Journal publications

 

  1. Controlling the Potential of Affordable Quasi-Solid Composite Gel Polymer Electrolytes for High-Voltage Lithium-Ion Batteries; Govind Kumar Mishra, Manoj Gautam, K. Bhawana, Manisha Patro, Shishir Kumar Singh, and Sagar Mitra; accepted in Batteries & Supercaps; 2nd Feb 2024.
  2. Unravelling Redox Phenomenon and Electrochemical Stability of Li1.6Al0.5Ge1.5P2.9Si0.1O12 Solid Electrolyte Against Li Metal and Silicon Anodes for Advanced Solid-State Batteries; Supriya Sau, Manas Ranjan Panda, Gayatree Barik, Manoj Gautam, Md. Adil, S.N. Jha, and Sagar Mitra; Materials Today Energy, accepted on 19th Oct 2023.
  3. Endorsing Na+ Storage Mechanism in Low Tortuosity, High Plateau Capacity Hard Carbon Towards Development of High-Performance Sodium-ion Pouch Cells; K Bhawana, Manoj Gautam, Govind Kumar Mishra, Nilanjan Chakrabarty, S Wajhal, Dhruv Kumar, Dimple P. Dutta and Sagar Mitra; Carbon 214, 118319, 2023.
  4. Design of Low-Stress Robust Silicon and Silicon-Carbide Anode with High Areal Capacity and High Energy Density for Next-Generation Lithium-Ion Batteries; Manoj Gautam, Govind Kumar Mishra, Mohammad Furquan, K Bhawana, Dhruv Kumar and Sagar Mitra, Chemical Engineering Journal 472, 144916, 2023.
  5. Energy Density Lithium-Ion Pouch Cell with Modified High Voltage Lithium Cobalt Oxide Cathode and Graphite Anode: Prototype Stabilization, Electrochemical and Thermal Study; Govind Mishra; Manoj Gautam; K Bhavana; Jit Ghosh; Sagar Mitra; Journal of Power Sources 580, 233395, 2023.
  6. Transition Metal Nitrides: An Emerging Nanostructured Materials for Oxygen Electrocatalysis; Nadeema Ayesha, Aakash Ahuja and Sagar Mitra; ChemistrySelect 8 (29), e202300885, 2022.
  7. Germanium-Free Dense Lithium Superionic Conductor and Interface Re-Engineering for All-Solid-State Lithium Batteries against High Voltage Cathode” Mishra, Govind; Gautam, Manoj; Bhawana, K; Chakrabarty, Nilanjan; Mitra, Sagar; ACS Applied Materials & Interfaces 15 (8), 10629-10641, 2022.
  8. Lower Diffusion-Induced Stress in Nano-crystallites of P2-Na2/3Ni1/3Mn1/2Ti1/6O2 Novel Cathode for High Energy Na-ion Batteries; Abhinanda Sengupta, Ajit Kumar, Gayatree Barik, Aakash Ahuja, Jit Ghosh, Harshita Lohani, Pratima Kumari, Tanmay K. Bhandakkar and Sagar Mitra; Small 19 (12), 2206248, 2022.
  9. Regulating Polysulfide Conversion Kinetics Using Tungsten Diboride as Additive For High-Performance Li–S Battery;Tuhin Subhra Sahu, Abhijitha V G, Ipsita Pal, Supriya Sau, Manoj Gautam, Birabar R. K. Nanda, Sagar Mitra; Small 18 (41), 2203222, 2022
  10. Artificial Organo-Fluoro-Rich Anode Electrolyte Interface and Partially Sodiated Hard Carbon Anode for Improved Cycle Life and Practical Sodium-Ion Batteries; Harshita Lohani, Ajit Kumar, Pratima Kumari, Aakash Ahuja, Manoj Gautam, Abhinanda Sengupta, and Sagar Mitra; ACS Applied Materials & Interfaces, 14, 33, 37793-37803, 2022.
  11. An Excellent and Fast Anode for Lithium-Ion Batteries Based on 1T’–MoTe2 Phase Material” Authors: Panda, Manas; Sau, Supriya; Gangwar, Rashmi; Pandey, Dhanshree; Muthuraj, Divyamahalakshmi; Chen, Wanqing; Chakrabarti, Aparna; Banerjee, Arup; Sagdeo, Archna; Bao, Qiaoliang; Majumder, Mainak; Mitra, Sagar; ACS Applied Energy Materials; 5, 8, 9625-9640,2022.
