Kenneth Ikechukwu Ozoemena Explained

Kenneth Ikechukwu Ozoemena
Nationality:Nigerian
Occupation:Physical chemist, materials scientist, and academic
Education:BSc (Hons) in Industrial Chemistry
MSc in Chemistry
MSc in Pharm Chemistry
Ph.D. in Chemistry
Alma Mater:Abia State University
University of Lagos
Rhodes University
University of Pretoria
Thesis Title:Metallophthalocyanines as photocatalysts for transformation of chlorophenols and self-assembled monolayers for electrochemical detection of thiols and cyanides
Thesis Url:http://hdl.handle.net/10962/d1007709
Thesis Year:2003
Workplaces:University of the Witwatersrand
Cornell University

Kenneth Ikechukwu Ozoemena is a Nigerian physical chemist, materials scientist, and academic. He is a research professor at the University of the Witwatersrand (Wits) in Johannesburg[1] where he Heads the South African SARChI Chair in Materials Electrochemistry and Energy Technologies (MEET), supported by the Department of Science and Innovation (DSI), National Research Foundation (NRF) and Wits.[2]

Ozoemena group conducts interdisciplinary research across physics, chemistry, biomedical, chemical, and metallurgical engineering.[1] He has authored numerous peer-reviewed articles,[3] 11 book chapters, and edited books, including Nanomaterials for Fuel Cell Catalysis, and Nanomaterials in Advanced Batteries and Supercapacitors.[4]

Ozoemena became a Fellow of the Royal Society of Chemistry (FRSC) in 2011, Fellow of the African Academy of Sciences (FAAS) in 2015, and a Member of the Academy of Science of South Africa (ASSAf) in 2016.[5] He serves as an Associate Editor for Electrocatalysis[6] and co-Editor-in-Chief of Electrochemistry Communications.[7]

Earl life and education

He is an indigene of Obinikpa Umuokpara, Okohia in Umuna, Onuimo local government area of Imo State, Nigeria. Ozoemena earned his Baccalaureate degree in Industrial Chemistry from the University of Abia in 1992 and went on to receive master's degrees in Chemistry and Pharmaceutical Chemistry in 1997 and 1998, respectively, from the University of Lagos. In 2003, he completed his Ph.D. at Rhodes University in South Africa and served as a Research Fellow at the University of Pretoria.[1]

Career

Following his Ph.D., Ozoemena began his academic career as an Andrew W. Mellon Lecturer of Chemistry at Rhodes University in 2004 and held an appointment at the University of Pretoria as a Senior Lecturer of Chemistry in 2006, and later as Extraordinary Professor of Chemistry from 2009 to 2017. He was also appointed as an Extraordinary Professor of Chemistry at the University of the Western Cape from 2011 to 2014, and an Honorary Professor of Chemistry at the University of the Witwatersrand from 2014 to 2017. Subsequently, in 2017, after about an 8-year stint at the Council for Scientific and Industrial Research (CSIR), he was appointed as professor, and later promoted to research professor at the School of Chemistry of the University of the Witwatersrand.[8] He serves as an Honorary Visiting professor at the Wuhan University of Technology, China.[9] Ozoemena was elected African representative of the International Society of Electrochemistry from 2010 to 2015 and Chair of the Scientific Meeting Committee (SMC) of the International Society of Electrochemistry. He was the Chair of the Organising Committee of the 70th Annual Meeting of the International Society of Electrochemistry (ISE) Durban, the first conference of the ISE on the African continent. Subsequently, he served as the lead Guest Editor of the special issue of the conference in Electrochimica Acta.[10]

Research

Ozoemena has focused his research in the field of materials electrochemistry, with a specific interest in advanced batteries, fuel cells, and electrochemical sensors as the primary aspects of investigation.

Lithium-ion batteries

Ozoemena has worked on improving the structural and electrochemical properties of lithium-ion batteries.[11] [12] One of his innovations include the use of microwave-assisted synthesis[13] [14] to mitigate the problems of manganese dissolution and the so-called Jahn-Teller distortion which conspire against the development and commercialization of high-energy and low-cost manganese-based cathode materials.[15]

Aqueous mobile ion batteries & supercapacitors

Ozoemena's enquiry on the microwave-assisted synthesis and use of low cost and environmentally friendly manganese-based raw materials has led to the discovery of a new strategy of making triplite manganese fluorophosphate.[16] [17] In addition, Ozoemena group has demonstrated that nanostructured manganese-based complexes are promising materials for the development of high-performance supercapacitors and pseudocapacitors.[18] [19]

Fuel cells & electrolyzers

Ozoemena worked on the use of microwave-assisted synthesis to bring about ‘top-down’ nanosizing of palladium catalysts, introducing the term “MITNAD” which is an acronym for “microwave-induced top-down nanostructuring and decoration”.[20] He has continued to explore the application of this technique and related techniques for the development of high-performance electrocatalysts for fuel cells and electrolyzers.[21] [22]

Zinc-ion and rechargeable zinc-air batteries

Ozoemena and collaborators have studied several electrode materials that can enhance the efficacy of zinc-ion and rechargeable zinc-air batteries (RZAB).[23] The key research focus in this field has been to develop real and relevant RZAB technology for stationary and mobile applications.[24]

