1.Effect of ionomer content on performance of Direct Methanol Fuel cells, Balaji Krishnamurthy, S.Deepalochani and K.S.Dhathatreyan, Fuel cells, Volume 8, Issue 6, Pages 404-409, (2009);
2.Effect of PTFE content on performance of Direct Methanol fuel cells, Balaji Krishnamurthy and S.Deepalochani, International Journal of Hydrogen Energy, 34(2009) 446-452.
3.An Experimental analysis of Platinum Utilization in Direct Methanol fuel cells, Balaji Krishnamurthy and S.Deepalochani, Journal of Applied Electrochemistry, Vol 39, Issue 7, 1003, (2009);
4.Performance of Platinum Black and Supported Platinum catalysts in a Direct Methanol fuel cell, Balaji Krishnamurthy, International Journal of Electrochemical Science, 4, (2009), 386-395;
5.A Capacity fade model for lithium ion batteries including diffusion and kinetics, ShriHari Sankarasubramaniam and Balaji Krishnamurthy, Electrochimica Acta, Volume 70, 30 May 2012, Pages 248-254;
6.An Empirical rate constant based model to study capacity fading in lithium ion batteries, Srivatsan Ramesh and Balaji Krishnamurthy, International Journal of Electrochemistry, Volume 2015, Article ID 439015;
7.A Mathematical model to study the capacity fading in lithium ion batteries-formation and dissolution reactions, Srivatsan Ramesh and Balaji Krishnamurthy, Journal of Electrochemical Society, 162(4), A 545(2015);
8. Modeling the effect of potential drop across the SEI layer on the performance of lithium ion batteries, Saksham Phul, Abhishek Deshpande and Balaji Krishnamurthy, Electrochimica Acta, 164, 281 (2015).
9. A generalized mathematical model to study capacity fading in lithium ion batteries-Effect of Solvent and lithium transport, Journal of Electrochemical Science and Engineering, 2015, 10.5599/jese.197.
10.Transient Analysis of DMFC anode, Sai Darshan and Balaji Krishnamurthy, Electrochimica Acta, 191,(2016), 317.
11. Effect of acid attack on the capacity fading in lithium ion batteries, Rohit Singhvi, Rohit Nagpal and Balaji Krishnamurthy, J. Electrochemical Society, 163,(7) A1-A5 (2016).
12. Modeling the performance of an enzymatic glucose fuel cell, Soham Jariwala and Balaji Krishnamurthy, J. of Electroanalytical Chemistry, 801 (2017), 354-359.
13. Analyzing the leakage current in a DMFC, Deeksha Reddy and Balaji Krishnamurthy, J. of Solid State Electrochemistry, DOI.10.1007/s 10008-017-3739-4.
14. Screening Pencil leads coated with MWCNT and PANI as enzymatic bio fuel cell (EBFC) cathode, Madhavi B, B.Krishnamurthy and Sanket Goel, International Journal of Hydrogen Energy, 42, 2017,44, 27220-27229.
15. Modeling the temperature distribution in a Direct Methanol fuel cell, Vaideeswaran Ramesh and B. Krishnamurthy, Journal of Electroanalytical Chemistry, 809 (2018), 1-7.
16. Transport equation in a enzymatic glucose fuel cell, S. Jariwala and B.Krishnamurthy, Chemical Physics letters,
692, (2018), 7-13.
17. Modeling the performance of direct carbon fuel cells, International Journal of hydrogen Energy, K. Maheshwari, A. Sen and B. Krishnamurthy, 43, (2018), 20077-20085.
18. Functionalized and enhanced HB pencil graphite as bio anode for glucose oxygen bio fuel cells, IEEE sensors, M. Bandapathi, P. Rewatkar, B. Krishnamurthy and S. Goel, 3, 802-811, 2019.
19. Modeling the concentration of gases in the anode of a Direct Carbon fuel cells, Rizwan Kareemi and B. Krishnamurthy, Journal of Electroanalytical Chemistry, 834,(2019), 167-172.
20. Fully assembled membraneless glucose bio fuel cells with MWCNT modified Pencil graphite leads as novel bio electrodes, M.Bandapati, B.Krishnamurthy and S.Goel, IEEE transaction on Nanobioscience, DOI:10.1109/TNB
2019, 2896207.
