PATENT :

1. A system for monitoring solar photovoltaic based on IOT technology,  Application No.-20224100105, Publication Date-21.01.2022 (Patent)
2. Smart street lamps with monitoring, navigation and mechanism to support sanitization needs, Application No.-202221061828, Filled-31.10.2022 (Patent)
3. Solar Photovoltaics Current-Voltage Measuring Device, Application No. 353697-001, Accepted date – 13.01.2022 (Design Application)
4. Solar powered building monitoring device, Application No. 362438-001, Accepted date – 27.06.2022 (Design Application)
5. Device to detect electrical characteristics, Application No. 366558-001, Accepted date – 29.09.2022 (Design Application)
6. Intelligent Plant Pot with Self Sustaining System,Application No. 372566-001, Accepted date – 30.12.2022 (Design Application)
7. Smart Pot for Automatic Water Dispension, Application No. 385161-001, Accepted date – 17.08.2023 (Design Application)

SCI/SCOPUS PAPER

1. Agrawal,A., Siddiqui,S.A., Soni,A., and Sharma,G.D., 2022. Advancements, frontiers and analysis of metal oxide semiconductor, dye, electrolyte and counter electrode of dye sensitized solar cell, Solar Energy 223, Elsevier pp.378-407.

2. Agrawal, A., Siddiqui, S.A., Soni, A., Khandelwal, K. and Sharma, G.D., 2021. Performance analysis of TiO2 based dye sensitized solar cell prepared by screen printing and doctor blade deposition techniques. Solar Energy, Elsevier, 226, pp.9-19.

3. Agrawal, A., Tomar, N., Dhaka, V.S. and Surolia, P.K., (2020) Ruthenium complexes based dye sensitized solar cells: Fundamentals and research trends. Solar Energy, Elsevier, 207, pp.59-76.

4. Schlachter, A., Marineau-Plante, G., Harvey, P.D., Agrawal, A. and Sharma, G.D., (2022). Efficient ternary bulk heterojunction organic solar cells using a low-cost nonfullerene acceptor. Journal of Materials Chemistry C, 10(11), pp.4372-4382.

5. Dahiya, H., Agrawal, A., Sharma, G.D. and Singh, A.K., 2022. Organic bulk heterojunction enabled with nano capsules of hydrate vanadium pentaoxide layer for high responsivity self-powered photodetector. Journal of Semiconductors, 43(9), pp.092302-1.

6. Pradhan, R., Agrawal, A., Bag, B. P., Singhal, R., Sharma, G. D., & Mishra, A. 2022. High-Efficiency Ternary Organic Solar Cells Enabled by Synergizing Dicyanomethylene-Functionalized Coumarin Donors and Fullerene-Free Acceptors. ACS Applied Energy Materials, 5(7), 9020-9030.

7. Keshtov, M.L., Konstantinov, I.O., Kuklin, S.A., Davydova, N.K., Alekseev, V.G., Xie, Z., Agrawal, A. and Sharma, G.D., 2022. New wide-bandgap D–A polymer based on pyrrolo [3, 4-b] dithieno [2, 3-f: 3′, 2′-h] quinoxalindione and thiazole functionalized benzo [1, 2-b: 4, 5- b′] dithiophene units for high-performance ternary organic solar cells with over 16% efficiency. Sustainable Energy & Fuels, 6 (3), pp. 682-692.

8. Li, P., Wu, F., Fang, Y., Dahiya, H., Keshtov, M.L., Xu, H., Agrawal, A. and Sharma, G.D., 2022. Truxene π-Expanded BODIPY Star-Shaped Molecules as Acceptors for Non-Fullerene Solar Cells with over 13% Efficiency. ACS Applied Energy Materials, 5 (2), pp. 2279-2289

9. Sharma, G.D., Agrawal, A., Pradhan, R., Keshtov, M.L., Singhal, R., Liu, W., Zhu,X. and Mishra,A., 2021. Fullerene-Free All-Small-Molecule Ternary Organic Solar Cells with Two Compatible Fullerene-Free Acceptors and a Coumarin Donor Enabling a Power Conversion Efficiency of 14.5%. ACS Applied Energy Materials, 4(10), pp.11537-11544.

10. Privado, M., Agrawal, A., de la Cruz, P., Keshtov, M.L., Sharma, G.D. and Langa, F., 2021. Noncovalent Conformational Locks Enabling Efficient Nonfullerene Acceptors. Solar RRL, pp.2100768.

11. Keshtov M.L., Kuklin S.A., Agrawal A., Dahiya H., Chen F.C., Sharma G.D., (2021) Ternary polymer solar cells based on wide bandgap and narrow bandgap nonfullerene acceptors with an efficiency of 16.40 % and low energy loss of 0.53 eV, Materials Today Energy, Elsevier, pp. 100843.

