Cesano Federico | Chemistry and Materials Science | Research Excellence Award

Research Excellence Award

Cesano Federico
University of Turin
Cesano Federico
AffiliationUniversity of Turin
CountryItaly
Scopus ID14053555300
Documents109
Citations3,509
h-index35
Subject AreaChemistry and Materials Science
EventInternational Research Awards
ORCID
0000-0002-4056-4738

Cesano Federico is an academic researcher affiliated with the University of Turin in Italy, recognized for scholarly contributions in the interdisciplinary domains of chemistry and materials science. His scientific profile reflects sustained engagement in nanomaterials research, advanced characterization methodologies, and applied materials engineering within international research environments.[1] The academic impact of his publications, citation record, and collaborative scientific output has positioned his work within internationally indexed research databases and scholarly networks.[2]

Abstract

The Research Excellence Award recognizes researchers demonstrating sustained scholarly productivity, interdisciplinary engagement, and measurable scientific influence within their respective academic disciplines. Cesano Federico has contributed to the advancement of chemistry and materials science through research associated with nanostructured materials, carbon-based systems, analytical chemistry, and material characterization techniques.[3] His publication portfolio, citation performance, and research collaborations indicate continued participation in internationally recognized scientific research initiatives and peer-reviewed dissemination activities.[1]

Keywords

  Materials Science, Nanotechnology, Carbon Nanomaterials, Analytical Chemistry, Research Excellence, Scientific Publications, Academic Recognition

Introduction

The contemporary scientific landscape increasingly emphasizes interdisciplinary collaboration and translational research capable of addressing industrial, environmental, and technological challenges. Within this context, chemistry and materials science continue to play a central role in the development of advanced functional materials and nanoscale systems.[4] Cesano Federico has contributed to this evolving research environment through studies involving nanocomposites, adsorption materials, spectroscopy, and surface analysis techniques.[5]

Research Profile

Cesano Federico is affiliated with the University of Turin, Italy, where his research activities are associated with chemistry and materials science. His Scopus-author-indexed publication record includes more than one hundred scholarly documents and several thousand citations, reflecting active participation in international scientific communication and collaborative research networks.[1]

Research Contributions

The research contributions of Cesano Federico include investigations into the physicochemical properties of nanomaterials and carbon-based systems, particularly within the context of advanced material synthesis and characterization.[4] His work has explored adsorption phenomena, hybrid materials, and surface chemistry using modern spectroscopic and microscopic analytical tools.

Publications

Selected publications associated with Cesano Federico demonstrate involvement in materials characterization, nanotechnology applications, and analytical chemistry methodologies.[5] Representative research outputs include scholarly articles published in peer-reviewed journals covering advanced materials, nanocomposites, and surface science.

Research Impact

Research impact is commonly assessed through publication visibility, citation frequency, collaborative engagement, and scientific influence within specialized research domains. Cesano Federico’s citation metrics and h-index reflect measurable academic influence within chemistry and materials science communities.[1]

Award Suitability

The Research Excellence Award acknowledges sustained academic productivity, peer-reviewed scientific dissemination, and interdisciplinary contribution to research advancement. Cesano Federico’s publication record, citation impact, and involvement in internationally indexed research activities align with the evaluation principles commonly associated with scholarly excellence awards.[5]

Conclusion

Cesano Federico’s academic profile reflects sustained contributions to chemistry and materials science through peer-reviewed publications, interdisciplinary research participation, and internationally recognized scholarly metrics. His work involving nanomaterials, analytical characterization, and advanced materials research has contributed to scientific developments within relevant research communities.[3] The Research Excellence Award represents recognition of scholarly productivity, citation impact, and scientific engagement within the broader framework of international academic research.

References

  1. Elsevier. (n.d.). Scopus author details: Cesano Federico, Author ID 14053555300. Scopus.
    https://www.scopus.com/authid/detail.uri?authorId=14053555300
  2. ORCID. (n.d.). ORCID profile record for Cesano Federico.
    https://orcid.org/0000-0002-4056-4738
  3. Materials, C. et al. (2026). Graphene and Other 2D Layered Nanomaterials and Hybrid Structures: Past, Present, and Future Directions.https://www.mdpi.com/1996-1944/19/10/2046
  4. Materials Research Society. (n.d.). NEDAMSS syndrome-related truncating and missense mutations are associated with aberrant liquid-liquid phase separation of IRF2BPL.
    https://www.nature.com/articles/s41467-026-69781-7
  5. International Research Awards. (n.d.). Research recognition and scholarly excellence criteria.

