David Chepkonga | Thermal and Metallurgical Processes | Innovative Research Award

Published on by Metallurgical Engineering

Innovative Research Award

David Chepkonga
Jomo Kenyatta University of Agriculture and Technology, Kenya
David Chepkonga
Affiliation Jomo Kenyatta University of Agriculture and Technology
Country Kenya
Scopus ID 59419267100
Documents 3
Citations 4
h-index 1
Subject Area Thermal and Metallurgical Processes
Event Metallurgical Engineering Awards
ORCID 0000-0002-2180-1718

David Chepkonga is a Kenyan scholar in applied and computational mathematics whose academic work has contributed to the advancement of numerical modelling, heat transfer analysis, fluid dynamics, and computational simulation. His interdisciplinary research profile combines mathematical theory with engineering-oriented applications relevant to thermal and metallurgical processes.[1] Through scholarly publications, conference participation, and university teaching, he has demonstrated a commitment to analytical research and academic development in East Africa and beyond.[2]

Abstract

David Chepkonga and his contributions to applied mathematics, computational modelling, and engineering-oriented scientific research. His academic activities include numerical analysis, magnetohydrodynamic flow studies, thermal systems simulation, and epidemic modelling.[3] Through publications in peer-reviewed journals and participation in international conferences, Chepkonga has contributed to research areas connected to thermal sciences and metallurgical engineering applications. His research profile reflects an emphasis on analytical rigor, interdisciplinary collaboration, and mathematical approaches to industrial and environmental challenges.[4]

Keywords

Applied Mathematics, Thermal Engineering, Metallurgical Processes, Computational Modelling, Fluid Dynamics, Heat Transfer, Numerical Analysis, Magnetohydrodynamics, Scientific Simulation, Engineering Research

Introduction

David Chepkonga working in this field often apply numerical techniques and mathematical simulations to understand heat transfer, fluid flow, and material behaviour under complex operating conditions. David Chepkonga has developed a research portfolio aligned with these objectives through studies involving nanofluid dynamics, magnetic field interactions, and predictive modelling systems.[2]

His academic work is associated with Jomo Kenyatta University of Agriculture and Technology in Kenya, where he completed advanced studies in applied mathematics and computational sciences. In addition to research, he has contributed to university teaching, supervision, curriculum development, and scholarly mentorship across multiple institutions.[1]

Research Profile

Chepkonga’s research profile focuses on computational fluid dynamics, thermal modelling, and engineering mathematics. His studies examine the interaction between magnetic fields, viscous flow systems, and heat transfer processes relevant to industrial and metallurgical applications.[3] His technical expertise includes MATLAB simulation, numerical analysis, and mathematical modelling techniques applied to engineering and environmental systems.

Research Contributions

A major component of Chepkonga’s work involves analysing thermal transport phenomena through computational approaches. His studies on gyro-tactic hybrid nanofluids and porous convergent pipe systems provide mathematical insight into complex flow behaviours and thermal conductivity patterns.[3] He has also contributed to mathematical epidemiology through research on disease transmission dynamics, including SIR-based modelling frameworks for Monkeypox and other infectious diseases. These studies illustrate the adaptability of mathematical methods across engineering and biomedical domains.[4]

Publications

  • Spectral Relaxation Analysis of Rotating Magnetohydrodynamic Viscous Flow and Heat Transfer Past a Stretching Sheet, Results in Engineering, 2026.
  • Modelling Heat and Mass Transfer in Gyro-tactic Hybrid Nanofluid Flow Through a Converging Pipe, International Journal of Ambient Energy, 2025.
  • Numerical Study of Multiphase Hybrid Gyro-tactic Nanofluid Flow Through Porous Convergent Pipe, Engineering Letters, 2025.

