Ferdinand Harerimana Data-verified
Affiliation confirmed via AI analysis of OpenAlex, ORCID, and web sources.
Researcher
unknown
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Biography and Research Information
OverviewAI-generated summary
Ferdinand Harerimana's research focuses on the simulation and analysis of nanoscale materials, particularly graphene, for energy harvesting and vibration-based applications. His work utilizes molecular dynamics simulations to investigate the mechanisms behind spontaneous curvature inversion in compressed graphene ripples, exploring their potential for energy generation. Harerimana has also examined arrays of graphene variable capacitors for vibration-based applications and has analyzed freestanding graphene heat engines using stochastic thermodynamics. His recent publications include "Mechanisms of Spontaneous Curvature Inversion in Compressed Graphene Ripples for Energy Harvesting Applications via Molecular Dynamics Simulations" (2021), "Array of Graphene Variable Capacitors on 100 mm Silicon Wafers for Vibration-Based Applications" (2022), and "Freestanding graphene heat engine analyzed using stochastic thermodynamics" (2023). Harerimana has collaborated with P. M. Thibado, James M. Mangum, and Millicent Gikunda at the University of Arkansas at Fayetteville on multiple publications.
Metrics
- h-index: 4
- Publications: 6
- Citations: 42
Selected Publications
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Freestanding graphene heat engine analyzed using stochastic thermodynamics (2023)
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Array of Graphene Variable Capacitors on 100 mm Silicon Wafers for Vibration-Based Applications (2022)
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Mechanisms of Spontaneous Curvature Inversion in Compressed Graphene Ripples for Energy Harvesting Applications via Molecular Dynamics Simulations (2021)
Collaboration Network
Top Collaborators
- Mechanisms of Spontaneous Curvature Inversion in Compressed Graphene Ripples for Energy Harvesting Applications via Molecular Dynamics Simulations
- Array of Graphene Variable Capacitors on 100 mm Silicon Wafers for Vibration-Based Applications
- Freestanding graphene heat engine analyzed using stochastic thermodynamics
- Mechanisms of Spontaneous Curvature Inversion in Compressed Graphene Ripples for Energy Harvesting Applications via Molecular Dynamics Simulations
- Array of Graphene Variable Capacitors on 100 mm Silicon Wafers for Vibration-Based Applications
- Freestanding graphene heat engine analyzed using stochastic thermodynamics
- Mechanisms of Spontaneous Curvature Inversion in Compressed Graphene Ripples for Energy Harvesting Applications via Molecular Dynamics Simulations
- Array of Graphene Variable Capacitors on 100 mm Silicon Wafers for Vibration-Based Applications
- Freestanding graphene heat engine analyzed using stochastic thermodynamics
- Array of Graphene Variable Capacitors on 100 mm Silicon Wafers for Vibration-Based Applications
- Array of Graphene Variable Capacitors on 100 mm Silicon Wafers for Vibration-Based Applications
- Array of Graphene Variable Capacitors on 100 mm Silicon Wafers for Vibration-Based Applications
- Array of Graphene Variable Capacitors on 100 mm Silicon Wafers for Vibration-Based Applications
- Freestanding graphene heat engine analyzed using stochastic thermodynamics
- Freestanding graphene heat engine analyzed using stochastic thermodynamics
- Freestanding graphene heat engine analyzed using stochastic thermodynamics
- Freestanding graphene heat engine analyzed using stochastic thermodynamics
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