m
m (Papers to read)
Line 2: Line 2:
 
= Papers to read =
 
= Papers to read =
  
From {{thisday|31|December|2023}} onward, {{I}}'m starting the new "tradition" of keeping track of the papers I need to read. By "read" I mean, really, "study" in some depth (skimming through a paper is the lot of the researcher).
+
From {{thisday|31|December|2023}} onward, {{I}}'m starting the new "tradition" of keeping track of the papers I need to read. By "read" I mean, really, "study" in some depth (skimming through a paper is the lot of the researcher), and typically record a summary and/or thoughts/comments on the work itself (which can be accessed by clicking on the title).
  
 
# {{wang19a}} Since 14:57 on {{thisday|31|December|2023}} for its fundamental and extremely clean characterization of a [[2LS]].
 
# {{wang19a}} Since 14:57 on {{thisday|31|December|2023}} for its fundamental and extremely clean characterization of a [[2LS]].

Revision as of 12:59, 2 January 2024

Si l’on mettait d’un côté ce qu’il a ingurgité durant sa vie et de l’autre ce qu’il a rendu par le haut et par le bas, cela ferait deux énormes tas. C’est ainsi qu’il se présentera un jour devant Dieu, avec ses deux tas, l’un à sa droite, l’autre à sa gauche.
Nikos Kazantzakis dans «Le Christ Recrucifié» (Ο Χριστός Ξανασταυρώνεται)

Papers to read

From 31 December (2023) onward, I'm starting the new "tradition" of keeping track of the papers I need to read. By "read" I mean, really, "study" in some depth (skimming through a paper is the lot of the researcher), and typically record a summary and/or thoughts/comments on the work itself (which can be accessed by clicking on the title).

  1. Turning a molecule into a coherent two-level quantum system . D. Wang, H. Kelkar, D. Martin-Cano, D. Rattenbacher, A. Shkarin, T. Utikal, S. Götzinger and V. Sandoghdar in Nature Phys. 15:483 (2019). Since 14:57 on 31 December (2023) for its fundamental and extremely clean characterization of a 2LS.
  2. Photon Bunching in Cathodoluminescence. S. Meuret, L. Ti, N. T. Cazima, N. R. Bourrell, N. H. C., A. F. Treu and A. M. Kociak in Phys. Rev. Lett. 114:197401 (2015). Since 16:01 on 31 December (2023), for their $1/N$ analysis of the antibunching of $N$ emitters.
  3. Photophysics of quantum emitters in hexagonal boron-nitride nano-flakes. M. K. Boll, I. P. Radko, A. Huck and U. L. Andersen in Opt. Express 28:7475 (2020). Since 16:02 on 31 December (2023) for their flat $g^{(2)}(\tau)$ (see Fig. 3).
  4. Stable Solid-State Source of Single Photons. C. Kurtsiefer, S. Mayer, P. Zarda and H. Weinfurter in Phys. Rev. Lett. 85:290 (2000). Since 16:07 on 31 December (2023). GreenTick.png19:00 on 31 December (2023)
  5. Limitations on Practical Quantum Cryptography. G. Brassard, N. Lütkenhaus, T. Mor and B. C. Sanders in Phys. Rev. Lett. 85:1330 (2000). Since 16:17 on 31 December (2023) for SPDC being better than weak laser pulses (I'm interested in general in how weak laser pulses are useless SPS for QIP).
  6. Photophysics of single silicon vacancy centers in diamond: implications for single photon emission. E. Neu, M. Agio and C. Becher in Opt. Express 20:19956 (2012). Since 19:26 on 31 December (2023) for further details on shelving dynamics on $g^{(2)}$.
  7. Electrically driven photon antibunching from a single molecule at room temperature. M. Nothaft, S. Höhla, F. Jelezko, N. Frühauf, J. Pflaum and J. Wrachtrup in Nature Comm. 3:628 (2012). Since 19:28 on 31 December (2023) for further details their model for $g^{(2)}$.
  8. Multiple time scale blinking in InAs quantum dot single-photon sources. M. Davanço, C. S. Hellberg, S. Ates, A. Badolato and K. Srinivasan in Phys. Rev. B 89:161303 (2014). Since 19:31 on 31 December (2023) for details on their very elaborate rate-equation description of $g^{(2)}$.
  9. Photophysics of single nitrogen-vacancy centers in diamond nanocrystals. M. Berthel, O. Mollet, G. Dantelle, T. Gacoin, S. Huant and A. Drezet in Phys. Rev. B 91:035308 (2015). Since 19:41 on 31 December (2023) for further details their model for $g^{(2)}$.
  10. Probabilité des jugements en matière criminelle et en matière civile, précédées des règles générales du calcul des probabilités, S. Poisson, Paris, France: Bachelier (1837). Since 18:29 on 1 January (2024) ‒ classic.
  11. Correlations in light emitted by three-level atoms. D. T. Pegg, R. Loudon and P. L. Knight in Phys. Rev. A 33:4085 (1986). for their quantum model producing bunching elbows Since 19:43 on 1 January (2024).
  12. Single germanium vacancy centers in nanodiamonds with bulk-like spectral stability. M. Nahra, D. Alshamaa, R. Deturche, V. Davydov, L. Kulikova, V. Agafonov and C. Couteau in AVS Quantum Sci. 3:012001 (2021). Since 20:02 on 1 January (2024) for their shelving model.
  13. Photon Bunching in Cathodoluminescence. S. Meuret, L. Ti, N. T. Cazima, N. R. Bourrell, N. H. C., A. F. Treu and A. M. Kociak in Phys. Rev. Lett. 114:197401 (2015). Since 20:02 on 1 January (2024) for their shelving model and supplementary material.
  14. Bringing home the atomic world: Quantum mysteries for anybody. N. D. Mermin in Am. J. Phys. 49:940 (1981). Since 12:43 on 2 January (2024) — one of the best papers of physics according to Feynman
  15. Is the Moon There When Nobody Looks? Reality and the Quantum Theory. N. D. Mermin in Physics Today 38:38 (1985). Since 10:25 on 2 January (2024) The polished version of the above (with a cameo by Feynman). GreenTick.png12:58 on 2 January (2024)
  16. What is quantum mechanics trying to tell us?. N. D. Mermin in Am. J. Phys. 66:753 (1998). Since 10:27 on 2 January (2024).

As well as those I did finally read:

  1. Stable Solid-State Source of Single Photons. C. Kurtsiefer, S. Mayer, P. Zarda and H. Weinfurter in Phys. Rev. Lett. 85:290 (2000). Since 16:07 on 31 December (2023). GreenTick.png19:00 on 31 December (2023)
  2. Is the Moon There When Nobody Looks? Reality and the Quantum Theory. N. D. Mermin in Physics Today 38:38 (1985). Since 10:25 on 2 January (2024) The polished version of the one below (with a cameo by Feynman). GreenTick.png12:58 on 2 January (2024)