  12. Single‐Crystal Spinel Li1.08Mn1.92O4 octahedra cathode covered with Li-ion permeable robust NMC thin-layer protection for high voltage lithium‐ion batteries ; Aakash Ahuja, Ajit Kumar, Abhinanda Sengupta, Manoj Gautam, Harshita Lohani, Pratima Kumari and Sagar Mitra; Energy Storage Materials 52, 169-179, 2022.
  13. A comprehensive study of sodium copper hexacyanoferrate, as a sodium-rich low-cost positive electrode for sodium-ion batteries” Adil, Md; Sau, Supriya; Darmmala, Pradeep; Mitra, Sagar; Energy & Fuels 36 (14), 7816-7828, 2022.
  14. Sodium-Ion Batteries: Chemistry of Biomass Derived Disordered Carbon in Carbonate and Ether-based electrolytes; K Bhawana, Amlan Roy, Nilanjan Chakrabarty, Manoj Gautam, Dimple P. Dutta* and Sagar Mitra*; Electrochimica Acta 425, 140744, 2022.
  15. Non-Aqueous Rechargeable Calcium-ion Batteries Based on High Voltage Zirconium-doped Ammonium Vanadium Oxide Cathode; Md Adil; Ananta Sarkar; Supriya Sau; Divyamahalakshmi Muthuraj; Sagar Mitra; Journal of Power Sources 541, 231669, 2022.
  16. Water-in-salt electrolyte-based extended voltage range, safe, and long cycle life aqueous calcium-ion cells” by Adil, Md.; Ghosh, Arpita; Mitra, Sagar; ACS Applied Materials & Interfaces 14 (22), 25501-25515, 2022.
  17. Direct Contact Prelithiation of Si-C Anode Study as a Function of Time, Pressure, Temperature and the Cell Ideal Time; Gautam, Manoj; Mishra, Govind; Ahuja, Aakash; Sau, Supriya; Furquan, Mohammad; Mitra, Sagar; ACS Applied Materials & Interfaces 14 (15), 17208-17220, 2022.
  18. Enhanced electrochemical properties of W-doped Na3V2(PO4)2F3@C as cathode material in sodium ion batteries; Jeffry Nongkynrih;Abhinanda Sengupta; Brindaban Modak; Sagar Mitra; A.K.Tyagi; Dimple P.Dutta: Electrochimica Acta 415, 140256, 2022.
  19. Electrocatalytic Activity of Polyaniline in Magnesium-Sulfur Batteries: Krishna, Murali; Ghosh, Arnab; Muthuraj, Divyamahalakshmi; Das, Sharmistha; Mitra, Sagar, J. Phys. Chem. Lett. 13, 5, 1337–1343, 2022.
  20. Surface Modified Lithium Cobalt Oxide (LiCoO2) with Enhanced Performance at higher rates through Li-vacancy Ordering in Monoclinic Phase” by Mishra, Govind; Gautam, Manoj; Sau, Supriya; Mitra, Sagar; ACS Appl. Energy Mater., 4, 12, 14260–14272, 2021.
  21. Zirconium-doped Vanadium oxide and Ammonium linked Layered cathode to construct a full-cell magnesium-ion battery: A Structural and Electrochemical Study; Divyamahalakshmi Muthuraj, Ananta Sarkar, Manas Ranjan Panda, Md. Adil, Archna Sagdeo, and Sagar Mitra, Accepted in Batteries & Supercaps; 12 August 2021.
  22. Sub-zero and room-temperature sodium–sulfur battery cell operations: A rational current collector, catalyst and sulphur-host design and study; Ajit Kumar, Arnab Ghosh, Arpita Ghosh, Aakash Ahuja, Abhinanda Sengupta, Maria Forsyth,*, Douglas R. MacFarlane,* and Sagar Mitra,*; Energy Storage Materials: 42, 608-617, 2021 (IF 17.789)
  23. Electrochemical properties of biomass-derived carbon and its composite along with Na 2 Ti 3 O 7 as potential high-performance anodes for Na-ion and Li-ion batteries; Manas Ranjan Panda, Anish Raj Kathribail, Brindaban Modak, Supriya Sau, Dimple P. Dutta*, Sagar Mitra*; Electrochimica Acta; 392, 139026, 2021.
  24. Simple route to Lithium dendrite prevention for long cycle-life lithium metal batteries; Arnab Ghosh, Pavel Cherepanov, Cuong Nguyen, Arpita Ghosh, Ajit Kumar, Aakash Ahuja, Mega Kar, Douglas R. MacFarlane, Sagar Mitra; Applied Materials Today; 23, 101062, 2021.
