Citation
Abstract
This article describes how a quantitative analysis of the dominant source of relaxation in ruby spin systems is used to make predictions of key maser amplifier parameters. The spin-lattice Hamiltonian which describes the interaction of the electron spins with the thermal vibrations of the surrounding lattice 1s obtained from the literature. Taking into account the vibrational anisotropy of ruby, Fermt’s rule is used to calculate the spin transition rates between the maser energy levels. The spin population rate equations are solved for the spin transition relaxation times, and a comparison with previous calculations is made. Predictions of ruby gain, inversion ratio, and noise temperature as a function of physical temperature are made for 8.4-GHz and 32-GHz maser pumping schemes. The theory predicts that ruby oriented at 90 deg will have approximately 50 percent higher gain in dB and slightly lower noise temperature than a 54.7-deg ruby at 32 GHz (assuming pump saturation). A specific calculation relating pump power to inversion ratio is given for a single channel of the 32-GHz reflected wave maser.
Details
- Volume
- 42-98
- Published
- August 15, 1989
- Pages
- 63–85
- File Size
- 921.9 KB