Dr. Kousik Bera | Editorial Board Member

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Dr. Kousik Bera | Editorial Board Member

Indian Institute of Technology Bombay | India

Kousik Bera is an emerging researcher in optical physics and advanced materials science, with an h-index of 4, 11 research documents, and 48 citations across 44 citing works. He earned his research training at premier Indian institutions, focusing extensively on Raman spectroscopy, thermal transport in two-dimensional materials, nonlinear optics, and quantum photonics. His experience spans studies on hexagonal boron nitride (hBN), GaN nanowall networks, Heusler alloys, Pd–Ag nanostructures, and entangled photon generation using PPKTP crystals. He has contributed to prestigious journals such as Optics Communications, Physical Review B, Journal of Applied Physics, Applied Physics Letters, Optical Materials, and Nanotechnology. His research interests include 2D materials, ultrafast laser–matter interactions, spectroscopy-driven materials characterization, superconductivity, and quantum-enhanced optical systems. Bera’s work integrates experimental materials science with quantum photonic applications, highlighting his interdisciplinary expertise. His contributions have supported advancements in thermal conductivity engineering, strain analysis, nonlinear optical behavior, and surface-enhanced Raman spectroscopy (SERS). He has collaborated with multiple national and international research groups, extending the impact of his work across several domains of condensed matter physics. With a steadily growing publication record and diversified research output, he continues to advance innovative spectroscopic and nanomaterial-based methodologies.

Profiles : Google Scholar | Scopus Orcid

Featured Publications

Bera, K., Dubey, P. K., Kumar, A., & Jha, M. (2025). Bright source of degenerate polarization-entangled photons using type-0 PPKTP crystal: Effects of accidental coincidences. Optics Communications, 132401. https://doi.org/10.1016/j.optcom.2025.132401

Bera, K., Moram, S. S. B., Banerjee, D., Lahiri, J., & Rao Soma, V. (2024). Surface enhanced Raman scattering-based sensing and ultrafast nonlinear optical properties of silver-hexagonal boron nitride nanocomposites achieved by femtosecond laser ablation. Optical Materials, 157, 116393. https://doi.org/10.1016/j.optmat.2024.116393

Das, N. M., Chauhan, A., Bharati, M. S. S., Bera, K., et al. (2024). Nanostructured bi-metallic Pd–Ag alloy films for surface-enhanced Raman spectroscopy-based sensing application. Journal of Vacuum Science & Technology A, 42(5). https://doi.org/10.1116/6.0003748

Bera, K., Chugh, D., Bandopadhyay, A., Tan, H. H., Roy, A., & Jagadish, C. (2023). Decoupling the roles of defects/impurities and wrinkles in thermal conductivity of wafer-scale hBN films. Journal of Applied Physics, 134(15). https://doi.org/10.1063/5.0168186

Rahaman, A., Paramanik, T., Pal, B., Pal, R., Maji, P., Bera, K., et al. (2023). Surface-phase superconductivity in a Mg-deficient V-doped MgTi₂O₄ spinel. Physical Review B, 107(24), 245124. https://doi.org/10.1103/physrevb.107.245124

Mr. Jia-Xin Peng | Editorial Board Member

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Mr. Jia-Xin Peng | Editorial Board Member

Nantong University | China

Jia-Xin Peng is a theoretical physicist whose research advances quantum optics, optomechanics, and precision quantum measurement. He has authored 74 scientific documents, accumulating approximately 796 citations with an h-index of 17, reflecting his growing influence in the field. His work focuses on macroscopic quantum coherence, quantum synchronization, photon–magnon and optomechanical coupling, quantum estimation theory, and hybrid Laguerre–Gaussian cavity systems. He has contributed significantly to understanding quantum coherence in molecular optomechanical systems, quantum-enhanced sensing, entanglement in rotating and rovibrational mirrors, and fast/slow-light engineering through cavity modulation. His academic background includes research appointments in optical physics and quantum engineering, where he collaborated with leading groups on whispering-gallery-mode resonators, magnomechanical cavities, and driven–dissipative systems. His recent achievements include demonstrating quantum-complete synchronization in molecular optomechanics and developing improved estimation schemes using squeezed vacuum and coherent feedback. His publications appear in major journals such as Physical Review A, Physical Review Applied, Chaos, Solitons & Fractals, Optics Express, and Physics Letters A. While formal awards are not publicly documented, his consistent publication record and innovative theoretical contributions highlight his promise as a rising researcher in quantum optomechanics and precision measurement science.