  25. Sodium-ion Battery full-cell study with Molybdenum selenide-porous carbon [NC@MoSe2@rGO] composite anode and intercalated sodium vanadium fluorophosphate [Na3(VO)2(PO4)2F] cathode; Amlan Roy, Ananta Sarkar, Md. Adil, Supriya Sau, N. Abharana and Sagar Mitra; Batteries&Supercaps; 4 (6), 978-988, 2021.
  26. Approach to increase the utilization of active material in a high sulfur-loaded cathode for high areal capacity room-temperature sodium-sulfur batteries; Kumar, Ajit; Ghosh, Arnab; Ghosh, Arpita; Ahuja, Aakash; Forsyth, Maria; MacFarlane, Douglas; Mitra, Sagar; ACS Appl. Energy Mater. 4(1), 384–393, 2021.
  27. Magnesium polysulfide catholyte (MgSx): Synthesis, electrochemical and computational study for magnesium-sulfur battery application; Divyamahalakshmi Muthuraj; Madhu Pandey; Murali Krishna; Raja Sen; Priya Johari; Arnab Ghosh and Sagar Mitra,; J. Power Sources, 486, 229326, 2021.
  28. Mechanical and the Electrochemical Stability Improvement of SiC-Reinforced Si-based Composite Anode for Li-ion Battery by Furquan, Mohammad; Jangid, Manoj; K, Anish Raj; Savithri, Vijayalakshmi; Mukhopadhyay, Amartya; Mitra, Sagar, ACS Applied Energy Materials, 3(12), 12613–12626,2020.
  29. Unique Structure-induced Magnetic and Electrochemical Activity in Nanostructured Transition metal Tellurates Co1-xNixTeO4 (x = 0, 0.5, and 1); Patel, Akhilesh Kumar; Panda, Manas; Rani, Ekta; Singh, Harishchandra; Samatham , S. ; Nagendra, Abharana; Jha, Sambhu Nath; Bhattacharyya, Dibyendu; Suresh, Krishnawarrier; Mitra, Sagar; ACS Appl. Energy Mater. 2020, 3, 9, 9436–9448.
  30. Lewis acid-base interactions between polysulfides and boehmite enables stable room-temperature sodium–sulfur batteries; Arnab Ghosh, Ajit Kumar, Tisita Das, Arpita Ghosh, Sudip Chakraborty, Mega Kar, Douglas R. MacFarlane and Sagar Mitra*; Adv. Funct. Mater.;2005669,2020. (IF 16.836)
  31. High Performance Lithium-Ion Batteries Using Layered 2H-MoTe2 as Anode; Manas Ranjan Panda, Rashmi Gangwar, Divyamahalakshmi Muthuraj, Supriya Sau, Dhanshree Pandey, Arup Banerjee, Aparna Chakrabarti, Archna Sagdeo, Matthew Weyland, Mainak Majumder, Qiaoliang Bao, Sagar Mitra*; Small; 16, 2002669,2020. (IF 11.459)
  32. Free-radical catalysis and the enhancement of the redox kinetics for room-temperature sodium-sulfur batteries: Kumar, Ajit; Ghosh, Arnab; Forsyth, Maria; Macfarlane, Douglas; Mitra, Sagar; ACS Energy Letters, 5, 6, 2112–2121 2020. (IF 19.00)
  33. Ultrathin lithium aluminate nanoflakes inlaid sulfur as cathode material for lithium–sulfur batteries with high areal capacity; Arnab Ghosh, Ajit Kumar, Amlan Roy, Cuong Nguyen, Aakash Ahuja, Md Adil, Manjunath Chatti, Mega Kar, Douglas R MacFarlane, Sagar Mitra; ACS Applied Energy Materials 2020.
  34. Halogen-free flame-retardant sulfur copolymers with stable Li–S battery performance; M Monisha, P Preetham, A Ghosh, A Kumar, S Zafar, S Mitra, B Lochab; Energy Storage Materials 29, 350-360, 2020.
  35. A novel chemical reduction/co-precipitation method to prepare sulfur functionalized reduced graphene oxide for lithium-sulfur batteries; PH Wadekar, A Ghosh, RV Khose, DA Pethsangave, S Mitra, S Some; Electrochimica Acta, 136147, 2020.
  36. A simple approach to minimize the first cycle irreversible loss of sodium titanate anode towards the development of sodium-ion battery; A Sarkar, CV Manohar, S Mitra; Nano Energy 70, 104520, 2020.
