Krishnaiah Mokurala
PhD
Department of Physics krishnaiah.mokurala@utu.fi Office: 25 ORCID identifier: https://orcid.org/0000-0001-9258-2607 |
Areas of expertise
Innovating at the intersection of materials science and device engineering
Indoor and outdoor photovoltaics
Broadband photodetectors
Memristors
flexible optoelectronics
neuromorphic devices
Physical sensors
Supercapacitors.
Cleanroom microfabrication: lithography, etching, and passivation for device reliability.
nanomaterial synthesis, thin‑film deposition
Microfabrication & Thin Film Deposition (Cleanroom-Based)
• RF/DC sputtering:
• Thermal & e-beam evaporation
Innovating at the intersection of materials science and device engineering
Indoor and outdoor photovoltaics
Broadband photodetectors
Memristors
flexible optoelectronics
neuromorphic devices
Physical sensors
Supercapacitors.
Cleanroom microfabrication: lithography, etching, and passivation for device reliability.
nanomaterial synthesis, thin‑film deposition
Microfabrication & Thin Film Deposition (Cleanroom-Based)
• RF/DC sputtering:
• Thermal & e-beam evaporation
Research community or research topic
Memristor Miniaturization for Edge Computing Applications.
Memristor Miniaturization for Edge Computing Applications.
Biography
Research
Dr. Mokurala Krishnaiah is a materials scientist and device engineer with international research experience in India, South Korea, the USA, and Finland. He earned his PhD from IIT Bombay and was a Marie Curie Postdoctoral Researcher at Tampere University until 31 March 2026. His work focuses on photodetectors, photovoltaics, memristors, RRAM, flexible electronics, and AI-driven materials design. He is currently working on memristor miniaturization for edge computing at Wihuri Physical Laboratory.
Teaching
Publications
- Perovskite‐Inspired Cs₂AgBi₂I₉: A Promising Photovoltaic Absorber for Diverse Indoor Environments (2025)
- Advanced Energy Materials
(A1 Refereed data article in a scientific journal) - Pyridine-Based Multifunctional Surface Passivators Enable Efficient and Stable Perovskite Indoor Photovoltaics (2025)
- ACS Applied Materials and Interfaces
(A1 Refereed original research article in a scientific journal) - Surpassing the 10% Efficiency Threshold in Perovskite-Inspired Indoor Photovoltaics (2025)
- ACS Energy Letters
(A1 Refereed original research article in a scientific journal)
UTU Research Portal