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39 results on '"Adak, Amitava"'

1. Universal behavior of highly-confined heat flow in semiconductor nanosystems: from nanomeshes to metalattices

Author

McBennett, Brendan, Beardo, Albert, Nelson, Emma E., Abad, Begoña, Frazer, Travis D., Adak, Amitava, Esashi, Yuka, Li, Baowen, Kapteyn, Henry C., Murnane, Margaret M., and Knobloch, Joshua L.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Nanostructuring on length scales corresponding to phonon mean free paths provides control over heat flow in semiconductors and makes it possible to engineer their thermal properties. However, the influence of boundaries limits the validity of bulk models, while first principles calculations are too computationally expensive to model real devices. Here we use extreme ultraviolet beams to study phonon transport dynamics in a 3D nanostructured silicon metalattice with deep nanoscale feature size, and observe dramatically reduced thermal conductivity relative to bulk. To explain this behavior, we develop a predictive theory wherein thermal conduction separates into a geometric permeability component and an intrinsic viscous contribution, arising from a new and universal effect of nanoscale confinement on phonon flow. Using experiments and atomistic simulations, we show that our theory applies to a general set of highly-confined silicon nanosystems, from metalattices, nanomeshes, porous nanowires to nanowire networks, of great interest for next-generation energy-efficient devices.

Published
2022
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3. Observation of ultrafast laser-plasma evolution by pump-probe reflectometry and Doppler spectrometry

Author

Adak, Amitava, Singh, Prashant Kumar, Lad, Amit D., Chatterjee, Gourab, and Kumar, G. Ravindra

Subjects
Physics - Plasma Physics
Abstract

We demonstrate pump-probe techniques, namely the Doppler spectrometry and the reflectometry in detail, which directly capture the time-resolved ultrafast evolution of high intensity femtosecond laser-driven hot, dense plasma. These techniques are capable of capturing ultrafast plasma dynamics on time scales of sub 100 femtosecond. We have shown the dynamics of high intensity femtosecond laser-driven shock like disturbance into the plasma at densities more than 10^22/cc. This can help understanding the physics related to shock ignition, supernova explosion and many other astrophysical scenarios and also can have implications in medicine and chemistry. Furthermore, we have investigated the ultrafast acoustic phenomena due to hydrodynamics inside an expanding hot, dense plasma in its transient phase by the correlated measurements of Doppler spectrometry and reflectometry.

Published
2019

4. Absorption of High Intensity, High Contrast Femtosecond Laser Pulses by a Solid

Author

Adak, Amitava, Lad, Amit D., Shaikh, Moniruzzaman, Dey, Indranuj, Sarkar, Deep, and Kumar, G. Ravindra

Subjects
Physics - Plasma Physics
Abstract

The basic understanding of high-intensity femtosecond laser absorption in a solid is crucial for high-energy-density science. This multidimensional problem has many variables like laser parameters, solid target material, and geometry of the excitation. This is important for a basic understanding of intense laser-matter interaction as well for applications such as `plasma mirror'. Here, we have experimentally observed high-intensity, high-contrast femtosecond laser absorption by an optically polished fused silica target at near-relativistic laser intensities ($\sim$10$^{18}$ W/cm$^2$). The laser absorption as a function of angle of incidence and incident energy is investigated for both $p$- and $s$-polarized pulses in detail, providing a strong indication of the presence of collisionless processes. At an optimum angle of incidence, almost as large as 80% of the laser ($p$-polarized) energy gets absorbed in the target. Such a high percentage of absorption at near-relativistic intensities has not been observed before. At smaller angles of incidence the high reflectivity (e.g. about 60 - 70% at 30$^\circ$ incidence) indicate that, this study is fundamentally relevant for plasma mirrors at near-relativistic intensities., Comment: 5 pages, 6 figures

Published
2018

6. High-resolution measurements of the spatial and temporal evolution of megagauss magnetic fields created in intense short-pulse laser-plasma interactions

Author

Chatterjee, Gourab, Singh, Prashant Kumar, Adak, Amitava, Lad, Amit D., and Kumar, G. Ravindra

Subjects
Physics - Plasma Physics
Abstract

A pump-probe polarimetric technique is demonstrated, which provides a complete, temporally and spatially-resolved mapping of the megagauss magnetic fields generated in intense short-pulse laser-plasma interactions. A normally-incident time-delayed probe pulse reflected from its critical surface undergoes a change in its ellipticity according to the magneto-optic Cotton-Mouton effect due to the azimuthal nature of the ambient self-generated megagauss magnetic fields. The temporal resolution of the magnetic field mapping is of the order of the pulsewidth, whereas a spatial resolution of a few microns is achieved by this optical technique. In addition, this technique does not suffer from refraction effects due to the steep plasma density gradients owing to the near-normal incidence of the probe pulse and consequently, higher harmonics of the probe can be employed to penetrate deeper into the plasma to even near-solid densities. The spatial and temporal evolution of the megagauss magnetic fields at the target front as well as at the target rear are presented. The micron-scale resolution of the magnetic field mapping provides valuable information on the filamentary instabilities at the target front, whereas probing the target rear mirrors the highly complex fast electron transport in intense laser-plasma interactions., Comment: 11 pages, 12 figures

