Tshifhiwa Masikhwa | Materials Chemistry | Best Researcher Award

Published on by Chemical Scientist

Best Researcher Award

Tshifhiwa Masikhwa β€” 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

Emil Babić | Materials Chemistry | Best Researcher Award

Published on by Chemical Scientist

Prof. Dr. Emil Babić | Materials Chemistry | Best Researcher Award

professor |Β  University of Zagreb | Croatia

Prof. Emil Babić is a distinguished Croatian physicist with a long and impactful career in condensed matter physics and materials science. Educated at the Faculty of Science, University of Zagreb, he went on to become a leading academic and researcher, contributing significantly to the study of high-entropy alloys, metallic glasses, and superconducting materials. His work has been published in high-impact journals, with over 50 years of scholarly contributions shaping the field. Prof. Babić has played a central role in mentoring generations of physicists, guiding around 50 theses, 13 doctoral dissertations, and 5 post-doctoral fellows. His expertise in electronic structures, alloy behavior, and advanced materials has been widely recognized through his publications and collaborations with international research groups. With a career that spans fundamental discoveries and applied innovations, Prof. Babić stands as a respected figure in Croatian and global physics, celebrated for his scientific rigor, mentorship, and dedication to advancing knowledge.

Professional ProfileΒ 

Prof. Emil BabiΔ‡ pursued his entire academic education at the Faculty of Science, University of Zagreb, Croatia, where he developed a deep foundation in physics. He earned his Master of Science degree in Physics , marking the beginning of his lifelong journey into advanced materials and solid-state research. His early academic training combined theoretical and experimental approaches, equipping him with the tools to explore the structural and electronic properties of complex alloys and materials. Building on his master’s research, he later obtained a PhD in Physics from the same institution, further cementing his expertise in condensed matter physics. His doctoral work laid the groundwork for his future research on metallic glasses, high-entropy alloys, and superconductivity. The rigorous academic environment of Zagreb’s Faculty of Science, combined with his own intellectual curiosity, enabled him to emerge as a scientist of international recognition, contributing broadly to physics and material sciences.

ExperienceΒ 

Prof. Emil Babić has accumulated decades of rich academic and research experience, primarily within the Department of Physics, Faculty of Science, University of Zagreb. His career spans during which he served in both teaching and research positions. He has been a central figure in advancing Croatian physics research, contributing not only through publications but also by actively participating in collaborative international projects. Prof. Babić has mentored around 50 theses, 13 doctoral dissertations, and 5 post-doctoral researchers, leaving a strong academic legacy. His expertise has led him to engage in groundbreaking studies on superconductivity, metallic glasses, and high-entropy alloys, often collaborating with prominent international scientists. In addition to research, he has played an essential role in curriculum development, conference participation, and the organization of scientific activities, thus enriching the academic and research landscape in Croatia and beyond. His experience reflects both leadership and innovation.

Professional Development

Throughout his career, Prof. Emil Babić has actively pursued professional development, ensuring continuous growth as a researcher, mentor, and collaborator. He has remained engaged with the international scientific community by publishing influential research articles, contributing to conferences, and co-authoring studies with physicists from Europe and beyond. His professional journey also included securing academic scholarships and participating in exchange programs, which broadened his perspective on global scientific challenges. Importantly, Prof. Babić fostered a strong academic culture within the University of Zagreb, promoting interdisciplinary approaches to physics and materials science. He also took on organizational roles in scientific conferences, strengthening the visibility of Croatian research in the global arena. By mentoring young researchers and doctoral candidates, he continuously developed his leadership and supervisory skills, adapting to evolving methodologies in physics. His career reflects a balance of independent research, collaborative teamwork, and dedication to professional growth within academia.

Skills & Expertise

Prof. Emil Babić’s expertise spans a broad spectrum of condensed matter physics and materials science, with particular specialization in high-entropy alloys, metallic glasses, superconductivity, and electronic structures. His deep knowledge of advanced experimental techniques has enabled him to study phase transitions, bulk glass-forming ability, and the role of doping in improving material properties. His expertise extends to both theoretical analysis and laboratory-based experimentation, making him a versatile scientist. In addition, Prof. BabiΔ‡ has demonstrated strong mentorship and supervisory skills, having guided numerous graduate and doctoral students toward successful academic careers. He is adept at collaborative, cross-disciplinary research, working with international teams on complex projects. His ability to bridge fundamental physics with applied research highlights his innovative approach. Moreover, his publication record showcases his capacity to contribute impactful insights into material design, alloy characterization, and superconductivity, solidifying his reputation as a skilled and knowledgeable leader in his field.

