MnBi Thin Films: Physical Properties and Memory Applications

Thin films of MnBi possess many unusual physical properties and are particularly suitable for memory applications using laser Curie-point writing and magneto-optical readout. Films prepared on mica substrates have the easy direction of magnetization perpendicular to the film plane. They typically ha...

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Veröffentlicht in:	Journal of applied physics 1968-07, Vol.39 (8), p.3916-3927
Hauptverfasser:	Chen, D., Ready, J. F., Bernal G., E.
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Sprache:	eng
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creator	Chen, D. Ready, J. F. Bernal G., E.
description	Thin films of MnBi possess many unusual physical properties and are particularly suitable for memory applications using laser Curie-point writing and magneto-optical readout. Films prepared on mica substrates have the easy direction of magnetization perpendicular to the film plane. They typically have a specific Faraday rotation of 5×105 deg/cm, and an absorption coefficient of 3.8×105 cm−1 for 6328 Å wavelength, permitting a readout rate of 109 bits/sec at 1 mW laser power level using available detectors. Curie-point writing and erasing of a spot a few microns in diameter in a 1000 Å thick film with a 4 μsec pulse from a 13 mW Gaussian laser beam have been achieved. For a 106 bits/cm2 packing density, heating at adjacent spots is negligible. Calculations show that the writing magnetic field can be reduced to less than 10 Oe by using a memory plane consisting of discrete squares of MnBi. Analytical and experimental results as well as memory design considerations are presented.
doi_str_mv	10.1063/1.1656875
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F. ; Bernal G., E.</creator><creatorcontrib>Chen, D. ; Ready, J. F. ; Bernal G., E.</creatorcontrib><description>Thin films of MnBi possess many unusual physical properties and are particularly suitable for memory applications using laser Curie-point writing and magneto-optical readout. Films prepared on mica substrates have the easy direction of magnetization perpendicular to the film plane. They typically have a specific Faraday rotation of 5×105 deg/cm, and an absorption coefficient of 3.8×105 cm−1 for 6328 Å wavelength, permitting a readout rate of 109 bits/sec at 1 mW laser power level using available detectors. Curie-point writing and erasing of a spot a few microns in diameter in a 1000 Å thick film with a 4 μsec pulse from a 13 mW Gaussian laser beam have been achieved. For a 106 bits/cm2 packing density, heating at adjacent spots is negligible. Calculations show that the writing magnetic field can be reduced to less than 10 Oe by using a memory plane consisting of discrete squares of MnBi. 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F.</creatorcontrib><creatorcontrib>Bernal G., E.</creatorcontrib><title>MnBi Thin Films: Physical Properties and Memory Applications</title><title>Journal of applied physics</title><description>Thin films of MnBi possess many unusual physical properties and are particularly suitable for memory applications using laser Curie-point writing and magneto-optical readout. Films prepared on mica substrates have the easy direction of magnetization perpendicular to the film plane. They typically have a specific Faraday rotation of 5×105 deg/cm, and an absorption coefficient of 3.8×105 cm−1 for 6328 Å wavelength, permitting a readout rate of 109 bits/sec at 1 mW laser power level using available detectors. Curie-point writing and erasing of a spot a few microns in diameter in a 1000 Å thick film with a 4 μsec pulse from a 13 mW Gaussian laser beam have been achieved. For a 106 bits/cm2 packing density, heating at adjacent spots is negligible. 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Curie-point writing and erasing of a spot a few microns in diameter in a 1000 Å thick film with a 4 μsec pulse from a 13 mW Gaussian laser beam have been achieved. For a 106 bits/cm2 packing density, heating at adjacent spots is negligible. Calculations show that the writing magnetic field can be reduced to less than 10 Oe by using a memory plane consisting of discrete squares of MnBi. Analytical and experimental results as well as memory design considerations are presented.</abstract><doi>10.1063/1.1656875</doi><tpages>12</tpages><oa>free_for_read</oa></addata></record>
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title	MnBi Thin Films: Physical Properties and Memory Applications
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