Published
2013
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10. Structural and Elastic Properties of Empty-Pore Metalattices Extracted via Nondestructive Coherent Extreme UV Scatterometry and Electron Tomography

Author

Knobloch, Joshua L., primary, McBennett, Brendan, additional, Bevis, Charles S., additional, Yazdi, Sadegh, additional, Frazer, Travis D., additional, Adak, Amitava, additional, Nelson, Emma E., additional, Hernández-Charpak, Jorge N., additional, Cheng, Hiu Y., additional, Grede, Alex J., additional, Mahale, Pratibha, additional, Nova, Nabila Nabi, additional, Giebink, Noel C., additional, Mallouk, Thomas E., additional, Badding, John V., additional, Kapteyn, Henry C., additional, Abad, Begoña, additional, and Murnane, Margaret M., additional

Published
2022
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11. Formation and evolution of post-solitons following a high intensity laser-plasma interaction with a low-density foam target

Author

Blackman, David, Adak, Amitava, Kumar Singh, Prashant, Lad, Amit D., Chatterjee, Gourab, Ridgers, Christopher Paul, Del Sorbo, Dario, Trines, R.M.G.M., Robinson, A.P.L., Nazarov, Wigen, Kumar, G. Ravindra, and Pasley, John Richard

Abstract

The formation and evolution of post-solitons has been discussed for quite some time both analytically and through the use of particle-in-cell (PIC) codes. It is however only recently that they have been directly observed in laser-plasma experiments. Relativistic electromagnetic (EM) solitons are localised structures that can occur in collisionless plasmas. They consist of a low-frequency EM wave trapped in a low electron number-density cavity surrounded by a shell with a higher electron number-density. Here we describe the results of an experiment in which a 100 TW Ti:sapphire laser (30 fs, 800 nm) irradiates a 0:03 gcm^-3 TMPTA foam target with a focused intensity I_l = 9:5x10^17 Wcm^-2. A third harmonic (lambda_probe ~ 266 nm) probe is employed to diagnose plasma motion for 25 ps after the main pulse interaction via Doppler-Spectroscopy. Both radiation-hydrodynamics and 2-D PIC simulations are performed to aid in the interpretation of the experimental results. We show that the rapid motion of the probe critical-surface observed in the experiment might be a signature of post-soliton wall motion.

Published
2021

15. Formation and evolution of post-solitons following a high intensity laser-plasma interaction with a low-density foam target

Author

Blackman, David R, primary, Adak, Amitava, additional, Singh, Prashant K, additional, Lad, Amit D, additional, Chatterjee, Gourab, additional, Ridgers, Christopher P, additional, Del Sorbo, Dario, additional, Trines, Raoul M G M, additional, Robinson, A P L, additional, Nazarov, Wigen, additional, Ravindra Kumar, G, additional, and Pasley, John, additional

Published
2021
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16. Micro-optics for ultra-intense lasers

Author

Habara, H., primary, Lad, Amit D., additional, Nagami, R., additional, Singh, Prashant Kumar, additional, Chatterjee, Gourab, additional, Adak, Amitava, additional, Dalui, Malay, additional, Jha, J., additional, Brijesh, P., additional, Mishima, Y., additional, Nagai, K., additional, Sakagami, H., additional, Tata, Sheroy, additional, Trivikram, T. Madhu, additional, Krishnamurthy, M., additional, Tanaka, K. A., additional, and Kumar, G. Ravindra, additional

Published
2021
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20. Controlling femtosecond-laser-driven shock-waves in hot, dense plasma

Author

Adak, Amitava, Singh, Prashant Kumar, Blackman, David R., Lad, Amit D., Chatterjee, Gourab, Pasley, John, Robinson, A. P.L., and Ravindra Kumar, G.

Subjects
Physics::Optics
Abstract

Ultrafast pump-probe reflectometry and Doppler spectrometry of a supercritical density plasma layer excited by 1017-1018 W/cm2 intensity, 30 fs, and 800 nm laser pulses reveal the interplay of laser intensity contrast and inward shock wave strength. The inward shock wave velocity increases with an increase in laser intensity contrast. This trend is supported by simulations as well as by a separate independent experiment employing an external prepulse to control the inward motion of the shock wave. This kind of cost-effective control of shock wave strength using femtosecond pulses could open up new applications in medicine, science, and engineering.