Resarch Focus

Prof. Emil Babić’s research focus lies primarily in condensed matter physics, with an emphasis on metallic glasses, high-entropy alloys, and superconducting materials. His studies investigate the structural, electronic, and magnetic properties of these complex systems, aiming to understand their behavior under varying physical conditions. A recurring theme in his research is the transition from high-entropy to conventional alloys, where he has explored questions of stability, performance, and material optimization. Additionally, he has studied the enhancement of superconducting properties through nanostructuring and doping, contributing valuable insights to applied physics. His work is not only of theoretical importance but also holds technological significance, particularly in energy storage, advanced materials, and industrial applications. By publishing in leading journals and collaborating with international experts, Prof. BabiΔ‡ has advanced the global understanding of how alloys can be designed and manipulated to achieve desirable physical and functional properties.

Awards & Recognitions

Prof. Emil Babić’s long and impactful career has been recognized through academic honors, scholarships, and professional achievements. Over the past five decades, he has received recognition for both his scientific output and his contributions to academic mentorship. His research has been published in high-impact journals such as Journal of Applied Physics, Materials, Journal of Alloys and Compounds, and Europhysics Letters, which itself is a recognition of the international value of his work. He has also been invited to collaborate with international teams, highlighting his reputation as a trusted expert in physics. At the University of Zagreb, his role in mentoring over 50 theses and 13 doctoral dissertations has been celebrated as a vital contribution to the academic community. Furthermore, his involvement in organizing scientific conferences and contributing to research networks has earned him respect and acknowledgment, both within Croatia and internationally, as a leader in condensed matter physics.

Publication Top NotesΒ 

Title: Mechanism of Enhancement in Electromagnetic Properties of MgB2 by Nano SiC Doping
Authors: SX Dou, O Shcherbakova, WK Yoeh, JH Kim, S Soltanian, XL Wang, E Babić
Year: 2007
Citations: 370

Title: High-transport critical current density above 30 K in pure Fe-clad MgB2 tape
Authors: S Soltanian, XL Wang, I Kuőević, E Babić, AH Li, MJ Qin, J Horvat, HK Liu
Year: 2001
Citations: 232

Title: Superconductivity in zirconium-nickel glasses
Authors: E Babić, R Ristić, M Miljak, MG Scott, G Gregan
Year: 1981
Citations: 75

Title: Production of large samples of ultra-rapidly quenched alloys of aluminium by means of a rotating mill device
Authors: E Babić, E Girt, R Krsnik, B Leontic
Year: 1970
Citations: 64

Title: Correlation between doping induced disorder and superconducting properties in carbohydrate doped MgB2
Authors: JH Kim, SX Dou, S Oh, M JerčinoviΔ‡, E BabiΔ‡, T Nakane, H Kumakura
Year: 2008
Citations: 58

Title: Temperature dependent impurity resistivity in Al-based 3-d transition metal alloys
Authors: E BabiΔ‡, R Krsnik, B LeontiΔ‡, M Očko, Z VučiΔ‡, I ZoriΔ‡, E Girt
Year: 1972
Citations: 50

Title: Hall effect and electronic structure of glassy Zr 3d alloys
Authors: J Ivkov, E Babić, RL Jacobs
Year: 1984
Citations: 49

Title: Sugar as an optimal carbon source for the enhanced performance of MgB2 superconductors at high magnetic fields
Authors: OV Shcherbakova, AV Pan, JL Wang, AV Shcherbakov, SX Dou, E Babić
Year: 2008
Citations: 47

Title: Stoner excitations in the strong itinerant amorphous ferromagnets FexNi80βˆ’xB18Si2 and Fe80B20
Authors: E Babić, Ž Marohnić, EP Wohlfarth
Year: 1983
Citations: 43

Title: The influence of pinning centres on magnetization and loss in Fe-Ni-B-Si amorphous alloys
Authors: J Horvat, Ž Marohnić, E Babić
Year: 1989
Citations: 42

Title: Magnetoresistance and V-I curves of Ag-sheathed (Bi,Pb tape)
Authors: E Babić, I Kuőević, SX Dou, HK Liu, QY Hu
Year: 1994
Citations: 41

Title: Synthesis, structural characterization and magnetic properties of iron boride nanoparticles with or without silicon dioxide coating
Authors: M Mustapić, D Pajić, N Novosel, E Babić, K Zadro, M Cindrić, J Horvat
Year: 2010
Citations: 38

