Melek Derman

About Me

I am a Ph.D. student and Graduate Research Assistant at Oregon State University, working under Professor Todd S. Palmer. My research interests include Monte Carlo and deterministic particle transport methods, as well as computational techniques for developing scalable algorithms on exascale systems.

I hold a B.S. in Physics with Honors from Akdeniz University (Turkey) and an M.S. in Nuclear Engineering from Texas A&M University, where I focused on nuclear safeguards monitoring approaches for molten salt reactors. My doctoral research involves high-performance computing optimization and multiscale physics simulations, with applications ranging from reactor physics to radiation effects in electronic systems.

Research areas

Monte Carlo Methods

Monte Carlo simulations for particle transport simulations on exascale systems. Contributing to MC/DC development with a focus on high-performance Python code for radiation transport. CEMeNT

Deterministic Transport Methods

Fast spectral methods for accelerated transport analysis. Efficient iterative solvers (Block Jacobi, GMRES) for large-scale computations on parallel architectures.

Electron Transport

Charged-particle transport and radiation damage simulation for electronic systems. Integrating multiscale, multiparticle physics to enable predictive simulation and reduce reliance on physical testing for electronics resilience applications. CARRE

Quantum Computing Applications

Exploring quantum algorithms for charged-particle transport and radiation effects simulation on near-term quantum devices.

High-Performance Computing

Performance profiling and optimization on heterogeneous architectures (AMD/NVIDIA). GPU-acceleration for large-scale transport simulations.

Affiliations

CARRE

Center for Advancing the Radiation Resilience of Electronics, a PSAAP-IV project funded by the Department of Energy, grant number: DE-NA0004268.

RTRP

Radiation Transport and Reactor Physics Group at Oregon State University