Md Lutfor Rahman | Polymer Chemistry | Editorial Board Member

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Prof. Md Lutfor Rahman | Polymer Chemistry | Editorial Board Member

Professor | University Malaysia Sabah | Malaysia

Dr. Rahman is a distinguished multidisciplinary researcher whose work spans advanced materials, environmental remediation, polymer engineering, micro-machining, and biosensor development, with influential contributions recognized across the global scientific community. His highly cited research on heavy-metal removal using efficient adsorbents provides vital advancements toward sustainable water-treatment technologies, addressing critical global contamination challenges through novel adsorbent design and performance optimization . In precision engineering, his analytical three-dimensional cutting-force model for micro end-milling has become a referenced framework in both industrial and academic studies, offering essential insights into tool workpiece interactions and supporting improvements in micro-manufacturing systems . Dr. Rahman’s contributions to biosensor science include the immobilization of glucose oxidase on cellulose acetate–polymethylmethacrylate membranes, a significant development that enhances enzyme stability and functional reliability for biochemical detection platforms used in diagnostics and analytical applications . His extensive work in polymer modification and carbohydrate-based material science includes pioneering studies on graft copolymerization of methyl acrylate onto sago starch, expanding understanding of initiator behavior, polymer grafting mechanisms, and the resulting structural–functional relationships of modified biopolymers . Further strengthening his contributions to functional materials, his synthesis and characterization of poly(amidoxime) chelating resins derived from polyacrylonitrile-grafted starch highlights his expertise in designing selective ion-binding materials with applications in separation science, environmental cleanup, and resource recovery . Across his scholarly portfolio, Dr. Rahman demonstrates a commitment to methodological rigor, innovation, and societal relevance, consistently integrating theoretical insight with practical application to address critical scientific and technological challenges while fostering impactful interdisciplinary collaborations.

Profiles : Google Scholar

Featured Publications

1.  Zaimee, M. Z. A., Sarjadi, M. S., & Rahman, M. L. (2021). Heavy metals removal from water by efficient adsorbents. Water, 13(19), 2659.

2.  Zaman, M. T., Kumar, A. S., Rahman, M., & Sreeram, S. (2006). A three-dimensional analytical cutting force model for micro end milling operation. International Journal of Machine Tools and Manufacture,     46(3–4), 353–366.

3.  Rauf, S., Ihsan, A., Akhtar, K., Ghauri, M. A., Rahman, M., Anwar, M. A., & Khalid, A. M. (2006). Glucose oxidase immobilization on a novel cellulose acetate–polymethylmethacrylate membrane. Journal of   Biotechnology, 121(3), 351–360.*

4.  Rahman, L., Silong, S., Zin, W. M., Rahman, M. Z. A., Ahmad, M., & Haron, J. (2000). Graft copolymerization of methyl acrylate onto sago starch using ceric ammonium nitrate as an initiator. Journal of Applied   Polymer Science, 76(4), 516–523.*

5.  L. M. R., Sidik, S., Wan, Z., R. M. Z., Mansor, A., & Jelas, H. (2000). Preparation and characterization of poly(amidoxime) chelating resin from polyacrylonitrile grafted sago starch. European Polymer Journal,       36(10), 2105–2113.*

Dr. Rahman’s research delivers impactful advancements in environmental remediation, precision engineering, and functional materials, addressing critical global challenges through innovative and widely cited scientific contributions. His work continues to influence research directions and support sustainable technological progress worldwide.

