AI Article Synopsis
- Photoemission involves generating charged particles from materials when exposed to photons, and advancements in ultrashort lasers have enabled research into this process at very fast timescales (femtoseconds).
- Experimental measurements were conducted using two ultrashort ultraviolet laser pulses to investigate how these pulses influence electron release from a copper cathode within a radio-frequency photoinjector.
- By adjusting the delay between the laser pulses, the study examined the impact of two-photon photoemission on beam brightness and analyzed the outcomes in relation to the electronic temperature, modeling the cathode as a two-temperature system.
Article Abstract
Photoemission is one of the fundamental processes that describes the generation of charged particles from materials irradiated by photons. The continuous progress in the development of ultrashort lasers allows investigation into the dynamics of the process at the femtosecond timescale. Here we report about experimental measurements using two ultrashort ultraviolet laser pulses to temporally probe the electrons release from a copper cathode in a radio-frequency photoinjector. By changing their relative delay, we studied how the release mechanism is affected by two-photon photoemission when tens of / intensities are employed. We evaluated the limits it poses on the achievable beam brightness and analyzed the resulting emission yield in terms of the electronic temperature by modeling the cathode as a two-temperature system.
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| http://dx.doi.org/10.1364/OL.423880 | DOI Listing |
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