Pump requirements for betatron-generated femtosecond X-ray laser at saturation from inner-shell transitions

M. Ribière; S. Sebban; S. Jacquemot; B. G. Chéron; K. Ta Phuoc; J. Gautier; J. Grunenwald; P. Ribeiro; M. Kozlova; P. Zeitoun; A. Rousse

doi:10.1007/s00340-012-4912-1

Pump requirements for betatron-generated femtosecond X-ray laser at saturation from inner-shell transitions

M. Ribière
, S. Sebban
, S. Jacquemot
, B. G. Chéron
, K. Ta Phuoc
, J. Gautier
, J. Grunenwald
, P. Ribeiro
, M. Kozlova
, P. Zeitoun
, A. Rousse

Research output: Contribution to journal › Article › peer-review

Abstract

We study pump requirements to produce femtosecond X-ray laser pulses at saturation from inner-shell transitions in the amplified spontaneous emission regime. Since laser-based betatron radiation is considered as the pumping source, we first study the impact of the driving laser power on its intensity. Then we investigate the amplification behavior of the K-α transition of nitrogen at 3.2 nm (395 eV) from radiative transfer calculations coupled with kinetics modeling of the ion population densities. We show that the saturation regime may be experimentally achieved by using PW-class laser-accelerated electron bunches. Finally, we show that this X-ray laser scheme can be extended to heavier atoms and we calculate pump requirements to reach saturation at 1.5 nm (849 eV) from the K-α transition of neon.

Original language	English
Pages (from-to)	809-816
Number of pages	8
Journal	Applied Physics B: Lasers and Optics
Volume	106
Issue number	4
DOIs	https://doi.org/10.1007/s00340-012-4912-1
Publication status	Published - 1 Mar 2012

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title = "Pump requirements for betatron-generated femtosecond X-ray laser at saturation from inner-shell transitions",

abstract = "We study pump requirements to produce femtosecond X-ray laser pulses at saturation from inner-shell transitions in the amplified spontaneous emission regime. Since laser-based betatron radiation is considered as the pumping source, we first study the impact of the driving laser power on its intensity. Then we investigate the amplification behavior of the K-α transition of nitrogen at 3.2 nm (395 eV) from radiative transfer calculations coupled with kinetics modeling of the ion population densities. We show that the saturation regime may be experimentally achieved by using PW-class laser-accelerated electron bunches. Finally, we show that this X-ray laser scheme can be extended to heavier atoms and we calculate pump requirements to reach saturation at 1.5 nm (849 eV) from the K-α transition of neon.",

author = "M. Ribi{\`e}re and S. Sebban and S. Jacquemot and Ch{\'e}ron, \{B. G.\} and \{Ta Phuoc\}, K. and J. Gautier and J. Grunenwald and P. Ribeiro and M. Kozlova and P. Zeitoun and A. Rousse",

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doi = "10.1007/s00340-012-4912-1",

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TY - JOUR

T1 - Pump requirements for betatron-generated femtosecond X-ray laser at saturation from inner-shell transitions

AU - Ribière, M.

AU - Sebban, S.

AU - Jacquemot, S.

AU - Chéron, B. G.

AU - Ta Phuoc, K.

AU - Gautier, J.

AU - Grunenwald, J.

AU - Ribeiro, P.

AU - Kozlova, M.

AU - Zeitoun, P.

AU - Rousse, A.

PY - 2012/3/1

Y1 - 2012/3/1

N2 - We study pump requirements to produce femtosecond X-ray laser pulses at saturation from inner-shell transitions in the amplified spontaneous emission regime. Since laser-based betatron radiation is considered as the pumping source, we first study the impact of the driving laser power on its intensity. Then we investigate the amplification behavior of the K-α transition of nitrogen at 3.2 nm (395 eV) from radiative transfer calculations coupled with kinetics modeling of the ion population densities. We show that the saturation regime may be experimentally achieved by using PW-class laser-accelerated electron bunches. Finally, we show that this X-ray laser scheme can be extended to heavier atoms and we calculate pump requirements to reach saturation at 1.5 nm (849 eV) from the K-α transition of neon.

AB - We study pump requirements to produce femtosecond X-ray laser pulses at saturation from inner-shell transitions in the amplified spontaneous emission regime. Since laser-based betatron radiation is considered as the pumping source, we first study the impact of the driving laser power on its intensity. Then we investigate the amplification behavior of the K-α transition of nitrogen at 3.2 nm (395 eV) from radiative transfer calculations coupled with kinetics modeling of the ion population densities. We show that the saturation regime may be experimentally achieved by using PW-class laser-accelerated electron bunches. Finally, we show that this X-ray laser scheme can be extended to heavier atoms and we calculate pump requirements to reach saturation at 1.5 nm (849 eV) from the K-α transition of neon.

U2 - 10.1007/s00340-012-4912-1

DO - 10.1007/s00340-012-4912-1

M3 - Article

AN - SCOPUS:84859725465

SN - 0946-2171

VL - 106

SP - 809

EP - 816

JO - Applied Physics B: Lasers and Optics

JF - Applied Physics B: Lasers and Optics

IS - 4

ER -

Pump requirements for betatron-generated femtosecond X-ray laser at saturation from inner-shell transitions

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