jacky even
Professor INSA Rennes
https://www.insa-rennes.fr/
FOTON Institute (CNRS lab. UMR 6082)
http://foton.cnrs.fr/v2016/
13
Documents
Identifiants chercheurs
- jacky-even
- ResearcherId : C-6212-2008
- 0000-0002-4607-3390
- Google Scholar : https://scholar.google.fr/citations?user=wZSGnjYAAAAJ&hl=fr
- IdRef : 076470482
- ResearcherId : http://www.researcherid.com/rid/C-6212-2008
Site web
- http://www.iufrance.fr/les-membres-de-liuf/membre/1913-jacky-even.html
Présentation
1984-1988: ENS Cachan (now ENS Paris-Saclay): Physics
1987-1988: Agrégation in Physics, Master Degree in Liquid Physics
1989-1992: University Paris VI/ Rennes I, PhD Thesis
1992-1999: Associate Professor (University Rennes I), Habilitation Degree
1999-now: Professor, Institut National des sciences Appliquées (INSA) de Rennes
1999-now: Creation and head of FOTON-INSA simulation team https://www.institut-foton.eu/physique-des-materiaux-et-dispositifs-perovskites/
2006-2009: Head of Materials Science and Nanotechnology Department, INSA Rennes
2010-2012: Director of Education, INSA Rennes
2018-2023: Senior member of IUF (Institut Universitaire de France) (http://www.iufrance.fr/les-membres-de-liuf/membre/1913-jacky-even.html)
2019/2020/2021/2022/2023: Highly Cited Researcher (Clarivate Analytics) https://clarivate.com/highly-cited-researchers/
2022 [Jean-Ricard Prize of the French Physical Society ](https://www.sfpnet.fr/jacky-even-laureat-du-prix-jean-ricard-2022-de-la-sfp)
2023-now: Re-elected Senior member of IUF
2013 : Video of invited presentation about Halide perovskites (in French):[videos-jnpv\_2013](http://webcast.in2p3.fr/videos-jnpv_2013_avancees_recentes_dans_le_domaine_des_perovskites_hybrides_pour_les_applications_photovoltaiques__jacky_even) containing among others: the first theoretical predictions of exciton screening in halide perovskites, importance of spin-orbit coupling, Rashba-Dresselhaus effect, symmetry analyses, first predictions of Kane parameters and results published in J. Even et al, Phys. Rev B 2012, J. Phys. Chem. Lett. 2013, J. Phys. Chem. C 2014, RRL Solar 2014, ChemPhysChem 2014. More presentations (in French) in 2016: https://videosjnpv2016.geeps.centralesupelec.fr/files/hybrides-organiques-perovskites_1.mp4. and 2021: https://videosjnpv2021.geeps.centralesupelec.fr/files/even.mp4
The prediction in 2013 (https://hal.science/hal-04500208) of low exciton binding energy and high effective dielectric constant of primary importance for the perovskite photovoltaic mechanism was finally published in 2014 (Even et al J. Phys. Chem. C 118, 11566, 2014) and exactly checked experimentally in 2015 by H. Snaith and coworkers at LNCMI Toulouse and Oxford University (Miyata et al, Nature Physics 11, 582, 2015)
Selected papers (2016-2023):
H. Tsai et al, Nature 536, 312 (2016)
W Nie et al, Nature Comm. 5, 11574 (2016)
H. Fang et al, Science Adv. 2, e1600534 (2016)
H. Fang et al, Light Science and Appl. 5, e16056 (2016)
A. Neukirch et al, Nano Letters 16, 3809 (2016)
L. Pedesseau et al, ACS Nano 10, 9776 (2016)
J. Even et al, Nanoscale 8, 6222 (2016)
D. Sapori et al, Nanoscale 8, 6369 (2016)
C. Robert et al, Phys. Rev.B 94, 075445 (2016)
J.C. Blancon et al, Science eaal4211 (2017)
M. Fu et al, Nano Letters 17, 2895 (2017)
H. Tsai et al, Adv. Ener. Mat. 7, 1602159 (2017)
C. Soe et al, J. Am. Chem. Soc. 139, 6297 (2017)
L. Mao et al, J. Am. Chem. Soc. 139, 11956 (2017)
