Samuel Humphrey scite author profile

The use of metals of nanometer dimensions to enhance and manipulate light-matter interactions for emerging plasmonics-enabled nanophotonic and optoelectronic applications is an interesting yet not highly explored area of research beyond plasmonics. Even more importantly, the concept of an active metal that can undergo an optical nonvolatile transition has not been explored. Here, we demonstrate that antimony (Sb), a pure metal, is optically distinguishable between two programmable states as nanoscale thin films. We show that these states, corresponding to the crystalline and amorphous phases of the metal, are stable at room temperature. Crucially from an application standpoint, we demonstrate both its optoelectronic modulation capabilities and switching speed using single subpicosecond pulses. The simplicity of depositing a single metal portends its potential for use in any optoelectronic application where metallic conductors with an actively tunable state are important.

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Magnetostructural Coupling Drives Magnetocaloric Behavior: The Case of MnB versus FeB

Bocarsly

Levin

Humphrey

et al. 2019

Chem. Mater.

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Materials with strongly coupled magnetic and structural transitions can display a giant magnetocaloric effect, which is of interest in the design of energy-efficient and environmentally-friendly refrigerators, heat pumps, and thermomagnetic generators. There also exist however, a class of materials with no known magnetostructural transition that nevertheless show remarkable magnetocaloric effects. MnB has been recently suggested as such a compound, displaying a large magnetocaloric effect at its Curie temperature (570 K) showing promise in recovering low-grade waste heat using thermomagnetic generation. In contrast, we show that isostructural FeB displays very similar magnetic ordering characteristics, but is not an effective magnetocaloric. Temperature-and field-dependent diffraction studies reveal dramatic magnetoelastic coupling in MnB, which exists without a magnetostructural transition. No such behavior is seen in FeB. Furthermore, the magnetic transition in MnB is shown to be subtly first-order, albeit with distinct behavior from that displayed by other magnetocalorics with first-order transitions. Density functional theory-based electronic structure calculations point to the magnetoelastic behavior in MnB as arising from a competition between Mn moment formation and B-B bonding.

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Antimony thin films demonstrate programmable optical non-linearity

Cheng¹,

Milne²,

Salter³

et al. 2020

Preprint

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Missile delivered explosive sound system

Applebaum¹,

Will²,

Humphrey³

et al. 1985

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Deformable Membrane Frequency Tuning of Microchip Lasers

Keszenheher

Prince

Mooradian

et al. 1996

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Samuel Humphrey

Antimony thin films demonstrate programmable optical nonlinearity

Magnetostructural Coupling Drives Magnetocaloric Behavior: The Case of MnB versus FeB

Antimony thin films demonstrate programmable optical non-linearity

Missile delivered explosive sound system

Deformable Membrane Frequency Tuning of Microchip Lasers

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