Uybelacker, M. et al. Real-time attosecond observation of electron tunneling within atoms. nature 446627–632 (2007).
Young, L. et al. Femtosecond electronic response of atoms to ultra-intense X-rays. nature 46656–61 (2010).
Driver, T. et al. Attosecond delays in X-ray molecular ionization. nature 632762–767 (2024).
Gambhir, SS Molecular imaging of cancer by positron emission tomography. nut. cancer pastor 2683–693 (2002).
Lecoq, P., Korzhik, M., Vasiliev, A. Can transient phenomena help improve the temporal resolution of scintillators? IEEE Trans. Nucl.Science. 61229–234 (2014).
Surti, S. & Karp, JS An update on the latest advances in time-of-flight PET. Physics. medicine. 80251–258 (2020).
Ritos, M. et al. Highly efficient acceleration of electron beams in plasma wakefield accelerators. nature 51592–95 (2014).
van Tilborg, J., Gonsalves, AJ, Esarey, E., Schroeder, CB & Leemans, WP Highly sensitive plasma density retrieval in a common-pass second harmonic interferometer with simultaneous measurements of group and phase velocities. Physics. plasma 26023106 (2019).
Teubner, U., Bergmann, J., Van Wonterghem, B., Schafer, FP & Sauerbrey, R. Angle-dependent X-ray emission and resonant absorption in laser-produced plasmas generated by high-intensity ultrashort pulses. Physics. Pastor Rhett. 70794–797 (1993).
Emma, P. et al. Initial oscillation and operation of angstrom wavelength free electron lasers. nut. photon. 4641–647 (2010).
Altarelli, M. European X-ray Free Electron Laser Facility in Hamburg. Nuclear equipment methods Physics B 2692845–2849 (2011).
Decking, W. et al. MHz repetition rate hard X-ray free electron laser driven by a superconducting linear accelerator. nut. photon. 14391–397 (2020).
Lecoq, P. and others. A roadmap to the 10 ps flight time PET challenge. Physics. medicine. Biol. 6521RM01 (2020).
Ultrafast timing enables reconstruction-free positron emission imaging. nut. photon. 15914–918 (2021).
M. Kolzik, G. Tamuratis, AN Vasilev Physics of fast scintillator processes (Springer International Publishing, 2020).
Tao, K. A simulation study to understand the sensitivity and timing characteristics of a PET optical property modulation-based radiation detection concept. Physics. medicine. Biol. 65215021 (2020).
Jeong, D. et al. Cascading time and density simulation of ionized charge carriers for a new radiation detection method based on modulation of optical properties. medicine. Physics. 511383–1395 (2024).
Miller, DAB Atjoule Optoelectronics for Low Energy Information Processing and Communications. J. Lightwave technology. 35346–396 (2017).
Roques-Carmes, C. et al. A scintillation framework in nanophotonics. science 375eabm9293 (2022).
Tao, L., Daghighian, HM & Levin, CS Promising new mechanism for ionizing radiation detection in positron emission tomography: modulation of optical properties. Physics. medicine. Biol. 617600–7622 (2016).
Coincident time resolution of 30 ps FWHM using MCP-PMT pair integrated with Cerenkov radiator by Ryo Ota et al. Physics. medicine. Biol. 6407LT01 (2019).
Kim, H.W. et al. Aiming for jitter-free ultrafast electron diffraction technology. nut. photon. 14245–249 (2020).
Weathersby, SP et al. Mega-electronvolt ultrafast electron diffraction at SLAC National Accelerator Laboratory. Rev. Know Instrument 86073702 (2015).
Harmand, M. et al. Achieving time selection of several femtoseconds using a hard X-ray free electron laser. nut. photon. 7215–218 (2013).
Diez, M. et al. High-sensitivity, high-repetition arrival time monitor for X-ray free electron lasers. nut. General. 141–9 (2023).
Tao, L., Coffee, RN, Jeong, D. & Levin, CS Ionizing photon interactions modulate optical properties of crystals with femtosecond-scale time resolution. Physics. medicine. Biol. 66045032 (2021).
Cesar, DB, Musumeci, P. & Alesini, D. Ultrafast gating of mid-infrared laser pulses with sub-PC relativistic electron beams. J. Appl. Physics. 118234506 (2015).
Jeong, D. et al. Study of complex refractive index modulation induced by ultrafast relativistic electrons using infrared and THz probe pulses. Physics. medicine. Biol. 69235010 (2024).
Bethe, H. Braking formula for electrons at relativistic velocities. Z. Physics. 76293–299 (1932).
Burstein, E. Anomalous optical absorption limits of InSb. Physics. pastor 93632–633 (1954).
Moss, T.S. Interpretation of the properties of indium antimonide. Procedural physics. Society B 67775–782 (1954).
Durbin, SM, Clevenger, T., Graber, T. & Henning, R. X-ray pumped optical probe cross-correlation studies of GaAs. nut. photon. 6111–114 (2012).
Oudar, JL, Hulin, D., Migus, A., Antonetti, A. & Alexandre, F. Sub-picosecond spectral hole burning by non-thermalized photoexcited carriers in GaAs. Physics. Pastor Rhett. 552074–2077 (1985).
Manser, JS, Kamat, PV Band filling with free charge carriers in organometallic halide perovskites. nut. photon. 8737–743 (2014).
Price, M. et al. Hot carrier cooling and photoinduced refractive index changes in organic-inorganic lead halide perovskites. nut. General. 68420 (2015).
Ziaja, B. et al. Time-resolved observation of band gap reduction and electron lattice thermalization in X-ray excited gallium arsenide. Science. Member of Parliament 518068 (2016).
Baró, J., Sempau, J., Fernández-Varea, JM & Salvat, F. PENELOPE: Algorithm for Monte Carlo simulation of electron and positron penetration and energy loss in materials. Nuclear equipment methods Physics B 10031–46 (1995).
Mott, NF Electrons in disordered structures. Advanced Physics. 1649–144 (1967).
Bennett, BR, Soref, RA & Del Alamo, JA Carrier-induced refractive index changes in InP, GaAs, and InGaAsP. IEEE J. Quantum Electron. 26113–122 (1990).
Alig, RC & Bloom, S. Electron-hole pair generation energy in semiconductors. Physics. Pastor Rhett. 35677–680 (1977).
Google Scholar
Wolff, PA Theory of the band structure of highly degenerate semiconductors. Physics. pastor 126405–412 (1962).
Cardona, M. & Greenaway, DL Fundamental reflectance and band structure of ZnTe, CdTe, and HgTe. Physics. pastor 13198–103 (1963).
Shkayev, P. et al. Excitation-dependent carrier lifetimes and diffusion lengths in bulk CdTe are determined by time-resolved optical pump-probe techniques. J. Appl. Physics. one two three025704 (2018).
Nie, Z. et al. Cross-polarized common-path temporal interferometry for highly sensitive strong-field ionization measurements. option. express 3025696–25706 (2022).
Polianski, Minnesota Refractiveindex.info optical constant database. Science. data 1194 (2024).
Tellinghuisen, J. Propagation of statistical errors. J. Phys. Chemistry. a 1053917–3921 (2001).
Pinard, P., Demers, H., Salvat, F., Gauvin, R. pyPENELOPE http://pypenelope.sourceforge.net (2016).
Jeong, D. et al. Dataset of strong ultrafast nonlinear optical responses from MeV electrons in semiconductors. fig share https://doi.org/10.6084/m9.figshare.28199918 (2026).
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