 

Gunjan Jadon | Medicinal Chemistry | Women Researcher Award

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Dr. Gunjan Jadon | Medicinal Chemistry | Women Researcher Award

Professor | Pacific College of Pharmacy | India

Dr. Gunjan Jadon is an emerging researcher in pharmaceutical analysis and analytical chemistry, known for her contributions to quality-centered method development and scientific rigor. With a growing academic profile reflected through 3 peer-reviewed publications, 54 citations, and an h-index of 2, she has steadily established her presence within the analytical science community. Her research focuses on chromatographic method development, impurity assessment, pharmaceutical quality control, and the systematic application of Analytical Quality by Design (QbD) principles. One of her notable works includes the development and validation of a QbD-based RP-HPLC method for the quantification of dobutamine, demonstrating her expertise in experimental optimization, response-surface modeling, and regulatory aligned method validation. Dr. Jadon’s broader research interests integrate risk assessment, analytical robustness studies, and the enhancement of method precision and reproducibility to support high-quality pharmaceutical evaluation. She actively collaborates with multidisciplinary teams of pharmaceutical scientists and analytical chemists, strengthening the practical and translational impact of her findings. Her work contributes to improving drug-evaluation workflows, ensuring analytical reliability, and promoting safer therapeutic outcomes across the pharmaceutical sector. Beyond her research outputs, she remains engaged in scientific dialogue through collaborative networks, co-authored studies, and participation in academic platforms aimed at advancing analytical science. Her contributions hold societal relevance by supporting the development of robust analytical frameworks that enhance the quality, safety, and consistency of pharmaceutical products. Driven by a commitment to scientific integrity and continuous innovation, Dr. Jadon continues to explore emerging analytical challenges while expanding the methodological landscape of pharmaceutical research, demonstrating promise as a dedicated and impactful early-career scientist.

Profiles : Google Scholar | Scopus | ResearchGate

Featured Publications

1. Dahiya, R., Dahiya, S., Fuloria, N. K., Kumar, S., Mourya, R., Chennupati, S. V., et al. (2020). Natural bioactive thiazole-based peptides from marine resources: Structural and pharmacological aspects. Marine Drugs, 18(6), 329.

2. Joshi, S. K., Bhadauria, R. S., & Diwaker, A. K. (2012). Introduction to neoplasm: Tumor classification – A review article. International Journal of Advanced Research in Pharmaceutical & Bio Sciences, 22.

3. Jadon, G., & Kumawat, L. (2011). Synthesis, spectral and biological evaluation of some phenyl acetic acid hydrazone derivatives. International Journal of Pharmaceutical Sciences and Research, 2(10), 2572.

4. Gunjan, J., & Kumawat, L. (2011). Synthesis, spectral and biological evaluation of some hydrazone derivatives. International Journal of Pharmaceutical Sciences and Research, 2(9), 2408–2412.

5. Gunjan, J., Rahul, N., Divya, S., Praveen, K. S., & Diwaker, K. A. (2012). Antioxidant activity of various parts of Punica granatum: A review. Journal of Drug Delivery & Therapeutics, 2, 138–141.

Gunjan Jadon’s work advances analytical chemistry and pharmaceutical quality assurance by developing robust, regulatory-aligned methods that improve drug safety and evaluation. Her research contributes to more reliable therapeutic quality control, supporting innovation, precision, and societal well-being across the pharmaceutical sector.

Pouya Taheri | Nanotechnology | Best Researcher Award

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Mr. Pouya Taheri | Nanotechnology | Best Researcher Award

