Journals

2025

1. P. Singh, P. P. Kannan, S. Sankaranarayanan, & J. Saha, “Sustainably engineered pollen-derived carbon dots for efficient multi metal-ion sensing”, Microchemical Journal, 114384, 2025.

2. P. Singh, H. Vithalani, A. Adhyapak, T. Semwa, N. Singh, M. Dhanka, D. Bhatia, J. Saha, “Microwave-Assisted Green Synthesis of Fluorescent Graphene Quantum Dots: Metal Sensing, Antioxidant Properties, and Biocompatibility Insights”, J. of Fluorescence, 1-17, 2025.

3. M.A. Kharadi, T.K. Agarwal, I. Mahariq, J. Saha, "Type-II band-alignment in vertical transition metal-di-chalcogenide heterostructures for near infrared and visible light detection", Physica Scripta 100 (3), 035559, 2025.

2024

1. A Kumari, J Saha, A Saini, A Kumar, "Development of an analytical model of drain current for junctionless GAA MOSFET including source/drain resistance", Applied Data Science and Smart Systems, 43-48, 2024.

2. R. B. Barot, N. D. Gawande,S. Omprabha, C. Kaushal, J.Saha, D. Bhatia,S. Sankaranarayanan, "Novel carbon nanoparticles derived fromBougainvilleamodulate vegetative growth via Auxin-Cytokinin signaling in Arabidopsis", Chemical Papers, 1-18, 2024.

3. P. Singh, A. Dan, P.P. Kannan, M. Dhanka, D. Bhatia, J. Saha*, “Non-toxic fabrication of fluorescent carbon nanoparticles from medicinal plants/sources with their antioxidant assay”, arXiv preprint arXiv:2401.10673, 2024.

2023

1. M.A. Kharadi, S. Mittal, J. Saha, “Structural, electronic and optical properties of fluorinated bilayer silicone”, Optical Materials, 136, 113418, 2023.

2. R. Kumar, J. Saha, B. Tongbram, D. Panda, R. Gourishetty, R. Kumar, S. A. Gazi, S. Chakrabarti , "InAs quantum dot-in-a-well heterostructures with InGaAs, GaAsN and GaAsSb well using digital alloy capping layer”, Current Applied Physics, 2023 .

3. K. Mehta, S. Soumyashree, J. Pandya, P. Singh, R. K. Kushawaha, P. Kumar, S. Shinde, J. Saha, and P. K. Baruah. "Impact of viscosity of liquid on nanoparticles synthesized by laser ablation in liquid: An experimental and theoretical investigation." Applied Physics A, 129, no. 5, 388, 2023.

2022

1. M.A. Kharadi, J. Saha, “Silicene/GaAs van der Waals heterostructure for optoelectronic applications”, Journal of Materials Science 57 (46), 21324-21338, 2022.

2. Shriram, S.R., Gourishetty, R., Panda, D., Das, D., Dongre, S., Saha, J. and Chakrabarti, S., 2022. Subsiding strain-induced In-Ga intermixing in InAs/InxGa1−xAs sub-monolayer quantum dots for room temperature photodetectors. Infrared Physics & Technology, 121, p.104047.  

3. R Kumar, J. Saha, S Chakrabarti, “Strain minimization of InAs QDs heterostructures using dual quaternary-ternary/ternary-quaternary capping materials via digital alloy capping layer approach”, IEEE Transactions on Nanotechnology, vol. 21, pp. 489-498, 2022.

2021

1. Choudhary, S., Das, D., Saha, J., Panda, D., & Chakrabarti, S. (2021). Hybrid stranski-krastanov/submonolayer quantum dot heterostructure with type-II band alignment: an efficient way of near infrared photovoltaic energy conversion. Journal of Luminescence, 118281. 

2. Gourishetty, R., Panda, D., Dongre, S., Saha, J., Gazi, S. A., & Chakrabarti, S. (2021). Hybrid strain-coupled multilayer SK and SML InAs/GaAs quantum dot heterostructure: Enabling higher absorptivity and strain minimization for enhanced optical and structural characteristics. Journal of Luminescence, 233, 117899. 

