Local SiC photoluminescence evidence of non-mutualistic hot spot formation and sub-THz coherent emission from a rectangular Bi2Sr2CaCu2O8+δ mesa

Abstract

From the photoluminescence of SiC microcrystals uniformly covering a rectangular mesa of the high transition temperature Tc superconductor Bi2Sr2CaCu2O8+δ, the local surface temperature T( r) was directly measured during simultaneous sub-THz emission from the N103 intrinsic Josephson junctions (IJJs) in the mesa. At high bias currents I and low bath temperatures T bath~35 K, the center of a large elliptical hot spot with T( r)> Tc jumps dramatically with little current-voltage characteristic changes. The hot spot doesn't alter the ubiquitous primary and secondary emission conditions: the ac Josephson relation and the electromagnetic cavity resonance excitation, respectively. Since the intense sub-THz emission was observed for high T bath~50 K in the low I bias regime where hot spots are absent, hot spots can not provide the primary mechanisms for increasing the output power, the tunability, or for promoting the synchronization of the N IJJs for the sub-THz emission, but can at best coexist non-mutualistically with the emission. No T( r) standing waves were observed.