University of Mazandaran | Iran

Pouya Taheri is an emerging researcher in nanomaterials, catalysis, and advanced chemical synthesis whose work focuses on the design, characterization, and application of metal–organic frameworks (MOFs), transition-metal nanocomposites, and functional hybrid materials for efficient and sustainable chemical transformations. His research contributions emphasize the development of catalytic systems that enhance selectivity, yield, and reaction efficiency, while supporting environmentally responsible approaches aligned with global trends in green chemistry. With 5 publications, 5 citations, and an h-index of 1 listed in Scopus, he has steadily contributed to the expanding scientific understanding of nanoscale catalytic mechanisms and engineered materials. His notable work, “Unveiling the synergistic interplay between Cu and Ni with ZIF-8 nanomaterials: a catalyst for the synthesis of triazole derivatives in nanoscale chemistry”, reflects his interest in synergistic metal interactions and structurally responsive nanocatalysts that offer improved performance across various synthetic processes. Taheri has collaborated with over 14 co-authors, demonstrating strong interdisciplinary engagement in synthetic chemistry, reaction engineering, nanostructure design, and applied catalysis. Such collaborations have strengthened the rigor and applicability of his scientific outputs, contributing to progress in pharmaceutical synthesis, fine chemical manufacturing, and eco-friendly catalytic solutions. His work holds societal relevance through its focus on greener synthesis pathways, scalable catalyst platforms, and advanced nanomaterials capable of addressing real-world industrial and environmental challenges. Taheri’s growing portfolio reflects a commitment to methodological precision, academic excellence, and impactful research that advances the broader field of materials chemistry. As he continues to develop innovative catalytic frameworks and contribute to interdisciplinary scientific efforts, he remains well positioned to play a meaningful role in shaping future directions in nanoscale materials science and sustainable chemical research.

Profiles : Google Scholar | Scopus | ORCID | LikedIn

Featured Publications

  1. Taheri, P., Molaei, P., Abazari, A., Tajbakhsh, M., & Yeganeh-Salman, E. (2025). Unveiling the synergistic interplay between Cu and Ni with ZIF-8 nanomaterials: A catalyst for the synthesis of triazole derivatives in nanoscale chemistry. Research on Chemical Intermediates, 1–27.

  2. Aghdami, R. M., Yeganeh-Salman, E., Taheri, P., Mighani, H., & Ghorbanian, M. (2025). Synthesis and characterization of high thermal resistance acetal-containing heterocyclic polyamides. Journal of Molecular Structure, 1321, 139801.

  3. Najafi, M., Alinezhad, H., Taheri, P., Yeganeh-Salman, E., & Ghasemi, S. (2024). Decorated Cu nanoparticles on ZPD as a novel and highly proficient nanocatalyst for synthesis of chromene and Biginelli reactions. Research on Chemical Intermediates, 50(3).
    Cited by: 6

  4. Taheri, P., Tajbakhsh, M., & Fallah, Z. (2024). Modified agro waste-derived nano-silica for synthesizing tetrahydrobenzo [b] pyrans. Catalysis Surveys from Asia, 28(2), 209–229.
    Cited by: 1

  5. Shojaei, R., Mighani, H., Yeganeh-Salman, E., Taheri, P., & Ghorbanian, M. (2024). Synthesis of the glycodendrimer macromolecule based on porphyrin as a targeted drug delivery system. International Journal of Polymeric Materials and Polymeric Biomaterials, 73(…).

Dr. Pouya Taheri’s research advances sustainable nanocatalysis and green chemistry, creating efficient catalytic systems that minimize environmental impact while enhancing reaction performance. His work bridges nanomaterials innovation with industrial applications, contributing to global progress in cleaner and smarter chemical manufacturing.

Nadeem Abbas | Nanotechnology | Editorial Board Member

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Dr. Nadeem Abbas | Nanotechnology | Editorial Board Member

