Your search keyword '"Dalui, Malay"' showing total 3 results

1. Bacterial cells enhance laser driven ion acceleration.

Author

Dalui M, Kundu M, Trivikram TM, Rajeev R, Ray K, and Krishnamurthy M

Subjects

Carbon chemistry, Carbon metabolism, Escherichia coli metabolism, Hydrodynamics, Ions chemistry, Protons, Bacteria metabolism, Lasers

Abstract

Intense laser produced plasmas generate hot electrons which in turn leads to ion acceleration. Ability to generate faster ions or hotter electrons using the same laser parameters is one of the main outstanding paradigms in the intense laser-plasma physics. Here, we present a simple, albeit, unconventional target that succeeds in generating 700 keV carbon ions where conventional targets for the same laser parameters generate at most 40 keV. A few layers of micron sized bacteria coating on a polished surface increases the laser energy coupling and generates a hotter plasma which is more effective for the ion acceleration compared to the conventional polished targets. Particle-in-cell simulations show that micro-particle coated target are much more effective in ion acceleration as seen in the experiment. We envisage that the accelerated, high-energy carbon ions can be used as a source for multiple applications.

Published

2014

2. Luminous, relativistic, directional electron bunches from an intense laser driven grating plasma.

Author

Lad, Amit D., Mishima, Y., Singh, Prashant Kumar, Li, Boyuan, Adak, Amitava, Chatterjee, Gourab, Brijesh, P., Dalui, Malay, Inoue, M., Jha, J., Tata, Sheroy, Trivikram, M., Krishnamurthy, M., Chen, Min, Sheng, Z. M., Tanaka, K. A., Kumar, G. Ravindra, and Habara, H.

Subjects

PARTICLE beam bunching, SURFACE plasmon resonance, LASER pulses, RELATIVISTIC electrons, LASERS, RELATIVISTIC energy, ENERGY transfer

Abstract

Bright, energetic, and directional electron bunches are generated through efficient energy transfer of relativistic intense (~ 1019 W/cm2), 30 femtosecond, 800 nm high contrast laser pulses to grating targets (500 lines/mm and 1000 lines/mm), under surface plasmon resonance (SPR) conditions. Bi-directional relativistic electron bunches (at 40° and 150°) are observed exiting from the 500 lines/mm grating target at the SPR conditions. The surface plasmon excited grating target enhances the electron flux and temperature by factor of 6.0 and 3.6, respectively, compared to that of the plane substrate. Particle-in-Cell simulations indicate that fast electrons are emitted in different directions at different stages of the laser interaction, which are related to the resultant surface magnetic field evolution. This study suggests that the SPR mechanism can be used to generate multiple, bright, ultrafast relativistic electron bunches for a variety of applications. [ABSTRACT FROM AUTHOR]

Published

2022

3. Micro-optics for ultra-intense lasers.

Author

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

Subjects

MICRO-optics, LASER fusion, LASERS, INERTIAL confinement fusion, HOT carriers, RELATIVISTIC electrons

Abstract

Table-top, femtosecond lasers provide the highest light intensities capable of extreme excitation of matter. A key challenge, however, is the efficient coupling of light to matter, a goal addressed by target structuring and laser pulse-shaping. Nanostructured surfaces enhance coupling but require "high contrast" (e.g., for modern ultrahigh intensity lasers, the peak to picosecond pedestal intensity ratio >1012) pulses to preserve target integrity. Here, we demonstrate a foam target that can efficiently absorb a common, low contrast 105 (in picosecond) laser at an intensity of 5 × 1018 W/cm2, giving ∼20 times enhanced relativistic hot electron flux. In addition, such foam target induced "micro-optic" function is analogous to the miniature plasma-parabolic mirror. The simplicity of the target—basically a structure with voids having a diameter of the order of a light wavelength—and the efficacy of these micro-sized voids under low contrast illumination can boost the scope of high intensity lasers for basic science and for table-top sources of high energy particles and ignition of laser fusion targets. [ABSTRACT FROM AUTHOR]

Published

2021