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Thermal Management in Large Bi2212 Mesas used for Terahertz Sources

We present a thermal analysis of a patterned mesa on a Bi2Sr2CaCu2O8 (Bi2212) single crystal that is based on tunneling characteristics of the c-axis stack of ~800 intrinsic Josephson junctions in the mesa. Despite the large mesa volume (e.g., 40x300x1.2 micron3) and power dissipation that result in selfheating and backbending of the current-voltage curve (I-V), there are accessible bias conditions for which significant polarized THz-wave emission can be observed. We estimate the mesa temperature by equating the quasiparticle resistance, Rqp(T), to the ratio V/I over the entire I-V including the backbending region. These temperatures are used to predict the unpolarized black-body radiation reaching our bolometer and there is substantial agreement over the entire I-V. As such, backbending results from the particular Rqp(T) for Bi2212, as first discussed by Fenton, rather than a significant suppression of the energy gap. This model also correctly predicts the observed disappearance of backbending above ~60 K.

preprint2009arXivOpen access
C. KurterK. E. GrayJ. F. ZasadzinskiL. OzyuzerA. E. KoshelevQ. LiT. YamamotoK. KadowakiW. - K. KwokM. TachikiU. Welp
cond-mat.supr-con
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Open access11 authors1 topic
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C. KurterK. E. GrayJ. F. ZasadzinskiL. OzyuzerA. E. KoshelevQ. LiT. YamamotoK. KadowakiW. - K. KwokM. TachikiU. Welp

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