Rammohan Sriramdas
Rammohan Sriramdas
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Exceeding milli-watt powering magneto-mechano-electric generator for standalone-powered electronics
V Annapureddy, SM Na, GT Hwang, MG Kang, R Sriramdas, H Palneedi, ...
Energy & Environmental Science 11 (4), 818-829, 2018
Performance enhancement of piezoelectric energy harvesters using multilayer and multistep beam configurations
R Sriramdas, S Chiplunkar, RM Cuduvally, R Pratap
IEEE Sensors Journal 15 (6), 3338-3348, 2015
Lead-free piezoelectric materials and composites for high power density energy harvesting
D Maurya, M Peddigari, MG Kang, LD Geng, N Sharpes, V Annapureddy, ...
Journal of Materials Research 33 (16), 2235-2263, 2018
High Power Magnetic Field Energy Harvesting through Amplified Magneto‐Mechanical Vibration
MG Kang, R Sriramdas, H Lee, J Chun, D Maurya, GT Hwang, J Ryu, ...
Advanced Energy Materials 8 (16), 1703313, 2018
Energy harvesting and strain sensing in smart tire for next generation autonomous vehicles
D Maurya, P Kumar, S Khaleghian, R Sriramdas, MG Kang, RA Kishore, ...
Applied Energy 232, 312-322, 2018
Broadband dual phase energy harvester: Vibration and magnetic field
HC Song, P Kumar, R Sriramdas, H Lee, N Sharpes, MG Kang, D Maurya, ...
Applied Energy 225, 1132-1142, 2018
3D printed graphene-based self-powered strain sensors for smart tires in autonomous vehicles
D Maurya, S Khaleghian, R Sriramdas, P Kumar, RA Kishore, MG Kang, ...
Nature communications 11 (1), 1-10, 2020
Scaling and performance analysis of MEMS piezoelectric energy harvesters
R Sriramdas, R Pratap
Journal of Microelectromechanical Systems 26 (3), 679-690, 2017
Crumpled sheets of reduced graphene oxide as a highly sensitive, robust and versatile strain/pressure sensor
S Kundu, R Sriramdas, KR Amin, A Bid, R Pratap, N Ravishankar
Nanoscale 9 (27), 9581-9588, 2017
Large Power Amplification in Magneto‐Mechano‐Electric Harvesters through Distributed Forcing
R Sriramdas, MG Kang, M Meng, M Kiani, J Ryu, M Sanghadasa, S Priya
Advanced Energy Materials 10 (8), 1903689, 2020
Maximizing power generation from ambient stray magnetic fields around smart infrastructures enabling self-powered wireless devices
H Lee, R Sriramdas, P Kumar, M Sanghadasa, MG Kang, S Priya
Energy & Environmental Science 13 (5), 1462-1472, 2020
Linear thermomagnetic energy harvester for low-grade thermal energy harvesting
RA Kishore, D Singh, R Sriramdas, AJ Garcia, M Sanghadasa, S Priya
Journal of Applied Physics 127 (4), 044501, 2020
An experimentally validated lumped circuit model for piezoelectric and electrodynamic hybrid harvesters
R Sriramdas, R Pratap
IEEE Sensors Journal 18 (6), 2377-2384, 2017
Bismuth Telluride/Half‐Heusler Segmented Thermoelectric Unicouple Modules Provide 12% Conversion Efficiency
W Li, B Poudel, A Nozariasbmarz, R Sriramdas, H Zhu, HB Kang, S Priya
Advanced Energy Materials 10 (38), 2001924, 2020
Self‐Powered Red/UV Narrowband Photodetector by Unbalanced Charge Carrier Transport Strategy
Y Hou, C Wu, X Huang, D Yang, T Ye, J Yoon, R Sriramdas, K Wang, ...
Advanced Functional Materials, 2007016, 2020
Nature of terrace edge states (TES) in lower-dimensional halide perovskite
K Wang, T Wu, C Wu, R Sriramdas, X Huang, K Wang, Y Jiang, H Liu, ...
Journal of Materials Chemistry A 8 (16), 7659-7670, 2020
Design considerations for optimal absorption of energy from a vibration source by an array of harvesters
R Sriramdas, S Rastogi, R Pratap
Energy Harvesting and Systems 3 (2), 121-131, 2016
Vibrational energy harvesting: Design, performance and scaling analysis
R Sriramdas
Indian Institute of Science, 2016
Understanding the Low Frequency Response of Carbon Nanotube Thermoacoustic Projectors
P Kumar, R Sriramdas, AE Aliev, JB Blottman, NK Mayo, RH Baughman, ...
Journal of Sound and Vibration, 115940, 2021
Universal Multienergy Harvester Architecture
R Sriramdas, D Yang, MG Kang, M Sanghadasa, S Priya
ACS Applied Materials & Interfaces, 2020
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