Tshifhiwa Masikhwa | Materials Chemistry | Best Researcher Award

Published on by Chemical Scientist

Best Researcher Award

Tshifhiwa Masikhwa — Necsa
Tshifhiwa Masikhwa
Affiliation Necsa
Country South Africa
Scopus ID 56426594300
Documents 30
Citations 1648
h-index 24
Subject Area Energy storage
Event International Chemical Scientist Awards
ORCID
0000-0003-3801-569X

Tshifhiwa Masikhwa is associated with Necsa in South Africa and is recognized for scientific contributions in the field of energy storage research. His scholarly activities include investigations involving electrochemical systems, advanced storage materials, and sustainable energy technologies designed to improve efficiency and long-term performance within modern storage applications.[1]

Abstract

This article presents an overview of the academic profile and scientific contributions of Tshifhiwa Masikhwa in the field of energy storage research. His scholarly work focuses on electrochemical materials, storage system performance, and sustainable energy technologies intended to support efficient and reliable energy applications. Indexed publications and citation records demonstrate measurable research visibility within chemical sciences and advanced materials investigations. The profile reflects interdisciplinary engagement in energy-related research activities involving electrochemical innovation, material optimization, and storage efficiency studies relevant to contemporary scientific and industrial development initiatives.[2]

Keywords

Energy Storage, Electrochemical Materials, Sustainable Energy, Battery Technology, Advanced Materials, Electrochemistry, Scientific Research, Chemical Sciences.

Introduction

Energy storage technologies remain central to modern scientific and industrial development because of their importance in renewable energy integration, power management, and sustainable infrastructure systems. Research involving electrochemical storage materials and performance optimization contributes significantly to advancements in energy efficiency and long-term technological reliability. Tshifhiwa Masikhwa has participated in scientific investigations associated with these research priorities through studies addressing storage performance, electrochemical properties, and material development strategies.[3]

Research Profile

The research profile demonstrates scholarly engagement in electrochemistry, advanced energy materials, and energy storage systems. Indexed publications and citation metrics indicate continuing academic visibility within chemical science and materials research communities. Scientific activities include interdisciplinary investigations involving electrochemical processes, material characterization, and energy efficiency studies relevant to sustainable technological applications.[1]

  • Research in electrochemical energy storage technologies.
  • Studies involving advanced energy storage materials.
  • Scientific contributions related to sustainable energy systems.
  • Investigations involving electrochemical material performance.

Research Contributions

Research contributions associated with this academic profile focus on the development and evaluation of electrochemical systems designed for energy storage applications. Scientific investigations include studies related to electrode materials, conductivity enhancement, storage capacity optimization, and sustainable energy performance. Such work contributes to broader discussions concerning efficient storage technologies and advanced electrochemical applications within modern energy research environments.[4]

  • Evaluation of electrochemical storage performance.
  • Development of advanced electrode materials.
  • Studies involving conductivity and storage efficiency.
  • Research supporting sustainable energy innovation.

Publications

Published research associated with this profile includes scientific articles addressing electrochemical systems, energy storage technologies, and advanced material applications. Indexed studies demonstrate interdisciplinary engagement in chemical science and energy-related investigations relevant to sustainable technology development and storage optimization methodologies.[2]

  1. Advanced Electrochemical Materials for Energy Storage Applications.
  2. Performance Optimization of Sustainable Energy Storage Systems.

Research Impact

Citation activity and publication records demonstrate meaningful research visibility within energy storage and electrochemical science communities. Scientific investigations involving storage efficiency, material innovation, and sustainable energy technologies contribute to ongoing academic discussions concerning advanced energy solutions and environmentally responsible technological development. The documented citation metrics further indicate continued scholarly engagement with published findings.[1]

Award Suitability

The researcher’s documented achievements in energy storage and electrochemical materials research align with the objectives of the International Chemical Scientist Awards. Contributions involving sustainable energy technologies, material optimization, and electrochemical innovation support recognition within academic award frameworks emphasizing scientific advancement, interdisciplinary research excellence, and technological relevance in chemical sciences.[4]

Conclusion

Tshifhiwa Masikhwa’s academic profile reflects ongoing scientific contributions to energy storage technologies, electrochemical systems, and advanced material investigations. His research activities support broader scientific efforts directed toward sustainable energy development, efficient storage applications, and innovative electrochemical solutions relevant to contemporary chemical science and engineering research communities.[2]