21. A review of catalyst utilization in PEM and Direct Methanol fuel cells, M.Bandapati, S. Goel and B.Krishnamurthy, J.Electrochem.Sci.Eng, (2019); doi; 10.5599/jese.665.
22. Parametric modeling of microbial fuel cells, Amandeep Singh and B. Krishnamurthy, JESE, 2019, doi:10.5599/jese671
23. Modeling the leakage current in a Solid oxide fuel cell, B. Krishnamurthy and R. Hariharan, Journal of Electrochemical Science and Engineering, JESE,2020, http://dx.doi.org/10.5599/jese.770
24. Pencil graphite electrodes as anodes for enzymatic bio fuel cells, M.Bandapati, S. Goel and B. Krishnamurthy, Journal of Electrochemical Science and Engineering, http://dx/doi.org/10.5599/jese.807
25. E-coli fed paper based microfluidic microbial fuel cell with MWCNT composed bucky paper bioelectrodes,
D. Nath, Sai Kiran, P. Rewatkar, B. Krishnamurthy, S. Ganesh and S.Goel, IEEE Transactions on NanoBioscience, vol. 18, no. 3, pp. 510-515, 2019.
26. Modeling the effect of GDL porosity on high temperature fuel cells , V. Jha, R. Hariharan and B. Krishnamurthy, Internatational Journal of Heat and Mass transfer, 161,(2020), 120311.
27. Modeling the effect of rib width and channel dimensions on the performance of high temperature fuel cells, V.Jha and B. Krishnamurthy,
DOI: https://doi.org/10.5599/jese.907.
28.Modeling the performance of DC SOFC-Anode Supported configuration, S.Raj, S.Gnanasundaram, B.Krishnamurthy, Journal of Electrochemical Science and Engineering, http://dx.doi.org/10.5599/jese.933(2021)
29. Modeling the concentration profiles of CO,CO2 in the anode of a DC SOFC,S. Raj, S.Gnanasundaram, B.Krishnamurthy, Ionics, https://doi.org/10.1007/s11581-020-03834-9.
30. Investigations of structural and residual trapping phenomena during CO2 sequestration in Deccan Volcanic of the Saurastra region, Gujarat, P.R. Punnam, B. Krishnamurthy and V.K. Surasani, International Journal of Chemical Engineering,
https://doi.org/10.1155/2021/7762127.
31.
A 3-dimensional mathematical model to study the effect of geometrical parameters on performance of Solid oxide fuel cell, V.Jha, V.K. Surasani and B. Krishnamurthy, published in Journal of Electrochemical Science and Engineering, DOI: https://doi.org/10.5599/jese.109732. Modeling the effect of anode particle radius and reaction rate constant on loss of cyclable Li in capacity fading of Li-ion batteries, V. Jha and B. Krishnamurthy, JESE, https:doi.org/10.5599/jese.1147 (2021)
33. Modeling the effect of acid attack on the capacity fading in lithium ion batteries under conditions of cycling, V. Jha and B. Krishnamurthy, Ionics,(2022) https://doi.org/10.1007/s11581-022-04457-y.
34. Modeling the SEI layer formation and its growth in lithium ion batteries during charge discharge cycling, V. Jha and B. Krishnamurthy, Ionics, http://doi.org. 10.1007/s11581-022-04617-0.
35. Modeling the pressure drop in Vanadium redox flow batteries-Serpentine configuration, S. Yadav and B. Krishnamurthy, under review.
36. Modeling the velocity profiles in Vanadium redox flow batteries-Serpentine Configuration, S.Yadav and B.Krishnamurthy accepted in Journal of Electrochemical Science and Engineering.
37. Modeling the pressure drop in Vanadium redox flow batteries-Interdigitated configuration, S. Yadav and B. Krishnamurthy Accepted in E prime, Advances in Electrical Engineering, Electronics and Energy.
38. Modeling the velocity profiles in a Vanadium redox flow batteries-Interdigitated configuration, S.Yadav and B.Krishnamurthy under review.
Patent:
A system and method for electric power and process thereof for manufacturing the system, Indian Patent application, 201711046160, S.Goel, P.Rewatkar, M. Bandapati and B. Krishnamurthy (2018).