Wenlong Cai | Electrochemistry | Best Researcher Award

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Assist. Prof. Dr. Wenlong Cai | Electrochemistry | Best Researcher Award

Associate Professor at Sichuan University, China

Wenlong Cai is an accomplished Associate Professor at Sichuan University, specializing in Materials Science and Engineering. 🎓 He has pursued extensive research on next-generation energy storage technologies, focusing on lithium-ion, sodium-ion, and zinc-ion batteries 🔋. With a Ph.D. from the University of Science and Technology of China and postdoctoral work at Tsinghua University, Wenlong has earned recognition as a Double Hundred Talents Distinguished Expert 🏅. His innovative work aims to enhance battery performance across various environments, supporting sustainable energy solutions 🌱. Wenlong continues to lead cutting-edge research projects, shaping the future of material innovation and electrochemical science 🚀.

Publication Profile

Google Scholar

Academic Background

Wenlong Cai completed his Bachelor’s degree at Sichuan University in Light Chemical Engineering 🎯, then earned a Master’s in Chemical Engineering at Zhejiang University 🧪. He pursued his Ph.D. in Materials Physics and Chemistry at the University of Science and Technology of China 🥼, supported by a National Scholarship and working under Academician Yitai Qian 🏆. He then completed postdoctoral research at Tsinghua University in Chemical Engineering, co-advised by Distinguished Young Scholar Qiang Zhang 🔬. Throughout his academic journey, Wenlong consistently achieved top honors and scholarships, laying a strong foundation for his research career 📚.

Professional Background

Since 2021, Wenlong Cai has served as an Associate Professor at Sichuan University, focusing on materials science and fast-charging battery technology 🔋. From 2019 to 2021, he completed his prestigious Shuimu Scholar postdoctoral fellowship at Tsinghua University 🌟. During his Ph.D. from 2016 to 2019 at USTC, he specialized in material physics and chemistry 🔍. His early academic training includes a Master’s degree from Zhejiang University and a Bachelor’s degree from Sichuan University 🎓. Wenlong’s career highlights his steady rise through China’s top research institutions, marked by impactful research projects and growing academic influence 🚀.

Awards and Honors

Wenlong Cai has received numerous prestigious awards throughout his academic career 🏅. He was selected as a Double Hundred Talents Distinguished Expert by Sichuan Province 🌟. He earned the National Scholarship during both his Master’s and Ph.D. studies 🧠, along with School-level and Provincial-level Outstanding Graduate Awards 🥇. As a postdoctoral fellow, he was honored as a Shuimu Scholar at Tsinghua University 🏫. Earlier in his undergraduate years, he received Prize Scholarships three times for academic excellence 🎖️. These recognitions reflect his consistent excellence, innovation, and leadership potential in advanced material science research 🔬.

Research Focus

Wenlong Cai’s research focuses on the development of advanced anode materials like graphite, Si/C, and hard carbon for fast-charging lithium-ion batteries 🔋. He studies how solvation structures affect battery electrochemical performance across wide temperature and voltage ranges 🌡️⚡. His work includes designing carbon hosts and catalytic substrates for high-energy lithium-sulfur batteries 🧪. He specializes in advanced characterization techniques to reveal electrochemical mechanisms in Li, Na, and Zn-based secondary batteries 🔍. Through his innovative projects, he aims to revolutionize energy storage systems for improved efficiency, reliability, and environmental adaptability 🌎🚀.

Publication Top Notes

Regulating interfacial chemistry in lithium‐ion batteries by a weakly solvating electrolyte 📚
Year: 2021 📅 | Cited by: 592 📈

A review on energy chemistry of fast-charging anodes
Year: 2020 📅 | Cited by: 493 📈

Rationalizing electrocatalysis of Li–S chemistry by mediator design: progress and prospects 🔋
Year: 2020 📅 | Cited by: 408 📈

Inhibiting solvent co‐intercalation in a graphite anode by a localized high‐concentration electrolyte in fast‐charging batteries 🔥
Year: 2021 📅 | Cited by: 350 📈

Conclusion

In conclusion, Wenlong Cai is a highly promising candidate for the Research for Best Researcher Award, particularly suited for early-to-mid career recognition or national-level honors. With a Ph.D. from the University of Science and Technology of China, prestigious postdoctoral research at Tsinghua University as a Shuimu Scholar, and his current role as Associate Professor and Double Hundred Talents Distinguished Expert at Sichuan University, he has demonstrated strong academic excellence and research leadership. His work in advanced energy storage systems, including lithium-ion, sodium-ion, and zinc-ion batteries, addresses critical challenges in fast charging and low-temperature performance. Actively leading nationally funded research projects and producing highly cited publications, Wenlong Cai exemplifies innovation, dedication, and impactful contributions to the field of materials science and electrochemistry. For highly competitive international awards, additional global visibility through ultra-high-impact publications or major global recognitions could further strengthen his candidacy.