  37. Atomic layer deposition of nitrogen incorporated molybdenum oxide: Unveiling carrier transport mechanism and its application in Li-ion battery; A Dhara, D Saha, S Mitra, SK Sarkar; Journal of Vacuum Science & Technology A: Vacuum, Surfaces, and Films 38 (2), 022409, 2020.
  38. Chemically sodiated ammonium vanadium oxide as a new generation high-performance cathode; A Sarkar, S Mitra; Journal of Power Sources 452, 227832, 2020.
  39. Practical Aqueous Calcium-Ion Battery Full-Cells for Future Stationary Storage; M Adil, A Sarkar, A Roy, MR Panda, A Nagendra, S Mitra; ACS Applied Materials & Interfaces 12 (10), 11489-11503, 2020.
  40. High-Potential Cathode for Sodium-Ion Battery; A Sarkar, P Raj, MR Panda, S Mitra; Advances in Energy Research, Vol. 1, 371-377, 2020.
  41. Carbon Derived from Sucrose as Anode Material for Lithium-Ion Batteries; R Kumar, KA Raj, S Mitra, P Bhargava; Journal of Electronic Materials 48 (11), 7593-7593, 2019.
  42. Sodium-Ion Battery Anode Stabilization; PK Dutta, A Ghosh, S Mitra; Nanomaterials for Electrochemical Energy Storage Devices, 377, 2019.
  43. High-energy density room temperature sodium-sulfur battery enabled by sodium polysulfide catholyte and carbon cloth current collector decorated with MnO2 nanoarrays; A Kumar, A Ghosh, A Roy, MR Panda, M Forsyth, DR MacFarlane, S Mitra; Energy Storage Materials 20, 196-202, 2019.
  44. Sulfur, Nitrogen Dual Doped Reduced Graphene Oxide Supported Two‐Dimensional Sb2S3 Nanostructures for the Anode Material of Sodium‐Ion Battery; S Bag, A Roy, S Mitra; ChemistrySelect 4 (22), 6679-6686, 2019
  45. Nanostructured vanadium tri-oxides, as a long life and high performance anode for sodium-ion battery; A Sarkar, AK Sinha, S Mitra; Electrochimica Acta 299, 914-925, 2019
  46. Bio-derived mesoporous disordered carbon: An excellent anode in sodium-ion battery and full-cell lab prototype; MR Panda, DP Dutta, S Mitra; Carbon 143, 402-412, 2019
  47. Insights of Diffusion Doping in Formation of Dual-Layered Material and Doped Heterostructure SnS–Sn:Sb2S3 for Sodium Ion Storage; S Bera, A Roy, AK Guria, S Mitra, N Pradhan; The journal of physical chemistry letters 10 (5), 1024-1030, 2019
  48. Improved performance of silver doped titania/poly (vinylidine fluoride) nanofibers polymer electrolyte for lithium ion battery; MV Bhute, S Mitra, SB Kondawar; Materials Letters 236, 225-228, 2019
  49. Nitrogen and Sulfur Doped Carbon Cloth as Current Collector and Polysulfide Immobilizer for Magnesium‐sulfur Batteries; D Muthuraj, A Ghosh, A Kumar, S Mitra; ChemElectroChem 6 (3), 684-689, 2019
  50. Nano-/Micro-engineering for Future Li–Ion Batteries; PK Dutta, A Sengupta, V Goel, P Preetham, A Ahuja, S Mitra; Nano-Energetic Materials, 141-176, 2019.
  51. The Study of Higher Discharge Capacity, Phase Transition and Relative Structural Stability in Li2FeSiO4 Cathode upon Lithium Extraction using Experimental and Theoretical Approach and Full cell Prototype Study”; Singh, Shivani; K, Anish Raj; Panda, Manas; Sen, Raja; Johari, Priya; Sinha, Anil; Meena, Sher Singh; Mitra, Sagar; accepted in ACS Applied Energy Materials, 9 August 2019.
  52. Blocks of molybdenum ditelluride: A high rate anode for sodium-ion battery and full cell prototype study; Manas Ranjan Panda, Anish Raj K, Arnab Ghosh, Ajit Kumar, Divyamahalakshmi Muthuraj, Supriya Sau, Wenzhi Yu, Yupeng Zhang, A K Sinha, Matthew Weyland, Qiaoliang Bao*, Sagar Mitra*; NanoEnergy, 64, 103951, 2019.
