emitted from a Black Body is referred to as Black Body Radiation

Question 28

Wien’s Displacement Law

Answer 28

λ(max)*T = constant = 0.0029 mK

Question 29

Photosphere

Answer 29

The light-emitting outer layer of a given star (One uses Wien’s Law to work out the absolute temperature T of this layer). Often referred to as the surface of the star

Question 30

Stefan’s Law

Answer 30

P = σAT^4

Power output of the star = (Stefan-Boltzmann Constant)(Surface Area)(Absolute Temperature)^4

Question 31

Luminosity

Answer 31

Power Output of a star

Question 32

Balmer Lines

Answer 32

The name given to the hydrogen absorption lines corresponding to the excitation of hydrogen atoms from the n=2 state to higher energy levels. These can be used in addition to T to determine the spectral class of a star

Question 33

Dwarf Star

Answer 33

A star that is much smaller in diameter than the Sun

Question 34

Giant Star

Answer 34

A star that is much larger in diameter than the Sun

Question 35

Supernova

Answer 35

Rapid expulsion of mass due to a collapsing star that releases so much energy as to outshine its host galaxy

Question 36

Standard Candles

Answer 36

A class of objects whose distance can be found due to their known peak luminosity/absolute magnitude (approx M = -19) and presence of strong silicon absorption line

Question 37

Dark Energy

Answer 37

Hypothesis used to explain the breakdown of Hubble expansion laws at large distances

Question 38

Neutron Star

Answer 38

Core of a supernova after all the surrounding matter has been thrown off into space. It is extremely small in size compared with a star such as the Sun

Question 39

Pulsars

Answer 39

Rapidly rotating neutron star which emits radio waves in two beams (like a lighthouse)

Question 40

Black Hole

Answer 40

An object so dense that not even light can escape it due to the immense gravitational pull at its centre (an infinitely dense point called a singularity). This is because the escape velocity is greater than the speed of light (c)

Question 41

Event Horizon

Answer 41

Sphere surrounding the black hole from which nothing can emerge (the radius of which is the Schwarzschild radius; r = 2GM/c^2)

Question 42

Red Shift

Answer 42

The characteristic spectral lines of the elements are all at a longer wavelength than you would expect. Frequency falls and the wavelength increases as the object is moving away

Question 43

Blue Shift

Answer 43

The characteristic spectral lines of the elements are all at a shorter wavelength than you would expect. Frequency increases and the wavelength decreases if the object is moving nearer

Question 44

Doppler Shift

Answer 44

The change in wavelength and frequency as an object moves towards/away from the viewer

Question 45

Spectroscopic Binary

Answer 45

Two or more stars that orbit each other but are too far away to be individually resolved

Question 46

Hubble’s Law

Answer 46

v = Hd

Question 47

Big Bang Theory

Answer 47

The theory that the universe was created in a massive primordial explosion and has been expanding ever since

Question 48

Quasar

Answer 48

A supermassive black hole surrounded by orbiting disks of gas; more like a massive star than a galaxy in terms of size, but its light output is on a galactic scale or greater

Question 49

Supermassive Black Hole

Answer 49

Largest type of black hole, on the order of hundreds of thousands to billions of solar masses, and is found in the centre of almost all currently known massive galaxies (including the Milky Way)

Question 50

Exoplanets

Answer 50

A planet that orbits a star outside our solar system