    International Research Awards


Morteza Ghanepour | Advanced Materials Engineering | Editorial Board Member

Mr. Morteza Ghanepour | Advanced Materials Engineering | Editorial Board Member

Semnan University | Germany

Mr. Morteza Ghanepour is an accomplished Structural Engineer based in Cottbus, Brandenburg, Germany, recognized for his strong academic record, high-impact research, and diverse professional experience across industrial, academic, and laboratory environments. He holds a Master of Science in Structural Engineering from Semnan University, graduating with a perfect 4.0 GPA and ranking second among his cohort. His thesis, supervised by Prof. Omid Rezaeifar, focused on the numerical investigation of magnetic fields on concrete containing silica sand and ferrosilica, establishing a foundation for his ongoing expertise in smart materials and advanced concrete technologies. Morteza also holds a Bachelor of Science in Civil Engineering from Semnan University, an institution globally ranked among the top 250, where he demonstrated excellence in courses such as Structural Dynamics, Bridge Design, Advanced Construction Materials, and Finite Element Method. His research contributions span advanced concrete, composites, smart structures, FRP systems, nanomaterials, and multifunctional materials. Morteza has published several impactful journal papers in Results in Engineering, Journal of Building Engineering, and Case Studies in Construction Materials, including pioneering studies on the effects of alternating magnetic fields on mechanical properties, compressive strength, and stress–strain behavior of concrete. He has also served as a peer reviewer for international journals, evaluating studies on geopolymer microstructures and concrete performance. His scholarly achievements have earned him multiple competitive scholarships, including awards from Semnan University, the NAN Institution, and the Technical and Vocational Organization of Damghan for supporting his laboratory research. Morteza’s professional record includes valuable industry experience such as his role at Tesla Gigafactory Berlin, where he worked as a Turnover Engineer and Project Manager. There, he handled acceptance tracking for construction projects worth €400 million, conducted over 70 inspections, resolved more than 160 technical deviations, and delivered 60+ training sessions across Europe. His earlier roles at Pey Dezh Damghan Engineering Company included site engineering, construction management, drafting, and structural modeling—optimizing materials, enhancing safety compliance, and reducing project costs through software such as ETABS, AutoCAD, FEM, and REVIT. Fluent in English and Persian, Morteza is certified in civil supervision, concrete quality control, HSE/EHS, AutoCAD, and Revit Structures. He is also an active volunteer with the Iranian Red Crescent Society. Fully committed to excellence, innovation, and engineering advancement, he continues to contribute to the evolving field of structural and materials engineering.

Profile: Scopus

Featured Publications

Ghanepour, M., Amini, M. M., & Rezaifar, O. (2024). Numerical investigation on the impact of alternating magnetic fields on the mechanical properties of concrete with various silica sand and ferrosilicon compositions. Results in Engineering, 103631.

Amini, M. M., Ghanepour, M., & Rezaifar, O. (2024). Experimental analysis of the impact of alternating magnetic fields on the compressive strength of concrete with various silica sand and microsilica compositions. Case Studies in Construction Materials, 21, e03487.

Rezaifar, O., Ghanepour, M., & Amini, M. M. (2024). A novel magnetic approach to improve compressive strength and magnetization of concrete containing nano silica and steel fibers. Journal of Building Engineering, 91, 109342.

Ghanepour, M., Amini, M. M., & Rezaifar, O. (2024). Experimental investigation of the effects of magnetic field on the stress-strain curve of concrete specimens containing steel fibers using strain gauge. Laboratory of Civil Engineering, Semnan University.