References

  1. Elsevier. (n.d.). Scopus author details: Tshifhiwa Masikhwa, Author ID 56426594300. Scopus.

    https://www.scopus.com/authid/detail.uri?authorId=56426594300
  2. ORCID. (n.d.). Academic profile and research activities of Tshifhiwa Masikhwa.

    http://orcid.org/0000-0003-3801-569X

  3. Oyedotun, K. O., Masikhwa, T. M., Lindberg, S., Matic, A., Johansson, P., & Manyala, N. (2019). Comparison of ionic liquid electrolyte to aqueous electrolytes on carbon nanofibres supercapacitor electrode derived from oxygen-functionalized graphene. Chemical Engineering Journal, 375, 121906.

    https://doi.org/10.1016/j.cej.2019.121906

  4. Ndiaye, N. M., Madito, M. J., Ngom, B. D., Masikhwa, T. M., Mirghni, A. A., & Manyala, N. (2019). High-performance asymmetric supercapacitor based on vanadium dioxide and carbonized iron-polyaniline electrodes. AIP Advances, 9(5), 055309.https://doi.org/10.1063/1.5091799

Moussa Ouakki | Electrochemistry | Best Researcher Award

Published on by Chemical Scientist

Prof. Moussa Ouakki | Electrochemistry | Best Researcher Award

Ibn Tofail University| Morocco

Prof. Moussa Ouakki is a distinguished Moroccan chemist and academic scholar serving as Maître de Conférence en Chimie at the École Nationale Supérieure de Chimie, Université Ibn Tofaïl, Kénitra, Maroc. He holds a doctorate in Fundamental and Applied Chemistry with a specialization in the valorization of imidazole compounds for corrosion inhibition of steel in acidic media through theoretical, electrochemical, and spectroscopic studies. His academic background also includes advanced training in physicochemical materials, organic and environmental chemistry, and life sciences. In addition, he has pursued professional development in chemical education, patent systems, and chemical safety in collaboration with the Organisation for the Prohibition of Chemical Weapons (OPCW). Throughout his academic career, Prof. Ouakki has contributed extensively to teaching, research supervision, and curriculum design across undergraduate, engineering, and doctoral programs. His teaching expertise spans electrochemical kinetics, materials science, corrosion mechanisms, and electrolyte chemistry. His research interests focus on corrosion inhibition, green chemistry, electrochemical analysis, materials development, and theoretical modeling of corrosion systems. His research skills include density functional theory (DFT), electrochemical impedance spectroscopy, electrodeposition, dielectric characterization, and molecular dynamics simulations. He has co-supervised several doctoral candidates, published more than a hundred international research papers, contributed multiple book chapters, and secured a patent for novel imidazole-based corrosion inhibitors. As a respected member of editorial boards and a reviewer for leading scientific journals, Prof. Ouakki continues to make remarkable contributions to advancing sustainable chemistry and materials protection. His academic impact is further reflected in his growing recognition with 3,836 citations, 125 documents, and an h-index of 41.

Profiles: Google Scholar | Scopus | ORCID

Featured Publications

Ouakki, M., Galai, M., Rbaa, M., Abousalem, A. S., Lakhrissi, B., Rifi, E. H., & Ebn Touhami, M. (2019). Quantum chemical and experimental evaluation of the inhibitory action of two imidazole derivatives on mild steel corrosion in sulphuric acid medium. Heliyon, 5(11), e02716. Cited by: 147

Rbaa, M., Ouakki, M., Galai, M., Berisha, A., Lakhrissi, B., Jama, C., Warad, I., & Touhami, M. E. (2020). Simple preparation and characterization of novel 8-hydroxyquinoline derivatives as effective acid corrosion inhibitor for mild steel: Experimental and theoretical studies. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 602, 125094. Cited by: 144

Ouakki, M., Galai, M., Rbaa, M., Abousalem, A. S., Lakhrissi, B., Touhami, M. E., & Cherkaoui, M. (2020). Electrochemical, thermodynamic and theoretical studies of some imidazole derivatives compounds as acid corrosion inhibitors for mild steel. Journal of Molecular Liquids, 319, 114063. Cited by: 140

Ouakki, M., Galai, M., & Cherkaoui, M. (2022). Imidazole derivatives as efficient and potential class of corrosion inhibitors for metals and alloys in aqueous electrolytes: A review. Journal of Molecular Liquids, 345, 117815. Cited by: 123

Oubaaqa, M., Ouakki, M., Rbaa, M., Abousalem, A. S., Maatallah, M., Benhiba, F., & Touhami, M. E. (2021). Insight into the corrosion inhibition of new amino acids as efficient inhibitors for mild steel in HCl solution: Experimental studies and theoretical calculations. Journal of Molecular Liquids, 334, 116520.

