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公开(公告)号:US20170294551A1
公开(公告)日:2017-10-12
申请号:US15632550
申请日:2017-06-26
CPC分类号: H01L33/0004 , G01J3/108 , G01J3/42 , G01J3/4412 , G01N21/3577 , G01N2201/062 , H01L23/345 , H01L25/0753 , H01L33/02 , H01L33/20 , H01L33/30 , H01L33/36 , H01L33/44 , H01L33/48 , H01L33/645 , H01L2924/0002 , H01L2924/00
摘要: Contrary to conventional wisdom, which holds that light-emitting diodes (LEDs) should be cooled to increase efficiency, the LEDs disclosed herein are heated to increase efficiency. Heating an LED operating at low forward bias voltage (e.g., V
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公开(公告)号:US20210208470A1
公开(公告)日:2021-07-08
申请号:US17091905
申请日:2020-11-06
摘要: Optical read-out of a cryogenic device (such as a superconducting logic or detector element) can be performed with a forward-biased optical modulator that is directly coupled to the cryogenic device without any intervening electrical amplifier. Forward-biasing at cryogenic temperatures enables very high modulation efficiency (1,000-10,000 pm/V) of the optical modulator, and allows for optical modulation with millivolt driving signals and microwatt power dissipation in the cryogenic environment. Modulated optical signals can be coupled out of the cryostat via an optical fiber, reducing the thermal load on the cryostat. Using optical fiber instead of electrical wires can increase the communication bandwidth between the cryogenic environment and room-temperature environment to bandwidth densities as high as Tbps/mm2 using wavelength division multiplexing. Sensitive optical signals having higher robustness to noise and crosstalk, because of their immunity to electromagnetic interference, can be carried by the optical fiber.
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