Title: Correlation between mechanical, thermal and electronic properties in Zr–Ni, Cu amorphous alloys
Authors: R RistiΔ‡, M Stubičar, E BabiΔ‡
Year: 2007
Citations: 38

Title: Phase transformations during isochronal annealing of Fe40Ni40B20 glass
Authors: M Stubičar, E BabiΔ‡, D SubaΕ‘iΔ‡, D Pavuna, Ε½ MarohniΔ‡
Year: 1977
Citations: 38

Prof. Emil Babić demonstrates exceptional research excellence in condensed matter physics and materials science, with impactful publications, mentorship achievements, and contributions to alloy and superconductivity research. His long-standing academic leadership and pioneering studies on metallic glasses and high-entropy alloys position him as a highly deserving candidate for the Best Researcher Award. Strengthening industry impact and international recognition could further solidify his profile, but his current record already reflects outstanding scientific excellence and influence.

Fa-Feng Xu | Materials Chemistry | Chemical Scientist Award

Published on by Chemical Scientist

Dr. Fa-Feng Xu | Materials Chemistry | Chemical Scientist Award

assistant researcher, Qinghai Institute of Salt Lakes, Chinese Academy of Sciences inΒ  China.

πŸ”¬ Short BiographyΒ πŸŒΏπŸ’ŠπŸ“š

Dr. Fa-Feng Xu πŸ§ͺ is an accomplished researcher specializing in photonic materials and microlasers. He currently serves as an Assistant Research Fellow at the Key Laboratory of Green and High-End Utilization of Salt Lake Resources, Qinghai Institute of Salt Lakes, Chinese Academy of Sciences πŸ‡¨πŸ‡³. He earned his Ph.D. in Physical Chemistry from the Institute of Chemistry, Chinese Academy of Sciences in 2020 πŸŽ“, following his bachelor’s degree in Material Chemistry from Jilin University in 2014. His postdoctoral work at the same institute focused on material engineering under the supervision of renowned scholars. Dr. Xu’s interdisciplinary research integrates chemistry, materials science, and photophysics to develop advanced optical devices such as microlaser arrays for applications in displays and encryption. With multiple high-impact publications and patents, Dr. Xu is a rising talent in the field of optoelectronic materials 🌟.

PROFILEΒ 

OrcidΒ 

πŸ” Summary of Suitability:

Based on the provided CV, Dr. Fa-Feng Xu is a highly suitable candidate for the Chemical Scientist Award. His academic training and professional journey demonstrate a profound command over physical chemistry, material science, and photochemistryβ€”disciplines central to the chemical sciences. Dr. Xu holds a Ph.D. in Physical Chemistry from the Chinese Academy of Sciences and has engaged in impactful postdoctoral research in materials engineering. He has consistently worked on the synthesis and functionalization of advanced photonic materials, particularly organometallic complexes and organic microlasers, which are at the cutting edge of chemical innovation.

πŸ”Ή Education & ExperienceΒ 

Dr. Xu’s academic journey began at Jilin University, where he earned his Bachelor’s degree in Material Chemistry in 2014 πŸŽ“. He then pursued a Ph.D. in Physical Chemistry at the Institute of Chemistry, Chinese Academy of Sciences, mentored by distinguished professors including Academician Jiannian Yao 🧬. His research focused on photochemistry and organic photonic materials. After earning his doctorate in 2020, Dr. Xu continued as a Postdoctoral Fellow in Material Engineering at the same institute, collaborating with Prof. Yu-Wu Zhong. Since November 2023, he has been serving as an Assistant Research Fellow at the Qinghai Institute of Salt Lakes, Chinese Academy of Sciences, contributing to the sustainable utilization of salt lake resources 🧫. His career reflects deep expertise across disciplines including chemistry, optics, and nanomaterials, shaping innovations in photonic applications πŸ’‘.

πŸ”ΉProfessional Development

Dr. Fa-Feng Xu has developed a robust professional skill set grounded in multidisciplinary science πŸ§ͺ. His expertise spans organic synthesis, materials design, and photonic device fabrication. With a strong foundation in chemistry and materials science, he designs and synthesizes organometallic and liquid crystal systems with high-performance photonic properties 🌈. He is skilled in fabricating organic microlasers and constructing patterned microlaser arrays for advanced applications like laser displays and information encryption πŸ”. Dr. Xu is adept in characterizing materials using techniques such as UV-Vis, SEM, TEM, XRD, and AFM. His practical experience extends to the use of cutting-edge instrumentation including electron beam lithography and femtosecond lasers for device testing. Through collaborations and continuous research, he brings innovation to organic photonics, contributing significantly to applied optical science and advanced materials development 🎯.