Electrochemical sensors

Ozoemena has contributed in connecting biomedicine with electrochemistry, resulting in the creation of electrochemical bio- and immuno-sensors capable of detecting diseases that are mostly found in resource-limited countries, including tuberculosis in HIV-positive patients,[25] vibrio cholera toxins in water bodies,[26] substance abuse such as tramadol,[27] and human papillomavirus (HPV) biomarkers for cervical cancer.[28]

Awards and honors

Bibliography

Edited books

Selected articles

Notes and References

  1. Web site: Kenneth Ozoemena. www.wits.ac.za.
  2. Web site: South African Research Chairs Initiative.
  3. Web site: Kenneth Ikechukwu Ozoemena. scholar.google.com.
  4. Web site: Nanostructured platinum-free electrocatalysts in alkaline direct alcohol fuel cells.
  5. Web site: Nanostructured platinum-free electrocatalysts in alkaline direct alcohol fuel cells: catalyst design, principles and application .
  6. Web site: Electrocatalysis. Springer.
  7. Web site: Editorial board – Electrochemistry Communications | ScienceDirect.com by Elsevier. www.sciencedirect.com.
  8. Web site: Ozoemena. African Scientists Directory.
  9. Web site: Advanced Sensors and Energy Materials 编委会又获知名国际科学家加盟!. 知乎专栏.
  10. Electrochemistry: Linking resources to sustainable development (ISE 2019): Foreword. Kenneth I.. Ozoemena. Janice. Limson. Mkhulu K.. Mathe. February 20, 2021. Electrochimica Acta. 370. 137718. ScienceDirect. 10.1016/j.electacta.2021.137718. 234034446 .
  11. Conversion of electrolytic MnO2 to Mn3O4 nanowires for high-performance anode materials for lithium-ion batteries. Nithyadharseni. Palaniyandy. Funeka P.. Nkosi. Kumar. Raju. Kenneth I.. Ozoemena. January 15, 2019. Journal of Electroanalytical Chemistry. 833. 79–92. ScienceDirect. 10.1016/j.jelechem.2018.11.002. 105865267 .
  12. Synthesis, characterisation and electrochemical intercalation kinetics of nanostructured aluminium-doped Li[Li0.2Mn0.54Ni0.13Co0.13]O2 cathode material for lithium ion battery]. Charl J.. Jafta. Kenneth I.. Ozoemena. Mkhulu K.. Mathe. Wiets D.. Roos. December 15, 2012. Electrochimica Acta. 85. 411–422. ScienceDirect. 10.1016/j.electacta.2012.08.074.
  13. Rapidly Microwave-Synthesized SnO2 Nanorods Anchored on Onion-Like Carbons (OLCs) as Anode Material for Lithium-Ion Batteries. Nithyadharseni. Palaniyandy. Mesfin A.. Kebede. Kenneth I.. Ozoemena. Mkhulu K.. Mathe. July 1, 2019. Electrocatalysis. 10. 4. 314–322. Springer Link. 10.1007/s12678-019-0508-4. 104462304 .
  14. Effects of microwave irradiation on the electrochemical performance of manganese-based cathode materials for lithium-ion batteries. Aderemi B.. Haruna. Kenneth I.. Ozoemena. December 1, 2019. Current Opinion in Electrochemistry. 18. 16–23. ScienceDirect. 10.1016/j.coelec.2019.08.005. 202878775 .
  15. Microwave irradiation suppresses the Jahn-Teller distortion in Spinel LiMn2O4 cathode material for lithium-ion batteries. Aderemi B.. Haruna. Dean H.. Barrett. Cristiane B.. Rodella. Rudolph M.. Erasmus. Andrew M.. Venter. Zeldah N.. Sentsho. Kenneth I.. Ozoemena. September 10, 2022. Electrochimica Acta. 426. 140786. ScienceDirect. 10.1016/j.electacta.2022.140786. 250189924 .
  16. Insights into the Synergistic Roles of Microwave and Fluorination Treatments towards Enhancing the Cycling Stability of P2-Type Na0.67[Mg0.28Mn0.72]O2 Cathode Material for Sodium-Ion Batteries. Funeka P.. Nkosi. Kumar. Raju. Nithyadharseni. Palaniyandy. M. V.. Reddy. Caren. Billing. Kenneth I.. Ozoemena. November 2, 2017. Journal of the Electrochemical Society. 164. 13. A3362. 10.1149/2.1721713jes. free.
  17. Fluorinated Mn3O4 nanospheres for lithium-ion batteries: Low-cost synthesis with enhanced capacity, cyclability and charge-transport. Nithyadharseni. Palaniyandy. Funeka P.. Nkosi. Kumar. Raju. Kenneth I.. Ozoemena. April 15, 2018. Materials Chemistry and Physics. 209. 65–75. ScienceDirect. 10.1016/j.matchemphys.2018.01.003.