 

 

Jyoti Sharma | Metallo Organic Chemistry | Best Researcher Award

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Prof. Jyoti Sharma | Metallo Organic Chemistry | Best Researcher Award

Prof. Jyoti Sharma, University of Rajasthan, Jaipur, India

Prof. Jyoti Sharma is a distinguished Professor of Chemistry at the University of Rajasthan, Jaipur. With over two decades of experience in teaching and research, she specializes in Synthetic Inorganic and Organometallic Chemistry. She has published 42 research papers and guided 8 Ph.D. scholars. Prof. Sharma has led two UGC-funded projects and contributed significantly to academic development through her involvement in refresher courses, BOS, and university committees. A committed educator and researcher, she is an active member of several prestigious societies including CRSI, ISCB, and ISCA. Her academic journey reflects dedication, innovation, and excellence in the field of chemistry. 🧪📘

Publication Profile

Google Scholar

🎓 Education

Prof. Jyoti Sharma completed her M.Sc. and Ph.D. in Chemistry from the University of Rajasthan, Jaipur. Her academic training was further enriched through a two-year postdoctoral fellowship as a Research Associate at the same university from 1997 to 2000. With a strong foundation in chemical sciences, her advanced studies focused on inorganic and organometallic compounds, setting the stage for her specialized research work. Throughout her academic life, she has maintained a keen interest in interdisciplinary approaches involving coordination chemistry and ligand interaction studies, forming the core of her academic and scientific expertise. 🎓🧫

📚 Experience

Prof. Sharma boasts 24 years of research and teaching experience in Chemistry, with 2 additional years of postdoctoral work. She has taught undergraduate students for over two decades and postgraduate students for 2 years. She has guided 8 Ph.D. students and currently supervises 2 more. Apart from teaching, she has held several administrative roles, including serving as Proctor and Convener for PG Admissions. She is actively engaged in academic governance as a member and Convenor of the Board of Studies in Chemistry. Her experience reflects a deep engagement in both academic and administrative aspects of higher education. 👩‍🏫🧪

🏅 Awards and Honors

Though no formal awards are currently listed, Prof. Jyoti Sharma’s professional journey is marked by academic recognitions and leadership roles. She has been elected as a Board of Studies member (2021-22) and currently serves as its Convenor. She has also organized and attended several refresher and orientation courses and served as Deputy Coordinator. Her selection for these roles demonstrates institutional trust in her academic leadership. Additionally, she has served as a proctor and contributed to multiple university committees, reflecting her strong commitment to academic service and university administration. 🏆📖

🔬 Research Focus

Prof. Sharma’s research primarily focuses on Synthetic Inorganic and Organometallic Chemistry, emphasizing the synthesis, spectral characterization, and bioactivity of metal complexes involving antimony, arsenic, and bismuth. Her work involves mixed valency derivatives and studies of compounds with oxygen, nitrogen, and sulfur ligands. She has completed two UGC-funded research projects and has over 40 peer-reviewed publications. Her scientific contributions aim to explore the chemical behavior and potential applications of metallorganic compounds, especially in bioinorganic systems. Her work stands out for its structural and functional insights into coordination chemistry. 🧪🧬