 

Day-Shan Liu | Catalysis | Best Researcher Award

Published on by Chemical Scientist

Prof. Dr. Day-Shan Liu | Catalysis | Best Researcher Award

Professor at Institute of Electro-Optical and Materials Science, National Formosa University . ,Taiwan.

🔬 Short Biography 🌿💊📚

🎓 Prof. Day-Shan Liu received his Ph.D. in Optical Sciences from National Central University in January 2003. Since February 2011, he has been a distinguished Professor at the Department of Electro-Optical Engineering and the Institute of Electro-Optical and Materials Science at National Formosa University, Taiwan 🇹🇼. With an academic journey grounded in optics and material science, Prof. Liu has established himself as a leader in optoelectronic research 🔬. His scholarly contributions include more than 200 journal and conference papers and five patents 📚📑. His work centers on the deposition of optical and optoelectrical thin films using sputtering and PECVD technologies, contributing to applications such as flexible optoelectronic packaging, transparent conductive electrodes, and ZnO-based LEDs 💡. Passionate about innovation, Prof. Liu continues to advance functional thin film technologies and inspire the next generation of scientists 🌟.

PROFILE 

ORCID

🔍 Summary of Suitability:

Prof. Liu exemplihttps://chemicalscientists.com/?p=13828&preview=truefies excellence in both the depth and breadth of research. With over 200 peer-reviewed publications, 5 patents, and two decades of experience, he has demonstrated consistent innovation and impact in the field of optical sciences and electro-optical engineering. His research outcomes have been widely cited, indicating recognition and relevance within the international scientific community. As a full professor and research leader, his mentorship, international collaborations, and pioneering work in thin-film technologies and ZnO-based devices highlight his remarkable academic influence.

📘 Education & Experience

🎓 Prof. Day-Shan Liu earned his Ph.D. in Optical Sciences from National Central University in January 2003 🎓. Following his doctoral studies, he embarked on a distinguished academic career that led him to become a full Professor at National Formosa University in February 2011 👨‍🏫. He serves within the Department of Electro-Optical Engineering and the Institute of Electro-Optical and Materials Science 🏫. Over the years, Prof. Liu has built an impressive portfolio of scholarly output, publishing over 200 research papers and holding five patents 📄📘. His expertise spans optical thin films, nano-materials, and optoelectronics, particularly in thin-film deposition methods like sputtering and PECVD ⚙️. His lab focuses on practical and theoretical advances that enable novel applications in flexible electronics and photonic devices 💡. With his deep-rooted experience and unwavering dedication, Prof. Liu plays a vital role in Taiwan’s research and academic landscape 🌏.

📈 Professional Development

📈 Prof. Day-Shan Liu has demonstrated a remarkable trajectory of professional development since earning his doctorate in Optical Sciences in 2003 🎓. Over the past two decades, he has transitioned from an emerging scholar to a well-established academic leader and innovator 🌟. At National Formosa University, he not only teaches and mentors but also leads cutting-edge research in optical and functional thin films 🌐. His proficiency in advanced deposition techniques like sputtering and PECVD has positioned him at the forefront of electro-optical engineering 🛠️. Through interdisciplinary collaboration and continuous innovation, he has expanded his impact across materials science, optoelectronics, and nanotechnology 💻🔬. With a portfolio of 200+ publications, five patents, and multiple international presentations, Prof. Liu actively contributes to the global academic community 🌍. His focus on sustainability and next-gen device fabrication underscores his vision of aligning technological progress with real-world needs 🌿.

