Hiram Conley scite author profile

We report the influence of uniaxial tensile mechanical strain in the range 0-2.2% on the phonon spectra and bandstructures of monolayer and bilayer molybdenum disulfide (MoS2) two-dimensional crystals. First, we employ Raman spectroscopy to observe phonon softening with increased strain, breaking the degeneracy in the E' Raman mode of MoS2, and extract a Grüneisen parameter of ~1.06. Second, using photoluminescence spectroscopy we measure a decrease in the optical band gap of MoS2 that is approximately linear with strain, ~45 meV/% strain for monolayer MoS2 and ~120 meV/% strain for bilayer MoS2. Third, we observe a pronounced strain-induced decrease in the photoluminescence intensity of monolayer MoS2 that is indicative of the direct-to-indirect transition of the character of the optical band gap of this material at applied strain of ~1%. These observations constitute a demonstration of strain engineering the band structure in the emergent class of two-dimensional crystals, transition-metal dichalcogenides.

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The effect of intrinsic crumpling on the mechanics of free-standing graphene

Nicholl

et al. 2015

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Free-standing graphene is inherently crumpled in the out-of-plane direction due to dynamic flexural phonons and static wrinkling. We explore the consequences of this crumpling on the effective mechanical constants of graphene. We develop a sensitive experimental approach to probe stretching of graphene membranes under low applied stress at cryogenic to room temperatures. We find that the in-plane stiffness of graphene is 20–100 N m−1 at room temperature, much smaller than 340 N m−1 (the value expected for flat graphene). Moreover, while the in-plane stiffness only increases moderately when the devices are cooled down to 10 K, it approaches 300 N m−1 when the aspect ratio of graphene membranes is increased. These results indicate that softening of graphene at temperatures <400 K is caused by static wrinkling, with only a small contribution due to flexural phonons. Together, these results explain the large variation in reported mechanical constants of graphene devices and pave the way towards controlling their mechanical properties.

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High-Field Electrical and Thermal Transport in Suspended Graphene

Dorgan¹,

Behnam²,

et al. 2013

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We study the intrinsic transport properties of suspended graphene devices at high fields (≥1 V/μm) and high temperatures (≥1000 K). Across 15 samples, we find peak (average) saturation velocity of 3.6 × 10(7) cm/s (1.7 × 10(7) cm/s) and peak (average) thermal conductivity of 530 W m(-1) K(-1) (310 W m(-1) K(-1)) at 1000 K. The saturation velocity is 2-4 times and the thermal conductivity 10-17 times greater than in silicon at such elevated temperatures. However, the thermal conductivity shows a steeper decrease at high temperature than in graphite, consistent with stronger effects of second-order three-phonon scattering. Our analysis of sample-to-sample variation suggests the behavior of "cleaner" devices most closely approaches the intrinsic high-field properties of graphene. This study reveals key features of charge and heat flow in graphene up to device breakdown at ~2230 K in vacuum, highlighting remaining unknowns under extreme operating conditions.

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Optically Monitored Electrical Switching in VO₂

et al. 2015

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We demonstrate a hybrid silicon-vanadium dioxide (Si-VO 2 ) electro-optic modulator that enables direct probing of both the electrically triggered semiconductor-to-metal phase transition in VO 2 and the reverse transition from metal to semiconductor. By using a twoterminal in-plane VO 2 electrical switch atop a single-mode silicon waveguide, the phase change can be initiated electrically and probed optically, separating the excitation and measurement processes and simplifying the analysis of the metal-to-semiconductor dynamics. We demonstrate a record switch-on time for high-speed electrical semiconductor-to-metal transition, with switching times less than 2ns, and quantify the slower inverse transition, which is dominated by thermal dissipation and relaxation of the metallic rutile lattice to the monoclinic semiconducting

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Hiram Conley

Bandgap Engineering of Strained Monolayer and Bilayer MoS₂

The effect of intrinsic crumpling on the mechanics of free-standing graphene

High-Field Electrical and Thermal Transport in Suspended Graphene

Optically Monitored Electrical Switching in VO₂

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Resources

About

Hiram Conley

Bandgap Engineering of Strained Monolayer and Bilayer MoS2

The effect of intrinsic crumpling on the mechanics of free-standing graphene

High-Field Electrical and Thermal Transport in Suspended Graphene

Optically Monitored Electrical Switching in VO2

Contact Info

Product

Resources

About

Bandgap Engineering of Strained Monolayer and Bilayer MoS₂

Optically Monitored Electrical Switching in VO₂