Publication Top Notes

📘 Kangaroo mother care vs conventional care for LBW babies – SM Ali, J Sharma, R Sharma, S Alam | Cited by 95 | 🗓️ 2009 👶💖
🔬 Boron compounds of semicarbazones: antimicrobial & nanosized B₂O₃ – J Bhomia, J Sharma, RA Sharma, Y Singh | Cited by 16 | 🗓️ 2018 🧪🦠
⚗️ Triorganotin(IV) & Schiff bases: synthesis & antimicrobial study – P Bhatra, J Sharma, RA Sharma, Y Singh | Cited by 16 | 🗓️ 2017 🔬⚛️
🧬 Metal-induced benzothiazoline ring rearrangement with organoantimony(V) – D Shanker, RK Sharma, J Sharma, et al. | Cited by 12 | 🗓️ 2007 🔁⚗️
🧪 Antimony(III) heteroleptic derivatives: synthesis & antibacterial activity – S Beniwal, A Kumar, J Sharma, et al. | Cited by 9 | 🗓️ 2019 💊🔍
🧫 Triphenylarsenic(V)/antimony(V) & Schiff bases: antimicrobial – R Agrawal, J Sharma, et al. | Cited by 9 | 🗓️ 2011 ⚗️🧪
📐 Triphenylantimony(V) heteroleptics: XRD, antibacterial & antioxidant – S Beniwal, A Kumar, J Sharma, et al. | Cited by 7 | 🗓️ 2019 🧪📊
🧪 Monophenylantimony(III) & dithiocarbamates: synthesis & antimicrobial – DK Sharma, Y Singh, J Sharma | Cited by 7 | 🗓️ 2013 🧫🔬
👶 Serum ferritin as sepsis marker in pediatric patients – J Sharma, R Sharma | Cited by 6 | 🗓️ 2018 🩸📈
🧬 Organoboron semicarbazones: synthesis, antimicrobial & antifertility – RASYS Jyoti Bhomia, J Sharma, et al. | Cited by 6 | 🗓️ 2018 🧪👩‍🔬
🧪 Heteroleptic boron Schiff base derivatives: synthesis & antimicrobial – V Jangir, J Sharma, et al. | Cited by 6 | 🗓️ 2016 ⚗️🧫
🔬 Mixed Chloro Bis [Dithiophosphato] Antimony(III) & boron derivatives – R Agrawal, J Sharma, et al. | Cited by 6 | 🗓️ 2010 ⚛️🔍

Xuefeng Song | Photocatalysis | Best Researcher Award

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Prof. Dr. Xuefeng Song | Photocatalysis | Best Researcher Award

Prof. Dr. Xuefeng Song, Shanghai Jiao Tong University, China

Prof. Dr. Xuefeng Song is a distinguished materials scientist specializing in functional micro/nanostructures, nanocomposites, and energy applications. He earned his Ph.D. in Materials Science from the Shanghai Institute of Ceramics, Chinese Academy of Sciences, in 2009. He further advanced his research as a Postdoctoral Fellow at the University of Cologne, Germany (2009-2012). Since 2012, he has been a key faculty member at Shanghai Jiao Tong University, leading groundbreaking research in photocatalysis, energy storage, and protective coatings. With over 100 publications in top-tier journals, 4,300+ citations, and 32 invention patents, his contributions to materials science are globally recognized. He has led over 20 major research projects, funded by prestigious institutions like the National Natural Science Foundation of China and the BMBF Fellowship in Germany. His numerous accolades, including the VinFuture Prize nomination and IAAM Fellowship, highlight his impact in the field.

Publication Profile

Google Scholar

Education 🎓📚

Prof. Dr. Xuefeng Song pursued his Ph.D. in Materials Science at the Shanghai Institute of Ceramics, Chinese Academy of Sciences, in 2009, focusing on the controlled synthesis of functional micro/nanostructures. He further enriched his academic expertise through a postdoctoral fellowship at the Institute of Inorganic Chemistry, University of Cologne, Germany, from 2009 to 2012, where he worked on innovative nanocomposite systems. Since 2012, he has been a faculty member at Shanghai Jiao Tong University, contributing to advanced research in energy materials and protective coatings. His academic journey is marked by extensive interdisciplinary research, blending chemistry, physics, and engineering to pioneer new material technologies. He has also contributed to three English-language academic monographs, enhancing global knowledge dissemination. His education provided a solid foundation for his pioneering work in photocatalysis, energy conversion, and nanostructured materials, positioning him as a leading scientist in materials research.

