**Author details**

Tae Moon Jeong and Jongmin Lee\*

\*Address all correspondence to: leejm@gist.ac.kr

Handong Global University, Pohang, Republic of Korea

### **References**


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can make use of the laser pulse as a small-scale and versatile particle accelerator. This is a primary purpose for developing high-intensity laser facilities. The interaction between an intense laser pulse and energetic charged particles produces high-energy photon as well. Many interesting schemes, such as undulator radiation, betatron radiation, and inverse Compton scattering, have been studied for producing high-energy photons. The high-energy photons can be used in many disciplines including industrial application, medical imaging, nuclear engineering, national security, and so on. As the intensity obtainable with the high-power laser

gated by light pulses with an ultrashort time scale. Since the invention of laser, the application field of laser has been dramatically expanded as the laser intensity increases. Now, the acceleration of charged particle by intense coherent light field became possible in the relativ‐ istic laser intensity regime, and new era for studying the laser-plasma interaction in the

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, some of the fundamental physical processes can be investi‐

pulse increases over 1024 W/cm2

30 High Energy and Short Pulse Lasers

Tae Moon Jeong and Jongmin Lee\*

\*Address all correspondence to: leejm@gist.ac.kr

Handong Global University, Pohang, Republic of Korea

dye laser. Appl. Phys. Lett. 1974;24(8):373–375.

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**Author details**

**References**

ultrarelativistic laser intensity regime will be open soon.


Esarey. Multi-GeV Electron beams from capillary-discharge-guided subpetawatt laser pulses in the self-trapping regime. Phys. Rev. Lett. 2014;113(24):245002.

