Deck 6: Telescopes: Portals of Discovery

A)1 m.
B)2 m.
C)5 m.
D)10 m.
E)100 m.

A)to reduce light pollution
B)to reduce light distortion
C)to reduce light absorption
D)to be able to observe at radio wavelengths
E)to be able to observe at infrared wavelengths

A)a point of light in Earth's atmosphere created by a laser for the purpose of monitoring atmospheric fluctuations
B)a satellite orbiting Earth
C)a meteor
D)a possible source of dark matter in the universe
E)the unseen member of a binary star system

A)eye,photographic film,CCD
B)photographic film,CCD,eye
C)CCD,eye,photographic film
D)CCD,photographic film,eye
E)eye,CCD,photographic film

A)the chemical composition of a distant star
B)the speed at which a distant galaxy is moving away from us
C)the surface temperature of a distant star
D)the rotation rate of a distant star
E)the size of a distant galaxy

A)Light pollution refers to pollution caused by light industry as opposed to heavy industry.
B)Light pollution refers to harmful gases emitted by common street lights.
C)Light pollution refers to light used for human activities that brightens the sky and hinders astronomical observations.
D)Light pollution refers to the lights that must be used inside major observatories and that make it difficult for astronomers' eyes to adapt to darkness.
E)Light pollution is another name for sunlight,which makes it impossible to see stars in the daytime.

A)radio waves
B)ultraviolet
C)X-rays
D)both B and C
E)both A and C

A)In a healthy eye,light is focused on the retina.
B)Film should be placed at the focal plane in a camera.
C)If you try to look at an image that is not formed at the focal plane,it will be blurry.
D)The focal plane of a reflecting telescope is always located within a few inches of the primary mirror.
E)Light can be focused with a lens or a mirror.

A)the rate at which a variable star brightens and dims
B)the general shape of an interstellar cloud of gas
C)the color of a planet
D)the brightness of a star in our sky
E)the number of bright stars in a nearby star cluster

A)CCDs allow long exposures (e.g. ,minutes or hours),and film does not.
B)CCDs can record the colors of astronomical objects accurately,while film cannot.
C)CCDs capture a much higher percentage of the incoming photons than does film.
D)Images recorded with CCDs never require any image processing,while images recorded by film often do.
E)CCDs can be attached to modern telescopes more easily than cameras.

A)It is closer to the stars.
B)Stars do not twinkle when observed from space.
C)It can observe infrared and ultraviolet light,as well as visible light.
D)It never has to close because of bad weather.
E)Observers on the ground can use it at any time of day (i.e. ,not only during their night).

A)studying how different stars differ in their chemical compositions
B)studying whether a particular star's brightness is steady or variable
C)determining the age of the solar system
D)measuring the rotation rate of a distant star
E)estimating the time since the Big Bang

A)Telescopes can collect far more light with far better angular resolution.
B)Telescopes can collect far more light with far greater magnification.
C)Telescopes have much more magnification and better angular resolution.
D)Telescopes collect more light and are unaffected by twinkling.
E)Telescopes can see farther without image distortion and can record more accurate colors.

A)You will not be able to see these two stars at all.
B)The two stars will look like a single point of light.
C)The two stars will appear to be touching,looking rather like a small dumbbell.
D)You will see two distinct stars.
E)You will see only the larger of the two stars,not the smaller one.

A)It is a measure of how much energy an object emits in different parts of the electromagnetic spectrum.
B)It is a measure of how close two spectral lines can be distinguished.
C)It is a measure of how close two point sources can be distinguished.
D)It is the same as angular resolution when applied to telescopes operating at different wavelengths.

A)They are always very pretty.
B)They are always displayed with the highest possible angular resolution.
C)They are always useful for seeing through things.
D)They are always displayed in false color.
E)They are always displayed with north pointing upward in the images.

A)It is the maximum size to which any telescope can be built.
B)It describes the farthest distance to which the telescope can see.
C)It describes the maximum exposure time for images captured with the telescope.
D)It is the best angular resolution the telescope could achieve with perfect optical quality and in the absence of atmospheric distortion.

A)It is intrinsic to the stars-their brightness varies as they expand and contract.
B)variations in the absorption of the atmosphere
C)variable absorption by interstellar gas along the line of sight to the star
D)bending of light rays by turbulent layers in the atmosphere
E)the inability of the human eye to see faint objects

A)New telescopes incorporate new technology to increase their efficiency.
B)Telescopes have to adapt to the greater distortion of the atmosphere at shorter wavelengths.
C)Photons of different energy have different wavelengths,some of which are not accessible from Earth's surface and require different collection strategies.
D)Light pollution is worse at radio wavelengths than visible wavelengths.
E)Astronomers and engineers enjoy the challenge of making new telescope designs.

