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D. Comparat

Identifiers

  • name variant D. Comparat 0.60 · backfill

Papers (31)

  1. Fluorescence and Relaxation Dynamics of Cesium in Argon Matrices: Multiple Trapping Sites and Host-Guest Interactions physics.atom-ph · 2026 · author #9
  2. Analytical emission model for the design of primary effusive sources physics.atom-ph · 2026 · author #4
  3. Positronium laser cooling via the $1^3S$-$2^3P$ transition with a broadband laser pulse physics.atom-ph · 2023 · author #18
  4. High repetition rate sub ns-electron pulses from Resonant Pulsed Rydberg Field Ionization physics.atom-ph · 2023 · author #2
  5. A cryogenic tracking detector for antihydrogen detection in the AEgIS experiment physics.ins-det · 2022 · author #10
  6. Determining a vibrational distribution with a broadband optical source physics.atom-ph · 2020 · author #3
  7. Ion and Electron Ghost Imaging physics.ins-det · 2020 · author #3
  8. Rydberg-positronium velocity and self-ionization studies in 1T magnetic field and cryogenic environment physics.atom-ph · 2019 · author #8
  9. Narrow-Band Pulsed Electron Source Based on Near-Threshold Photoionization of Cs in a Magneto-Optical Trap physics.atom-ph · 2019 · author #5
  10. Efficient $2^3S$ positronium production by stimulated decay from the $3^3P$ level physics.atom-ph · 2019 · author #10
  11. Real-time trajectory control on a deterministic ion source physics.ins-det · 2018 · author #3
  12. Velocity selected production of $2^3S$ metastable positronium physics.atom-ph · 2018 · author #11
  13. Producing long-lived $2^3\text{S}$ Ps via $3^3\text{P}$ laser excitation in magnetic and electric fields physics.atom-ph · 2018 · author #12
  14. Rovibrational optical cooling of a molecular beam physics.atom-ph · 2017 · author #4
  15. Measurement of antiproton annihilation on Cu, Ag and Au with emulsion films hep-ex · 2017 · author #13
  16. Ion microscopy based on laser-cooled cesium atoms cond-mat.mes-hall · 2016 · author #9
  17. Annihilation of low energy antiprotons in silicon physics.ins-det · 2013 · author #16
  18. Laser cooling of rotation and vibration by optical pumping physics.atom-ph · 2013 · author #8
  19. Rovibrational cooling of molecules by optical pumping physics.atom-ph · 2012 · author #7
  20. Observation of a resonant four-body interaction in cold cesium Rydberg atoms physics.atom-ph · 2011 · author #7
  21. Coherent excitation of a single atom to a Rydberg state quant-ph · 2010 · author #5
  22. Entanglement of two individual atoms using the Rydberg blockade quant-ph · 2009 · author #9
  23. Observation of collective excitation of two individual atoms in the Rydberg blockade regime quant-ph · 2008 · author #6
  24. Formation Of A Cold Antihydrogen Beam in AEGIS For Gravity Measurements physics.atom-ph · 2008 · author #14
  25. Efficient positronium laser excitation for antihydrogen production in a magnetic field quant-ph · 2008 · author #5
  26. Non-Holonomic Control IV : Coherence Protection in a Rubidium isotope quant-ph · 2005 · author #3
  27. Non-Holonomic Control III : Coherence Protection by the Quantum Zeno Effect and Non-Holonomic Control quant-ph · 2005 · author #3
  28. Non-holonomic Control II : Non-holonomic Quantum Devices quant-ph · 2005 · author #3
  29. Non-Holonomic Control I quant-ph · 2005 · author #3
  30. Implementation of a CNOT gate in two Rydberg atoms by the nonholonomic control technique quant-ph · 2005 · author #2
  31. Coherence protection by the quantum Zeno effect and non-holonomic control in a Rydberg Rubidium isotope quant-ph · 2004 · author #3

Mentions

  • 2308.15333 #2 · arxiv_oai · confidence 0.70 D. Comparat
  • 2310.08760 #18 · arxiv_oai · confidence 0.70 D. Comparat
  • 2203.03055 #10 · arxiv_oai · confidence 0.70 D. Comparat
  • 1911.04342 #8 · arxiv_oai · confidence 0.70 D. Comparat
  • 2010.01088 #3 · arxiv_oai · confidence 0.70 D. Comparat
  • 2003.02186 #3 · arxiv_oai · confidence 0.70 D. Comparat
  • 1909.03791 #5 · arxiv_oai · confidence 0.70 D. Comparat
  • 1904.09004 #10 · arxiv_oai · confidence 0.70 D. Comparat
  • 0805.4727 #14 · arxiv_oai · confidence 0.70 D. Comparat
  • 1812.09039 #3 · arxiv_oai · confidence 0.70 D. Comparat
  • 1808.01808 #11 · arxiv_oai · confidence 0.70 D. Comparat
  • 1802.07012 #12 · arxiv_oai · confidence 0.70 D. Comparat
  • 1709.06797 #4 · arxiv_oai · confidence 0.70 D. Comparat
  • 0910.0729 #9 · arxiv_oai · confidence 0.70 D. Comparat
  • 1701.06306 #13 · arxiv_oai · confidence 0.70 D. Comparat
  • quant-ph/0403227 #3 · arxiv_oai · confidence 0.70 D. Comparat
  • 1601.01446 #9 · arxiv_oai · confidence 0.70 D. Comparat
  • 1111.2488 #7 · arxiv_oai · confidence 0.70 D. Comparat
  • 1005.2153 #5 · arxiv_oai · confidence 0.70 D. Comparat
  • 1311.4982 #16 · arxiv_oai · confidence 0.70 D. Comparat
  • 1306.3461 #8 · arxiv_oai · confidence 0.70 D. Comparat
  • 1211.2652 #7 · arxiv_oai · confidence 0.70 D. Comparat
  • 0810.2960 #6 · arxiv_oai · confidence 0.70 D. Comparat
  • 0804.0371 #5 · arxiv_oai · confidence 0.70 D. Comparat
  • quant-ph/0507159 #3 · arxiv_oai · confidence 0.70 D. Comparat
  • quant-ph/0507158 #3 · arxiv_oai · confidence 0.70 D. Comparat
  • quant-ph/0507157 #3 · arxiv_oai · confidence 0.70 D. Comparat
  • quant-ph/0507156 #3 · arxiv_oai · confidence 0.70 D. Comparat
  • quant-ph/0507112 #2 · arxiv_oai · confidence 0.70 D. Comparat
  • 1311.4982 #16 · backfill · confidence 0.70 D. Comparat
  • 1306.3461 #8 · backfill · confidence 0.70 D. Comparat
  • 1211.2652 #7 · backfill · confidence 0.70 D. Comparat
  • 1111.2488 #7 · backfill · confidence 0.70 D. Comparat
  • 2605.15840 #9 · arxiv_oai · confidence 0.70 D. Comparat
  • 1005.2153 #5 · backfill · confidence 0.70 D. Comparat
  • 0910.0729 #9 · backfill · confidence 0.70 D. Comparat
  • 0810.2960 #6 · backfill · confidence 0.70 D. Comparat
  • 0804.0371 #5 · backfill · confidence 0.70 D. Comparat

Frequent Coauthors