Hamid Ali | Energy based materials | Best Researcher Award

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Dr. Hamid Ali | Energy based materials | Best Researcher Award

Postdoctoral Researcher at Shenzhen Institute of Information Technology, China

Dr. Hamid Ali is a distinguished materials scientist specializing in Material Science and Engineering with expertise in high-temperature superalloys, high-entropy alloys, heterogeneous catalysis, and advanced nanomaterials. Currently based in Shenzhen, China, he has contributed extensively to materials characterization, computational modeling, and experimental synthesis. His research integrates density functional theory (DFT), first-principles calculations, and catalyst synthesis for developing energy-efficient materials. Dr. Ali has a strong publication record, reflecting his commitment to advancing materials science for real-world applications. πŸ“šπŸ”¬

Publication Profile

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Education πŸŽ“

Dr. Ali earned his Ph.D. in Material Science and Engineering, focusing on the fine crystal structure, phase transitions, thermodynamic properties, and site preferences of atoms in high-temperature alloys. His doctoral work also covered heterogeneous catalysis, surface adsorption, and electrocatalysis using g-C₃Nβ‚„, MXene frameworks, MOFs, and CMPs. Proficient in XRD, SEM, TEM, FTIR, and thermal analysis, he has leveraged computational tools like MATLAB, VESTA, Materials Studio, VASP, and PHONOPY for material simulations. His academic background combines theoretical modeling and experimental synthesis, equipping him with a robust foundation in advanced materials. πŸ“–βš›οΈ

Experience 🏭

Dr. Ali has extensive experience in materials research, focusing on computational and experimental approaches to material synthesis, catalysis, and characterization. His work involves DFT-based modeling, first-principles calculations, and theoretical simulations for understanding mechanical, elastic, and thermodynamic properties of advanced materials. With expertise in catalyst development, photocatalytic Hβ‚‚ evolution, COβ‚‚ reduction, and electrocatalysis, he has successfully designed and managed research projects, collaborating with interdisciplinary teams. His ability to bridge theoretical and experimental materials science makes him a valuable asset in innovative material design and energy research. βš™οΈπŸ”

Awards & Honors πŸ†

Dr. Ali has been recognized for his significant contributions to material science, earning accolades for his high-impact research, innovative methodologies, and pioneering work in advanced materials. He has received awards for excellence in computational modeling, catalyst design, and interdisciplinary research. His outstanding publications and conference presentations have been acknowledged at international platforms, reinforcing his status as a leading researcher in materials engineering. His contributions to DFT-based simulations, first-principles calculations, and photocatalysis research have been instrumental in shaping advancements in sustainable materials. πŸŽ–οΈπŸ“œ

Research Focus πŸ”¬

Dr. Ali’s research spans high-entropy alloys, heterogeneous catalysis, nanomaterials, and computational materials science. His focus includes phase transitions, atomic site preferences, and thermodynamic properties of advanced materials, utilizing DFT, ab initio methods, and computational modeling. His expertise extends to photocatalysis, electrocatalysis, and COβ‚‚ reduction, where he explores MXenes, MOFs, COFs, and CMPs for clean energy applications. His interdisciplinary work integrates material synthesis, adsorption studies, and theoretical calculations, aiming to develop next-generation materials for sustainable energy and catalysis. πŸš€πŸ’‘

 

Publication Top Notes

πŸ“– A review on the synthesis, properties, and characterizations of graphitic carbon nitride (g-C₃Nβ‚„) for energy conversion and storage applications | πŸ† Cited by: 110 | πŸ“… Year: 2023

πŸ“– Recent advances in ground-breaking conjugated microporous polymers-based materials, their synthesis, modification and potential applications | πŸ† Cited by: 93 | πŸ“… Year: 2023

πŸ“– Recent advances, properties, fabrication and opportunities in two-dimensional materials for their potential sustainable applications | πŸ† Cited by: 72 | πŸ“… Year: 2023