Experience 🏆🔬

Prof. Dr. Xuefeng Song has over a decade of research experience in materials science, focusing on nanostructured materials and energy applications. As a Principal Investigator, he has led over 20 major research projects, including those funded by the National Natural Science Foundation of China, the Shanghai Natural Science Foundation, and the HY Program of the Equipment Development Department. His expertise spans from laboratory research to industrial applications, particularly in photocatalysis, energy storage, and protective coatings. His work has led to significant advancements in sustainable energy solutions and advanced coatings. He has authored over 100 high-impact publications, earning 4,300+ citations, and filed 32 invention patents, with 28 already granted. His leadership in research has positioned him as an influential figure in nanomaterials and their applications in energy-efficient and environmentally friendly technologies, bridging the gap between scientific discovery and real-world innovation.

Awards & Honors 🏅🎖️

Prof. Dr. Xuefeng Song’s contributions to materials science have earned him numerous prestigious honors. He is a VinFuture Prize nominator, recognizing his influence in cutting-edge research. He has been awarded Fellowship of the International Association of Advanced Materials (IAAM) for his impact on materials innovation. As a Science Ambassador for Bentham Science Publishers, he actively promotes scientific advancements. He has also received the SMC-Chenxing Young Scholar Award, recognizing his outstanding early-career achievements. His research excellence has been acknowledged through prestigious talent programs, including the Longcheng Talent Program (Changzhou) and the Class B Scholar of the Ming Shi Zhi Xiang Program (Shaoxing). His global recognition, spanning academia and industry, underscores his exceptional contributions to nanomaterials, energy storage, and advanced coatings, making him a leading scientist in his field.

Research Focus 🔬⚡

Prof. Dr. Xuefeng Song’s research is centered on controlled synthesis of functional micro/nanostructures, the construction of nanocomposite systems, and their applications in photocatalysis, energy storage, and protective coatings. His work in photocatalysis focuses on developing advanced materials for efficient light-driven chemical reactions, crucial for environmental sustainability. His contributions to energy storage and conversion include innovations in battery and supercapacitor technologies, enhancing energy efficiency and performance. His research on protective coatings aims to develop high-performance, durable coatings for industrial applications. His interdisciplinary approach integrates chemistry, nanotechnology, and engineering to create next-generation materials for energy and environmental applications. His research has had a significant impact, with over 100 publications in top-tier journals, 4,300+ citations, and 32 patents, reinforcing his position as a leader in the field of advanced materials science. 🚀

Publication Top Notes

📄 Facile synthesis and hierarchical assembly of hollow nickel oxide architectures bearing enhanced photocatalytic properties | 🔗 X Song, L Gao | 🏛️ The Journal of Physical Chemistry C | 📅 2008 | 🔍 Cited by: 232

📄 Self‐Assembled α‐Fe₂O₃ Mesocrystals/Graphene Nanohybrid for Enhanced Electrochemical Capacitors | 🔗 S Yang, X Song, P Zhang, J Sun, L Gao | 🏛️ Small | 📅 2014 | 🔍 Cited by: 209

📄 Facile Synthesis of Nitrogen-Doped Graphene–Ultrathin MnO₂ Sheet Composites and Their Electrochemical Performances | 🔗 S Yang, X Song, P Zhang, L Gao | 🏛️ ACS Applied Materials & Interfaces | 📅 2013 | 🔍 Cited by: 177

📄 Mapping the surface adsorption forces of nanomaterials in biological systems | 🔗 XR Xia, NA Monteiro-Riviere, S Mathur, X Song, L Xiao, SJ Oldenberg, … | 🏛️ ACS Nano | 📅 2011 | 🔍 Cited by: 160

📄 Fabrication of hollow hybrid microspheres coated with silica/titania via sol–gel process and enhanced photocatalytic activities | 🔗 X Song, L Gao | 🏛️ The Journal of Physical Chemistry C | 📅 2007 | 🔍 Cited by: 156

📄 Covalently Coupled Ultrafine H-TiO₂ Nanocrystals/Nitrogen-Doped Graphene Hybrid Materials for High-Performance Supercapacitor | 🔗 S Yang, Y Lin, X Song, P Zhang, L Gao | 🏛️ ACS Applied Materials & Interfaces | 📅 2015 | 🔍 Cited by: 143

📄 Synthesis, characterization, and gas sensing properties of porous nickel oxide nanotubes | 🔗 X Song, L Gao, S Mathur | 🏛️ The Journal of Physical Chemistry C | 📅 2011 | 🔍 Cited by: 120