Researcher | Prince Sultan University | Saudi Arabia

Dr. N. Abbas is a distinguished researcher recognized for his pioneering contributions to fluid mechanics, heat transfer, and nanofluid dynamics, with a strong focus on hybrid nanofluids, magnetohydrodynamics (MHD), nonlinear stretching surfaces, and microscale thermal phenomena. His research emphasizes the development of advanced mathematical and computational models to analyze complex flow behaviors relevant to modern engineering and biomedical systems. With an extensive publication record in leading international journals such as Chinese Journal of Physics, Computer Methods and Programs in Biomedicine, Results in Physics, and International Communications in Heat and Mass Transfer, Dr. Abbas has established himself as an influential figure in applied mathematics and thermofluid sciences. His most cited works on MHD hybrid nanofluid flow over nonlinear stretching cylinders, hybrid-based nanofluid flow over curved surfaces, and three-dimensional stagnation point flows have collectively garnered over 800 citations, reflecting his significant academic impact. Integrating analytical, numerical, and simulation-based approaches, Dr. Abbas’s research addresses key challenges in energy systems, materials processing, and biomedical fluid modeling, fostering international collaborations across the Middle East and Asia that advance the understanding of hybrid nanofluid applications for enhanced heat transfer and optimized fluid performance. His recent studies on nonlinear modeling of hybrid nanofluid flows over permeable and thermally slipping surfaces provide valuable insights into sustainable energy systems and industrial cooling processes. Through his innovative research and globally recognized publications, Dr. Abbas continues to contribute substantially to computational physics, applied mathematics, and mechanical engineering, driving progress in smart materials and nanofluid technologies with profound scientific and societal relevance.

Profiles : Google Schalor

Featured Publications

  1. Abbas, N., Nadeem, S., Saleem, A., Malik, M. Y., Issakhov, A., & Alharbi, F. M. (2021). Models base study of inclined MHD of hybrid nanofluid flow over nonlinear stretching cylinder. Chinese Journal of Physics, 69, 109–117.
    Cited by: 235

  2. Nadeem, S., Abbas, N., & Malik, M. Y. (2020). Inspection of hybrid based nanofluid flow over a curved surface. Computer Methods and Programs in Biomedicine, 189, 105193.
    Cited by: 228

  3. Nadeem, S., Abbas, N., & Khan, A. U. (2018). Characteristics of three-dimensional stagnation point flow of hybrid nanofluid past a circular cylinder. Results in Physics, 8, 829–835.
    Cited by: 155

  4. Abbas, N., Saleem, S., Nadeem, S., Alderremy, A. A., & Khan, A. U. (2018). On stagnation point flow of a micropolar nanofluid past a circular cylinder with velocity and thermal slip. Results in Physics, 9, 1224–1232.
    Cited by: 122

  5. Abbas, N., Rehman, K. U., Shatanawi, W., & Malik, M. Y. (2022). Numerical study of heat transfer in hybrid nanofluid flow over permeable nonlinear stretching curved surface with thermal slip. International Communications in Heat and Mass Transfer, 135, 106107.
    Cited by: 108

Dr. N. Abbas’s research on hybrid nanofluid dynamics and magnetohydrodynamics has significantly advanced the understanding of thermal and flow transport phenomena, enabling innovations in energy efficiency, biomedical engineering, and sustainable industrial processes. His work bridges fundamental science and practical application, fostering global progress in advanced materials and fluid technologies.

Marius Zaharia | Polymer Chemistry | Best Researcher Award

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Dr. Marius Zaharia | Polymer Chemistry | Best Researcher Award

Reseacher | Institute of Macromolecular Chemistry Petru Poni | Romania

A distinguished figure in polymer science and nanomaterials research, this scholar has made notable contributions to the development of advanced macromolecular systems for sustainable and biomedical applications. With over 43 peer-reviewed publications, 508 citations, and an h-index of 13, their research demonstrates a strong global impact and consistent academic excellence. The work focuses on the synthesis and functionalization of environmentally friendly and multifunctional polymeric materials, including thermoresponsive copolymers, nanocomposites, and hydrogel-based systems. Pioneering studies on Chitosan-graft-Poly(N-isopropylacrylamide) hybrid copolymers, alginate-based hydrogels, and green synthesis of metal nanoparticles have significantly advanced understanding in biocompatibility, controlled drug delivery, and tissue engineering. Collaborating extensively with over 100 researchers worldwide, this scientist has contributed to interdisciplinary efforts bridging chemistry, materials science, and biotechnology. Recent investigations into the in situ synthesis of gold nanoparticles mediated by thermoresponsive copolymers and the formation of nanocrystalline hydroxyapatite hydrogels for bone regeneration exemplify their innovative and application-driven research approach. Through a commitment to sustainable design, material innovation, and collaborative science, this researcher continues to influence the global landscape of macromolecular chemistry and contribute to advancements addressing environmental and healthcare challenges.

