Fig. 1. Temperature and density range of typical plasma

Fig. 2. Area division of distribution of permittivity and permeablity of materials

Fig. 3. Schematic diagram of PEPC

Fig. 4. Schematic diagram of low loss PEPC based on DKDP crystal

Fig. 5. Design diagram of reflective PEPC

Fig. 6. Basic principle of laser amplification based on plasma medium

Fig. 7. (a) The gas-filled balloon target is used to create a uniform plasma to amplify a single seed beam (red) by combination of eight pumping beams (yellow), (b) the incident power of all the beams

Fig. 8. Laser pulse-shape conditioning with a double plasma-mirror (DPM)

Fig. 9. Temporal profile of the laser pulses delivered by a 10 TW, 60 fs laser system, in logarithmic scale, with and without DPM

Fig. 10. (a) Experimental setup for tight focusing of ultrahigh-intensity laser pulses by low F-number confocal EPM. (b) Focal spot provided by the conventional F/2.7 output. (c) Focal spot in the output of the F/0.4, images are in common logarithm scale

Fig. 11. (a) Schematic diagram of cross beam interaction in plasma. (b) Excitation characteristics of cross beam energy transfer and phase shift

Fig. 12. Conceptual design of plasma polarizer and plasma wave plate

Fig. 13. The extreme Faraday effect of strongly magnetized plasma

Fig. 14. Schematic of the target arrangement to study the interaction of the PII-beam with a solid target

Fig. 15. Schematic of a plasma optical modulator

Fig. 16. Schematic diagram of plasma holographic formation process

Fig. 17. Characteristics of Q-plate based on magnetized plasma