Profile : Orcid

Featured Publications

Peng, J.-X., Zhao, C., Djorwe, P., Emale, K. B., Yu, Z.-W., & Asjad, M. (2025). Macroscopic quantum coherence and quantum complete synchronization in molecular optomechanical system. Chaos, Solitons & Fractals, 197, 116473. https://doi.org/10.1016/j.chaos.2025.116473

Peng, J.-X., et al. (2025). Quantum estimation for improving optomechanical coupling strength with two-level atoms, coherent feedback loop, and squeezed vacuum injection. Physical Review A, 111, 012607. https://doi.org/10.1103/PhysRevA.111.012607

Hidki, A., Peng, J.-X., Singh, S. K., Khalid, M., & Asjad, M. (2024). Entanglement and quantum coherence of two YIG spheres in a hybrid Laguerre–Gaussian cavity optomechanics. Scientific Reports, 14, 11204. https://doi.org/10.1038/s41598-024-61670-7

Jin, L., Peng, J.-X., Yuan, Q.-Z., & Feng, X.-L. (2021). Macroscopic quantum coherence in a spinning whispering-gallery-mode resonator. Optics Express, 29(25), 41191–41205. https://doi.org/10.1364/OE.443486

Dr. Jian Lei | Editorial Board Member

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Dr. Jian Lei | Editorial Board Member

Chongqing Three Gorges Medical College | China

Dr. Jian Lei is a promising researcher in organic optoelectronic materials with a PhD in Chemistry from National Tsing Hua University, where he specialized in advanced molecular engineering for high-performance organic emitters. He currently serves at Chongqing Three Gorges Medical College, contributing to research and foundational science education. Dr. Lei has established a strong publication record, with an h-index of 21, more than 20 research documents, and over 240 citations. His work focuses on thermally activated delayed fluorescence (TADF), azepine-modulated emitters, multiple-resonance molecular systems, and strategies for suppressing nonradiative decay to achieve efficient, stable, and narrowband OLED emission. He has authored impactful papers in top-tier journals such as Materials Horizons, Chemical Science, ACS Materials Letters, JACS Au, and The Journal of Physical Chemistry C. His contributions include breakthroughs in azepine engineering, high-EQE blue OLEDs, and molecular strategies for boosting afterglow and upconversion performance. Although early in his career, his rapidly growing citation record and consistent publications underscore his rising influence in materials chemistry and optoelectronic device research. In conclusion, Dr. Lei is an emerging scientist whose innovative molecular designs hold strong potential for advancing next-generation OLED technologies.

Profile : Orcid

Featured Publications

Chen, Y.-K., Lei, J., Chao, Y.-C., Kung, Y.-C., Hung, W.-Y., Hsu, L.-Y., & Wu, T.-L. (2025). Strategic azepine engineering realizes highly efficient and stable blue narrowband light-emitting diodes. Materials Horizons.

Lei, J., Chen, Y.-K., Wang, M.-J., Ko, C.-L., Hung, W.-Y., Hsu, L.-Y., Cheng, C.-H., & Wu, T.-L. (2025). Azepine modulation in thermally activated delayed fluorescence emitters for OLEDs achieving nearly 40% EQE. ACS Materials Letters.

Liu, P.-C., Lei, J., Liu, C.-C., Fan, Y.-T., & Wu, T.-L. (2025). Rational molecular design for boosting afterglow efficiency in nonplanar carbazolocarbazoles. JACS Au.

Chen, Y.-K., Lei, J., & Wu, T.-L. (2024). Elevating the upconversion performance of a multiple resonance thermally activated delayed fluorescence emitter via an embedded azepine approach. Chemical Science.

Lei, J., Chang, C.-W., Chen, Y.-K., Chou, P.-Y., Hsu, L.-Y., Cheng, C.-H., & Wu, T.-L. (2024). Strategy of modulating nonradiative decay for approaching efficient thermally activated delayed fluorescent emitters. The Journal of Physical Chemistry C.

