Raja Shekhar Kondrapolu Data-verified
Affiliation confirmed via AI analysis of OpenAlex, ORCID, and web sources.
Researcher
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Research Areas
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Biography and Research Information
OverviewAI-generated summary
Raja Shekhar Kondrapolu, a graduate student at the University of Arkansas at Little Rock, focuses on electrocatalysis for energy conversion and carbon dioxide utilization. His research spans diverse areas, including conducting polymers, fuel cell materials, asymmetric hydrogenation, and click chemistry. Kondrapolu also investigates heterocyclic compound synthesis, chemical synthesis and analysis, HER2/EGFR in cancer research, and lung cancer treatments and mutations. His recent work includes exploring enhanced oxygen reduction reactions using a non-precious electrocatalyst derived from nanocellulose, dopamine, and a cobalt complex. He has also published on natural amino acid-derived iron(III) catalysts for green oxidation chemistry and pincer nickel(II)-catalyzed oxidative carbonylation of amines for isocyanate and urea synthesis. His primary research interests lie in catalysis and energy conversion.
Metrics
- h-index: 1
- Publications: 3
- Citations: 7
Selected Publications
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Synthesis of Indole-Thiazolidinedione-1,2,3-triazole Conjugates as Tubulin Polymerization Inhibitors and Some in silico Studies (2025)
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Natural Amino Acid-Derived Iron(III) Catalysts for Green Oxidation Chemistry Applications (2025)
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Synthesis and in-vitro anti-EGFR screening of new 1,2,3-triazole-benzimidazole hybrids and insilico studies (2025)
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Pincer Nickel(II) Catalyzed Oxidative Carbonylation of Amines: A Phosgene-Free Synthesis for Isocyanates and Ureas (2025)
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Exploring Enhanced Oxygen Reduction Reactions: A Study on Nanocellulose, Dopamine, and Cobalt Complex-Derived Non-Precious Electrocatalyst (2024)
Collaboration Network
Top Collaborators
- Exploring Enhanced Oxygen Reduction Reactions: A Study on Nanocellulose, Dopamine, and Cobalt Complex-Derived Non-Precious Electrocatalyst
- Natural Amino Acid-Derived Iron(III) Catalysts for Green Oxidation Chemistry Applications
- Exploring Enhanced Oxygen Reduction Reactions: A Study on Nanocellulose, Dopamine, and Cobalt Complex-Derived Non-Precious Electrocatalyst
- Pincer Nickel(II) Catalyzed Oxidative Carbonylation of Amines: A Phosgene-Free Synthesis for Isocyanates and Ureas
- Pincer Nickel(II) Catalyzed Oxidative Carbonylation of Amines: A Phosgene-Free Synthesis for Isocyanates and Ureas
- Natural Amino Acid-Derived Iron(III) Catalysts for Green Oxidation Chemistry Applications
- Exploring Enhanced Oxygen Reduction Reactions: A Study on Nanocellulose, Dopamine, and Cobalt Complex-Derived Non-Precious Electrocatalyst
- Exploring Enhanced Oxygen Reduction Reactions: A Study on Nanocellulose, Dopamine, and Cobalt Complex-Derived Non-Precious Electrocatalyst
- Exploring Enhanced Oxygen Reduction Reactions: A Study on Nanocellulose, Dopamine, and Cobalt Complex-Derived Non-Precious Electrocatalyst
- Exploring Enhanced Oxygen Reduction Reactions: A Study on Nanocellulose, Dopamine, and Cobalt Complex-Derived Non-Precious Electrocatalyst
- Exploring Enhanced Oxygen Reduction Reactions: A Study on Nanocellulose, Dopamine, and Cobalt Complex-Derived Non-Precious Electrocatalyst
- Exploring Enhanced Oxygen Reduction Reactions: A Study on Nanocellulose, Dopamine, and Cobalt Complex-Derived Non-Precious Electrocatalyst
- Pincer Nickel(II) Catalyzed Oxidative Carbonylation of Amines: A Phosgene-Free Synthesis for Isocyanates and Ureas
- Natural Amino Acid-Derived Iron(III) Catalysts for Green Oxidation Chemistry Applications
- Natural Amino Acid-Derived Iron(III) Catalysts for Green Oxidation Chemistry Applications
- Natural Amino Acid-Derived Iron(III) Catalysts for Green Oxidation Chemistry Applications
- Natural Amino Acid-Derived Iron(III) Catalysts for Green Oxidation Chemistry Applications