Profiles : Google Scholar | Scopus | ORCID | ResearchGate

Featured Publications

1. Bucatariu, F., Ghiorghita, C. A., Zaharia, M. M., Schwarz, S., Simon, F., & Mihai, M. (2020). Removal and separation of heavy metal ions from multicomponent simulated waters using silica/polyethyleneimine composite microparticles. ACS Applied Materials & Interfaces, 12(33), 37585–37596. [Cited by: 59]

2. Ghiorghita, C. A., Borchert, K. B. L., Vasiliu, A. L., Zaharia, M. M., Schwarz, D., & others. (2020). Porous thiourea-grafted-chitosan hydrogels: Synthesis and sorption of toxic metal ions from contaminated waters. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 607, 125504. [Cited by: 56]

3. Racovita, S., Trofin, M. A., Loghin, D. F., Zaharia, M. M., Bucatariu, F., Mihai, M., & others. (2021). Polybetaines in biomedical applications. International Journal of Molecular Sciences, 22(17), 9321. [Cited by: 53]

4. Roman, T., Pui, A., Lukacs, A. V., Cimpoesu, N., Lupescu, S., Borhan, A. I., & others. (2019). Structural changes of cerium doped copper ferrites during sintering process and magneto-electrical properties assessment. Ceramics International, 45(14), 17243–17251. [Cited by: 35]

5. Bucatariu, F., Schwarz, D., Zaharia, M., Steinbach, C., Ghiorghita, C. A., & others. (2020). Nanostructured polymer composites for selective heavy metal ion sorption. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 603, 125211. [Cited by: 33]

Dr. Marius Mihai Zaharia’s work contributes to global innovation by developing sustainable polymeric and nanocomposite materials that address critical challenges in environmental remediation and biomedical engineering. His research fosters advancements in eco-friendly technologies, promotes resource efficiency, and supports the transition toward a cleaner and more sustainable industrial future.

Ravindra Kumar | Organic Chemistry | Excellence in Research Award

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Dr. Ravindra Kumar | Organic Chemistry | Excellence in Research Award

Principal Scientist | CSIR-Central Drug Research Institute | India

Dr. Ravindra Kumar is a distinguished researcher whose scientific contributions have significantly advanced the fields of synthetic organic chemistry and medicinal chemistry. With 38 published documents, 673 citations, and an h-index of 14, his work demonstrates consistent research productivity, scientific rigor, and growing global impact. His research primarily focuses on the development of novel organic transformations, design of bioactive molecules, and mechanistic exploration of complex reactions that bridge fundamental chemistry with biomedical applications. Dr. Kumar has made notable advancements in areas such as chemo and regio-selective dual-functionalization of arenes, aromaticity modulation, and construction of multifunctional aromatic compounds through innovative dearomatization scission–aromatization strategies. His recent publications in highly reputed journals, including Chemical Communications and the European Journal of Medicinal Chemistry, highlight his pioneering efforts in creating 3,3-disubstituted oxindoles and quinoline carboxylic acid-based hybrids with promising anti-adipogenic and antidyslipidemic activities. Collaborating with over 78 co-authors across diverse research institutions, Dr. Kumar has fostered strong interdisciplinary partnerships that merge synthetic chemistry, catalysis, and pharmacological evaluation. His research is characterized by innovation and translational potential, contributing not only to the scientific community but also to the development of therapeutically relevant compounds addressing metabolic and lifestyle-related disorders. Through his sustained scholarly excellence and collaborative approach, Dr. Ravindra Kumar continues to contribute meaningfully to global efforts in drug discovery, molecular synthesis, and sustainable organic methodologies, reinforcing the vital role of chemical research in advancing health, innovation, and societal progress.