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

A)It allows two or more telescopes to obtain a total light-collecting area much larger than the total light-collecting area of the individual telescopes.
B)It allows two or more telescopes to obtain the angular resolution of a single telescope much larger than any of the individual telescopes.
C)It allows us to determine the chemical composition of stars.
D)It allows astronomers to make astronomical observations without interference from light pollution.
E)It allows the same telescope to make images with both radio waves and visible light.

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

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

A)several football fields,in a natural depression in Puerto Rico.
B)tens of miles across,in the deserts of New Mexico.
C)the state of New Mexico.
D)the continental United States.
E)Earth.

A)radio
B)extreme infrared
C)visible
D)X-ray
E)gamma-ray

A)Telescopes can collect far more light with far better angular resolution.
B)Telescopes can collect far more light with far greater magnification.
C)Telescopes collect more light and are unaffected by twinkling.
D)Telescopes have much more magnification and better angular resolution.

A)twinkling of stars
B)light pollution
C)magnification of images
D)diffraction of light

A)It is an electronic detector that can be used in place of photographic film for making images.
B)It is an abbreviation for the world's largest operating telescope.
C)It refers to any kind of instrument that can be hooked up to a telescope.
D)It is a unit used by astronomers to measure angular resolution.

A)high angular resolution
B)high turbulence
C)a radio telescope
D)high spectral resolution

A)Light pollution is a type of air pollution created by lightweight gases such as hydrogen and helium.
B)Light pollution is light from human sources that makes it difficult to see the stars at night.
C)Light pollution means contamination of light caused by chemicals in the Earth's atmosphere.
D)Light pollution is a term used to describe the appearance of the sky in regions that are crowded with stars.

A)A refracting telescope uses a transparent glass lens to focus light while a reflecting telescope uses a mirror to focus light.
B)A refracting telescope produces refracted images while a reflecting telescope produces reflected images.
C)Reflecting telescopes make much clearer images than can refracting telescopes of the same size.
D)It is much easier to make a large refracting telescope than a large reflecting telescope.

A)the angular size of the smallest features that the telescope can see
B)the brightness of an image
C)the size of an image
D)the number of electromagnetic waves captured by an image

A)It is the upper surface of the telescope's primary lens or mirror.
B)It is the place where,if we mounted film or an electronic detector,we could get a clear (not blurry)image of an object viewed through the telescope.
C)It is the lower surface of the telescope's primary lens or mirror.
D)It is the surface of the lens on the eyepiece,through which you would look to see objects in the telescope's field of view.

A)It describes the farthest distance to which the telescope can see.
B)It is the angular resolution the telescope could achieve if nothing besides the size of its light-collecting area affected the quality of its images.
C)It is the maximum size to which any telescope can be built.
D)It describes the maximum exposure time for images captured with the telescope.

A)They are always shown with colors that are not the true colors of the objects that were photographed.
B)They always are made with adaptive optics.
C)They show us light with extremely long wavelengths compared to the wavelengths of visible light.
D)They always have very high angular resolution.
E)They are always very pretty.

A)about 1 degree
B)about 1 arcsecond (1/3600 of a degree)
C)about 1 arcminute,or 1/60 of a degree
D)about 1 milliarcsecond

A)filtering to look at just a single color from an object
B)timing to track how an object's brightness varies with time
C)spectroscopy to spread an object's light into a spectrum
D)imaging to get a picture of an astronomical objects

A)The one that still looks sharp at large size has better (smaller)angular resolution than the one that looks fuzzy.
B)The one that looks fuzzy at large size has better angular resolution (smaller)than the one that looks sharp.
C)Both photographs have the same angular resolution,because they were both printed at the same sizes in each case.
D)Both photographs have the same angular resolution,because they are both photographs of the same object.

A)studying how different planets differ in their surface compositions
B)studying how a star's brightness varies over a period of 3 years
C)measuring the rotation rate of a distant star
D)determining the age of the solar system

A)It allows two or more small telescopes to achieve the angular resolution of a much larger telescope.
B)It allows two or more small telescopes to achieve a larger light-collecting area than they would have independently.
C)It is designed to prevent light pollution from interfering with astronomical observations.
D)It reduces the twinkling of stars caused by atmospheric turbulence.