πŸ“– Nanostructured materials based on g-C₃Nβ‚„ for enhanced photocatalytic activity and potential applications: A review | πŸ† Cited by: 63 | πŸ“… Year: 2022

πŸ“– Recent advances and future perspectives of metal-based electrocatalysts for overall electrochemical water splitting | πŸ† Cited by: 59 | πŸ“… Year: 2023

πŸ“– Efficiency of a novel nitrogen-doped Fe₃Oβ‚„ impregnated biochar (N/Fe₃Oβ‚„@BC) for arsenic (III and V) removal from aqueous solution | πŸ† Cited by: 52 | πŸ“… Year: 2022

πŸ“– Current progresses in two-dimensional MXene-based framework: Prospects from superficial synthesis to energy conversion and storage applications | πŸ† Cited by: 51 | πŸ“… Year: 2023

πŸ“– Different dimensionalities, morphological advancements and engineering of g‐C₃N₄‐based nanomaterials for energy conversion and storage | πŸ† Cited by: 49 | πŸ“… Year: 2023

πŸ“– Molecular engineering optimized carbon nitride photocatalyst for COβ‚‚ reduction to solar fuels | πŸ† Cited by: 43 | πŸ“… Year: 2022

πŸ“– Synergetic effect of bismuth vanadate over copolymerized carbon nitride composites for highly efficient photocatalytic Hβ‚‚ and Oβ‚‚ generation | πŸ† Cited by: 37 | πŸ“… Year: 2022

πŸ“– Developing new-generation covalent organic frameworks as sustainable catalysts: Synthesis, properties, types and solar energy production | πŸ† Cited by: 31 | πŸ“… Year: 2024

πŸ“– Use of carbon-based advanced materials for energy conversion and storage applications: Recent development and future outlook | πŸ† Cited by: 26 | πŸ“… Year: 2024

πŸ“– A reasonable approach to describe the atom distributions and configurational entropy in high entropy alloys based on site preference | πŸ† Cited by: 26 | πŸ“… Year: 2022

πŸ“– Embedding aromatic conjugated monomer within carbon nitride for efficient photocatalytic reduction reactions | πŸ† Cited by: 25 | πŸ“… Year: 2022

πŸ“– The site preference and doping effect on mechanical properties of Ni₃Al-based Ξ³β€² phase in superalloys by combining first-principles calculations and thermodynamic model | πŸ† Cited by: 21 | πŸ“… Year: 2022

πŸ“– A general approach to simulate the atom distribution, lattice distortion, and mechanical properties of multi-principal element alloys based on site preference | πŸ† Cited by: 20 | πŸ“… Year: 2023

πŸ“– Emerging breakthroughs in covalent triazine frameworks: From fundamentals towards photocatalytic water splitting and challenges | πŸ† Cited by: 19 | πŸ“… Year: 2024

πŸ“– Efficient pyrolysis process of lignin over dual catalyst bed for the production of phenols and aromatics | πŸ† Cited by: 19 | πŸ“… Year: 2022

πŸ“– The ordering behavior of Co₃Al-based Ξ³β€² phase with L1β‚‚ structure predicted by the thermodynamic model with support of first-principles calculations | πŸ† Cited by: 17 | πŸ“… Year: 2022

πŸ“– Recent advances in COF-based framework: Synthesis, potential applications, current challenges and future direction | πŸ† Cited by: 14 | πŸ“… Year: 2024

Conclusion

Dr. Hamid Ali is a highly suitable candidate for the Research for Best Researcher Award. His work addresses critical scientific challenges and has significant applications in energy materials, catalysis, and advanced material design, making him a strong contender for recognition.