Profiles : Scopus | ORCID | ResearchGate | LinkedIn

Featured Publications

  1. Kumar, R., et al. (2025). Dearomatization–scission–aromatization of anilines: En route to synthesis of 3,3-disubstituted oxindoles with a wide range of heteroatom nucleophiles. Chemical Communications.

  2. Kumar, R., et al. (2025). Chemo- and regio-selective dual-functionalization of arenes: Synthesis of multi-functional aromatics via aromaticity destruction–reconstruction process. [Journal name not specified — likely a review journal]. Citations: 1

  3. Kumar, R., et al. (2025). Design, synthesis, and biological evaluation of novel quinoline carboxylic acid-based styryl/alkyne hybrid molecule as a potent anti-adipogenic and antidyslipidemic agent via activation of Wnt/β-catenin pathway. European Journal of Medicinal Chemistry.  Citations: 1

Dr. Ravindra Kumar’s research advances the frontiers of synthetic and medicinal chemistry through the design of novel organic molecules and innovative reaction mechanisms. His work fosters the development of therapeutically significant compounds, driving progress in drug discovery, sustainable synthesis, and global healthcare innovation.

 

Shraddha Yadav | Green Chemistry | Women Researcher Award

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Dr. Shraddha Yadav | Green Chemistry | Women Researcher Award

Postdoctoral Fellow |Indian Institute of Technology Bombay | India

Dr. Shraddha Yadav is a distinguished researcher known for her impactful work in environmental catalysis, electrochemical remediation, and sustainable materials engineering. With 21 publications, 263 citations, and an h-index of 8, her research demonstrates strong scientific productivity and interdisciplinary significance. Her recent studies, published in high-impact journals such as Chemical Engineering Journal and Electrochimica Acta, explore advanced nanostructured catalyst systems, including Fe₃C-infused hydrochar-based cathodes and MIL-53(Fe)-derived Fe₃O₄ MWCNT composites, for the efficient degradation of persistent organic pollutants. By integrating green chemistry, nanomaterial synthesis, and electrochemical process optimization, she contributes to developing sustainable wastewater treatment and pollution control technologies. Her comparative analyses of bio-electro-Fenton and bio-electro-peroxone systems provide key insights into improving catalytic efficiency and environmental compatibility. Through collaborations with more than 25 co-authors from diverse scientific backgrounds, she advances interdisciplinary approaches to address global environmental challenges. Collectively, her work supports the advancement of catalytic and electrochemical pathways for pollutant degradation, aligning with sustainable development goals on clean water, responsible production, and climate action while reinforcing the role of scientific innovation in promoting a cleaner, greener future.

Profiles : Google Scholar | Scopus | ORCID | ResearchGate | LinkedIn

Featured Publications

Farzaneh Bayat | Polymer Chemistry | Best Researcher Award

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Assoc. Prof. Dr. Farzaneh Bayat | Polymer Chemistry | Best Researcher Award

Associate Professor | Azarbaijan Shahid Madani University | Iran

Dr. Farzaneh Bayat is a distinguished researcher whose work has made significant contributions to materials chemistry and nanoscience, particularly in plasmonic nanomaterials, photocatalysis, and polymer-based nanocomposites. With 37 published documents, 248 citations, and an h-index of 10, her research record reflects consistent innovation and academic influence. Her recent studies emphasize the design and functionalization of nanostructured materials for applications in environmental remediation, sensing technologies, and energy-efficient catalysis. Notably, her 2025 publications in leading journals such as Microchemical Journal and Journal of Alloys and Compounds explore plasmonic core–shell nanoparticles and 2D semiconductor frameworks for enhanced photocatalytic and detection performance. Her investigations into polymer–nanocomposite systems and selenium-based optical materials reveal interdisciplinary expertise bridging chemistry, materials science, and nanotechnology. Dr. Bayat’s work stands out for its dual emphasis on fundamental understanding and practical solutions, addressing challenges in pollution control, sustainable materials, and nanostructure design. With collaborations involving over 70 co-authors globally, she actively promotes scientific exchange and multidisciplinary innovation. Through her pioneering contributions to plasmon-enhanced photocatalysis, hybrid nanocomposite engineering, and green nanotechnology, Dr. Bayat continues to advance material synthesis and characterization methods that support sustainability and technological progress. Her dedication to impactful research and innovation positions her as a recognized figure in functional materials and applied nanotechnology, shaping the future of global nanoscience