Published
2017

21. Probing ultrafast dynamics in a solid-density plasma created by an intense femtosecond laser

Author

Adak, Amitava, Blackman, Dave, Chatterjee, Gourab, Singh, Prashant Kumar, Lad, Amit D., Brijesh, P., Robinson, A. P L, Pasley, John, and Ravindra Kumar, G.

Subjects
Physics::Optics
Abstract

We report a study on the dynamics of a near-solid density plasma using an ultraviolet (266 nm) femtosecond probe laser pulse, which can penetrate to densities of ∼ 1022 cm-3, nearly an order of magnitude higher than the critical density of the 800 nm, femtosecond pump laser. Time-resolved probe-reflectivity from the plasma shows a rapid decay (picosecond- timescale) while the time-resolved reflected probe spectra show red shifts at early temporal delays and blue shifts at longer delays. This spectral behaviour of the reflected probe can be explained by a laser-driven shock moving inward and a subsequent hydrodynamic free expansion in the outward direction.

Published
2016

24. Silicon nanowire based high brightness, pulsed relativistic electron source

Author

Sarkar, Deep, primary, Singh, Prashant Kumar, additional, Cristoforetti, G., additional, Adak, Amitava, additional, Chatterjee, Gourab, additional, Shaikh, Moniruzzaman, additional, Lad, Amit D., additional, Londrillo, P., additional, D’Arrigo, Giuseppe, additional, Jha, J., additional, Krishnamurthy, M., additional, Gizzi, L. A., additional, and Ravindra Kumar, G., additional

Published
2017
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31. Terahertz Acoustics in Hot Dense Laser Plasmas

Author

Adak, Amitava, primary, Robinson, A. P. L., additional, Singh, Prashant Kumar, additional, Chatterjee, Gourab, additional, Lad, Amit D., additional, Pasley, John, additional, and Kumar, G. Ravindra, additional

Published
2015
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32. Effi cient Production of Fast Electron Via Surface Plasmon Resonance Induced by Intense Laser Light

Author

MISHIMA, Yosuke, primary, HABARA, Hideaki, additional, K. SINGH, Prashant, additional, ADAK, Amitava, additional, CHATTERJEE, Gourab, additional, D. LAD, Amit, additional, P., BRIJESH, additional, DALUI, Malay, additional, INOUE, Masahiko, additional, J., JHA, additional, TATA, Sheroy, additional, T. TRIVIKRAM, Madhu, additional, M., KRISHNAMURTHY, additional, G. KUMAR, Ravindra, additional, and TANAKA, Kazuo A., additional

Published
2015
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39. Structural and Elastic Properties of Empty-Pore Metalattices Extracted viaNondestructive Coherent Extreme UV Scatterometry and Electron Tomography

Author

Knobloch, Joshua L., McBennett, Brendan, Bevis, Charles S., Yazdi, Sadegh, Frazer, Travis D., Adak, Amitava, Nelson, Emma E., Hernández-Charpak, Jorge N., Cheng, Hiu Y., Grede, Alex J., Mahale, Pratibha, Nova, Nabila Nabi, Giebink, Noel C., Mallouk, Thomas E., Badding, John V., Kapteyn, Henry C., Abad, Begoña, and Murnane, Margaret M.

Abstract

Semiconductor metalattices consisting of a linked network of three-dimensional nanostructures with periodicities on a length scale <100 nm can enable tailored functional properties due to their complex nanostructuring. For example, by controlling both the porosity and pore size, thermal transport in these phononic metalattices can be tuned, making them promising candidates for efficient thermoelectrics or thermal rectifiers. Thus, the ability to characterize the porosity, and other physical properties, of metalattices is critical but challenging, due to their nanoscale structure and thickness. To date, only metalattices with high porosities, close to the close-packing fraction of hard spheres, have been studied experimentally. Here, we characterize the porosity, thickness, and elastic properties of a low-porosity, empty-pore silicon metalattice film (∼500 nm thickness) with periodic spherical pores (∼tens of nanometers), for the first time. We use laser-driven nanoscale surface acoustic waves probed by extreme ultraviolet scatterometry to nondestructively measure the acoustic dispersion in these thin silicon metalattice layers. By comparing the data to finite element models of the metalattice sample, we can extract Young’s modulus and porosity. Moreover, by controlling the acoustic wave penetration depth, we can also determine the metalattice layer thickness and verify the substrate properties. Additionally, we utilize electron tomography images of the metalattice to verify the geometry and validate the porosity extracted from scatterometry. These advanced characterization techniques are critical for informed and iterative fabrication of energy-efficient devices based on nanostructured metamaterials.

Published
2022
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