Dr. Zahra Rasaei | Editorial Board Member

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Dr. Zahra Rasaei | Editorial Board Member

University of Tehran | Iran

Zahra Rasaei is a soil scientist specializing in Digital Soil Mapping, legacy soil inventories, soil classification, and clay mineralogy. She holds a PhD in Digital Soil Mapping and has conducted extensive research on integrating legacy soil data with modern geospatial and Bayesian statistical techniques to improve the accuracy of soil property and soil class predictions in Iran. Her work focuses on spatial filtering, Bayesian data fusion, land evaluation, and soil genesis, contributing to the modernization of Iran’s soil information systems. She has authored 6 scientific publications, with an h-index of 4 and 68 citations, reflecting her growing influence in pedometrics and geospatial soil science. Her research experience spans digital soil modeling, remote-sensing data integration, and the rescue of old soil survey inventories for national soil mapping. She has also served as a peer reviewer for the Journal of South American Earth Sciences. Her research interests include soil salinity prediction, zero-inflated data modeling, DEM-based covariate analysis, and improved soil classification frameworks. Although early in her career, she has made significant contributions to digital soil mapping methodologies, and her work supports soil-resource management and sustainable land-use planning. Overall, she is a promising researcher advancing modern soil-mapping science.

Profile : Orcid

Featured Publications

Rasaei, Z., Sarmadian, F., Jafari, A., & Flynn, T. (2025). Digital mapping of soil salinity: Overcoming the challenges of zero-inflated and skewed sample distributions. Pedosphere.

Rasaei, Z., Rossiter, D. G., & Farshad, A. (2020). Rescue and renewal of legacy soil resource inventories in Iran as an input to digital soil mapping. Geoderma Regional, 21, e00262.

Rasaei, Z., & Bogaert, P. (2019). Spatial filtering and Bayesian data fusion for mapping soil properties: A case study combining legacy and remotely sensed data in Iran. Geoderma, 344, 50–62.

Rasaei, Z., & Bogaert, P. (2019). Bayesian data fusion for combining maps of predicted soil classes: A case study using legacy soil profiles and DEM covariates in Iran. Catena, 182, 104138.

Rasaei, Z., Sarmadian, F., & Jafari, A. (2019). Comparison of fertility capability and taxonomic classification systems to classify soil map units in parts of Chaharmahal-va-Bakhtiari Province. Desert.

Dr. Mubbashar Nazeer | Editorial Board Member

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Dr. Mubbashar Nazeer | Editorial Board Member

Government College University Faisalabad | Pakistan

Dr. Mubbashar Nazeer is a prominent researcher in applied mathematics, specializing in fluid mechanics, bio-fluids, nanofluid dynamics, heat transfer, cavity flows, and finite element analysis. With an h-index of 23, over 90+ documents, and more than 1,800 citations, his research has made significant contributions to nonlinear rheology, multiphase flow modeling, magnetohydrodynamics, and thermal transport in complex fluids. His academic journey includes advanced training in applied mathematics and computational fluid dynamics, followed by extensive experience in numerical modeling, perturbation methods, and simulation-based analysis of non-Newtonian fluid flows. Dr. Nazeer’s research consistently addresses real-world engineering and physiological flow problems, emphasizing novel rheological models such as Eyring–Powell, Casson, Rabinowitsch, Ellis, Jeffrey, and Maxwell fluids. He has collaborated widely across international research groups and published influential work in high-impact journals such as International Communications in Heat and Mass Transfer, Case Studies in Thermal Engineering, Surfaces and Interfaces, and Numerical Methods for Partial Differential Equations. His contributions have earned recognition within the fluid mechanics community, including acknowledgments for outstanding research productivity and high-impact publications. Overall, Dr. Nazeer remains committed to advancing computational modeling and thermal–fluid sciences through innovative problem-solving and interdisciplinary collaboration.

Profile : Google Scholar

Featured Publications

Nayak, M. K., Shaw, S., Khan, M. I., Pandey, V. S., & Nazeer, M. (2020). Flow and thermal analysis on Darcy–Forchheimer flow of copper–water nanofluid due to a rotating disk: A static and dynamic approach. Journal of Materials Research and Technology, 9(4), 7387–7408.

Chu, Y. M., Nazeer, M., Khan, M. I., Hussain, F., Rafi, H., Qayyum, S., & Abdelmalek, Z. (2021). Combined impacts of heat source/sink, radiative heat flux, temperature-dependent thermal conductivity on forced convective Rabinowitsch fluid. International Communications in Heat and Mass Transfer, 120, 105011.

Nazeer, M., Khan, M. I., Rafiq, M. U., & Khan, N. B. (2020). Numerical and scale analysis of Eyring–Powell nanofluid towards a magnetized stretched Riga surface with entropy generation and internal resistance. International Communications in Heat and Mass Transfer, 119, 104968.