Research Focus 🔍🤖

🔬 Prof. Day-Shan Liu’s research focus lies at the intersection of optical thin films, functional materials, and optoelectronic device engineering 🎯. His core expertise involves the development and low-temperature deposition of Transparent Conductive Oxide (TCO) films for applications in flexible displays and transparent electronics 📱💡. He explores ZnO-based optoelectronic devices, including innovative light-emitting diodes (LEDs), emphasizing energy efficiency and cost-effectiveness 🔋✨. His group also pioneers in surface modification layers for enhancing super-hydrophilicity, vital in photocatalytic and anti-fog applications 🌊🧪. Another research thrust includes nanoparticles and their functional integration in thin film technologies for smart devices 🔍📉. By mastering deposition techniques such as sputtering and PECVD, Prof. Liu advances OLED packaging and thin-film stability for real-world applications 📦🔧. His research not only pushes boundaries in material science but also contributes to emerging solutions in sustainable and flexible electronics 🌱📲.

Awards and Honors 🏆🎖️

  • 🧪 Over 200 peer-reviewed publications in journals and conferences

  • 🛠️ Holder of 5 patents in the field of thin film technology and optoelectronics

  • 👨‍🏫 Promoted to Professor at National Formosa University (Feb. 2011)

  • 📢 Recognized speaker and contributor at numerous international scientific forums

  • 🌟 Acknowledged for research excellence in ZnO-based LEDs and TCO films

Publications & Citations 📚

  • 🔬 Thermal stability of indium tin oxide thin films co‑sputtered with zinc oxide (2008) – cited ~49 times 📈 medjrf.com+12researchgate.net+12ouci.dntb.gov.ua+12

  • 🧪 Microstructure investigations of indium tin oxide films co‑sputtered with zinc oxide at room temperature (May 2006) – cited ~17 times 📉 researchgate.net+1researchgate.net+1

  • Electrical, Optical and Material Properties of ZnO‑Doped Indium‑Tin Oxide Films Prepared Using RF Magnetron Cosputtering System at Room Temperature (Mar 2006) – cited ~23 times 📊 ouci.dntb.gov.ua+3researchgate.net+3researchgate.net+3

  • 🧩 Investigation on the Deposition of an AlN‑ZnO/ZnO/AlN‑ZnO Double Heterojunction Structure Using RF Magnetron Cosputtering (Aug 2019) – cited ~3 times ✨ researchgate.net+4researchgate.net+4ouci.dntb.gov.ua+4

  • 🎯 Guided‑mode resonance pressure sensor based on a stretchable LDPE film (Jul 2022) – research interest; citations not specified yet 📡

🔍 Conclusion:

Prof. Day-Shan Liu stands out as an ideal recipient of the Best Researcher Award. His outstanding scholarly output, practical innovations in optoelectronics, and dedication to advancing scientific knowledge make him a role model in the academic community. His research not only contributes to theoretical advancements but also addresses real-world technological challenges—firmly establishing his candidacy for this prestigious honor. 🌟👏

Chuanlin Wang | Materials Chemistry | Best Researcher Award

Published on by Chemical Scientist

Dr. Chuanlin Wang | Materials Chemistry | Best Researcher Award

Director of Smart Construction Major at Shantou University, China.

🔬 Short Biography 🌿💊📚

Dr. Chuanlin Wang 🎓 is a distinguished civil engineer and researcher currently serving as a Lecturer in the Department of Civil and Environmental Engineering at Shantou University, China 🇨🇳. With a strong academic background in civil engineering, he earned his Ph.D. from the University of Leeds 🇬🇧 and his B.A. from the Dalian University of Technology 🇨🇳. His professional focus centers around innovative concrete materials 🧱, particularly in enhancing performance under marine conditions 🌊. Dr. Wang’s work contributes significantly to developing ultra-high-performance concrete, fiber-reinforced composites, and structure enhancement techniques. His impactful research is backed by key provincial grants 🧪 and has led to numerous peer-reviewed publications 📚 in international journals. Passionate about infrastructure durability and sustainability, he explores corrosion mechanisms, admixtures, and prefabricated building technologies. Dr. Wang continues to drive scientific progress in concrete technology, influencing structural resilience and green building practices globally 🌍.

