Deck 2: Light and Telescopes

A) Visible
B) Radio
C) Ultraviolet
D) X-ray
E) Gamma ray

A) Fahrenheit.
B) Celsius.
C) Kelvin.
D) centigrade.
E) Ransom.

A) Gamma ray
B) X-ray
C) Ultraviolet
D) Visible
E) Infrared

A) The visible
B) The X-ray
C) The ultraviolet
D) The radio
E) The infrared

A) gamma rays.
B) ultraviolet rays.
C) visible light.
D) microwaves.
E) radio waves.

A) X-rays and gamma rays.
B) ultraviolet and visible light.
C) visible and infrared light.
D) visible and radio waves.
E) infrared and microwaves.

A) radius.
B) mass.
C) magnetic fields.
D) temperature.
E) direction of motion.

A) Amplitude
B) Wavelength
C) Frequency
D) Velocity
E) Photon energy

A) temperature.
B) radius.
C) line-of-sight speed.
D) chemical composition.

A) It appears black to us, regardless of its temperature.
B) Its energy is not a continuum.
C) Its energy peaks at the wavelength determined by its temperature.
D) If its temperature doubled, the peak in its curve would be doubled in wavelength.
E) It has a complete absence of thermal energy.

A) the wavelength in angstroms.
B) the amplitude in nm.
C) the frequency in Hertz.
D) the period in seconds.
E) the energy in milliwatts.

A) The visible
B) The X-ray
C) The ultraviolet
D) The radio
E) The infrared

A) The wavelength is 4.
B) The wavelength is 6.
C) The wavelength is 8.
D) The wavelength is 12.
E) The wavelength cannot be determined from this diagram.

A) red.
B) orange.
C) green.
D) blue.
E) violet.

A) a blueshift.
B) a redshift.
C) a shift in peak wavelength towards the red.
D) a shift in peak wavelength towards the blue.
E) no shift.

A) is halved.
B) is also doubled.
C) is unchanged, as c is constant.
D) is now 4 times longer.
E) becomes 16 times longer.

A) frequency times the period of the wave.
B) period times the energy of the wave.
C) amplitude times the frequency of the wave.
D) frequency times the wavelength of the wave.
E) amplitude times the wavelength of the wave.

A) The amplitude is 4.
B) The amplitude is 6.
C) The amplitude is 8.
D) The amplitude is 12.
E) The amplitude cannot be determined from this diagram.

A) proton.
B) electron.
C) neutron.
D) atom.
E) neutrino.

A) a continuum, strongest in the color red.
B) a few bright lines against a dark background.
C) a few dark lines in the continuum.
D) a continuum, but with both bright and dark lines mixed in.
E) not in the visible portion of the spectrum.

A) Large scopes have a larger field of view and sharper focus.
B) Large scopes are not subject to atmospheric turbulence and opacity like smaller ones.
C) Large scopes are easier to mount and control than small ones.
D) Large telescope have more light gathering power and better resolution.
E) Large telescopes give higher magnification and are easier to build.

A) To magnify and make distant objects appear closer.
B) To separate light into its component colors.
C) To measure the intensity of light very accurately.
D) To access wavelengths that we cannot see visually.
E) To collect a lot of light and bring it to a focus.

A) attract funding from NASA and the NSF.
B) give greater magnification.
C) increase their angular resolution and collect the very weak radio photons.
D) increase the range of waves they can collect.
E) detect shorter waves than optical telescopes for superior resolution.

A) proton.
B) ion.
C) neutrino.
D) neutron.
E) lepton.

A) They are badly affected by poor seeing and atmospheric turbulence.
B) The lightest breeze shakes them, making the observations blurry.
C) Their waves are blocked by water vapor, so they must be located in deserts.
D) Radio waves have long wavelengths, so radio telescopes have poor resolution.
E) The dust clouds in the Milky Way block almost all wavelengths except light.

A) Cassegrain reflector
B) Newtonian reflector
C) Prime focus reflector
D) Refractor
E) Interferometer

A) a continuous spectrum, since the neon is hot enough to glow.
B) a few bright emission lines, telling us the gas is neon.
C) a continuum, with dark lines identifying the neon atoms that are present.
D) a lot of random bright red lines due to the motion of the hot atoms.
E) nothing visible to us, but a lot of infrared lines as heat.

A) yield better seeing conditions with optical telescopes.
B) decrease the effects of light pollution in getting darker sky backgrounds.
C) improve the angular resolution of radio telescopes.
D) increase the sensitivity of infrared telescopes to longer wavelengths.
E) speed up the processing of CCD images.

A) Kirchhoff.
B) Bohr.
C) Fraunhofer.
D) Newton.
E) Mendeleev.

A) Molecules have two or more atoms.
B) Molecules can vibrate and rotate as well.
C) Molecules are heavier than atoms.
D) Molecules are the basis of life.
E) Most of the universe is made of molecules, not individual atoms.

A) Its ability to see very faint objects
B) Its ability to distinguish two adjacent objects close together in the sky
C) Its ability to make distant objects appear much closer to us
D) Its ability to separate light into its component colors for analysis
E) Its ability to focus more than just visible light for imaging

A) only make transitions between orbitals of specific energies.
B) are not confined to specific orbits.
C) are spread uniformly through a large, positive mass.
D) can be halfway between orbits.
E) move from orbit to orbit in many small steps.

A) they're less expensive to make than optical telescopes.
B) radio photons don't carry much energy.
C) atmospheric turbulence is more of a problem.
D) radio sources are harder to find.
E) radio waves are absorbed by the atmosphere.

A) redder than it is.
B) bluer than it is.
C) brighter than it is.
D) fainter than it is.
E) lower temperature than it is.

A) They have poorer angular resolution than a refractor.
B) They have better angular resolution than a reflector.
C) They are the smallest, most compact telescopes.
D) They can only be used above the atmosphere.
E) They are most sensitive to the opacity of the ozone layer.

A) 2× better
B) 4× better
C) 8× better
D) 16× better
E) 32× better

A) An analysis of the way in which atoms absorb and emit light
B) A study of the geometry of rainbows
C) An observational technique to measure the brightness of light at different colors
D) The use of CCDs to capture light more efficiently than with photographic film
E) A method to freeze atmospheric turbulence for better resolution

A) Defects in the optics of the telescope, such as the original Hubble mirror
B) The opacity of the Earth's atmosphere to some wavelengths of light
C) The light pollution of urban areas
D) Turbulence in the Earth's atmosphere which creates twinkling
E) Chromatic aberration due to use of only a single lens objective

A) Schmidt corrector plates
B) More sensitive spectrometers
C) Switching from film to CCD imaging
D) Use of interferometers
E) Chilling the infrared detectors

A) lenses made of germanium.
B) the prime focus design, with mirrors made of iron.
C) grazing incidence optics.
D) achromatic lenses to keep the X-rays in focus.
E) the Cassegrain design, with mirrors made of lead.

A) Radio
B) Infrared
C) Optical
D) Ultraviolet
E) X-ray

A) 7
B) 5
C) 3
D) 1
E) 0

A) radio waves are not scattered or deflected by Earth's atmosphere.
B) radio observations can be made even when the Sun is in the sky.
C) radio observations can be made even when the sky is obscured by clouds.
D) radio observations let astronomers study things that emit little visible light.
E) all of the above.

A) Gamma rays
B) X-rays
C) Ultraviolet
D) Microwaves
E) We now can access information in all spectral lengths.