High Power Laser Science and Engineering, Volume. 10, Issue 4, 04000e23(2022)
Parametric dependence of collisional heating of highly magnetized over-dense plasma by (far-)infrared lasers
Figures & Tables(4)
Fig. 1. The temperature of plasma versus laser propagation depth inside plasma for the incident planar flat-top RHCP laser with duration of 1 ns except for the red solid curve of 10 ns. Parameters of the two identical black curves in (a) and (b): laser wavelength of 
, intensity of 
, duration of 
ns, plasma density of 
, initial plasma temperature of 
keV and magnetic field of 
T. Each of the other six colourful curves has one of the above parameters being changed, that is, (a) 
ns (red, solid), 
(blue, solid), 
T (green, solid) and 
T (orange, solid); (b) 
(red, dotted), 
eV (blue, dotted) and 
(green, dotted).
Fig. 2. Heating of plasma with different densities by 
laser and Nd:YAG laser with 
, 
ns and 
keV. (a) Plasma temperature at the vacuum–plasma boundary versus plasma density: 
, 
T (black) and 
, 
T (red). (b) Averaged heating depth versus plasma density: 
, 
T (black) and 
, 
T (red), where the dots denote simulated depth and the lines denote the fitted curve.
Fig. 3. Heating of various plasmas by 
laser. (a) The uniform plasma is similar to the compressed plasma in Gotchev 
(blue) or 
(orange), 
ns, 
T and 
keV. (b) Sandwiched target with plasma densities of 
(
and 
) and 
(blue) or 
(yellow) (
), where 
, 
ns, 
keV and 
T.
Table 1. Power transmission of the laser (Trans.), increase of plasma temperature at the vacuum–plasma boundary (
), averaged heating depth in micrometres (
) and energy conversion efficiency from laser to plasma (
) versus various parameters, where 
means ‘increase with’, 
means ‘decrease with’ and 
means ‘not sensitive to’.View tableView in ArticleTable 1. Power transmission of the laser (Trans.), increase of plasma temperature at the vacuum–plasma boundary (
), averaged heating depth in micrometres () and energy conversion efficiency from laser to plasma () versus various parameters, where means ‘increase with’, means ‘decrease with’ and means ‘not sensitive to’.${n}_{\mathrm{e}}$ ${T}_0$ ${B}_0$ ${I}_{\mathrm{L}}$ ${\tau}_{\mathrm{L}}$ ${\lambda}_{\mathrm{L}}$ Trans. $\downarrow$ $\to$ $\uparrow$ $\to$ $\to$ $\uparrow$ ${T}_{\mathrm{b}}-{T}_0$ $\uparrow$ $\downarrow$ $\downarrow$ $\uparrow$ $\uparrow$ $\downarrow$ ${d}_{\mu \mathrm{m}}$ $\downarrow$ $\uparrow$ $\uparrow$ $\uparrow$ $\uparrow$ $\uparrow$ ${\eta}_{\mathrm{L}\to \mathrm{P}}$ $\downarrow$ $\to$ $\uparrow$ $\downarrow$ $\downarrow$ $\downarrow$
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K. Li, W. Yu. Parametric dependence of collisional heating of highly magnetized over-dense plasma by (far-)infrared lasers[J]. High Power Laser Science and Engineering, 2022, 10(4): 04000e23
Paper Information
Category: Research Articles
Received: May. 6, 2022
Accepted: Jun. 8, 2022
Published Online: Nov. 1, 2022
The Author Email: K. Li (kunli@stu.edu.cn)
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