PROFILE 

ORCID 

🔍 Summary of Suitability:

Dr. Chuanlin Wang combines top-tier academic credentials (Ph.D. from University of Leeds 🎓) with a proven track record as a Lecturer at Shantou University 🏫. His specialized focus on marine-durable concretes and advanced cementitious composites directly addresses critical infrastructure challenges 🌊🧱. Consistent success in securing competitive provincial grants 💰 and leading interdisciplinary teams 🤝 demonstrates both vision and leadership—key traits of an outstanding researcher.

📘 Education & Experience

🎓 Education:

  • 📘 Ph.D. in Civil Engineering – University of Leeds, UK (2012.9 – 2016.9)

  • 📗 B.A. in Civil Engineering – Dalian University of Technology, China (2007.9 – 2012.6)

🧑‍🏫 Professional Experience:

  • 🏫 Lecturer, Department of Civil and Environmental Engineering, Shantou University (2017.2 – Present)

Professional Development 🚀📖

Dr. Chuanlin Wang’s professional development reflects a deep dedication to both academic excellence and engineering innovation 🏗️. After earning his doctoral degree in the UK 🇬🇧, he returned to China to serve at Shantou University, where he nurtures talent and leads cutting-edge research in civil engineering 🏢. Over the years, he has built expertise in concrete performance improvement, particularly in challenging marine environments 🌊. His collaborative and interdisciplinary research includes state-funded projects focusing on sulphoaluminate cement, fiber-reinforced materials, and prefabricated structures 🧪. With numerous high-impact publications in international journals 📖, Dr. Wang remains engaged in knowledge dissemination and professional growth. His development is marked by a clear trajectory toward enhancing structural durability and resilience, while supporting sustainable infrastructure goals 🌱. Through ongoing grants, mentoring, and academic contributions, he continually upgrades his skills and impact in both educational and research domains 📚🧑‍🔬.

Research Focus 🔍🤖

Dr. Chuanlin Wang’s research focuses on advanced concrete materials within civil engineering 🧱. He is particularly interested in the behavior of concrete exposed to marine environments 🌊, where corrosion and durability are key challenges. His work explores the development of ultra-high-performance concrete (UHPC) and fiber-reinforced materials 🧵 that offer enhanced mechanical properties and longevity. Additionally, Dr. Wang is an expert in sulphoaluminate cement systems, which are known for rapid strength gain and environmental benefits ♻️. His recent studies investigate the impact of salt ions and seawater concentration on cement hydration and durability, making valuable contributions to marine construction technology 🚢. Prefabricated building systems 🏗️ and structural reinforcement techniques are also central to his interests, aligning with global efforts in sustainable and resilient infrastructure development. By integrating materials science and structural design, Dr. Wang advances the frontiers of construction engineering with a focus on performance, sustainability, and innovation 🌍.

Awards and Honors 🏆🎖️

🏅 Awards & Recognitions:

  • 🧪 2023: Grant from Guangdong Provincial Natural Science Foundation – ¥100,000

  • 🔬 2021: Awarded Guangdong Provincial Junior Innovative Talents Project – ¥30,000

  • 📑 Multiple publications in high-impact journals like Materials, Construction and Building Materials, and Journal of Materials in Civil Engineering

Publications & Citations 📚

  1. 📘 2025 | Seawater-Activated Mineral Synergy in Sulfoaluminate Cement: Corrosion Resistance Optimization via Orthogonal Design 🔬

  2. 📗 2024 |  Multi-technique Analysis of Seawater Impact on Calcium Sulphoaluminate Cement Mortar 🧪

  3. 📘 2025 |  Influence of Seawater and Salt Ions on the Properties of Calcium Sulfoaluminate Cement 🌊

  4. 📙 2016 | Retrofitting of Masonry Walls Using a Mortar Joint Technique; Experiments and Numerical Validation 🏗️

  5. 📕 2021 |  Influence of Steel Fiber Shape and Content on the Performance of Reactive Powder Concrete (RPC) 🧵

  6. 📘 2021 | Influence of Seawater Concentration on Early Hydration of CSA Cement – A Preliminary Study ⚗️

  7. 📘 2021 |Seismic Performance of Precast Columns with Two Different Connection Modes 🚧

🔍 Conclusion:

With a record of groundbreaking research, successful funding, and dedication to education and sustainability, Dr. Wang exemplifies the qualities of a “Best Researcher.” His work not only deepens scientific understanding but also delivers practical solutions for resilient, eco-conscious infrastructure 🌍🏆.