Research Impact

David Chepkonga’s studies combine mathematics, engineering analysis, and simulation techniques to address scientific questions relevant to industrial systems and emerging technological challenges.[5] His publications contribute to growing academic discussions in thermal sciences, metallurgical engineering processes, computational mathematics, and applied modelling. Participation in international conferences and academic workshops has also strengthened collaboration opportunities and research dissemination within the African scientific community.[2]

Award Suitability

David Chepkonga’s academic background and publication record support his suitability for recognition through the Innovative Research Award. His work demonstrates interdisciplinary integration between mathematics and engineering sciences, particularly in computational heat transfer and flow analysis.[3] The combination of research productivity, university-level teaching experience, conference engagement, and collaborative scholarly participation indicates sustained academic involvement.[4]

Conclusion

David Chepkonga represents a growing generation of African researchers contributing to computational mathematics and engineering analysis through applied scientific investigation. His research activities, publication portfolio, and commitment to higher education demonstrate continued engagement with interdisciplinary academic advancement. The Innovative Research Award recognizes scholarly contributions that support analytical problem-solving, engineering innovation, and scientific development within the broader academic and industrial community.

References

  1. Elsevier. (n.d.). Scopus author details: David Chepkonga, Author ID 59419267100. Scopus.
    https://www.scopus.com/authid/detail.uri?authorId=59419267100
  2. Chepkonga, D. (2019). Fluid flow and heat transfer through a vertical cylindrical collapsible tube in the presence of magnetic field and an obstacle. International Journal of Advances in Applied Mathematics and Mechanics
    web.archive.org
  3. Chepkonga, D. (2024). Modeling the spread of Mpox viral disease in African countries using a Bayesian hierarchical model. Commun. Math. Biol. Neurosci..
    https://scik.org/index.php/cmbn/article/view/8890
  4. Chepkonga, D. (2025). Optimizing Control Measures for a Vector-Host Epidemic Model: A Mathematical Analysis. Earth 
    https://www.researchgate.net/
  5. Chepkonga, D. (2024). Heat Transfer on a Non-Newtonian Hydromagnetic Fluid Flow through a Convergent Conduit with Chemical Reaction and Soret Effects.
    https://ijaamm.com/uploads/2/1/4/8/21481830/v12n1p6_57-69.pdf

Willie Nheta | Mineral Processing | Innovative Research Award

Published on by Metallurgical Engineering

Innovative Research Award

Willie Nheta
University of Johannesburg, South Africa
Willie Nheta
Affiliation University of Johannesburg
Country South Africa
Scopus ID 56195710700
Documents 61
Citations 301
h-index 6
Subject Area Mineral Processing
Event Metallurgical Engineering Awards
ORCID 0000-0002-7621-1379

Willie Nheta in the field of mineral processing and metallurgical engineering of Innovative Research Award recognizes the scholarly and technical contributions. His academic activities at the University of Johannesburg encompass research supervision, flotation technology, hydrometallurgy, extractive metallurgy, and process optimization within mineral beneficiation systems. His work has contributed to ongoing developments in sustainable metallurgical processing methodologies and advanced mineral recovery systems.[1]

Abstract

Willie Nheta is a metallurgical engineering academic whose work primarily focuses on mineral processing, froth flotation systems, hydrometallurgy, and sustainable beneficiation technologies. His research includes optimization of flotation parameters, recovery of platinum group metals, treatment of low-grade ores, recovery from mine tailings, and advanced extractive metallurgy methods. Through peer-reviewed publications, postgraduate supervision, and collaborative industrial research, he has contributed to developments in process efficiency and environmentally responsive mineral engineering approaches.[2]

Keywords

Mineral Processing, Froth Flotation, Hydrometallurgy, Metallurgical Engineering, Platinum Group Metals, Sustainable Beneficiation, Response Surface Methodology, Tailings Recovery, Ore Characterization, Process Optimization.