12. Keshtov M.L., Kuklin S.A., Zou Y., Dahiya H., Agrawal A., Sharma G.D., (2021) Wide bandgap D-A copolymers with same medium dithieno [2,3-e;3’2’-g]isoindole-7,9 (8H) acceptor and different donors for high-performance fullerene free polymer solar cells with efficiency up to 14.76%, Chemical Engineering Journal, Elsevier, 131404, pp. 1385-8947.

13. Cai, F., Guo, Y., Fang, Y., Gros, C.P., Agrawal, A., Sharma, G.D. and Xu, H., 2021. New BODIPY derivatives with triarylamine and truxene substituents as donors for organic bulk heterojunction photovoltaic cells. Solar Energy, 227, pp.354-364.

14. Keshtov, M.L., Konstantinov, I.O., Godovsky, D.Y., Ostapov, I.E., Alekseev, V.G., Agrawal, A., Dahiya, H. and Sharma, G.D., 2022. Energy Technology.

15. Banerjee, P., Roy, S., Sinha, A., Hassan, M.M., Burje, S., Agrawal, A., Bairagi, A.K., Alshathri, S. and El-Shafai, W., 2023. MTD-DHJS: Makespan-Optimized Task Scheduling Algorithm for Cloud Computing with Dynamic Computational Time Prediction. IEEE Access.

16. Keshtov, M.L., Konstantinov, I.O., Kuklin, S.A., Zou, Y., Agrawal, A., Chen, F.C. and Sharma, G.D., 2021. Binary and Ternary Polymer Solar Cells Based on a Wide Bandgap DA Copolymer Donor and Two Nonfullerene Acceptors with Complementary Absorption Spectral. ChemSusChem, 14 (21), pp. 4731-4740.

17. Barla, R., Lochab, B., Agrawal, A., Mishra, A., Keshtov, M.L. and Sharma, G.D., Incorporation of a Guaiacol Based Small Molecule Guest Donor Enables Efficient Nonfullerene Acceptor Based Ternary Organic Solar Cells. Solar RRL, Wiley, p.2100402.

CONFERENCE PUBLICATION

1. Agrawal A., Siddiqui S.A., Soni A., Sharma G.D., 2022. A Facile route synthesis for Pure and Ag doped ZnO for Dye sensitized Solar Cell. Flexible Electronics for Electric Vehicles, Lecture Notes in Electrical Engineering, Springer, vol. 863, pp. 465-473.
2. Sharma, P.K., Singh, M.K., Sharma, G.D. and Agrawal A., (2021) NiO nanoparticles: Facile route synthesis, characterization and potential towards third generation solar cell. Materials Today: Proceedings, 43, pp. 3061-3065. (Impact factor – 1.8)
3. Agrawal A., Siddiqui, S.A., Soni, A., Sharma, G.D. and Shrivastava, D.R. (2020) ZnO nanoparticles based dye sensitized solar cell: Fabrication and characterization. In AIP Conference Proceedings, vol. 2294, pp. 030005. AIP Publishing LLC. (Impact factor – 0.4)
4. Agrawal, A., Siddiqui, S.A., Soni, A., Sharma, G.D., (2020). Recent Development in Perovskite Solar Cell Based on Planar Structures. Intelligent Computing Techniques for Smart Energy Systems. Lecture Notes in Electrical Engineering, vol 607. Springer, Singapore. (Impact factor – 0.34)
5. Agrawal, A., Siddiqui, S.A., Soni, A., Sharma, G.D., (2020). Device Modeling and Characteristics of Solution-Processed Perovskite Solar Cell at Ambient Conditions. Intelligent Computing Techniques for Smart Energy Systems. Lecture Notes in Electrical Engineering, vol 607. Springer, Singapore. (Impact factor – 0.34)

BOOK PUBLISHED

Fundamental of Power Electronics and Application, GCS Publisher, ISBN No. 978819631251

BOOK CHAPTER

1. Dadarya D., Sinha A., M., Agrawal, A., Jain T., Gupta R.,Shekhawat R. S. (2023). Supervised Machine Learning and Deep Learning Methods for Yield Forecasting, Precision Agriculture for Sustaninability (Use of Smart Sensors, Actuators and Decision Support Systems), CRC Press, Taylor and Francis Group, ISBN: 971774913734.

2. Kumar, P., Sheoran, M., Agrawal, A., Soni, A., &Sahariya, J. (2023). End Life Cycle Cost-Benefit Analysis of 160 kW Grid-Integrated Solar Power Plant: BSDU Jaipur Campus. In Energy Conversion and Green Energy Storage, CRC Press, Taylor and Francis Group, pp. 43-56, ISBN: 9781003258209.