3. Shriram, S. R., Panda, D., Kumar, R., Saha, J., Tongbram, B., Mantri, M. R., ... & Chakrabarti, S. (2021). The role and growth of strain–reducing layer by molecular-beam epitaxy in a multi–stack InAs/(In, Ga) As sub-monolayer quantum dot heterostructure. Optical Materials, 114, 110817. 

2020

1. Saha, J., Tongbram, B., Panda, D., Das, D., & Chakrabarti, S. (2020). A comprehensive analysis of strain profile in the heterogeneously coupled Stranski-Krastanov (SK) on Submonolayer (SML) quantum dot heterostructures. Journal of Alloys and Compounds, 847, 156483. 

2. Deviprasad, V. P., Panda, D., Paul, S., Mondal, S., Saha, J., Das, D., ... & Chakrabarti, S. (2020). Room temperature operation and low dark current of In0. 15Ga0. 85As/InAs/In0. 15Ga0. 85As dot-in-well short-wave infrared photodetector: Experimental and theoretical correlation. Superlattices and Microstructures, 148, 106715. 

3. Kumar, R., Panda, D., Saha, J., Gazi, S. A., & Chakrabarti, S. (2020). Short-wave infrared (SWIR) photodetection by InAs/GaAs quantum dot heterostructures grown on Ge (100) substrate without Migration Enhanced Epitaxy layer. Superlattices and Microstructures, 148, 106714. 

4. Saha, J., Tongbram, B., Panda, D., Das, D., & Chakrabarti, S. (2020). Tuning the structural and optical characteristics of heterogeneously coupled InAs Submonolayer (SML) quantum dots grown on InAs Stranski-Krastanov (SK) quantum dots. Optical Materials, 109, 110292. 

5. Kumar, R., Saha, J., Panda, D., Kumar, R., Gazi, S. A., Gourishetty, R., & Chakrabarti, S. (2020). Ameliorating the optical and structural properties of InAs quantum dot heterostructures through digital alloy capping materials: Theory and experiment. Optical Materials, 108, 110419. 

6. Das, S., Saha, J., Shriram, S. R., & Chakrabarti, S. (2020). Influence of Sb accumulation on the inter-band and inter-subband transitions of InAs/GaAs1-x Sbx sub-mono layer (SML) quantum dot heterostructures. Superlattices and Microstructures, 145, 106646. 

7. Kumar, R., Panda, D., Saha, J., Tongbram, B., Das, D., Kumar, R., & Chakrabarti, S. (2020). Monolithic growth of GaAs/Al0. 3Ga0. 7As multiple quantum well structure on Ge substrate with low defects: theoretical and experimental correlation of the structural and optical properties. Journal of Physics D: Applied Physics, 53(43), 435301. 

8. Shriram, S. R., Kumar, R., Panda, D., Saha, J., Tongbram, B., Mantri, M. R., ... & Chakrabarti, S. (2020). Study on inter band and inter sub-band optical transitions with varying InAs/InGaAs sub-monolayer quantum dot heterostructure stacks grown by molecular beam epitaxy. IEEE Transactions on Nanotechnology, 19, 601-608. 

9. Kumar, R., Panda, D., Das, D., Chatterjee, A., Tongbram, B., Saha, J., ... & Chakrabarti, S. (2020). Realization of high-quality InGaAs/GaAs quantum dot growth on Ge substrate and improvement of optical property through ex-situ ion implantation. Journal of Luminescence, 223, 117208. 

10. Tongbram, B., Saha, J., Sengupta, S., & Chakrabarti, S. (2020). Metamorphosis of self-assembled InAs quantum dot through variation of growth rates. Journal of Alloys and Compounds, 824, 153870. 