Nazir, M. W., Javed, T., Ali, N., & Nazeer, M. (2021). Effects of radiative heat flux and heat generation on magnetohydrodynamics natural convection flow of nanofluid inside a porous triangular cavity. Numerical Methods for Partial Differential Equations.

Dr. Muhammad Bilal | Editorial Board Member

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Dr. Muhammad Bilal | Editorial Board Member

Shanghai University | China

Dr. Muhammad Bilal is an applied mathematics researcher at Shanghai University whose work focuses on nonlinear wave theory, optical solitons, plasma physics, and computational methods for complex dynamical systems. With a strong publication record comprising over 40 documents, more than 1,900 citations, and an h-index of 23, he has established himself as a significant contributor to mathematical physics and nonlinear wave propagation. He completed his advanced education in applied and computational mathematics and has accumulated extensive research experience through collaborative projects in wave dynamics, optical fiber modeling, modulation instability, and analytical methods for nonlinear differential equations. His research interests span nonlinear Schrödinger systems, shallow water wave models, ferromagnetic materials, fractional models, and stability analysis across diverse physical systems. Dr. Bilal has contributed widely cited analytical techniques and exact solution frameworks that have enhanced theoretical understanding and computational modeling in optical communication and fluid dynamics. His work has appeared in reputable international journals such as Mathematical Methods in the Applied Sciences, Results in Physics, Optical and Quantum Electronics, Modern Physics Letters B, and IEEE Access. He has also been recognized for his scientific impact through multiple high-quality publications and his growing influence in applied mathematics research.

Profile : Google Scholar

Featured Publications

Bilal, M. A., Zeeshan, M., Riaz, Q., Shahzad, M. K., Jabeen, H., & Haider, S. A., et al. (2021). Protocol-based deep intrusion detection for DoS and DDoS attacks using UNSW-NB15 and Bot-IoT datasets. IEEE Access, 10, 2269–2283.

Bilal, M., Seadawy, A. R., Younis, M., Rizvi, S. T. R., & Zahed, H. (2021). Dispersive propagation wave solutions to unidirectional shallow water wave Dullin–Gottwald–Holm system and modulation instability analysis. Mathematical Methods in the Applied Sciences, 44(5), 4094–4104.

Bilal, M., Seadawy, A. R., Younis, M., Rizvi, S. T. R., El-Rashidy, K., & Mahmoud, S. F. (2021). Analytical wave structures in plasma physics modelled by the Gilson-Pickering equation using two integration norms. Results in Physics, 23, 103959.

Younis, M., Sulaiman, T. A., Bilal, M., Rehman, S. U., & Younas, U. (2020). Modulation instability analysis and optical solutions to the modified nonlinear Schrödinger equation. Communications in Theoretical Physics, 72(6), 065001.

Younis, M., Younas, U., Rehman, S. U., Bilal, M., & Waheed, A. (2017). Optical bright–dark and Gaussian soliton with third-order dispersion. Optik, 134, 233–238.

Mr. Farshad Sadeghpour | Editorial Board Member

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Mr. Farshad Sadeghpour | Editorial Board Member

Petroleum University of Technology | Iran

Farshad Sadeghpour is a geomechanics and reservoir engineering researcher at the Petroleum University of Technology (PUT), known for his contributions to underground gas storage, petrophysics, and CO₂ geological sequestration. He has authored multiple peer-reviewed publications covering geomechanical upscaling, fracture development under stress, anisotropic rock behavior, storage-efficiency modeling, and petrophysical parameter estimation. His current Google Scholar record lists 22 citations, an h-index of 3, and 6 indexed documents, reflecting his growing influence in subsurface engineering. He holds academic training in petroleum engineering from PUT and additional postgraduate research experience from the Islamic Azad University, Science & Research Branch. His research experience includes collaborative studies on elastic property prediction, machine-learning-based evaluation of CO₂ storage feasibility, and advanced triaxial testing for characterizing anisotropic formations. His work demonstrates strong expertise in integrating experimental, computational, and data-driven approaches to solve complex reservoir challenges. His research interests include geomechanics, underground storage, CO₂ sequestration, petrophysical modeling, machine learning, and rock mechanics. Although still early in his career, his contributions indicate promise for impactful advancements in sustainable subsurface energy systems. Overall, Farshad Sadeghpour is an emerging researcher dedicated to improving geological storage, reservoir characterization, and the scientific foundations of low-carbon energy technologies.

