2013
DOI: 10.1038/srep03038
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Binary switching in a ‘symmetric’ potential landscape

Abstract: A binary switch is the basic building block for information processing. The potential energy profile of a bistable binary switch is a ‘symmetric' double well. The traditional method of switching it from one state (one well) to the other is to tilt the profile towards the desired state. Here, we present a case, where no such tilting is necessary to switch successfully, even in the presence of thermal noise. This happens because of the built-in dynamics inside the switch itself. It differs from the general perce… Show more

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Cited by 92 publications
(137 citation statements)
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“…In the first step, the magnetization rotates from the initial stable orientation along the major axis by an acute angle. In the second step, the magnetization rotates by an additional angle, bringing it closer to the other stable direction, and finally when the stresses are withdrawn, the magnetization settles into the other stable direction, completing a 180 o rotation 1 .There are other proposed methods of implementing 180 o rotation with strain, but they either require very precise timing of the stress cycle which is nearly impossible in the presence of thermal noise at room temperature 37,38 , or special material properties 39 . In contrast, the two step method does not call for extreme precision, is practical and error-resilient, and works with any magnetostrictive material, whether crystalline, poly-crystalline or amorphous.…”
mentioning
confidence: 99%
“…In the first step, the magnetization rotates from the initial stable orientation along the major axis by an acute angle. In the second step, the magnetization rotates by an additional angle, bringing it closer to the other stable direction, and finally when the stresses are withdrawn, the magnetization settles into the other stable direction, completing a 180 o rotation 1 .There are other proposed methods of implementing 180 o rotation with strain, but they either require very precise timing of the stress cycle which is nearly impossible in the presence of thermal noise at room temperature 37,38 , or special material properties 39 . In contrast, the two step method does not call for extreme precision, is practical and error-resilient, and works with any magnetostrictive material, whether crystalline, poly-crystalline or amorphous.…”
mentioning
confidence: 99%
“…If the system, on the other hand, is nonlinear, the bound-state contributions become important, modifying the photon statistics of the output light as shown in the main text. In the limit of U → ∞, B's become exactly the same as those of the coupled two-level atoms [50]. Finally, we can find the two-photon scattering matrix from, as in [33],…”
Section: Two-photon Scatteringmentioning
confidence: 89%
“…What makes it happen is the out-of-plane dynamics of the magnetization vector that generates a helpful torque to rotate the magnetization from 90 • to 180 • [85]. This out of plane dynamics, crucial for a complete bit flip or the 180 • rotation, is either absent or very weak in a pillar, making bit flip via stress nearly impossible.…”
Section: Other-spin-based Logic and Memorymentioning
confidence: 99%
“…The associated strain is transferred elastically to the magnetostrictive layer, generating stress in it and rotating its magnetization by large angles [76][77][78][79][80][81][82][83][84]. If the strain is withdrawn at the right juncture, rotation by ∼180 • is possible with >99.99% probability even in the presence of thermal noise at room temperature [85]. The switching takes less than 1 ns to complete, making this strategy one of the most energy efficient, and yet relatively fast, switching methodologies extant.…”
Section: Hybrid Spintronics and Straintronicsmentioning
confidence: 99%