  53. Mechanism of Na-​Ion Storage in BiOCl Anode and the Sodium-​Ion Battery Formation; Dutta, Prasit Kumar; Myung, Yoon; Kulangaramadom Venkiteswaran, Rohini; Mehdi, Layla; Browning, Nigel; Banerjee, Parag; Mitra, Sagar; Journal of Physical Chemistry C 123(18), 11500-11507, 2019.
  54. Three-​Dimensionally Reinforced Freestanding Cathode for High-​Energy Room-​Temperature Sodium-​Sulfur Batteries;Ghosh, Arnab; Kumar, Ajit; Roy, Amlan; Panda, Manas Ranjan; Kar, Mega; MacFarlane, Douglas R.; Mitra, Sagar; ACS Applied Materials & Interfaces; 11(15), 14101-14109, 2019.
  55. Dual Layered Material and Doped Heterostructure SnS-Sn:Sb2S3 as Efficient Energy Material: The Insights of Diffusion Doping; Bera, Suman; Roy, Amlan; Guria, Amit; Mitra, Sagar; Pradhan, Narayan; J.Phys.Chem.Lett., 10, 1024−1030, 2019.
  56. High-energy room temperature sodium-sulfur battery enabled by sodium polysulfide catholyte and MnO2 nanoarrays decorated carbon cloth ; Ajit Kumar, Arnab Ghosh, Amlan Roy, Manas Ranjan Panda, Maria Forsyth,* Douglas R. MacFarlane* and Sagar Mitra*; Energy Storage Materials,20, Pages 196-202, 2019.
  57. “Nanostructured Vanadium Tri-oxides, as a Long life and High Performance Anode for Sodium-ion Battery”; Ananta Sarkar, Anil Kumar Sinha and Sagar Mitra; Electrochimica Acta 299, 914-925, 2019.
  58. “N, S doped carbon cloth as current collector and polysulfide immobilizer for advanced magnesium-sulfur batteries’ by Divyamahalakshmi Muthuraj, Arnab Ghosh, Ajit Kumar and Sagar Mitra*; in ChemElectroChem, 6(3), 684-689, 2019.
  59. “Bio-derived Mesoporous Disordered Carbon: An Excellent Anode in Sodium-ion battery and full-cell Lab Prototype” by Anish Raj K, Manas Ranjan Panda, Dimple P. Dutta* and Sagar Mitra* in Carbon 143, 402-412, 2019.
  60. Covalent Organic Framework-based Microspheres as Anode Material for Rechargeable Sodium Batteries; Bidhan Chandra Patra, Sabuj Kanti Das, Arnab Ghosh, Anish Raj K, Parikshit Moitra, Matthew Addicoat, Sagar Mitra*, Asim Bhaumik,* Santanu Bhattacharya*, and Anirban Pradhan*; in Journal of Materials Chemistry A, 6, 16655 – 16663, 2018.
  61. High-performance Sodium Anode Comprised of Few-Layer of MoSe2 and N, P Doped Reduced Graphene Oxide Composites; Amlan Roy, Arnab Ghosh, Ajit Kumar and Sagar Mitra; Inorganic Chemistry Frontiers, 5(9), 2189-2197.2018.
  62. Role of N-Propyl-N-Methyl Pyrrolidinium bis(trifluoromethanesulfonyl)imide as an Electrolyte Additive in Sodium Battery Electrochemistry; C. V. Manohar, Maria Forsyth, Douglas R. MacFarlane and Sagar Mitra; Energy Technology, 6, 2232 –2237, 2018.
  63. Sustainable one step process of making carbon-free TiO2 anode and sodium-ion battery electrochemistry” by Tandeep S. Chadha, Prasit Kumar Dutta, Ramesh Raliya, Sagar Mitra, Pratim Biswas: Sustainable Energy & Fuels; 2,1582, 2018.
  64. “Passivation Behaviour of Aluminum Current Collector in Ionic Liquid Alkyl Carbonate (hybrid) Electrolytes” Sowmiya Theivaprakasam, Gaetan Girard, Patrick Howlett, Maria Forysth, Douglas MacFarlane, Sagar Mitra; NPJ Materials Degradation; 2(1), 1-9, 2018.
  65. “Ionic liquid electrolytes supporting high energy density in sodium-ion batteries based on sodium vanadium phosphate composites” by C V Manohara, Tiago Correia Mendes, Mega Kar , Dabin wang, Changlong Xiao, Maria Forsyth, Sagar Mitra, Douglas R. MacFarlane; Chem. Comm., 54, 3500-3503, 2018.
  66. “An Aqueous Ca-ion Full Cell Comprising BaHCF Cathode and MCMB Anode” by Md. Adil, Prasit Dutta, and Sagar Mitra; Chemistry Select, 3(13), 3687-3690, 2018.