Anjan Sil | Energy Storage Materials | Best Researcher Award

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Prof. Anjan Sil | Energy Storage Materials | Best Researcher Award

Professor (HAG), Indian Institute of Technology Roorkee, India

Prof. Anjan Sil holds a Ph.D. (1991) and M.Tech. (1986) in Materials Technology from Banaras Hindu University and an M.Sc. in Physics (1984) from IIT Kharagpur. With over 32 years of teaching experience, he has mentored numerous undergraduate and postgraduate students in materials science courses. His research spans 37+ years in energy storage materials ⚑ and functional ceramics 🏺, supervising 17 awarded and 5 ongoing Ph.D. theses. He has also mentored postdoctoral fellows in organic photovoltaics and transparent conducting oxides. His work significantly contributes to batteries πŸ”‹, composites πŸ—οΈ, and ceramic coatings.

Publication Profile

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Qualification

Prof. Anjan Sil is a distinguished researcher in Materials Technology, holding a Ph.D. (1991) πŸ… and M.Tech. (1986) πŸ—οΈ from Banaras Hindu University, along with an M.Sc. in Physics (1984) βš›οΈ from IIT Kharagpur. With decades of experience, his expertise lies in energy storage materials πŸ”‹, functional ceramics 🏺, and composite materials πŸ”¬. His academic contributions have shaped the fields of electronic materials, polymers, and renewable energy applications. As a mentor, he has guided numerous scholars, influencing advancements in batteries, coatings, and nanomaterials. His dedication to research and education continues to drive innovation in materials engineering.

Teaching experience

With over 32 years of teaching experience 🏫, Prof. Anjan Sil has mentored countless students in the field of Materials Science and Engineering. He has taught a diverse range of undergraduate and postgraduate courses, including Electrical and Electronic Materials ⚑, Energy Storage Materials πŸ”‹, Engineering Polymers and Composites πŸ—οΈ, Ceramics and Metal Powder Processing 🏺, and Microsensor & MEMS Devices πŸ€–. His expertise extends to Materials for Renewable Energy 🌱, Electro Ceramics πŸ”¬, Magnetic Materials 🧲, Polymers and Elastomers 🏭, and Smart Devices πŸ’‘. His commitment to education continues to inspire future scientists and engineers.

Research experience

With over 37 years of research experience in Materials Engineering πŸ—οΈ, Prof. Anjan Sil has made significant contributions to Energy Storage Materials πŸ”‹ and Functional Ceramics 🏺. His expertise in these fields has guided numerous scholars, with 17 Ph.D. theses successfully awarded πŸŽ“ and 5 currently ongoing πŸ“–. Additionally, he has supervised 26 M.Tech. theses πŸ†, with one more in progress. His dedication to advancing research and mentoring future scientists continues to shape the field, driving innovation in materials science and sustainable energy solutions. 🌍✨

πŸ† Recognitions & Awards

Prof. Anjan Sil has received numerous prestigious awards and recognitions for his contributions to Materials Engineering πŸ—οΈ. He chaired technical sessions at IIT Roorkee πŸ›οΈ (2023, 2024) and was felicitated as an Eminent Academician πŸŽ“ at Jiwaji University (2023). He received the ASEM-DUO India Fellowship 🌍 for collaboration with Denmark πŸ‡©πŸ‡° (2022) and the British Council UKIERI Award πŸ‡¬πŸ‡§ for research with Cambridge University (2008-2013). Additionally, he has been a visiting scientist πŸ”¬ under INSA-DFG (2017) and INSA-The Royal Society London πŸ‡¬πŸ‡§ (2003, 2007). His contributions to battery technology πŸ”‹, climate & energy 🌱, and functional ceramics 🏺 continue to shape the field.

πŸ“š Research Focus

Prof. Anjan Sil’s research spans several key areas in Materials Engineering βš™οΈ, particularly in energy storage materials πŸ”‹, functional ceramics 🏺, and tribological behavior of coatings πŸ› οΈ. His studies explore electrochemical performance of cathode materials for Li-ion batteries πŸ”‹ and the development of nanostructured coatings with enhanced wear resistance. He also investigates magnetic semiconductors for spintronics applications 🧲 and advanced materials for energy and environmental solutions 🌱. His work includes electrical and magnetic materials ⚑, composite materials πŸ§ͺ, and materials for renewable energy. Prof. Sil’s research has profound implications in sustainability 🌍 and energy storage technologies.