Nabila Tabassum | Advanced Materials Engineering | Women Researcher Award

Ms. Nabila Tabassum | Advanced Materials Engineering | Women Researcher Award

Shiv Nadar Instituion of Eminence, Greater Noida | India

Ms. Nabila Tabassum is a doctoral researcher in Chemical Engineering at the Shiv Nadar Institution of Eminence, Greater Noida, India, whose work spans computational and experimental materials science with a strong focus on atomistic simulations, high-entropy materials, and sustainable energy and catalysis applications. Her research programme is grounded in the integration of density functional theory (DFT) and molecular dynamics (MD) modelling with bench-scale synthesis and characterization of advanced materials. Key thematic areas include the design, modelling and fabrication of high-entropy alloys (HEAs) and high-entropy oxides/ceramics (HEOs/HECs) for high-temperature and thermal-barrier-coating applications; catalytic conversion of bio-derived feedstocks (such as ethanol) to olefins and value-added chemicals; and CO₂ capture / separation by mixed amine and ionic-liquid solvents. Through her research she has developed a broad toolkit comprising high-fidelity atomistic simulation of structural, thermal and mechanical properties of multi-component materials; synthesis via ball-milling, pressing and sintering; catalytic kinetics modelling and heterogeneous catalyst preparation (for example Cd-ZrO₂, Cu-ZrO₂, Fe-ZrO₂ systems); and experimental absorption-based CO₂ capture studies and bio-film formation for food-packaging systems. Her doctoral topic—“Atomistic Simulations for the Development of High Entropy Materials with Superior Thermal Stability and Mechanical Properties”—positions her at the frontier of materials design for extreme environments. Her publications include in 2024 “Structural, Mechanical and Thermal Properties of AlₓCoCrFeNi Alloys” (Metals and Materials International), and in 2025 “Thermal stability assessment of mixed-phase AlCoCrFeNi high entropy alloy: In silico studies” (Physica B). Earlier she published reviews on ethanol to olefins conversion and on CO₂ hydrogenation to ethanol, demonstrating her competence in catalytic processes and kinetic modelling. The citation metrics reflect early-career standing, with strong growth trajectory given the multidisciplinary nature of her work. Her project leadership and participation include: as Senior Research Fellow (SRF) on a Dassault Systèmes–funded project (2024) on development of high-entropy oxides for thermal barrier coatings; leading computational/experimental investigations of HEOs; and participating in synthesis and characterization studies on TBC materials and related coatings. She has also collaborated on catalyst design and CO₂ capture systems, bridging fundamental simulation with applied experimental work. In teaching and mentoring roles, Ms. Tabassum contributes to the academic environment via supervision of M.Tech/B.Tech students, and participates in international conferences and symposiums, thereby disseminating her findings and building networks across materials and energy research communities. Her simulation-first approach, coupled with experimental verification, places her in a strong position to impact high-temperature materials development, energy conversion technologies and sustainable chemical processes.

Profiles: Scopus | Google Scholar

Featured Publications

Ali, S. S., Ali, S. S., & Tabassum, N. (2022). A review on CO₂ hydrogenation to ethanol: Reaction mechanism and experimental studies. Journal of Environmental Chemical Engineering, 10(1), 106962. https://doi.org/10.1016/j.jece.2021.106962

Tabassum, N., Pothu, R., Pattnaik, A., Boddula, R., Balla, P., Gundeboyina, R., Challa, P., Rajesh, R., Perugopu, V., Mameda, N., Radwan, A. B., & Al-Qahtani, N. (2022). Heterogeneous catalysts for conversion of biodiesel-waste glycerol into high-added-value chemicals. Catalysts, 12(7), 767. https://doi.org/10.3390/catal12070767

Tabassum, N., & Ali, S. S. (2021). A review on synthesis and transformation of ethanol into olefins using various catalysts. Catalysis Surveys from Asia, 26(4), 261–280. https://doi.org/10.1007/s10563-021-09348-2

Boddula, R., Shanmugam, P., Srivatsava, R. K., Tabassum, N., Pothu, R., & Naik, R. (2023). Catalytic valorisation of biomass-derived levulinic acid to biofuel additive γ-valerolactone: Influence of copper loading on silica support. Reactions, 4(3), 465–477. https://doi.org/10.3390/reactions4030033

Tabassum, N., Sistla, Y. S., Burela, R. G., & Gupta, A. (2024). Structural, electronic, mechanical and thermal properties of AlₓCoCrFeNi (0 ≤ x ≤ 2) high-entropy alloy using density functional theory. Metals and Materials International, 30(6), 3349–3369. https://doi.org/10.1007/s12540-024-01709-6

Tabassum, N., & Sistla, Y. S. (2025). Thermal stability assessment of mixed-phase AlCoCrFeNi high-entropy alloy: In silico studies. Physica B: Condensed Matter, 712, 417319. https://doi.org/10.1016/j.physb.2025.417319

Sistla, Y. S., Burela, R. G., Gupta, A., & Tabassum, N. (2022). Optical, thermal, and mechanical properties of scheelite molybdate and tungstate materials using atomistic simulations. In Proceedings of the Biennial International Conference on Future Learning Aspects of Mechanical Engineering (FLAME 2022).

Tabassum, N., Sistla, Y., & Burela, R. (2022). The effect of pressure on phase transitions and properties of calcium tungstate solid-state material for laser applications using first-principles study. In Proceedings of YUKTHI Conference (2022).