  67. “Efficient Conversion of Sand to Nano-Silicon and Si-C Composite Anode Design for High Volumetric Capacity Lithium-Ion Battery” Mohammad Furquan; Anish K Raj; S Vijayalakshmi; Sagar Mitra, J. Power Sources; 382, 56-68, 2018.
  68. “Reversible Mg insertion into Chevrel Phase Mo6S8 cathode: Preparation, Electrochemistry and X-ray Photoelectron Spectroscopy Study”; Divyamahalakshmi Muthuraj and Sagar Mitra, Materials Research Bulletin 101, 167-174, 2018.
  69. “Stability enhancing ionic liquid hybrid electrolyte for NVP@C cathode based sodium batteries”; C V Manohar, Anish Raj K, Mega Kar, Maria Forsyth, Douglas R. MacFarlane, Sagar Mitra; Sustainable Energy and Fuels; 2(3), 566-576. 2018.
  70. In-situ surface coating of squaric acid with conductive polyaniline as high capacity and sustainable organic lithium battery anode; Arnab Ghosh and Sagar Mitra; ChemElectroChem 5(1), 159-165, 2018.
  71. Exceptionally high Sodium-ion Battery Cathode Capacity-Based on Doped Ammonium Vanadium Oxide and Full Cell SIB Prototype Study; Ananta Sarkar, Sudeep Sarkar and Sagar Mitra; Mater.Chem.A, 5,24929, 2017. [This article is part of the themed collection: 2017 Journal of Materials Chemistry A HOT Papers]
  72. Sulfur Co-polymer a New Cathode Structure for Room Temperature Sodium-Sulfur Batteries; Ghosh, Arnab; Shukla, Swapnil; Monisha, Monisha; Kumar, Ajit; Lochab, Bimlesh; Mitra, Sagar; ACS Energy Letters, 2 (10), pp 2478–2485, 2017.
  73. Advanced Sodium Storage Property in Exfoliated MoO3 Anode: The Stability and Performance Improvement by in-situ Impedance Mapping; Amlan Roy, Prasit Dutta and Sagar Mitra; Materials Chemistry A, 5, 20491–20496, 2017.
  74. Impact of Cl doping on electrochemical performance in orthosilicate (Li2FeSiO4): A DFT supported experimental approach”: Singh, Shivani; Raj, Anish; Sen, Raja; Johari, Priya; Mitra, Sagar, ACS Applied Materials & Interfaces, 9 (32), pp 26885–26896, 2017.
  75. Understanding the Behavior of LiCoO2 Cathodes at Extended Potentials in Ionic Liquid – Alkyl Carbonate Hybrid Electrolytes; by Theivaprakasam, Sowmiya; Wu, Jimmy; Pramudita, James; Sharma, Neeraj; Macfarlane, Douglas; Mitra, Sagar; Phys. Chem. C, 2017, 121 (29), pp 15630–15638.
  76. “Intermediate Phases in Sodium Intercalation into MoS2 Nanosheets and Their Implications for Sodium-Ion Battery” Q. Li, Z. Yao, J. Wu, Mitra, S. Hao, T. S. Sahu, Y, Li, C. Wolverton and V-P. Dravid; NanoEnergy; 38, 342–349, 2017.
  77. Controlled 3D Carbon Nanotube Architecture Coated with MoOx Material by ALD technique: A High Energy Density Lithium-ion Battery Electrode” By Arpan Dhara, Shaibal K. Sarkar, Sagar Mitra, Advanced Materials Interfaces, accepted on 5th May 2017.
  78. Efficient Sodium Storage: Experimental Study of Anode with Additive-free Ether-based Electrolyte System; Prasit Dutta and Sagar Mitra; Power Sources, 349,152–162, 2017.
  79. Conversion Anode and Intercalation Cathode Based High Rate Capable Full cell Lithium-ion Battery; Pavan S Veluri and Sagar Mitra, 4(3), 686-691, 2017.
  80. Exfoliated MoS2 Nanosheets Confined in 3-D Hierarchical Carbon Nanotube@Graphene Architecture with Superior Sodium-Ion Storage; Tuhin Subhra Sahu, Qianqian Li, Jinsong Wu, Vinayak P Dravid and Sagar Mitra; Materials Chemistry A, 5(1), 355-363, 2017.
  81. A Facile Bottom-up approach to construct hybrid felixible cathode scaffold for high performance lithium-sulfur batteries; Arnab Ghosh, R. Manjunatha, Rajat Kumar, Sagar Mitra, ACS Applied Materials Interfaces, 8(49), 33775, 2016.
