mirrors/lenses

Any three of the following: color, brightness, temperature, size, and composition (what it's made of).

Mass is inversely proportional to lifetime, therefore as the mass of a star increases, its lifetime decreases. In this case, Star B would live longer, because it has a lesser mass.

Binary star systems have 2 stars. They vary in terms of the types and sizes of those stars. Eclipsing binary stars are made up of two stars, but periodically one star moves in front of and blocks the light from the other star. This causes the light of the brighter, larger star to be dimmed for a period of time. The smaller, dimmer star then moves out of the way, and the large, bright star returns to its normal apparent brightness. This process repeats again and again, based on the orbits of the stars involved in the eclipsing binary system. A trinary star system is a group of three stars, all in a stable gravitational relationship with each other.

Dark matter is anything in the universe which does not give off light. Planets and dead stars are examples. Dark energy is the mysterious force which is believed to be causing the accelerated expansion of the universe. It is not presently proven; it is only a hypothesis at this moment.

The electromagnetic (EM) spectrum is composed of all of the different types of electromagnetic radiation, such as microwaves, radiowaves, visible light, etc. The visible light spectrum refers to ONLY the forms of EM that we can see: ROYGBV.

Generally speaking, stars proceed from coolest to hottest following the visible light spectrum, ROYGBV. Therefore, red would be coolest, yellow next, and blue hottest.

All stars are born from nebulae, and small mass stars are no different. Once the star has formed, it is called a Main Sequence star. After a certain period of time, it will burn through all of its Hydrogen, and expand to form a Giant star. Once it burns through all heavier elements (Helium, etc.) all nuclear fusion will cease. At this point, the gravity of the star will cause the core to collapse, while the star's atmosphere drifts away, forming a planetary nebula. Once the star's atmosphere has drifted away, all that is left is the white hot core, called a white dwarf. Finally, once the white dwarf has cooled completely, it is a cold, dark black dwarf star.

Even though it may not be directly visible, there may be another object present. In order for an object to cause a gravitational disturbance to something as large as a star, it must itself be very large. Only a planet or another dark object (e.g., black dwarf, black hole) would have sufficient gravity to cause this to occur.

The fact that the universe is currently expanding (and has been as long as we've been observing it) hints at an earlier time when it was smaller. If we extend that thinking logically back, we can imagine a moment when the universe was infinitesimally small. This is the moment of the big bang. A second piece of evidence is the cosmic background radiation, which we believe is the leftover thermal (heat) energy of the original big bang explosion. As the heat signature of the universe is still present, we can imagine that it was very, very hot.

From longest wavelength (lowest energy) to shortest wavelength (highest energy): radiowaves, microwaves, infrared, visible light, ultraviolet, X-rays, gamma waves.

Parallax is the apparent change in position of an object when it is viewed from different points of view. An object's parallax is inversely proportional to its distance: in other words, when an object is closer, it has a greater parallax, and when an object is farther away, it has a smaller parallax. Therefore, Star B, which is closer to earth, would demonstrate a greater parallax.

All stars are born from nebulae, and large mass stars are no different. Once the star has formed, it is called a Main Sequence star. After a certain period of time, it will burn through all of its Hydrogen, and expand to form a Supergiant star. Once it burns through all heavier elements (Helium, etc.) all nuclear fusion will cease. At this point, the gravity of the star will cause the core to collapse, but at some point the nuclear forces of the atoms making up the star resist the collapse of gravity, and explode in a Supernova. Following this explosion, gravity once again wins the day, and the star collapses to form one of the two densest objects in the universe. If the star is between 10-20 solar masses, it will form a neutron star. If the star is greater than 20 solar masses, it will form a black hole.

Open clusters are loosely organized collections of a few thousand stars. Open clusters still have much gas and dust, so they are active centers of new star formation. Globular clusters are densely packed groupings of older stars. Since there is very little gas and dust, very little new star formation occurs in globular clusters.

Hubble's Law states that the farther a galaxy is away from us, the faster it will be moving away from us (farther, faster). Conversely, the closer a galaxy is to us, the slower it will be moving away from us. Since the Sombrero Galaxy is farther away, it will be moving away from us at a faster rate.