Profiles : Google Scholar | Scopus | ORCID | ResearchGate | LinkedIn

Dr. Farzaneh Bayat’s research bridges nanomaterials, photonics, and biosensing technologies, driving innovations in renewable energy, early disease detection, and environmental sustainability. Her work enhances global scientific understanding and fosters practical solutions that advance healthcare and clean energy industries.

Yasmina Khane | Nanotechnology | Best Researcher Award

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Assoc. Prof. Dr. Yasmina Khane | Nanotechnology | Best Researcher Award

Associate Professor | University of Ghardaia | Algeria

Dr. Yasmina Khane, affiliated with the Université de Ghardaia in Algeria, is an accomplished researcher whose work bridges the disciplines of materials chemistry, environmental science, and nanotechnology. Her research primarily explores the synthesis, characterization, and functional applications of nanostructured materials particularly metal and metal oxide nanoparticles in catalysis, environmental remediation, and sustainable energy systems.Dr. Khane’s investigations have made notable contributions to green nanotechnology, especially through the development of phyto-synthesized nanoparticles using plant extracts as eco-friendly reducing agents. Her recent study on silver nanoparticles synthesized via Cotula cinerea extract highlights her commitment to sustainable materials science. This work demonstrated the potential of bio-fabricated nanomaterials in enhancing salt tolerance in wheat (Triticum durum), emphasizing agricultural resilience and plant-environment interactions under stress conditions.A central theme in her research is photocatalysis the design and optimization of semiconductor-based catalysts for pollutant degradation and energy-related reactions. Dr. Khane has synthesized and investigated photocatalytic systems such as ZnO-impregnated biomaterials and Cu₂NiSnS₄ thin films, which have shown remarkable efficiency in degrading organic contaminants like dyes and pharmaceutical residues. Her publications in journals such as Scientific Reports, Inorganic Chemistry Communications, and Reaction Kinetics, Mechanisms and Catalysis reflect her depth in reaction kinetics, surface chemistry, and materials modification.With over 657 citations, 34 publications, and an h-index of 12, Dr. Khane has established herself as an influential figure in applied chemical research. Her interdisciplinary collaborations with over 150 co-authors underscore a strong international research network. She continually integrates chemistry, physics, and biology to advance eco-conscious technologies for water purification, soil protection, and renewable energy conversion.Overall, Dr. Khane’s scientific portfolio demonstrates a commitment to environmental sustainability through the innovative use of nanostructured catalysts and green synthesis methods. Her work contributes meaningfully to the global pursuit of cleaner technologies, reflecting the synergy between nanoscience, catalysis, and environmental protection.

Profiles : Google Scholar | Scopus | ORCID | ResearchGate | LinkedIn

Featured Publications

  1. Fenniche, F., Khane, Y., Hafsi, Z., Farhat, M., Aouf, D., & Alarbi, F. (2025). Photo catalytic degradation of Coomassie Brilliant Blue using a ternary Polyaniline/Fe₂O₃/Graphene nanocomposite under visible light. Sebha University Conference Proceedings, 103–109.

  2. Daoud, M., Khane, Y., Aouf, D., Benturki, O., Girods, P., Rogaume, Y., & Fontana, S. (2025). Efficient removal of malachite green using modified Algerian date palm spikelet: Characterization, design of experiment (Box–Behnken), density functional theory analysis. Reaction Kinetics, Mechanisms and Catalysis, 1–27.