  82. Sonochemical synthesis of nanostructured spinel Li4Ti5O12 negative inseration material for lithium and sodium ion batteries; S. Ghosh, Sagar Mitra, P. Barpanda.; Electrochimica Acta; 222, 898-903, 2016.
  83. Iron phosphite (FeP) synthesis and full-cell lithium-ion battery study with LiNiMnCoO2 (NMC) cathode; P. S. Veluri, Sagar Mitra.; RSC Advances, 6, 87675, 2016.
  84. Preparation, structure study and electrochemistry of layered H2V3O8 materials: high capacity lithium-ion battery cathode; S. Sarkar, Arghya Bhowmik, Jaysree Pan, Mridula Dixit, Sagar Mitra; Power Sources, 329, 179-189, 2016.
  85. Cardanol benzoxazines-a sustainable/alternative linker to chemically bound elemental sufur to form sustainable feedstock for polymer; Swapnil Shukla, Arnab Ghosh, Prasun Kumar Roy, Sagar Mitra and Bimlesh Lochab; Polymer, 99(2), 349, 2016.
  86. An alternative process for nitric oxide and hydrogen production usng metal oxides; S. K. Thengane, S. Bandyopadhyay, Sagar Mitra, Sankar Bhattacharya, A. Hoadley, Chemical Eng. Research and Design, 6, 36, 2016.
  87. Solvent transfer of graphene oxide for synthesis of tin mono sulphide graphene composite and application as anode of lithium ion battery; A. Tripathi, Sagar Mitra, Materials Science and Engg. B; 3, 13852, 2016.
  88. Sustainable sulfur-rich co-polymer/graphene composite as lithium-sulfur battery cathode with excellent electrochemical performance; Arnab Ghosh, Swapnil Shukla, Gaganpreet Singh Khosla, Bimlesh Lochab, Sagar Mitra; Scientific Reports, 6, 25207, 2016.
  89. Intercalation-based tungsten disulphide (WS2) lithium-ion battery anode grown by atomic layer deposition; Dip K. Nandi, Uttam K. Sen, Arpan Dhara, Sagar Mitra, Shaibal K. Sarkar; RSC Advances, 6, 38024, 2016.
  90. Cardanol benzoxazine-sulfur co-polymers for Li-S batteries: symbiosis of sustainability and performance; Swapnil Shukla,Arnab Ghosh, Uttam Kumar Sen, Prasun Kumar Roy, Sagar Mitra, Bimlesh Lochab; Chemistry Select; 1(3), 594, 2016.
  91. Exergy efficiency improvement in hydrogen production process by recovery of chemical energy vs. thermal energy; Sonal K. Thengane, Andrew Hoadley, Sankar Bhattacharya, Sagar Mitra, Santanu Bandyopadhyay; Clean Technologies and Environmental Policy; 1-14, 2016.
  92. Facile synthesis of viologen and its reversible lithium storage property in organic lithium-ion batteries; Arnab Ghosh, Sagar Mitra; RSC Advances, 5, 105632, 2015.
  93. Electrochemical studies of N-methyl N-propyl pyrrolidinium bis(trifluoromethanesulfonyl)imide ionic liquid mixtures with conventional electrolytes in LiFePO4/Li cells; Sowmiya Theivaprakasama, Douglas R. MacFarlane, Sagar Mitra, Electrochimica Acta, 180, 737, 2015.
  94. Rechargeable sodium-ion battery: high capacity ammonium vanadate cathode with enhanced stability at high rates; Ananta Sarkar, Sudeep Sarkar, Tanmay Sarkar, Parveen Kumar, Mridula Bharadwaj, Sagar Mitra; ACS Applied Materials and Interfaces, 7, 17044, 2015.
  95. Exfoliated MoS2 sheets and reduced graphene oxide-an excellent and fast anode for sodium-ion battery; Tuhin Sahu, Sagar Mitra; Scientific Reports, 5, 12571, 2015.
  96. Atomic layer deposited tungsten nitride thin films as a new lithium-ion battery anode; Dip K. Nandi, Uttam K. Sen, Soumyadeep Sinha, Arpan Dhara, Sagar Mitra, Shaibal K. Sarkar; Chem.Chem.Phys., 17, 17445, 2015.
  97. Porous alfa Fe2O3 nanostructures and their lithium storage properties as full-cell configuration against LiFePO4; P.S. Veluri, A. Shaligram, Sagar Mitra, Power Sources, 5, 23671, 2015.