Profile : Google Scholar

Featured Publications

Sadeghpour, F., Darkhal, A., Gao, Y., Motra, H. B., Aghli, G., & Ostadhassan, M. (2024). Comparison of geomechanical upscaling methods for prediction of elastic modulus of heterogeneous media. Geoenergy Science and Engineering, 239, 212915.

Aghli, G., Aminshahidy, B., Motra, H. B., Darkhal, A., Sadeghpour, F., … (2024). Effect of stress on fracture development in the Asmari reservoir in the Zagros Thrust Belt. Journal of Rock Mechanics and Geotechnical Engineering, 16(11), 4491–4503.

Sadeghpour, F. (2025). Storage efficiency prediction for feasibility assessment of underground CO₂ storage: Novel machine learning approaches. Energy, 324, 136040.

Iranfar, S., Sadeghpour, F., Manshad, A. K., Naderi, M., & Shakiba, M. (2025). An eigenvalue-driven framework for the ranking and selection of optimal geological CO₂ storage sites. Results in Engineering, 106770.

Sadeghpour, F., Motra, H. B., Sethi, C., Wind, S., Hazra, B., Aghli, G., … (2025). Elastic properties of anisotropic rocks using a stepwise loading framework in a true triaxial testing apparatus. Geoenergy Science and Engineering, 251, 213883.

Assoc. Prof. Dr. Farzaneh Marahel | Editorial Board Member Award

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Assoc. Prof. Dr. Farzaneh Marahel | Editorial Board Member Award

Islamic Azad University | Iran

Dr. Farzaneh Marahel is a faculty member in the Department of Chemistry at Islamic Azad University, Tehran, Iran, where she has developed a strong research profile in analytical chemistry, sensor design and nanomaterials-based environmental and biological monitoring. Her documented output includes over 40 publications and more than 1,000 citations according to ResearchGate. While a formal h-index value could not be verified publicly, her citation record suggests a solid impact in her field. Her education background is in chemistry and nanomaterials (Iran) and she has progressed through roles involving analytical method development and nanostructured sensor fabrication for real-world samples (blood, urine, drinks, foods). Her research interests focus on quantum dots, G-C₃N₄ nanosheets, electrochemical and spectrofluorimetric sensing platforms for toxic compounds, dyes and pharmaceutically relevant analytes. Recent work includes a resonance Rayleigh scattering technique using GSH-capped PbS quantum dots and a square-wave anodic stripping voltammetric sensor employing G-C₃N₄ nanosheets. She is also active in peer-review, having reviewed for journals such as Langmuir, Separation and Purification Technology and Sustainable Chemistry & Pharmacy. Given her continuing output and review service, she is a promising mid-career researcher whose work helps bridge nanomaterials, environmental analysis and medical-bioanalytical sensing. In summary, Dr. Marahel represents an emerging leader in nanosensor research with growing scholarly impact and an applied focus on real-world analytical challenges.

Profile : Orcid 

Featured Publications

 Amouri, A., Marahel, F., Geramizadegan, A., & Asghariganjeh, M. R. (2025). Design of a resonance Rayleigh scattering technique and spectrofluorimetric method using GSH-capped PbS quantum dots for sensing nortriptyline in urine and blood samples. Spectroscopy Letters, 58(9), [Article e2554233]. https://doi.org/10.1080/00387010.2025.2554233

 Marahel, F., & Niknam, L. (2022). Application electrochemical sensor based on nanosheets G-C3N4/CPE by square-wave anodic stripping voltammetric for measuring amounts of toxic tartrazine color residual in different drink and foodstuffs. Journal of Environmental Science and Health, Part B, 57(6), 457–467. https://doi.org/10.1080/03601234.2022.2064676

Mr. Shehzad Khan | Best Researcher Award

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Mr. Shehzad Khan | Best Researcher Award

Nanjing University of Science and Technology | China

Mr. Shehzad Khan is a promising Pakistani quantum physicist with a growing research profile in the fields of quantum optics, quantum information, plasmonics, and nonlinear optics. With an h-index of 2, 3 published documents, and 7 citations, he has contributed to several high-impact journals, including Results in Physics, The European Physical Journal Plus, International Journal of Theoretical Physics, Journal of Magnetism and Magnetic Materials, and Physics Letters A. He completed his Bachelor’s degree in Physics from the University of Malakand (2019–2023), where his thesis focused on “Manipulation of Spectral Hole Burning in Atomic Medium by Doppler Broadening Effect.” His research expertise includes density matrix formalism, optical solitons, Goos-Hänchen shift, photonic spin Hall effect, and surface plasmon polaritons. Shehzad has demonstrated strong analytical and computational skills using Mathematica, MATLAB, and LaTeX, coupled with proficiency in data analysis and technical writing. Recognized for his academic excellence, he received the Higher Education Commission (HEC) Laptop Award for outstanding performance and an HEC Merit and Need-Based Scholarship. With a clear vision to advance the understanding of light-matter interaction and quantum systems, Shehzad Khan aspires to make impactful contributions to modern quantum science and optical physics.