11. Kumar, R., Saha, J., & Chakrabarti, S. (2020). Impact of Digital Alloy Capping Layers on Bilayer InAs Quantum Dot Heterostructures. IEEE Transactions on Nanotechnology, 19, 368-374. 

2019

1. Das, D., Saha, J., Panda, D., Tongbram, B., Raut, P. P., Ramavath, R., ... & Chakrabarti, S. (2019). Vertically Coupled Hybrid InAs Sub-Monolayer on InAs Stranski–Krastanov Quantum Dot Heterostructure: Toward Next Generation Broadband IR Detection. IEEE Transactions on Nanotechnology, 19, 76-83. 

2. Saha, J., Raut, P., Ramavath, R., Panda, D., Das, D., & Chakrabarti, S. (2019). Enhancing the performance of heterogeneously coupled InAs Stranski-Krastanov on submonolayer quantum dot heterostructures. Superlattices and Microstructures, 135, 106260. 

3. Panda, D., Chatterjee, A., Saha, J., Das, D., Singh, S. M., Pal, S. K., & Chakrabarti, S. (2019). Enhanced performance of in (Ga) as QD based optoelectronic devices through improved interface quality between QD and matrix material. physica status solidi (b), 256(11), 1900138. 

4. Saha, J., Das, D., Panda, D., Tongbram, B., Chatterjee, A., Liang, B., ... & Chakrabarti, S. (2019). Broad tunability of emission wavelength by strain coupled InAs/GaAs1− xSbx quantum dot heterostructures. Journal of Applied Physics, 126(15), 154302. 

5. Panda, D., Saha, J., Das, D., Singh, S. M., Rawool, H., & Chakrabarti, S. (2019). Theoretical correlation and effect of annealing on the photoresponse of vertically strain-coupled In0. 5Ga0. 5As/GaAs quantum dot heterostructures. Journal of Applied Physics, 126(12), 125705. 

6. Saha, J., Panda, D., Tongbram, B., Das, D., Chavan, V., & Chakrabarti, S. (2019). Higher performance optoelectronic devices with In0. 21Al0. 21Ga0. 58As/In0. 15Ga0. 85As capping of III-V quantum dots. Journal of Luminescence, 210, 75-82. 

7. Krishna, J. S., Panda, D., & Chakrabarti, S. (2019). Impact of Sb composition on strain profile of GaAs 1-x Sb x capped InAs quantum dots. IEEE Transactions on Nanotechnology, 18, 234-239. 

2018

1. Das, D., Panda, D. P., Tongbram, B., Saha, J., Deviprasad, V., Rawool, H., ... & Chakrabarti, S. (2018). Improved near infrared energy harvesting through heterogeneously coupled SK on SML quantum dot heterostructure. Solar Energy Materials and Solar Cells, 185, 549-557. 

2. Das, D., Panda, D. P., Tongbram, B., Saha, J., Chavan, V., & Chakrabarti, S. (2018). Optimization of hybrid InAs stranski krastanov and submonolayer quantum dot heterostructures and its effect on photovoltaic energy conversion efficiency in near infrared region. Solar Energy, 171, 64-72. 

3. Saha, J., Panda, D., & Chakrabarti, S. (2018). Tuning the optoeletronic characteristics of strain coupled InAs/GaAs bilayer quantum dot heterostructures through compositional and structural variabilities. Superlattices and Microstructures, 120, 335-343. 

4. Saha, J., Panda, D., Das, D., Chavan, V., & Chakrabarti, S. (2018). Enhanced luminescence and optical performance through strain minimization in self-assembled InAs QDs using dual quaternary-ternary/ternary-quaternary capping. Journal of Luminescence, 197, 297-303. 

5. Panda, D., Saha, J., Balgarkashi, A., Shetty, S., Rawool, H., Singh, S. M., ... & Chakrabarti, S. (2018). Optimization of dot layer periodicity through analysis of strain and electronic profile in vertically stacked InAs/GaAs Quantum dot heterostructure. Journal of Alloys and Compounds, 736, 216-224.