![]() ![]() For the problem in the previous example, what is the velocity of the galaxy, whose z=1.09? This looks rather complicated, and it is, but it does accurately calculate the velocity of very fast objects without breaking the speed of light rules.ġ. z = redshift, as defined in the previous formula section.velocity = velocity of object measured in km/s, since c is given in those units (300,000 km/s). ![]() Relativistic Redshift - This is used in place of the Doppler formula when the velocities become too large to be accurately represented by the regular Doppler formula, typically any velocities greater than 10% the speed of light. If you put this into the Doppler Shift formula above (using z = v/c), you'd get a velocity = 1.09 c, 9% greater than the speed of light, and that isn't possible! An absorption feature of calcium usually has a wavelength of 3934 Å, but it is observed in a distant galaxy to have a wavelength of 8209 Å. An absorption feature of calcium usually has a wavelength of 3934 Å, but it is observed in a galaxy to have a wavelength of 4002 Å. When dealing with distant galaxies, it is always positive.ġ. But as I said, this isn't always correct - there are times when "z" isn't equal to v/c, so it is sometimes easier to just leave it as "z".Īnd if the value of "z" is positive it is a "redshift" indicating motion away, but it can also be negative, which would be a "blueshift", indicating motion towards us. If we look at the previous formula (Doppler shift), "z" is just the value of v/c, the ratio of the velocity to the speed of light. There are reasons for that since you may not be able to calculate the velocity using the regular Doppler formula, but may have to use the Relativistic formula (next formula down). Redshift - this is sort of like the previous case, except the last steps aren't carried through - the velocity value isn't calculated. Now you can plug the values into the formula. Since this is a positive value, the object is moving away from us. Solution: First you need to determine the value for, which is the change in wavelength How fast is this galaxy moving, and is it moving towards or away from you? Typically for galaxies we tend to use km/s, so the speed of light in this case would be 3.0 x 10 5 km/sġ. The units you use for velocity and for "c" are sort of arbitrary. If it is positive, the motion is away from you, if it is negative the motion is towards you. It should be noted that is the difference or change in the value of the spectral feature from its normal wavelength ( ), and the change could be positive or negative. = the wavelength the feature should have, often measured in Ångstroms.= Shift in the wavelength of a feature in the spectra, often measured in Ångstroms, just so the units are the same as used for.c = speed of light, either 3.0 x 10 8 m/s or 3.0 x 10 5 km/s.v = velocity of the object, in m/s or km/s - same units used by "c".Basically it shows how much light is effected by velocity and allows us (astronomers) to determine velocities based upon the measurable effects. If the Hubble Constant is 68 km/s/Mpc, how fast should NGC 4442 be moving due to the expansion of the Universe?ĭoppler Shift - This formula was originally introduced when light was discussed, but now we're looking at it again. Solution: You can again just pop them into the formulaģ. What is the value of the Hubble constant based upon these values? Galaxy NGC 2342 has a velocity of 5,690 km/s and is at a distance of 74 Mpc away. ![]() Solution: Pop the values into the formulaĢ. How far away is the galaxy according to Hubble's Law? ![]() Galaxy NGC 123 has a velocity away from us of 1,320 km/s and the Hubble Constant's value is 70 km/s/Mpc. Technically, this is a very simplified version of the what the Universe is doing, but it is a good first approximation for what we see in the sky.ġ.
0 Comments
Leave a Reply. |
AuthorWrite something about yourself. No need to be fancy, just an overview. ArchivesCategories |