Introduction

The discipline of metallurgical engineering plays a critical role in modern mineral extraction, sustainable resource utilization, and industrial process innovation. Within this context, Willie Nheta has developed a research portfolio centered on flotation technology, hydrometallurgical recovery, and beneficiation of complex ores. His academic contributions at the University of Johannesburg reflect ongoing engagement with mineral recovery systems relevant to platinum group metals, nickel, iron ore, chromite, and base metal processing.[3]

His scholarly work integrates laboratory experimentation, process modeling, response surface methodology, and industrially applicable optimization strategies. These investigations contribute to understanding mineral liberation, flotation reagent interactions, and environmentally conscious extraction systems for low-grade and oxidized ores.[4]

Research Profile

Willie Nheta serves as Associate Professor and Mineral Processing Laboratory Manager at the University of Johannesburg. His educational background includes postgraduate studies in extraction metallurgy and non-ferrous metallurgy with specialization in precious metal smelting technologies. His professional and academic experience includes plant metallurgy operations, mineral processing research, and university-level supervision and instruction.[1]

  • Research specialization in mineral processing and hydrometallurgy.
  • Extensive supervision of postgraduate students in metallurgical engineering.
  • Laboratory management involving flotation and beneficiation systems.
  • Research collaboration on platinum group metals and base metal extraction.
  • Publication contributions in peer-reviewed journals and conferences.

Research Contributions

Willie Nheta’s research activities emphasize flotation optimization, recovery of valuable minerals from tailings, and development of sustainable beneficiation approaches. His investigations into oxidized platinum group metal ores, flotation chemistry, and low-grade ore processing have supported advancements in metallurgical process understanding.[5]

A significant aspect of his work involves the application of response surface methodology and central composite design for process optimization in flotation systems. These studies contribute to improved mineral recovery performance and operational efficiency in mineral processing operations.[6]

  • Optimization of chromite and platinum group metal flotation systems.
  • Development of beneficiation methodologies for low-grade ores.
  • Research on sustainable extraction and tailings valorization.
  • Application of nano-engineered adsorbents for selective metal extraction.
  • Studies on flotation reagent interactions and mineral surface chemistry.

Publications

Willie Nheta includes journal articles, conference proceedings, and book chapters covering flotation science, hydrometallurgy, mineral beneficiation, and sustainable processing technologies. Selected scholarly works include:

  1. Optimization of Reverse Cationic Flotation of Low-Grade Iron Oxide from Fluorspar Tails Using Taguchi Method.
  2. Application of Response Surface Methodology on the Optimization of Chromite Recovery from South African Middle Group Chromite Seams.
  3. Pretreatment and Recovery of Base Metals from Oxidised Ores by Froth Flotation Technology.
  4. Exploring the Characterization, Liberation and Flotation Response of a Nigerian Low-Grade Copper Ore.
  5. Beneficiation of Low-Grade Iron Plant Tailings Through Magnetization Roasting Using Macadamia Nutshell Reductant.

Several publications include studies on flotation kinetics, thermochemical reduction processes, and beneficiation of platinum-bearing materials. These contributions reflect interdisciplinary applications of metallurgy, process engineering, and mineral economics.[2]

Research Impact

Willie Nheta demonstrates measurable academic and industrial relevance through peer-reviewed publications, citation metrics, postgraduate supervision, and externally funded research activities. His supervision portfolio includes numerous completed master’s and doctoral projects related to flotation systems, ore characterization, and sustainable beneficiation technologies.[1]

His studies on flotation optimization, mine sludge processing, and chromite beneficiation contribute to broader discussions on mineral sustainability and resource recovery in the metallurgical engineering sector. Research findings have also supported advancements in process modeling and operational optimization methodologies for industrial mineral processing systems.[5]

Award Suitability

The Innovative Research Award aligns with Willie Nheta’s contributions to metallurgical engineering research, mineral beneficiation technologies, and sustainable extraction systems. His multidisciplinary investigations into flotation science, hydrometallurgical recovery, and process optimization reflect a sustained academic commitment to advancing metallurgical engineering knowledge.[4]

  • Long-term contribution to mineral processing research.
  • Demonstrated supervision and mentorship in postgraduate education.
  • Peer-reviewed scholarly publication record.
  • Industrial relevance in metallurgical process optimization.
  • Contribution to sustainable mineral beneficiation practices.