Publication Top Notes

  • A study on sliding and erosive wear behaviour of atmospheric plasma sprayed conventional and nanostructured alumina coatings
    Cited by: 157
    Year: 2011
  • Tribological behavior of plasma sprayed Cr2O3–3% TiO2 coatings
    Cited by: 62
    Year: 2011
  • Effect of carbon coating on electrochemical performance of LiFePO4 cathode material for Li-ion battery
    Cited by: 58
    Year: 2018
  • Photocatalytic response of Fe, Co, Ni doped ZnO based diluted magnetic semiconductors for spintronics applications
    Cited by: 57
    Year: 2019
  • Suppression of Jahn–Teller distortion by chromium and magnesium doping in spinel LiMn2O4: A first-principles study using GGA and GGA+ U
    Cited by: 55
    Year: 2009
  • Microstructural relationship with fracture toughness of undoped and rare earths (Y, La) doped Al2O3–ZrO2 ceramic composites
    Cited by: 51
    Year: 2011
  • Preparation and characterization of lithium manganese oxide cubic spinel Li1.03Mn1.97O4 doped with Mg and Fe
    Cited by: 50
    Year: 2010
  • Relationship between fracture toughness characteristics and morphology of sintered Al2O3 ceramics
    Cited by: 43
    Year: 2010
  • Wear of Plasma Sprayed Conventional and Nanostructured Al2O3 and Cr2O3, Based Coatings
    Cited by: 40
    Year: 2012
  • Mechanical and thermal characteristics of PMMA-based nanocomposite gel polymer electrolytes with CNFs dispersion
    Cited by: 31
    Year: 2015
  • SYNTHESIS AND CHARACTERISATION OF Li [Mn 2-xMgx] O 4(x= 0. 0-0. 3) PREPARED BY SOL-GEL SYNTHESIS
    Cited by: 29
    Year: 2010
  • Preparation of Fe doped ZnO thin films and their structural, magnetic, electrical characterization
    Cited by: 28
    Year: 2018
  • Tribological behaviour of nanostructured Al2O3 coatings
    Cited by: 28
    Year: 2012
  • Role of calcination atmosphere in vanadium doped Li4Ti5O12 for lithium ion battery anode material
    Cited by: 26
    Year: 2017
  • Effect of citric acid content on synthesis of LiNi1/3Mn1/3Co1/3O2 and its electrochemical characteristics
    Cited by: 26
    Year: 2010
  • Development of input output relationships for self-healing Al2O3/SiC ceramic composites with Y2O3 additive using design of experiments
    Cited by: 23
    Year: 2011
  • MnO anchored reduced graphene oxide nanocomposite for high energy applications of Li-ion batteries: The insight of charge-discharge process
    Cited by: 22
    Year: 2019
  • PEDOT:PSS coating on pristine and carbon coated LiFePO4 by one-step process: the study of electrochemical performance
    Cited by: 22
    Year: 2019
  • Energy and power densities of novel composite electrode driven by synergy of poly (3, 4-ethylene dioxythiophene): poly (styrene sulfonate) and single walled carbon nanotubes
    Cited by: 21
    Year: 2020
  • TiO2 shielded Si nano-composite anode for high energy Li-ion batteries: The morphological and structural study of electrodes after charge-discharge process
    Cited by: 20
    Year: 2019

Conclusion

Prof. Sil’s extensive research experience, impactful supervision, and contributions to advanced energy materials, he is a highly suitable candidate for the Best Researcher Award. His work aligns with global challenges in sustainable energy and materials innovation, making him a strong contender for recognition in research excellence.