  98. Flagella filament bio-templated inorganic oxide materials towards an efficient lithium battery anode; Sergei N. Beznosov, Pavan Veluri, Mikhil G. Pyatibratov, Abhijit Chatterjee, Douglas McFarlane, Oleg. V. Fedorov and Sagar Mitra; Scientific Reports, 5, 7736, 2015.
  99. Atomic layer deposited MoS2 as a carbon and binder free anode in lithium ion battery; Dip K.Nandi, Uttam K Sen, Sagar Mitra, Shaibal K. Sarkar; Electrochimica Acta, 146, 706, 2014.
  100. Excellent electrochemical performance of tin monosulfide (SnS) as sodium-ion battery anode; Prasit Dutta, Uttam Kumar Sen and Sagar Mitra; RSC Advances, 4, 43155, 2014.
  101. One step aerosol route synthesis of oriented one dimentional additive free single crystal TiO2 nanostructured anodes for high rate lithium-ion batteries; Tandeep S. Chadha, Alok M. Tripathi, Sagar Mitra and Pratim Biswas; Energy Technology, 2, 906, 2014.
  102. Intercalation anode material for lithium-ion battery based on molydbedium dioxide; Uttam K Sen, Apoorv Shaligram and Sagar Mitra, ACS Applied Materials and Interfaces, 6(16), 14311, 2014.
  103. Cost-benefit analysis of different hydrogen production technologies using AHP and Fuzzy AHP; Sonal K. Thengane, Andrew Hoadley, Sankar Bhattacharya, Sagar Mitra and Santanu Bandyopadhyay; Int. J. of hydrogen energy; 39, 15293-15306, 2014.
  104. An experimental and computational study to understand the lithium storage mechanism in molydbenium disulphide; U.K. Sen, Priya Johari, Sohini Basu, Chandrani Nayak, Sagar Mitra, Nanoscale; 6, 10243, 2014.
  105. Eco-friendly approach of making graphene-tin/tinoxide nanocomposite electrodes for energy storage; Alok Tripathi, Sagar Mitra, ChemElectroChem.; 1, 1327, 2014.
  106. Improved electrode fabrication method to enhance the performance and stability of MoS2-based lithium-ion battery anode; Uttam K. Sen, Sagar Mitra, Solid State Electrochemistry, 18, 2701, 2014.
  107. Li3V2(PO4)3 addition to olivine phase: understanding the effect in electrochemical performance; Sudeep Sarkar, Sagar Mitra, Physical Chemistry C, 118, 11512, 2014.
  108. Lithium rich composition of Li2RuO3 and Li2Ru1-xIrxO3 layered materials as li-ion battery cathode; Sudeep Sarkar, Pratibha Mahale, Sagar Mitra, Electrochem. Soc.; 161, A934, 2014.
  109. Morphology controlled synthesis of layered NH4V4O10 and the impact of binder on stable high rate electrochemical performance; Sudeep Sarkar, P.S. Veluri, Sagar Mitra; Electrochimica Acta; 132, 448, 2014.
  110. Atomic layer deposited molybdenum nitride thin film: a promising anode material for li-ion batteries; Dip K Nandi, Uttam Kumar Sen, Devika Choudhury, Sagar Mitra, and Shaibal Kanti Sarkar; ACS Applied Materials and Interfaces, 6, 6605, 2014.
  111. Electrochemical properties of spinel cobalt ferrite nanoparticles with sodium alginate as interactive binder; Sagar Mitra, P.S. Veluri, A. Chakraborty, R.K. Petla, ChemElectroChem.; 1, 1068, 2014.
  112. Improved electrochemical performance of SnO2-mesoporous carbon hybrid as anegative electrode for lithium ion battery applications; N. R. Srinivasan, Sagar Mitra, and Rajdip Bandyopadhyaya; Chem.Chem.Phy.; 16, 6639, 2014.
  113. Improved electrochemical activity of nanostructured Li2FeSiO4/MWCNTs composite cathode; Shivani Singh, Sagar Mitra; Electrochimica Acta; 123, 378, 2014.
  114. Tin sulfide (sns) nanorods: structural, optical and lithium storage property study; Alok Tripathi, Sagar Mitra, RSC Advances, 4, 10358, 2014.
  115. Phase transition, electrochemistry and structural studies of high rate LixV3O8 cathode with nanoplate morphology; S. Sarkar, Arghya Bhowmik, Mridula Dixit Bharadwaj, and Mitra; J. Electrochem. Soc., 161, A14, 2014.