Conclusion

Willie Nheta’s academic profile reflects active engagement in metallurgical engineering research with emphasis on flotation systems, hydrometallurgy, and sustainable mineral recovery technologies. His combination of industrial experience, academic supervision, publication activity, and applied mineral processing research supports recognition within the field of metallurgical engineering. The Innovative Research Award acknowledges these contributions and their relevance to contemporary mineral beneficiation and extractive metallurgy practices.[6]

References

  1. Elsevier. (n.d.). Scopus author details: Willie Nheta, Author ID 56195710700. Scopus.
    https://www.scopus.com/authid/detail.uri?authorId=56195710700
  2. M Ramudzwagi, N Tshiongo-Makgwe, W Nheta. (2020) Recent developments in beneficiation of fine and ultra-fine coal-review paper.
    https://www.sciencedirect.com/science/article/pii/S0959652620327402
  3. Nheta, W., Lubisi, T.P. and Ntuli, F. (2018). Optimization of Reverse Cationic Flotation of Low-Grade Iron Oxide from Fluorspar Tails Using Taguchi Method. Arabian Journal for Science and Engineering.
    https://link.springer.com/article/10.1007/s13369-017-2703-z
  4. Kaseba, C.N.Y.L. and Nheta, W. (2024). Application of Response Surface Methodology on the Optimization of Chromite Recovery from the South African Middle Group Chromite Seams. Journal of Sustainable Metallurgy.
    https://link.springer.com/article/10.1007/s40831-024-00820-7
  5. Nkosi, N. and Nheta, W. (2024). Pretreatment and recovery of base metals from oxidised ores by froth flotation technology – A review. Minerals Engineering.
    https://doi.org/10.1016/j.mineng.2024.109024
  6. Mpala, T.J., Fosso-Kankeu, E., Maree, J., Masindi, V., Nheta, W., and Mamba, B.B. (2025). Struvite from municipal wastewater applied for the recovery of iron oxide pigments from acid mine drainage: an experimental and geochemical modelling approach. Environmental Earth Sciences.
    https://doi.org/10.1007/s12665-025-12350-w

Ayesha Tasawar | Hydrometallurgical | Excellence in Research Award

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Mrs. Ayesha Tasawar | Hydrometallurgical | Excellence in Research Award

Scientific Assistant at Institute of Process Metallurgy and Metal Recycling (IME), RWTH Aachen University | Germany

Mrs. Ayesha Tasawar is an emerging researcher in process metallurgy and sustainable materials engineering, with a strong focus on lithium-ion battery recycling and resource recovery. Her research addresses key challenges in circular economy technologies, particularly the hydrometallurgical processing of lithium iron phosphate (LFP) blackmass. She is the lead author of peer-reviewed journal articles in Resources, Conservation and Recycling and Metals, demonstrating original contributions to efficient lithium recovery through oxidative roasting and organic-acid-enabled leaching. Her work combines scientific rigor with industrial relevance, offering environmentally responsible solutions for advanced battery recycling. Scopus profile, 2 publications, emerging citation record, and emerging h-index.

View ORCID Profile

Featured Publications

Bilal Ahmad | Computational Metallurgy | Research Excellence Award

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Mr. Bilal Ahmad | Computational Metallurgy | Research Excellence Award

University of Johannesburg | South Africa

Mr. Bilal Ahmad demonstrates emerging excellence in data science and artificial intelligence, with scholarly focus on machine learning and deep learning applications for complex, real-world problems. Research contributions emphasize predictive analytics and intelligent modeling, including peer-reviewed work on epidemic outbreak analysis using advanced computational techniques. The research reflects methodological soundness, interdisciplinary relevance, and alignment with current global challenges in data-driven systems. According to the Scopus profile, the researcher has 1 indexed publication, 2 total citations, and an h-index of 1, indicating early academic visibility and growing research impact. These contributions highlight strong potential for continued advancement and research excellence.