πŸ› οΈ Skills & Expertise

Dr. Fa-Feng Xu possesses a diverse set of interdisciplinary research skills that bridge the fields of chemistry, photophysics, and materials science πŸ§ͺπŸ”¬. He is proficient in the synthesis, purification, and analysis of organic and organometallic compounds, including platinum and iridium complexes and liquid crystal systems 🌈. His expertise extends to designing and fabricating organic microlaser arraysβ€”such as microdisks, microspheres, and microplatesβ€”for applications in laser displays and information encryption πŸ–₯οΈπŸ”. Dr. Xu is skilled in preparing polymer-based microstructures using materials like PS and PMMA for high-performance waveguiding and lasing functions ⚑. He is also experienced in constructing and characterizing inorganic nanostructures, such as silver nanowires 🧫. Technically adept, he operates advanced instruments including SEM, TEM, AFM, XRD, and UV-Vis for structural and optical characterization πŸ› οΈ. Furthermore, his familiarity with cutting-edge device fabrication techniquesβ€”such as vacuum deposition, lithography, and femtosecond lasersβ€”enables innovative work at the frontier of organic photonics and materials science πŸš€.

πŸ”¬ Research Focus

Dr. Xu’s research is centered on the intersection of organic photonics, microlasers, and advanced optical materials 🌟. He focuses on the rational design and synthesis of organometallic compounds (notably Pt and Ir complexes), liquid crystal systems, and polymeric microstructures for photonic applications. His work includes fabricating two-dimensional microcrystals and wavelength-tunable microlaser arrays, which find use in full-color laser displays and encrypted information systems πŸ–₯οΈπŸ”’. Dr. Xu also explores waveguiding phenomena and the development of photonic materials with thermal and optical responsiveness, bridging chemistry, optics, and device engineering. His contributions reflect a broader interest in next-generation optoelectronics, nonlinear optics, and nanostructured materials. The integration of organic systems into functional devices highlights his forward-thinking approach in applied physical chemistry and materials innovation πŸ”¬βœ¨.

πŸ† Awards & Recognitions

  • πŸ₯‡ Excellent Paper Certificate, 8th CAST Excellent Scientific Paper Selection Program

  • πŸŽ“ Merit Student, University of Chinese Academy of Sciences (UCAS), 2014–2015

  • πŸ† Outstanding Student Leader, UCAS, 2015–2016

  • πŸ’° Academic Scholarships, UCAS (2014–2019)

  • πŸŽ–οΈ National Encouragement Scholarships, Jilin University (2010–2012)

  • 🌟 Excellence Scholarship Student, Jilin University, 2010–2011

Publications & Citations πŸ“š

  1. πŸ“ Organoplatinum(II) Cruciform: A Versatile Building Block to Fabricate 2D Microcrystals with Full-Color and White Phosphorescence and Anisotropic Photon Transport, Angew. Chem. Int. Ed. πŸ“… 2022 | πŸ” Cited by: [citation data needed] πŸŒˆπŸ“Έ

  2. πŸ“ Wavelength-Tunable Single-Mode Microlasers Based on Photoresponsive Pitch Modulation of Liquid Crystals for Information Encryption, Research πŸ“… 2020 | πŸ” Cited by: [citation data needed] πŸ”’πŸ“‘

  3. πŸ“ Flat-Panel Laser Displays Based on Liquid Crystal Microlaser Arrays, CCS Chem. πŸ“… 2020 | πŸ” Cited by: [citation data needed] πŸ–₯️🎯

  4. πŸ“ Thermo-Responsive Light-Emitting Metal Complexes and Related Materials, Inorg. Chem. Front. πŸ“… 2020 | πŸ” Cited by: [citation data needed] πŸ”₯πŸ”¬

  5. πŸ“ Molecular Cocrystals with Hydrogen-Bonded Polymeric Structures and Polarized Luminescence, Materials πŸ“… 2022 | πŸ” Cited by: [citation data needed] πŸ’ŽπŸ’‘

  6. πŸ“ Research Progress of Cesium-Based Photonic Materials, J. of Salt Lake Research πŸ“… 2024 | πŸ” Cited by: [citation data needed] πŸ§‚πŸ”

πŸ” Conclusion:

Dr. Xu’s contributions lie at the intersection of synthetic chemistry, optics, and functional materials. His creative solutions to complex challenges in organic photonics and his strong publication and patent record mark him as an emerging leader in chemical research. His profile exemplifies the innovation and interdisciplinary excellence the Chemical Scientist Award aims to recognize.