Salvador Barraza-Lopez Data-verified
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Researcher
unknown
Research Areas
Biography and Research Information
OverviewAI-generated summary
Salvador Barraza-Lopez, a researcher at the University of Arkansas at Fayetteville, investigates the behavior of materials at the atomic and electronic level, with a particular focus on two-dimensional (2D) materials and their optical and mechanical properties. His work frequently employs theoretical and computational methods to explore phenomena such as strain engineering, phase transitions, and the optical susceptibility of various material systems.
Recent publications from Barraza-Lopez and his collaborators examine the optomechanics of molybdenum disulfide (MoS2) bilayers under strain, the second-order optical susceptibility of bulk materials using symmetry-enforced methods, and the electronic properties of strained graphene/hexagonal boron nitride (hBN) moiré trilayers. His research also delves into thermally-driven phase transitions in 2D materials like silicene, germanene, and stanene, as well as the elasticity and paraelectric phase transformations of 2D ferroelectrics.
Barraza-Lopez is a principal investigator on a National Science Foundation (NSF) grant totaling $499,113, aimed at establishing a high-performance computing system for research and education at the University of Arkansas. His collaborations include work with Joseph E. Roll, Angiolo Huamán, Luis Enrique Rosas-Hernandez, and Gustavo S. Orozco-Galvan, all based at the University of Arkansas.
Metrics
- Publications: 9
Selected Publications
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Perturbative second-order optical susceptibility of bulk materials: a symmetry-enforced return to non-orthogonal localized basis sets (2026)
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Perturbative second-order optical susceptibility of bulk materials: a symmetry-enforced return to non-orthogonal localized basis sets (2026)
Federal Grants 1 $499,113 total
Collaboration Network
Top Collaborators
- Elasticity of 2D ferroelectrics across their paraelectric phase transformation
- Slippery paraelectric transition metal dichalcogenide bilayers
- Winding Berry dipole on uniaxially strained graphene/hBN/hBN moiré trilayers
- Perturbative second-order optical susceptibility of bulk materials: a symmetry-enforced return to non-orthogonal localized basis sets
- Perturbative second-order optical susceptibility of bulk materials: a symmetry-enforced return to non-orthogonal localized basis sets
- Perturbative second-order optical susceptibility of bulk materials: a symmetry-enforced return to non-orthogonal localized basis sets
- Tuning Terahertz Optomechanics of MoS2 Bilayers with Homogeneous In-plane Strain
- Tuning Terahertz Optomechanics of MoS2 Bilayers with Homogeneous In-plane Strain
- Tuning Terahertz Optomechanics of MoS2 Bilayers with Homogeneous In-plane Strain
- Tuning Terahertz Optomechanics of MoS2 Bilayers with Homogeneous In-plane Strain
- Tuning Terahertz Optomechanics of MoS2 Bilayers with Homogeneous In-plane Strain
- Tuning Terahertz Optomechanics of MoS2 Bilayers with Homogeneous In-plane Strain
- Tuning Terahertz Optomechanics of MoS2 Bilayers with Homogeneous In-plane Strain
- Tuning Terahertz Optomechanics of MoS2 Bilayers with Homogeneous In-plane Strain
- Elasticity of 2D ferroelectrics across their paraelectric phase transformation
- Elasticity of 2D ferroelectrics across their paraelectric phase transformation
- Slippery paraelectric transition metal dichalcogenide bilayers
- Slippery paraelectric transition metal dichalcogenide bilayers
- Slippery paraelectric transition metal dichalcogenide bilayers
- Thermally-driven phase transitions in freestanding low-buckled silicene, germanene, and stanene
- Thermally-driven phase transitions in freestanding low-buckled silicene, germanene, and stanene
- Perturbative second-order optical susceptibility of bulk materials: a symmetry-enforced return to non-orthogonal localized basis sets
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