Citation Metrics ( Google Scholar )

5

3

2

1

0

Citations
2

Documents
1

h-index
1

Featured Publications


Exploration of Epidemic Outbreaks Using Machine and Deep Learning Techniques
– Advances in Cybersecurity, Cybercrimes, and Smart Emerging Technologies, 2023

Chen Xu | Martensitic Transformation | Best Materials Engineering Award

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Chen Xu | Martensitic Transformation | Best Materials Engineering Award

Doctor at China Jiliang University | China

Dr. Chen Xu is an Assistant Research Fellow at China Jiliang University specializing in the metallurgy and materials science of magnesium, aluminum, titanium, and copper alloys. He earned his Ph.D. in Materials Science and Engineering from Zhengzhou University, following an M.D. in Metallurgical Engineering from Lanzhou University of Technology and a B.A. in Metallurgical Engineering from Lanzhou College of Information Science and Technology. His research spans melting processes, microstructure, heat treatment, deformation treatment, corrosion resistance, coatings, martensitic transformations, and first-principles calculations. Dr. Xu has contributed to several national research projects, including those funded by the National Natural Science Foundation of China, and has authored multiple peer-reviewed publications in high-impact journals such as Materials & Design, Journal of Magnesium and Alloys, Materials Science & Engineering A, and Journal of Alloys and Compounds. His recent works cover topics like heat treatment effects on Mg-Sc alloys, martensitic transformation behavior, micro-galvanic corrosion, and advanced aluminum-titanium-carbon master alloys. He has also published research on the optimization of aluminum alloys and collaborated on interdisciplinary studies involving carbon quantum dots for cancer therapy. With a 7 Scopus-indexed publications citation count of 67 and an h-index of 4 on Scopus, his profile is at an early stage of international recognition, supported by active involvement in national projects, editorial board membership with Modern Chemical Research, and patent applications. Chen Xu’s contributions demonstrate a clear trajectory toward impactful innovations in advanced materials engineering, combining experimental studies with computational insights to advance alloy design and performance.

Profile: Scopus | ORCID

Featured Publicationns

Xu, C., Liu, S., Wang, J., & Li, H. (2023). Initial micro-galvanic corrosion behavior between Mg₂Ca and α-Mg via quasi-in situ SEM approach and first-principles calculation. Journal of Magnesium and Alloys, 11(3), 958–965. Cited by: 21

Xu, C. (2023). Martensitic transformation behavior during tensile testing at room temperature in β-type Mg-35 wt%Sc alloy. Materials Science & Engineering A, 865, 144602. Cited by: 7

Xu, C. (2023). Effect of quenching temperature on microstructure and mechanical properties of Mg-35 wt%Sc alloy. Journal of Alloys and Compounds, 943, 169165. Cited by: 5

Xu, C. (2019). Preparation and synthesis thermokinetics of novel Al-Ti-C-La composite master alloys. Journal of Alloys and Compounds, 776, 904–911. Cited by: 43

Xu, C. (2017). Effect of Al-5Ti-0.62C-0.2Ce master alloy on the microstructure and tensile properties of commercial pure Al and hypoeutectic Al-8Si alloy. Metals, 7(6), 227. Cited by: 52

Raghukumar Bommenahalli | Mechanical Metallurgy | Best Researcher Award

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Raghukumar Bommenahalli | Mechanical Metallurgy | Best Researcher Award

