postdoctoral researcher at The Pennsylvania State University, United States
Dr. Kavya S. Keremane is a distinguished postdoctoral research scholar at the Department of Materials Science and Engineering, Pennsylvania State University, USA. With a Ph.D. in Materials Science, her research bridges the realms of advanced optoelectronics, photovoltaics, and neuromorphic computing. She is an expert in designing, synthesizing, and fabricating next-generation materials and devices such as perovskite solar cells, biological sensors, and memory devices. Her journey encompasses experience from prestigious institutions across India, Singapore, and the United States. Dr. Keremane’s scholarly impact is evident through her editorial roles with Discover Energy (Springer Nature) and the Journal of Organic Chemistry Synthesis and Process Development, alongside a growing list of high-impact publications. Her interdisciplinary contributions continue to redefine how material science drives innovation in energy and bio-integrated electronics. 🌍🔬⚡
Professional Profiles
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ORCID
🎓 Education
Dr. Kavya S. Keremane earned her Ph.D. in Materials Science from the National Institute of Technology Karnataka (NITK), Surathkal, India, where she conducted pioneering work on perovskite solar modules and sustainable energy devices. She further deepened her expertise with thesis-based projects at Nanyang Technological University (NTU), Singapore, focusing on large-area carbon-based perovskite modules. Earlier, she completed her Master’s studies in Chemistry with a specialization in organic synthesis at a reputed Indian institution, contributing to research on β-amino acid derivatives at Syngene International Ltd., Biocon. Her academic journey blends theoretical knowledge with practical applications, especially in synthetic organic chemistry and device engineering. Dr. Keremane’s educational background reflects a seamless transition from drug discovery chemistry to energy harvesting materials, showcasing her versatile aptitude for research and innovation across multiple scientific domains. 📚🧪🌱
🧪 Experience
Dr. Keremane brings over a decade of multidisciplinary research and industrial experience. At Penn State University, she currently explores advanced optoelectronic materials, neuromorphic computing, and wireless power transfer systems. Her Ph.D. research included developing tandem solar cells, DSSCs, and large-area stable modules. During her time at NTU Singapore and NITK Surathkal, she focused on photovoltaics and organic semiconductor design. Before transitioning to academia, she worked at Biocon and SignalChem Lifesciences, where she contributed to the synthesis of anticancer drug candidates using advanced synthetic organic chemistry. Her research has led to innovations in DNA-perovskite memory devices and photochemical neurotransmitter sensors funded by NSF and AFSOR. As an editor and prolific researcher, Dr. Keremane integrates material design with translational goals, crafting cutting-edge solutions in energy and biosensing. Her diverse roles reflect her ability to merge deep scientific inquiry with technological application. 🔧⚗️🌞
🏅 Awards and Honors
Dr. Kavya S. Keremane has received prestigious fellowships and project grants from leading funding agencies, including the National Science Foundation (NSF), Air Force Office of Scientific Research (AFSOR), and the U.S. Army RIF program. These awards supported her groundbreaking research on DNA-integrated memory devices, laser-induced wireless power systems, and photoreceptive architectures. Her doctoral work on large-area carbon-based perovskite solar modules earned acclaim for its innovation and potential scalability. She has been recognized for academic excellence throughout her education and has played influential editorial roles in high-impact journals such as Discover Energy (Springer Nature). Her interdisciplinary research profile and significant scholarly output have positioned her as an emerging leader in material science and sustainable energy research. 🥇📖🌟
🔬 Research Focus
Dr. Keremane’s research traverses the interface of material science, optoelectronics, and bioelectronics. Her core areas include perovskite photovoltaics (including tandem and transparent structures), memristor devices for neuromorphic computing, and organic/inorganic hybrid materials for next-gen energy solutions. She is actively developing biosensors and biomimetic devices, photochemical neurotransmitter sensors, and quantum-enhanced optoelectronics. Her work integrates fundamental materials chemistry with device engineering, enabling practical applications in energy harvesting, wireless power transfer, and high-density data storage. She also explores large-area device fabrication for real-world deployment, emphasizing stability, scalability, and sustainability. With funding from top-tier organizations, her research continues to advance frontier technologies at the crossroads of electronics and biology. ⚡🧠🔍
🛠️ Research Skills
Dr. Kavya S. Keremane boasts a versatile skill set encompassing materials synthesis, nanostructuring, thin-film fabrication, and device engineering. She is proficient in optoelectronic material design, including quantum dots, hybrid perovskites, and organic semiconductors. Her expertise extends to solar cell fabrication (DSSC, tandem, organic, perovskite), photodetectors, and memristors. She has hands-on experience with laser-based systems for wireless energy transfer and designing bio-interfacing sensors for diagnostics. Her strong foundation in synthetic organic chemistry enables her to develop new functional molecules for both pharmaceutical and electronic applications. She is adept in advanced instrumentation, photophysical characterization, and collaborative R&D workflows, making her a valuable contributor to multidisciplinary scientific teams. 🧪💡🔬
✅ Conclusion
Dr. Kavya S. Keremane is an exceptionally qualified candidate for the Best Researcher Award, with a track record that reflects both depth and breadth across interdisciplinary scientific domains. Her work in materials science, optoelectronics, and energy technology not only advances fundamental understanding but also drives practical innovations with real-world impact. Through her commitment to rigorous research and creative problem-solving, she has consistently delivered high-quality publications and meaningful contributions to the scientific community. Dr. Keremane’s ability to bridge theory and application underscores her unique position as a forward-thinking researcher. While further expanding her leadership in research funding and translational innovation would enhance her already impressive portfolio, her current achievements stand as a testament to her excellence and promise. She serves as a role model for emerging scientists, inspiring through both intellect and integrity. Dr. Keremane is a brilliant scientist whose work exemplifies innovation, dedication, and impact—strongly deserving of the Best Researcher Award.
