Prototype spin-dependent tunneling isolators integrated with integrated circuit electronics

Low power, fast speed, small size, wide temperature range, and common-mode-noise-rejection capability are some of the attributes of magnetoresistive devices for galvanic isolation over conventional devices such as optical and capacitive devices. We have fabricated prototype galvanic isolators using...

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Veröffentlicht in:	Journal of applied physics 2002-05, Vol.91 (10), p.8405-8407
Hauptverfasser:	Wang, Dexin, Tondra, Mark, Nordman, Cathy, Qian, Zhenghong, Daughton, James M., Lange, Erik, Brownell, David, Tran, Loc, Schuetz, James
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container_title	Journal of applied physics
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creator	Wang, Dexin Tondra, Mark Nordman, Cathy Qian, Zhenghong Daughton, James M. Lange, Erik Brownell, David Tran, Loc Schuetz, James
description	Low power, fast speed, small size, wide temperature range, and common-mode-noise-rejection capability are some of the attributes of magnetoresistive devices for galvanic isolation over conventional devices such as optical and capacitive devices. We have fabricated prototype galvanic isolators using spin-dependent tunneling materials. The tunnel junctions have been deposited by rf diode sputtering and the Al2O3 barriers are formed by depositing a thin layer of Al, then oxidizing it with oxygen contained plasma. The junctions are then patterned using photolithography techniques to define the pinned and free layers separately. A series of tunnel junctions are connected in a Wheatstone bridge form and are fabricated directly on top of the integrated circuit (IC) electronics that are used to process the signals from the bridge. In its core magnetics design, this digital device simply employs a one-bit memory cell capable of operating at 5 V. The functions of the devices are tested using a function generator, an IC driver chip, a probe station, two dc power supplies, and a high-speed network analyzer. The power consumption for the isolator is
doi_str_mv	10.1063/1.1447203
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The power consumption for the isolator is <1 mW when operating at 2 MHz, a factor of 10 lower than the giant magnetoresistance product of similar functions. 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title	Prototype spin-dependent tunneling isolators integrated with integrated circuit electronics
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