Attosecond pulse formation in the "water window" range by optically dressed hydrogen-like plasma-based C5+ X-ray laser

TL;DR

This paper develops an analytical theory for generating attosecond pulses in the water window range using a plasma-based X-ray laser modulated by an optical field, achieving sub-200 attosecond pulses with high intensity.

Contribution

It introduces an analytical model for attosecond pulse formation in plasma-based X-ray lasers considering population inversion dynamics and optical modulation, validated by numerical solutions.

Findings

Attosecond pulses shorter than 200 as can be produced.

Peak intensity of pulses exceeds 10^12 W/cm^2.

Pulse shape can be optimized by spectral attenuation or absorption techniques.

Abstract

In this paper, we present the analytical theory of attosecond pulse formation via optical modulation of an active medium of the hydrogen-like C5+ plasma-based X-ray laser at 3.4 nm wavelength in the "water window" range, taking into account a variation of the population inversion caused by radiative decay of the upper lasing states. We derive an analytical solution for the X-ray field amplified by an X-ray laser with time-dependent population inversion, which is simultaneously irradiated by a strong optical laser field, and use it to find the optimal conditions for the attosecond pulse formation from a narrowband seeding X-ray field. We show that the shape of pulses can be improved at the cost of reduced pulse peak intensity (i) via external attenuation of the resonant spectral component of the amplified X-ray field or (ii) by using a resonantly absorbing medium (the active medium of the X-ray laser after the change of sign of the population inversion) for the pulse formation. The results of the analytical theory are in a good agreement with the numerical solutions of the Maxwell-Bloch equations which account for the nonlinearity, as well as the amplified spontaneous emission, of the active medium. Both analytically and numerically we show the possibility to produce a train of attosecond pulses with sub-200 as duration and the peak intensity exceeding 10^12 W/cm^2 at the carrier wavelength 3.4 nm in the "water window" range, which makes them attractive for the biological and medical applications.