Chandramouli Subramaniam
Affiliations: | 2014- | Indian Institute of Technology Bombay, Mumbai, Maharashtra, India |
Area:
Properties and behaviour of nanomaterialsWebsite:
https://www.chem.iitb.ac.in/csubbu/Google:
"Chandramouli Subramaniam"Mean distance: (not calculated yet)
Parents
Sign in to add mentor| Thalappil Pradeep | grad student | 2008 | Indian Institute of Technology Madras |
Children
Sign in to add trainee| Mohammed Aslam | grad student | IIT Bombay | |
| Nikita Chitre | grad student | IIT Bombay | |
| Vibhav Damodar | grad student | IIT Bombay | |
| Itisha Dwivedi | grad student | IIT Bombay | |
| Sudeshna Mondal | grad student | IIT Bombay | |
| Poulomi Nandi | grad student | IIT Bombay | |
| Ananya Sah | grad student | IIT Bombay | |
| Gitika Rani Saha | grad student | IIT Bombay | |
| Jayeeta Saha | grad student | IIT Bombay | |
| Shraddha Shinde | grad student | IIT Bombay | |
| Mihir Kumar Jha | grad student | 2015-2021 | IIT Bombay |
| Pramiti Hui | post-doc | IIT Bombay | |
| Rajeshkhanna Gadam | post-doc | 2019-2019 | IIT Bombay |
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Publications
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| Sah A, Sharma S, Saha S, et al. (2023) Phonon-Engineered Hard-Carbon Nanoflorets Achieving Rapid and Efficient Solar-Thermal Based Water Evaporation and Space-Heating. Acs Applied Materials & Interfaces. 15: 43810-43821 |
| Dwivedi I, Sarkar A, Rajaraman G, et al. (2022) Electric-Field-Induced Solid-Gas Interfacial Chemical Reaction in Carbon Nanotube Ensembles: Route toward Ultra-sensitive Gas Detectors. Acs Applied Materials & Interfaces. 14: 13271-13279 |
| Dwivedi I, Subramaniam C. (2021) Joule Heating-Driven Transformation of Hard-Carbons to Onion-like Carbon Monoliths for Efficient Capture of Volatile Organic Compounds. Acs Materials Au. 2: 154-162 |
| Mondal S, Subramaniam C. (2021) Scalable approach towards specific and ultrasensitive cation sensing under harsh environmental conditions by engineering the analyte-transducer interface. Nanoscale Advances. 3: 3752-3761 |
| Jha MK, Subramaniam C. (2021) Design Principles for Manipulating Electrochemical Interfaces in Solid-State Supercapacitors for Wearable Applications. Acs Omega. 6: 7970-7978 |
| Jha MK, Babu B, Parker B, et al. (2020) Hierarchically engineered nanocarbon florets as bifunctional electrode material for adsorptive and intercalative energy storage. Acs Applied Materials & Interfaces |
| Mondal S, Subramaniam C. (2020) Xenobiotic Contamination of Water by Plastics and Pesticides Revealed through Real-Time, Ultrasensitive, and Reliable Surface-Enhanced Raman Scattering Acs Sustainable Chemistry & Engineering. 8: 7639-7648 |
| Jha MK, Ball R, Seelaboyina R, et al. (2020) All Solid-State Coaxial Supercapacitor with Ultrahigh Scan Rate Operability of 250 000 mV/s by Thermal Engineering of the Electrode–Electrolyte Interface Acs Applied Energy Materials. 3: 3454-3464 |
| Jha MK, Jain T, Subramaniam C. (2020) Origami of Solid-State Supercapacitive Microjunctions Operable at 3 V with High Specific Energy Density for Wearable Electronics Acs Applied Electronic Materials. 2: 659-669 |
| Mukherjee A, Majumdar R, Saha SK, et al. (2020) Performance evaluation of an open thermochemical energy storage system integrated with flat plate solar collector Applied Thermal Engineering. 173: 115218 |