📄 Facile synthesis of polycrystalline NiO nanorods assisted by microwave heating | 🔗 X Song, L Gao | 🏛️ Journal of the American Ceramic Society | 📅 2008 | 🔍 Cited by: 116

📄 Synthesis, characterization, and optical properties of well-defined N-doped, hollow silica/titania hybrid microspheres | 🔗 X Song, L Gao | 🏛️ Langmuir | 📅 2007 | 🔍 Cited by: 116

📄 Active Fe₂O₃ nanoparticles encapsulated in porous g-C₃N₄/graphene sandwich-type nanosheets as a superior anode for high-performance lithium-ion batteries | 🔗 M Shi, T Wu, X Song, J Liu, L Zhao, P Zhang, L Gao | 🏛️ Journal of Materials Chemistry A | 📅 2016 | 🔍 Cited by: 106

📄 Heating-Rate-Induced Porous α-Fe₂O₃ with Controllable Pore Size and Crystallinity Grown on Graphene for Supercapacitors | 🔗 S Yang, X Song, P Zhang, L Gao | 🏛️ ACS Applied Materials & Interfaces | 📅 2015 | 🔍 Cited by: 104

📄 Phyllosilicate evolved hierarchical Ni-and Cu–Ni/SiO₂ nanocomposites for methane dry reforming catalysis | 🔗 T Wu, Q Zhang, W Cai, P Zhang, X Song, Z Sun, L Gao | 🏛️ Applied Catalysis A: General | 📅 2015 | 🔍 Cited by: 94

📄 ZnFe₂O₄ nanoparticles-cotton derived hierarchical porous active carbon fibers for high rate-capability supercapacitor electrodes | 🔗 S Yang, Z Han, F Zheng, J Sun, Z Qiao, X Yang, L Li, C Li, X Song, B Cao | 🏛️ Carbon | 📅 2018 | 🔍 Cited by: 90

📄 Surfactant-free hydrothermal synthesis of Cu₂ZnSnS₄ (CZTS) nanocrystals with photocatalytic properties | 🔗 J Wang, P Zhang, X Song, L Gao | 🏛️ RSC Advances | 📅 2014 | 🔍 Cited by: 89

📄 Crumpled nitrogen-doped graphene–ultrafine Mn₃O₄ nanohybrids and their application in supercapacitors | 🔗 S Yang, X Song, P Zhang, L Gao | 🏛️ Journal of Materials Chemistry A | 📅 2013 | 🔍 Cited by: 86

📄 Attapulgite modulated thorny nickel nanowires/graphene aerogel with excellent electromagnetic wave absorption performance | 🔗 F Sun, Q Liu, Y Xu, X Xin, Z Wang, X Song, X Zhao, J Xu, J Liu, L Zhao, … | 🏛️ Chemical Engineering Journal | 📅 2021 | 🔍 Cited by: 83

Conclusion

Prof. Dr. Xuefeng Song stands out as a highly accomplished researcher with a strong publication record, leadership in major projects, and a significant impact in materials science. His contributions to nanostructures, energy storage, and protective coatings, along with his extensive patent portfolio and global recognitions, make him a strong candidate for the Best Researcher Award. 🚀

Davit Davtyan | Catalyst | Best Researcher Award

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Dr. Davit Davtyan | Catalyst | Best Researcher Award

Dr. Davit Davtyan, Institute of Chemical Physics named after A.B. Nalbandyan NAS RA, Armenia

Dr. Davit Davtyan is an accomplished researcher and educator in the field of chemical sciences, specializing in catalysis, materials synthesis, and chemical analysis. He holds a Bachelor’s and Master’s degree in Chemistry from Yerevan State University, Armenia, and earned his Candidate of Chemical Sciences title from the Institute of Chemical Physics after A.B. Nalbandyan NAS RA in 2021. With extensive training in advanced analytical techniques across Italy, Estonia, and Finland, Dr. Davtyan is currently the Head of the Laboratory of Catalysis at the Institute of Chemical Physics, Yerevan. His research interests include the synthesis of nanopowders, catalytic processes, and the application of microwave-assisted methods in materials chemistry. He has authored several publications in prestigious journals such as Ceramics International and Chemical Engineering Journal. 🧪🔬