Prinicipal Engineer at DEKRA Certification, Inc. | United States

Mr. Raghukumar Bommenahalli is a seasoned mechanical engineer with over two decades of industrial experience specializing in zero-emission transportation and energy infrastructure. Currently serving as Principal Engineer at DEKRA Certification Inc., he leads the Vehicle Innovation Grid Lab (ViGIL) and ADAS Data Collection Program, advancing California’s clean transportation initiatives through rigorous EV and EVSE testing, standards compliance, and interoperability validation. Prior to this, he was Program Manager for Codes and Standards at Nikola Motor Corporation, where he guided regulatory compliance and standards development for battery-electric and fuel-cell electric vehicles, including cybersecurity frameworks and ADAS integration for heavy-duty trucks. His earlier role at Cummins Inc. as Codes and Standards Compliance Leader saw him authoring 40+ validation plans across UL, CSA, IEC, and EN standards while pioneering hydrogen fuel cell and BEV compliance programs. Raghukumar has also contributed to major engineering projects in roles with TAAL Technologies, Creative Synergies Group, Toyo Denki Power Systems, and Cummins Generator Technologies. He is actively involved in global standards development as a voting member on multiple SAE task forces and as Co-Chair of the CharIN NACI Task Force. With a strong academic foundation that includes an Executive Master’s in Engineering Management from St. Cloud State University, a Master’s in Machine Design, and a Bachelor’s in Mechanical Engineering from Visvesvaraya Technological University, he complements his technical expertise with certifications such as PMP, DFSS, and internal auditing. In addition to his leadership in compliance, testing, and certification, he contributes as a peer reviewer for leading journals, organizes technical conferences, and holds a registered design patent in EV charging efficiency.

Pofile: Scopus | ORCID

Featured Publication

Bommenahalli, R. (2025). Effect of nickel on the mechanical properties of spray-formed Al-15Si-2Cu alloy at elevated temperatures. Journal of Alloys and Compounds.

Bommenahalli, R. (2025). Computing device for enhancing charging efficiency in electric vehicle [Patent]. UK Intellectual Property Office.

Bommenahalli, R. (2025). Fuel cell Class 8 trucks: Pioneering the path to sustainable heavy transportation. Website article.

Bommenahalli, R. (2025). Navigating the future: Innovations reshaping the EV charging landscape. International Business Times.

Zhe Wang | Metallurgical Engineering | Best Researcher Award

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Prof. Dr. Zhe Wang | Metallurgical Engineering | Best Researcher Award

Professor at University of Science and Technology Beijing, China

Zhe Wang is a professor at the University of Science and Technology Beijing. His academic journey, marked by extensive research in metallurgical engineering, began with a Ph.D. from the University of Wollongong, Australia. Since 2016, he has been a dedicated contributor to advancing recycling technologies for critical metals. With a focus on innovative solutions to supply security risks and environmental challenges, Dr. Wang’s work has significantly impacted industrial practices. His methods, such as supergravity-enhanced separation and matte smelting for lithium-ion batteries, are transformative, earning recognition from prestigious organizations. A prolific author and inventor, he holds multiple patents and has published over 43 SCI-indexed papers. His leadership extends to editorial roles and professional committees, fostering collaboration in the metallurgical community.

Professional Profiles📖

Scopus

Education 🎓

Dr. Wang’s educational foundation is deeply rooted in metallurgical engineering. He earned his doctoral degree (2012-2015) from the University of Wollongong, where he delved into innovative recycling methods for metal resources. His Ph.D. thesis focused on the molten separation of metals and related electrochemical processes. Prior to that, he pursued foundational studies in materials science, developing a profound understanding of alloy behaviors and high-temperature reactions. His academic pursuits emphasized practical applications, paving the way for his later industrial collaborations. This strong theoretical grounding underpins his current research, as he continues to educate future leaders in metallurgy at the University of Science and Technology Beijing.

Work Experience💼

Dr. Wang‘s professional career spans over a decade of impactful contributions to metallurgical research and education. From his initial role as an Associate Research Fellow at the University of Wollongong, he transitioned to teaching and research positions at the University of Science and Technology Beijing. Serving as a Lecturer (2016–2018), Associate Professor (2018–2024), and now as Professor, he has led numerous projects funded by national foundations and industry partners. His work bridges academia and industry, driving innovation in metal recycling technologies. His hands-on approach to research has resulted in industrial implementations with significant cost and efficiency benefits.

