Fluctuations in Amplification of Quanta with Application to Maser Amplifiers
Abstract
Fluctuations in the amplification and absorption of waves by quantum processes are considered. Assuming for each quantum the probability (per unit time) a of producing another quantum, probability b of being absorbed, and assuming a probability c that a new quantum is introduced, a set of differential equations is obtained. By solving these equations, a complete expression for the probability of distribution of quanta is obtained, as well as expressions for the average values and fractional fluctuation. The expressions developed are applied in particular to maser-type amplifiers, and certain fluctuations in the amplification of electromagnetic waves are pointed out which are important when their quantum character becomes significant. This condition can occur in maser-type amplifiers, where thermal and extraneous noises may be very small. For such an amplifier, a is proportional to the number of excited molecules, whereas b consists of a term proportional to the number of molecules in the ground state plus terms due to certain other losses. The noise temperature of a maser-type traveling-wave amplifier is the “effective temperature” a(a-b)-1hν/k. In superregenerative and regenerative amplifiers using resonant cavities, the noise temperature is rather similar, if losses through the input coupling hole are excluded from b. In any case, the limiting noise for an ideal amplifier corresponds to a classical noise temperature of hν/k.
- Publication:
-
Journal of the Physical Society of Japan
- Pub Date:
- June 1957
- DOI:
- 10.1143/JPSJ.12.686
- Bibcode:
- 1957JPSJ...12..686S