Publication Profile

Orcid

Education & Training 🎓

Dr. Davit Davtyan, born on September 7, 1987, is an Armenian scientist with extensive training in chemistry and analytical sciences. He earned his Bachelor’s and Master’s degrees with honors in Applied Chemistry and Chemistry from Yerevan State University. Dr. Davtyan obtained his Candidate of Chemical Sciences degree from the Institute of Chemical Physics, NAS RA, in 2021. He has completed various specialized training courses, including MS-TOF and LC-MS Method Validation in Italy, Germany, Estonia, and Finland. His expertise extends to analytical instruments such as HPLC, UHPLC, GC, and elemental analyzers. Dr. Davtyan’s contact details are provided for further inquiries. 📚🔬

Work Experience 💼

Dr. Davit Davtyan has an extensive career in the field of chemical physics and catalysis. He is currently the Head and Acting Head of the Laboratory of Catalysis at the Institute of Chemical Physics after A.B. Nalbandyan, where he has been a researcher since 2021. Previously, he held the position of Junior Researcher at the same institution from 2016 to 2021. Dr. Davtyan also led the Medical Devices Registration Department at the Scientific Center of Drug and Medical Technology Expertise (2018–2021). His earlier roles include technical management and senior analysis in various research centers. Dr. Davtyan served as a Senior Sergeant and expert in chemical weapons defense in the RA Armed Forces. 🔬🧪

Research Focus 🔬🧪

Dr. Davit Davtyan’s research primarily focuses on the synthesis and catalytic applications of advanced materials, particularly carbides and nanopowders. His work includes the development of microwave-assisted synthesis techniques for producing various carbide-based catalysts like molybdenum and tungsten carbides, and their use in hydrogenation, desulfurization, and other catalytic reactions. He also explores the properties of rare-earth hexaborides, boron monophosphide, and rhenium diboride nanopowders for industrial applications. His contributions extend to enhancing the efficiency of catalytic processes, especially in fuel and environmental technologies. Dr. Davtyan’s expertise includes material characterization, catalyst design, and sustainable chemical processes. ⚗️🌍

Publication Top Notes

  • Microwave-Assisted Synthesis and Catalytic Activity of Nano-Sized Molybdenum Carbide in Naphthalene Hydrogenation – DOI: 10.2139/ssrn.4930994, 2024 | 🔬📈
  • Rapid Microwave-Assisted Synthesis of Rare-Earth Hexaborides Powders – DOI: 10.1177/17436753241302225, 2024 | ⚡💥
  • Catalytic Aerobic Desulfurization of Fuels in the Presence of Nanosized Mixed Carbide FeWC – DOI: 10.1016/j.cej.2023.142641, 2023 | 🔬💡
  • Microwave-Assisted Synthesis of Boron Monophosphide Nanopowder – DOI: 10.1016/j.ceramint.2022.10.330, 2023 | 🔄✨
  • Catalysts Based on Molybdenum Carbide Modified with Nickel and Alumina in Hydrogenation of Hydrocarbons and Hydrodesulfurization – DOI: 10.1134/s0040579522040042, 2022 | ⚙️🛢️
  • New Type of Catalyst for Efficient Aerobic Oxidative Desulfurization Based On Tungsten Carbide Synthesized by the Microwave Method – DOI: 10.1021/acsomega.1c06969, 2022 | 🔬🌿
  • Superhard B4C-ReB2 Composite by SPS of Microwave Synthesized Nanopowders – DOI: 10.1016/j.matlet.2020.129163, 2021 | 💪⚡
  • Hydrogenation of Alkenes on Molybdenum and Tungsten Carbides – DOI: 10.1134/s0040579520050036, 2020 | 🔬🔋
  • Microwave Synthesis of B4C Nanopowder for Subsequent Spark Plasma Sintering – DOI: 10.1016/j.jmrt.2019.09.052, 2019 | ⚡🧪
  • Microwave-Assisted Preparation and Characterization of Nanoscale Rhenium Diboride – DOI: 10.1016/j.ceramint.2018.08.359, 2018 | 🔬⚙️
  • Direct Reduction of Ammonium Molybdate to Elemental Molybdenum by Combustion Reaction – DOI: 10.1016/j.cej.2011.01.080, 2011 | 🔥🧪
  • Reduction of MoO3 by Zn: Reducer Migration Phenomena – DOI: 10.1016/j.ijrmhm.2010.05.005, 2010 | 🔄⚙️