Research Focus

Dr. Wang specializes in high-value recycling of critical metal resources, tackling challenges in supply chain security and sustainability. His pioneering approaches, including supergravity-assisted separation and electrochemical methods, emphasize efficiency and scalability. His focus extends to recycling low-melting-point metals, refining titanium and zirconium through stable electrolytes, and developing smelting processes for precious metals. His research integrates theoretical insights and practical applications, bridging the gap between laboratory innovation and industrial utility.

Awards & Honors

Dr. Wang‘s achievements have been celebrated with numerous awards. Among these, the First Prize in the China Nonferrous Metals Industry Technological Invention Award (2022) stands out for his advancements in molten salt electrorefining. His contributions to supergravity-enhanced technologies have also been supported by the National Natural Science Foundation of China. As a recognized leader, he serves on editorial boards and professional committees, further solidifying his reputation as a thought leader in the field. His work’s industrial impact has earned accolades from organizations such as Baosteel and Shougang Group.

Conclusion✅

Dr. Zhe Wang exemplifies the qualities of a deserving candidate for the Best Researcher Award. His pioneering work in high-value recycling of critical metals, combined with a track record of impactful publications, patents, and industrial applications, underscores his significant contributions to science and industry. Addressing minor areas for improvement, such as increasing global collaboration and interdisciplinary engagement, could further elevate his already stellar profile. Dr. Wang’s innovative research and dedication make him a strong contender for this prestigious recognition.

📚Publications to Noted

 

Extraction and recovery of rare earth elements from NdFeB waste using bismuth reinforced by supergravity

Authors: Z. Wang, Zhenxiang Zhang, Long Meng, Chunjiang Li, Zhancheng GuCitations: 0

Year: 2024

Sustainable recycling of pure aluminum from waste chips under supergravity-enhanced separation: A cleaning process

Authors: Bolin Sun, Lei Guo, Z. Wang, Xi Lan, Zhancheng Guo

Year: 2024

Preparation of SiC/Al composite material by supergravity infiltration method and its properties

Authors: Yuan Li, Z. Wang, Zhancheng Guo

Citations: 6

Year: 2024

Grade-preserving recycling of highly polluted Al-Mg-Si alloys scrap: Continuous filtration under supergravity-induced

Authors: Bolin Sun, Xi Lan, Z. Wang, Ningjie Sun, Zhancheng Guo

Citations: 1

Year: 2024

Weak Electrostatic Force on K+ in Gel Polymer Electrolyte Realizes High Ion Transference Number for Quasi Solid-State Potassium Ion Batteries

Authors: Huize Yang, Wei Wang, Zheng Huang, Shufeng Yang, Shuqiang Jiao

Citations: 12

Year: 2024

The fundamental research on suspended dross in hot dip Al–Zn galvanising process

Authors: Rensheng Chu, Z. Wang, Ningjie Sun, Chengliang Xu, Zhancheng Guo

Year: 2024

CFD simulation and water model experiments with overflow-type supergravity reactor set up for continuously removing inclusions from aluminum melt

Authors: Z. Wang, Qilong Wei, Meng Hu, Zhancheng GuoCitations: 0

Year: 2024

Effect of Al2O3/SiO2 mass ratio and CaO content on viscosity and structure of slag for pyrometallurgical processing of spent automotive catalysts

Authors: Z. Wang, Qilong Wei, Chengbin Shi, Zhancheng Guo

Citations: 5

Year: 2024

Insight into compositional dependence of thermophysical properties and structure of Al2O3-SiO2-CaF2-CaO-Li2O melts

Authors: Xiuxiu Wan, Z. Wang, Jian Yang, Chengbin Shi

Citations: 5

Year: 2024

Review—Preparation of Hafnium Metal by Electrolysis

Authors: Ranran Wei, Zheng Huang, Tianwei Wei, Z. Wang, Shuqiang Jiao

Citations: 2

Year: 2024