Publications Top Notes
New carbazole-based symmetric double D–A type chromophores for DSSC application: Impact of di-anchoring nature on photoelectrochemical processes
Journal of Photochemistry and Photobiology A: Chemistry — 2025
Citations: N/A (recent/forthcoming)
A Molecular‐Level Exploration of Dopant‐Free Pyrazine‐Derived Hole Transport Materials: Investigation of Interfacial Interaction in Perovskite Photovoltaics
ChemPlusChem — 2025
Citations: N/A
Recent Advances in Aggregation-Induced Emission (AIE) Fluorescent Sensors for Biomolecule Detection
Chemosensors — 2025
Citations: N/A
Deciphering Potent Protein Tyrosine Phosphatase‐1B Inhibitors Through In silico Molecular Docking, MMGBSA, and Molecular Dynamics
ChemistrySelect — 2025
Citations: N/A
Pioneering the future of dentistry: AI-driven 3D bioprinting for next-generation clinical applications
Translational Dental Research — 2025
Citations: N/A
Dopant-free hydrophobic fluorene-based hole transport materials: impact of methoxy-substituted triphenylamine and carbazole peripheral groups on the performance of perovskite solar cells
Sustainable Energy & Fuels — 2025
Citations: N/A
Push–pull carbazole twin dyads as efficient sensitizers/co-sensitizers for DSSC application: effect of various anchoring groups on photovoltaic performance
Journal of Materials Chemistry C — 2025
Citations: N/A
Photovoltaic bioelectronics merging biology with new generation semiconductors and light in biophotovoltaics photobiomodulation and biosensing
npj Biosensing — 2024
Citations: ~7
HFIP‐Mediated Dual C(Ar)‐Alkylation Process Towards the Regioselective Synthesis of Triarylmethanes (TRAMs)
Chemistry – An Asian Journal — 2024
Citations: N/A
HFIP‐Mediated Cyclodesulfurization Approach for the Synthesis of 2‐Aminobenzoxazole and 2‐Aminobenzothiazole Derivatives
Asian Journal of Organic Chemistry — 2024
Citations: ~3
Reductive C−N Bond Formation of Nitroarenes Using Pd@rGO‐CuFe₂O₄ Magnetic Nanoparticles in Water towards the Synthesis of N‐Aryl Formamide and Azole Derivatives
Asian Journal of Organic Chemistry — 2024
Citations: N/A
Metal‐Free Organic Dyes for NiO‐Based Dye‐Sensitized Solar Cells: Recent Developments and Future Perspectives
Energy Technology — 2024
Citations: ~6
Exploring optical, electrochemical, thermal, and theoretical aspects of simple carbazole-derived organic dyes
Heliyon — 2024
Citations: ~15
Perovskite Optoelectronic Devices (Book) — 2024
Citations: N/A (book citations not typically tracked)
Synthesis and Characterization of Novel Pd@rGO−CuFe₂O₄ Magnetic Nanoparticles: A Recyclable Catalyst for C−C Coupling Reaction in Biomass‐Derived Organic Solvent
Asian Journal of Organic Chemistry — 2023
Citations: N/A
Synthesis, optical, electrochemical, and computational investigation of new cyanopyridine-centered organic dyads
Optical Materials — 2023
Citations: ~23
Push‐Pull Phenoxazine‐Based Sensitizers for p‐Type DSSCs: Effect of Acceptor Units on Photovoltaic Performance
ChemSusChem — 2022
Citations: ~12
New Carbazole-Based Sensitizers for p-Type DSSCs: Impact of the Position of Acceptor Units on Device Performance
The Journal of Physical Chemistry C — 2022
Citations: ~10
Carbazole based organic dyes as effective photosensitizers: A comprehensive analysis of their structure‐property relationships
Electrochemical Science Advances — 2022
Citations: ~24
Simple carbazole derivatives with mono/dimethoxyphenylacrylonitrile substituents as hole‐transporting materials: Performance studies in hybrid perovskite solar cells
Electrochemical Science Advances — 2021
Citations: ~10
Improving the Performance of Carbon-Based Perovskite Solar Modules (70 cm²) by Incorporating Cesium Halide in Mesoporous TiO₂
ACS Applied Energy Materials — 2021
Citations: ~21
Simple 3,6‐disubstituted Carbazoles as Potential Hole‐Transport Materials: Photophysical, Electrochemical and Theoretical Studies
Photochemistry and Photobiology — 2020
Citations: ~24
A simple D-A-π-A configured carbazole based dye as an active photo-sensitizer: A comparative investigation on different parameters of cell
Journal of Molecular Liquids — 2020
Citations: ~44
Solvent selection for highly reproducible carbon-based mixed-cation hybrid lead halide perovskite solar cells via adduct approach
Solar Energy — 2020
Citations: ~15
Simple Thiophene Based Organic Dyes as Active Photosensitizers for DSSC Application: from Molecular Design to Structure Property Relationship
Journal of Nano- and Electronic Physics — 2020
Citations: ~9
Simple thiophene-bridged D–π–A type chromophores for DSSCs: a comprehensive study of their sensitization and co-sensitization properties
Physical Chemistry Chemical Physics — 2020
Citations: ~45
Improvement in performance of N3 sensitized DSSCs with structurally simple aniline based organic co-sensitizers
Solar Energy — 2018
Citations: ~46
Highly efficient carbazole based co-sensitizers carrying electron deficient barbituric acid for NCSU-10 sensitized DSSCs
Solar Energy — 2018
Citations: ~34