Photoexcitation Cascade and Quantum-Relativistic Jets in Graphene
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In Dirac materials linear band dispersion blocks momentum-conserving interband transitions, creating a bottleneck for electron-hole pair production and carrier multiplication in the photoexcitation cascade. Here we show that the decays are unblocked and the bottleneck is relieved by subtle many-body effects involving multiple off-shell e-h pairs. The decays result from a collective behavior due to simultaneous emission of many soft pairs. We discuss characteristic signatures of the off-shell pathways, in particular the sharp angular distribution of secondary carriers, resembling relativistic jets in high-energy physics. The jets can be directly probed using solid-state equivalent of particle detectors. Collinear scattering enhances carrier multiplication, allowing for emission of as many as ∼10 secondary carriers per single absorbed photon.
Date issued
2018-02Department
Massachusetts Institute of Technology. Department of PhysicsJournal
Physical Review Letters
Publisher
American Physical Society
Citation
Lewandowski, Cyprian and L. S. Levitov. "Photoexcitation Cascade and Quantum-Relativistic Jets in Graphene." Physical Review Letters 120, 7 (February 2018): 076601 © 2018 American Physical Society
Version: Final published version
ISSN
0031-9007
1079-7114