Publications

Link to google scholar

Preprints:

[23] Chakraborty, C., Ciccarino, C. J., Narang, P. Dynamic modulation of phonon-assisted transitions in quantum defects in monolayer transition-metal dichalcogenide semiconductors. Arxiv: Materials Science, 2007.14399 (2020)

Publications:

2020

[22] Moon, H., Grosso, G., Chakraborty, C., Peng, C., Taniguchi, T., Watanabe, K., and Englund, D. Dynamic exciton funneling by local strain control in a monolayer semiconductor. Nano Letters, (2020)

[21] Mukherjee, A., Chakraborty, C., Qiu, L., Vamivakas, N. Electric fi eld tuning of deterministically created quantum dots in WSe2. AIP Advances, 10, 075310 (2020)

[20] Chakraborty, C., Mukherjee, A., Moon, H., Kumarasiri, K., Qiu, L., Hou, W., Pena, T., Watson, C., Wu, S.M., Englund, D., and Vamivakas, N. Strain-tuning of the optical properties of localized emitters in an atomically thin semiconductor. Optica, 7, 580 (2020)

[19] Moon, H., Bersin, E., Chakraborty, C., Lu, A.Y., Grosso, G., and Englund, D. Strain-correlated Localized Exciton Energy in Atomically Thin Semiconductors. ACS Photonics 7, 1135 (2020)

2019

[18] Ciccarino., C. J., Chakraborty, C., Englund D., and Narang, P. Carrier Dynamics and Spin-Valley-Layer Effects in Bilayer Transition Metal Dichalcogenides. Faraday Discussions, 214, 175 (2019)

[17] Peyskens, F., Chakraborty, C., Muneeb, M.,Thourhout, D. V., Englund, D. Integration of Single Photon Emitters in 2D Layered Materials with a Silicon Nitride Photonic Chip. Nature Communications, 10, 4452 (2019)

[16] Chakraborty, C., Vamivakas, N., and Englund, D. Advances in quantum light emission from 2D materials. Nanophotonics (Review), 8, 2017 (2019)

[15] Chakraborty, C., Jungwirth, N. R., Fuchs, G. D., and Vamivakas, N. Electrical manipulation of the fine-structure splitting of WSe2 quantum emitters. Phys. Rev. B, 99, 045308 (2019)

[14] Qiu, L., Chakraborty, C., Dhara, S., and Vamivakas, N. Room-Temperature Valley Coherence in a Polaritonic System. Nature Communications, 10, 1513 (2019)

[13] Kumarasiri, K., Chakraborty, C., Mathur, N., Qiu, L., Mukherjee, A., Fuchs, G., and Vamivakas, N. Rabi oscillations and resonance fluorescence from a single hexagonal boron nitride quantum emitter. Optica, 6, 542 (2019)

[12] Chakraborty, C., Mukherjee, A., Qiu, L., and Vamivakas, N. Electrically tunable valley polarization and valley coherence in monolayer WSe2 embedded in a van der Waals heterostructure. Optical Materials Express, 9, 1479 (2019)

2018

[11] Dhara, S.*, Chakraborty, C.*, Qiu, L., Goodfellow, K., Oloughlin T., Wicks G, and Bhattacharjee S., and Vamivakas, N. Anomalous dispersion of microcavity trion-polaritons. Nature Physics, 14, 130 (2018)

[10] Chakraborty, C., Qiu, L., Kumarasiri, K., Mukherjee A., Dhara, S., and Vamivakas, N. 3D localized trion in monolayer WSe2 in a charge tunable van der Waals heterostructure. Nano Letters, 18, 2859 (2018)

2017

[9] Chakraborty, C., Goodfellow, K. M., Dhara, S., Yoshimura, A., Meunier, V., and Vamivakas, N. Quantum-confi ned Stark effect of individual defects in a van der Waals heterostructure. Nano Letters, 17, 2253 (2017)

2016

[8] Chakraborty, C., Goodfellow, K. M., and Vamivakas, A. N. Localized emission from defects in MoSe2 layers. Optical Materials Express, 6, 2081 (2016)

[7] Goodfellow, K. M., Chakraborty, C., Waduge, P., Sowers, K., Wanunu, M., Krauss, T., Driscoll, K., and Vamivakas, A. N. Distance-dependent energy transfer between CdSe/CdS quantum dots and a two-dimensional semiconductor. Applied Physics Letters, 108, 021101 (2016)

2015

[6] Chakraborty, C., Kinnischtzke, L., Goodfellow, K. M., Beams, R., and Vamivakas, A. N. Voltage-controlled quantum light from an atomically thin semiconductor. Nature Nanotechnology, 10, 507 (2015)

[5] Kinnischtzke, L., Goodfellow, K. M., Chakraborty, C., Lai,Y., Badolato, A., and Vamivakas, A. N. Graphene mediated Stark shifting of quantum dot energy levels. Applied Physics Letters, 108, 211905 (2015)

[4] Goodfellow, K. M.*, Chakraborty, C.*, Beams, R., Novotny, L., and Vamivakas, A. N. Direct On-Chip Optical Plasmon Detection with an Atomically Thin Semiconductor. Nano Letters, 15, 5477 (2015)

2014

[3] Chakraborty, C., Beams, R., Goodfellow, K. M., Wicks, G. W., Novotny, L., and Vamivakas, A. N. Optical antenna enhanced graphene photodetector. Applied Physics Letters, 105, 241114 (2014)

[2] Goodfellow, K. M., Beams, R., Chakraborty, C., Novotny, L., and Vamivakas, A. N. Integrated nanophotonics based on nanowire plasmons and atomically thin material. Optica, 1, 149 (2014)

2013

[1] Parikh, P.*, Chakraborty, C.*, Abhilash, T. S., Sengupta, S., Cheng, C., Wu, J., and Deshmukh, M. M. Dynamically Tracking the Strain Across the Metal-Insulator Transition in VO2 Measured Using Electromechanical Resonators. Nano Letters, 13, 4685 (2013)

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