  3. Kesbi, B., Salhi, N., Khane, Y., Albukhaty, S., Addad, A., Abideen, Z., Alsufyani, H., … (2025). Potential effect of phyto-synthesized silver nanoparticles using Cotula cinerea Del raw extract on salt tolerance of wheat seeds (Triticum durum desf., Boussellam variety). Scientific Reports, 15(1), 28061. Citations: 1

  4. Farhat, M., Al Madani, M. A., Abdullah, T., Embaya, M., Saeed, A., Saleh, A., … (2025). Evaluation of the physical properties of local wheat husk ash and its effects on the compressive strength of hardened cement paste. Discover Chemistry, 2(1), 89.

  5. Nezzari, A., Medina, S., Khane, Y., Boublenza, H., Guezzoul, M., Zoukel, A., … (2025). Synthesis, properties, and photocatalytic degradation of Brilliant Green dye using Cu₂NiSnS₄ thin films under ultraviolet irradiation. Inorganic Chemistry Communications, 174, 114021. Citations: 3

Dr. Yasmina Khane’s research advances sustainable nanotechnology through eco-friendly materials and photocatalysis, offering innovative solutions for environmental purification, agricultural resilience, and renewable energy. Her work bridges science and society, driving global progress toward a cleaner and greener future.

Shuang Guo | Spectroscopy | Best Researcher Award |

Published on by Chemical Scientist

Dr.Shuang Guo | Spectroscopy | Best Researcher Award |

Nanyang Institute of Technology | China

Dr. Shuang Guo is a dedicated materials scientist affiliated with the Nanyang Institute of Technology, Nanyang, China. With a growing international research presence, Dr. Guo has contributed significantly to the fields of chalcogenide phase-change materials, optical spectroscopy, and luminescent functional materials. His research primarily focuses on the structural, electronic, and photonic properties of advanced materials for next-generation data storage, energy conversion, and optoelectronic applications.Throughout his academic career, Dr. Guo has authored 28 scientific publications, which have collectively garnered over 509 citations, reflecting his active engagement and influence within the materials science community. His h-index of 11 underscores the sustained relevance and academic impact of his research contributions. Recent works, such as “Raman scattering spectroscopy study on chalcogenide phase-change materials” and “Insight into Cr³⁺-activated NIR phosphor with extremely high thermal stability for NIR LEDs” (2025), highlight his innovative approach to understanding phase transitions and optimizing photoluminescent behavior in complex material systems.Dr. Guo’s collaborative spirit is evident from his work with over 70 co-authors across interdisciplinary domains including physics, chemistry, and engineering. His studies bridge fundamental science with technological applications, offering insights crucial to the development of energy-efficient lighting, high-density data storage, and thermally stable luminescent devices. Beyond publications, his research contributes to advancing sustainable technologies and enhancing material performance under extreme conditions—key to progress in the semiconductor and optoelectronics industries. With a strong foundation in spectroscopic analysis and solid-state chemistry, Dr. Guo continues to drive scientific innovation through rigorous experimentation and collaborative inquiry, strengthening global research connections in the rapidly evolving landscape of materials science.

Profiles : Scopus | ORCID

Featured Publications

1. Guo, S., Wang, Y., Zhang, J., Wu, L., & Song, Z. (2025). Raman scattering spectroscopy study on chalcogenide phase-change materials. Materials Science & Engineering: B, 322, Article 118649.

2. Wang, Y., Liu, S., Guo, S., Zhou, J., … (2025). Insight into Cr³⁺-activated NIR phosphor with extremely high thermal stability for NIR LEDs. Journal of Alloys and Compounds. Cited by 4.

Dr. Shuang Guo’s research advances the understanding of phase-change and luminescent materials, driving innovations in energy-efficient lighting, high-density data storage, and next-generation optoelectronic devices. His work bridges fundamental spectroscopy and applied materials engineering, fostering scientific progress and technological sustainability on a global scale.