Profile : Scopus

Featured Publications

Khan, S., Bilal, M., Uddin, S., Akgül, A., & Riaz, M. B. (2024). Spherical manipulation of lateral shifts in reflection and transmission through chiral medium. Results in Physics, 107647.

Khan, S., Saeed, M., Khan, M. A., Aldosary, S. F., & Ahmad, S. Coherent manipulation of optical solitons in four-level N-type atomic medium. International Journal of Theoretical Physics.

Ullah, R., Khan, S., Amina, S., & Javaid, S. Tunable cratering of lateral Goos–Hänchen shift in reflection and transmission of structured light in a chiral atomic medium. The European Physical Journal Plus.

Ullah, H., Khan, S., & Bilal, M. Localized electric and magnetic tangent loss via parity-time symmetry in induced high magneto-optical atomic medium. Journal of Magnetism and Magnetic Materials.

Ahmad, M., Khan, S.*, Shah, S. M. H., Salman, M., & Yousaf, M. (2025). Coherent manipulation of sensitivity of structure plasmon polariton waves. The European Physical Journal Plus.

Mr. Harish Verma | Best Researcher Award

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Mr. Harish Verma | Best Researcher Award

Indian Institute of Technology (Banaras Hindu University) Varanasi | India

Dr. Harish Verma holds a B.Sc (UG), B.Ed, M.Sc (PG), and M.Phil in Physics and has qualified the CSIR-NET JRF examination. He is currently pursuing a Ph.D. in energy storage, dielectric materials, density functional theory (DFT), artificial intelligence (AI), and machine learning (ML) at the Indian Institute of Technology (BHU), Varanasi. His research focuses on the synthesis and characterization of advanced functional materials such as oxide perovskites, spinels, and graphene-based nanocomposites for dielectric and electrochemical energy storage applications. Dr. Verma integrates computational DFT analysis with AI- and ML-assisted materials modeling to accelerate the design and optimization of high-performance materials. His recent works include studies on dielectric and conductivity behavior of SrCeO₃, Ru-doped CNT/graphene-oxide supercapacitors, and MgAl₀.₅Fe₁.₅O₄ spinel ferrite systems. With over 20 scientific publications, an h-index of 6, and more than 90 citations, he has contributed significantly to understanding charge transport, dielectric relaxation, and structure–property relationships in multifunctional ceramics. His research aims to bridge experimental materials science and computational intelligence for developing sustainable, next-generation energy storage technologies and smart functional materials with enhanced performance and stability.

Profile : Google Scholar

Featured Publications

Verma, H., Tripathi, A., & Upadhyay, S. (2024). A comprehensive study of dielectric, modulus, impedance, and conductivity of SrCeO₃ synthesized by the combustion method. International Journal of Applied Ceramic Technology, 21(4), 3032–3047.

Verma, S., Das, T., Verma, S., Pandey, V. K., Pandey, S. K., Verma, H., & Verma, B. (2025). Hierarchically architecture of Ru-doped multichannel carbon nanotubes embedded with graphene oxide for supercapacitor material with long-term cyclic stability. Fuel, 381, 133517.

Verma, S., Maurya, A., Verma, H., Singh, R., & Bhoi, B. (2024). Unveiling the characteristics of MgAl₀.₅Fe₁.₅O₄ spinel ferrite: A study of structural, optical, and dielectric properties. Chemical Physics Impact, 9, 100674.

Nirala, G., Katheriya, T., Yadav, D., Verma, H., & Upadhyay, S. (2023). The evolution of coil-less inductive behaviour in La-doped Sr₂MnO₄. Emergent Materials, 6(6), 1951–1962.

Verma, H., Kumar, P., Satyarthi, S. K., Bhattacharya, B., Singh, A. K., & Upadhyay, S. (2025). Investigation of La₂FeO₄–rGO nanocomposite electrode material for symmetric and asymmetric supercapacitor. Journal of Energy Storage, 114, 115849.