A)radio,visible,and very limited portions of the infrared and ultraviolet regions
B)all light with wavelengths longer than ultraviolet wavelengths
C)all light with wavelengths shorter than infrared wavelengths
D)infrared,visible,and ultraviolet light

A)Observatory X can detect dimmer stars and Observatory Y reveals more detail in images.
B)Observatory Y can detect dimmer stars and Observatory X reveals more detail in images.
C)Observatory X both detects dimmer stars and reveals more detail in images.
D)Observatory Y both detects dimmer stars and reveals more detail in images.

A)It is closer to the stars.
B)Stars do not twinkle when observed from space.
C)It can observe infrared and ultraviolet light,as well as visible light.
D)It never has to close because of cloudy skies.

A)The Keck I Telescope on Mauna Kea.
B)The Hubble Space Telescope.
C)The Arecibo Radio Telescope in Puerto Rico.
D)The Chandra X-Ray Observatory.

A)Over the 60-year period,telescopes have gradually gotten bigger and more powerful.
B)Although there have been advances in cameras and computing power,telescopes themselves have not changed much in the last 60 years.
C)The world's most powerful telescope remained the same for most of this period,but in the past 20 years many new and more powerful telescopes have been built.
D)The only major change in telescope power has occurred because of our ability to launch telescopes into space rather than operating them only from the ground.

A)X-rays are too dangerous to be allowed on the ground.
B)X-rays do not penetrate Earth's atmosphere.
C)X-ray telescopes require the use of grazing incidence mirrors.
D)It was built by NASA.

A)turbulence in the Earth's atmosphere.
B)rapid changes in the brightnesses and colors of stars caused by changes in their spectra.
C)light pollution.
D)the bubbling and boiling of gases on the surfaces of stars.

A)The photograph will have far better angular resolution than you can see with your eye.
B)By using a long exposure time,the photograph can allow you to see objects that would be too dim to see with your eye.
C)If taken with a camera with a sensitive detector such as a CCD,the photograph can capture a much larger percentage of the incoming photons than can your eye.
D)The photograph provides a more reliable record of what is seen through the telescope than can a drawing made by eye.

A)X-ray
B)Gamma-ray
C)Infrared
D)Radio

A)It will allow us to study the highly redshifted light of distant galaxies,enabling us to observe them as they first formed in the early universe.
B)The infrared is not easily visible from Earth's surface.
C)It will allow us to be closer to the most distant galaxies,so we get better pictures.
D)It will allow us to see into other universes that are not visible from Earth's surface.

A)The 8-meter telescope has 16 times the light-collecting area of the 2-meter telescope.
B)The 8-meter telescope has 4 times the light-collecting area of the 2-meter telescope.
C)The 8-meter telescope has 8 times the light-collecting area of the 2-meter telescope.
D)The answer cannot be determined from the information given in the question.

A)The thin air on mountaintops makes the glass in telescope mirrors less susceptible to warping.
B)Being on a high mountain top means being relatively high in the atmosphere,which tends to limit turbulence.
C)Dry regions mean less rain and clouds,and mountaintops in dry regions may even allow some infrared observations.
D)Mountaintops far from cities are generally subject to less light pollution than locations nearer to cities.

A)CCDs allow long exposures (e.g. ,minutes or hours)and film does not.
B)CCDs capture a much higher percentage of the incoming photons than film.
C)CCDs can record the colors of astronomical objects accurately while film cannot.
D)CCDs can be attached to modern telescopes more easily than can photographic film.

A)Telescopes on the Moon could see objects in all parts of the sky equally well,whereas telescopes on Earth can see only portions of the sky that depend on their latitude.
B)Radio astronomy would be advantageous on the Moon because human radio transmissions are less likely to cause interference,especially on the far side of the Moon.
C)It would be possible to put telescopes for ultraviolet and X-ray astronomy on the surface,unlike the case on the surface of the Earth.
D)Telescopes on the Moon could observe stars even when it is daytime on the Moon.

A)It reduces blurring caused by atmospheric turbulence for telescopes on the ground.
B)It allows several small telescopes to work together like a single larger telescope.
C)It is a special technology that allows the Hubble Space Telescope to adapt to study many different types of astronomical objects.
D)It allows ground-based telescopes to observe ultraviolet light that normally does not penetrate the atmosphere.

A)The two stars will appear to be touching,looking rather like a small dumbbell.
B)The stars will not show up at all in your photograph.
C)The photo will seem to show only one star rather than two.
D)You will see two distinct stars in your photograph.

A)Getting an image of the same angular resolution requires a much larger telescope for radio waves than for visible light.
B)Radio telescopes are designed to collect sound rather than light.
C)It is because radio telescopes are used in the daytime and visible light telescopes are used at night.
D)Objects that emit radio waves are always much larger than objects that emit visible light,and therefore require larger telescopes.