  18. A high-rate aqueous symmetric pseudocapacitor based on highly graphitized onion-like carbon/birnessite-type manganese oxide nanohybrids. Katlego. Makgopa. Paul. M. Ejikeme. Charl. J. Jafta. Kumar. Raju. Marco. Zeiger. Volker. Presser. Kenneth. I. Ozoemena. September 1, 2015. Journal of Materials Chemistry A. 3. 7. 3480–3490. 10.1039/C4TA06715K. free. 2263/44136. free.
  19. Web site: High-performance symmetric electrochemical capacitor based on graphene foam and nanostructured manganese oxide.
  20. Synthesis of Pd-coated FeCo@Fe/C core–shell nanoparticles: microwave-induced 'top-down' nanostructuring and decoration. Omobosede O.. Fashedemi. Basil. Julies. Kenneth I.. Ozoemena. February 12, 2013. Chemical Communications. 49. 20. 2034–2036. pubs.rsc.org. 10.1039/C3CC38672D. 23381686 .
  21. High-performance aqueous asymmetric electrochemical capacitors based on graphene oxide/cobalt(II)-tetrapyrazinoporphyrazine hybrids. Joel N.. Lekitima. Kenneth I.. Ozoemena. Charl J.. Jafta. Nagao. Kobayashi. Yang. Song. Dennis. Tong. Shaowei. Chen. Munetaka. Oyama. January 29, 2013. Journal of Materials Chemistry A. 1. 8. 2821–2826. pubs.rsc.org. 10.1039/C2TA01325H. 2263/37003 . free.
  22. Influence of Microwave Irradiation and Combustion Fuels on the Rate Capability and Cycle Performance of Li 1.2 Mn 0.52 Ni 0.13 Co 0.13 Al 0.02 O 2 Layered Material. Funeka. Nkosi. Nithyadharseni. Palaniyandy. Kumar. Raju. Kenneth I.. Ozoemena. December 1, 2020. Electroanalysis. 32. 12. 3159–3169. CrossRef. 10.1002/elan.202060373. 226316907 .
  23. Manganese-based bifunctional electrocatalysts for zinc-air batteries. Aderemi B.. Haruna. Kenneth I.. Ozoemena. June 1, 2020. Current Opinion in Electrochemistry. 21. 219–224. ScienceDirect. 10.1016/j.coelec.2020.02.021. 216338418 .
  24. Zinc-Ion Inserted a-MnO2/Onion like Carbon (OLC) Nanorod Composite Cathode Materials for Aqueous Zn-Ion Battery . ECS Meeting Abstracts. 10.1149/ma2018-01/3/254 . 2018 . Palaniyandy . Nithyadharseni . Nkosi . Funeka Phumzile . Raju . Kumar . Ozoemena . Kenneth I. . Mathe . Mkhulu K. . 3 . 254 .
  25. Recognition of anti-mycolic acid antibody at self-assembled mycolic acid antigens on a gold electrode: a potential impedimetric immunosensing platform for active tuberculosis. Nsovo S.. Mathebula. Jeseelan. Pillay. Gianna. Toschi. Jan A.. Verschoor. Kenneth I.. Ozoemena. June 5, 2009. Chemical Communications. 23. 3345–3347. pubs.rsc.org. 10.1039/B905192A. 19503865 . 2263/14544 . free.
  26. Onion-like carbon re-inforced electrospun polyacrylonitrile fibres for ultrasensitive electrochemical immunosensing of Vibrio cholerae toxin. Okoroike C.. Ozoemena. Nsovo S.. Mathebula. Tobechukwu J.. Ehirim. Tobile. Maphumulo. Goodness M.. Valikpe. Jerry L.. Shai. Kenneth I.. Ozoemena. October 1, 2020. Electrochimica Acta. 356. 136816. ScienceDirect. 10.1016/j.electacta.2020.136816. 225507256 .
  27. Onion-like Carbons Provide a Favorable Electrocatalytic Platform for the Sensitive Detection of Tramadol Drug. Tobechukwu J.. Ehirim. Okoroike C.. Ozoemena. Patrick V.. Mwonga. Aderemi B.. Haruna. Thapelo P.. Mofokeng. Karolien. De Wael. Kenneth I.. Ozoemena. December 27, 2022. ACS Omega. 7. 51. 47892–47905. 10.1021/acsomega.2c05722. 36591171. 9798499.
  28. Electrochemical Immunosensor for Ultra-Low Detection of Human Papillomavirus Biomarker for Cervical Cancer. Siwaphiwe. Peteni. Okoroike C.. Ozoemena. Tobile. Khawula. Aderemi B.. Haruna. Frankie J.. Rawson. Leshweni J.. Shai. Oluwafunmilola. Ola. Kenneth I.. Ozoemena. July 28, 2023. ACS Sensors. 8. 7. 2761–2770. 10.1021/acssensors.3c00677. 37384904. 10391710.
  29. Updated science-wide author databases of standardized citation indicators. John P. A.. Ioannidis. Kevin W.. Boyack. Jeroen. Baas. October 16, 2020. PLOS Biology. 18. 10. e3000918. 10.1371/journal.pbio.3000918. 33064726. 7567353 . free .