S. Yun et al, Ang. Chem. Int. Ed. 56, 15806 (2017)
M.D. Smith et al, Chem. Sci. 8, 1960 (2017)
C.C. Stoumpos et al, Chem Cell 2, 427 (2017)
K. Appavoo et al, Phys. Rev. B 96, 195308 (2017)
H. Tsai et al, Science 360, 67 (2018)
C. Katan et al, Nature Materials 17, 377 (2018)
H. Fang et al, Nature Comm. 9, 243 (2018)
H. Tsai et al, Nature Comm. 9, 2130 (2018)
J.C. Blancon et al, Nature Comm. 9, 2554 (2018)
M. Fu et al, Nature Comm. 9, 3318 (2018)
W. Nie et al, Adv. Mat. 30, 1703879 (2018)
H. Tsai et al, Adv. Mat. 30, 1704217 (2018)
C. Soe et al, Adv. Ener. Mat. 8, 1700979 (2018)
H. Fang et al, Adv. Func. Mat. 28,1800305 (2018)
L. Zhou et al, ACS Energy Lett. 3, 787 (2018)
L. Mao et al, J. Am. Chem. Soc. 140, 3775 (2018)
X. Li et al, J. Am. Chem. Soc. 140, 12226 (2018)
L. Mao et al, J. Am. Chem. Soc. 140, 13078(2018)
M. Kepenekian et al, Nano Letters 18, 5603 (2018)
B. Traore et al, ACS Nano 12, 3321 (2018)
A. Marronnier et al, ACS Nano 12, 3477 (2018)
A. Ferreira et al, Phys. Rev. Lett. 121, 085502 (2018)
J. Leveillee et al, Phys. Rev. Mat. 2, 105406 (2018)
A. Gheno et al, RRL Solar 2, 1800191 (2018)
C. Katan et al, Chem. Rev. 119, 3140 (2019)
P. Tamarat et al, Nature Materials 18, 717 (2019)
C. Wei et al, Nature Comm. 10, 5342 (2019)
J. Leveillée et al, Nano Letters 19, 8732 (2019)
Soe et al, Proc. Nat. Acad. Sci. 116, 58 (2019)
N. Devesa Canicoba et al, ACS Mat. Lett. 1, 633 (2019)
J. M. Hoffman et al, J. Am. Chem. Soc. 141, 10661 (2019)
X. Li et al, J. Am. Chem. Soc. 141, 12880 (2019)
L. Mao et al, Chem Cell 5, 2593 (2019)
J. C. Blancon et al, Nature Nanotechnology,15, 969 (2020)
P. Tamarat et al, Nature Comm., 11, 6001 (2020)
H. Fang et al, Adv. Func. Mat. 29,1907979 (2020)
L. Chen et al, ACS Nano, 14,13127 (2020)
S. Kahman et al, ACS Ener. Lett., 5, 2512 (2020)
E. Kinigstein et al, ACS Mat. Lett. 2, 1360 (2020)
B. Traore et al, ACS Mat. Interf. 12, 6633 (2020)
C. Quarti et al, J. Phys. Mat. 3, 042001 (2020)
X. Fu et al, J. Am. Chem. Soc. 142, 4008 (2020)
T. Schmitt et al, J. Am. Chem. Soc. 142, 5060 (2020)
X. Li et al, J. Am. Chem. Soc. 142, 6625 (2020)
L. Mao et al, J. Am. Chem. Soc. 142, 8342 (2020)
I. Spanopoulos et al, J. Am. Chem. Soc. 142, 9028 (2020)
X. Li et al, J. Am. Chem. Soc. 142, 11482 (2020)
G. Roma et al, Phys. Rev. Mat. 4, 092402 (2020)
A. Ferreira et al, Comm. Phys. 3, 48 (2020)
F. Liu et al, Nature Comm., 12, 673 (2021)
S. Sidhik et al, Adv. Mat. 2007176 (2021)
A. Torma et al, ACS Nano 15, 20550 (2021)
S. Sidhik et al, Cell Rep. Phys. Sci. 2, 100601 (2021)
V. Diez‐cabanes et al, Adv. Opt. Mat., 2001832 (2021)
B. Song et al, ACS Mat. Lett. 3, 148 (2021)
F. Ledee et al, Materials Horizons 8,1547 (2021)
L. Gao et al, J. Am. Chem. Soc. 143, 12063 (2021)
S. Sidhik et al, Science 377, 1425 (2022)
Q. Akkerman et al, Science 377, 1406 (2022)
W. Li et al, Nature Nanotechnology 17, 45 (2022)
S. Cuthriell et al, Adv. Mat. 2202709 (2022)
Y. Qin et al, Adv. Mat. 2201666 (2022)
B. Traore et al, ACS. Ener. Lett. 7, 349 (2022)
L. Chen et al, Adv. Sci. 9, 2101661 (2022)
X. Li et al, J. Am. Chem. Soc. 144, 3902 (2022)
E. Vasileiadou et al, J. Am. Chem. Soc. 144, 6390 (2022)
B. Hehlen et al, Phys. Rev. B 105, 024306 (2022)
R. Nazarov et al, Phys. Rev. B 105, 245202 (2022)
L. Chen et al, Phys. Rev. B 106, 165310 (2022)
B. Traore et al, Phys. Rev. Mat. 6, 014604 (2022)
B. Cucco et al, RRL Solar 6, 2200718 (2022)
H. Zhang et al, Nature Physics, 19, 545 (2023)
J. Hou et al, Nature Synth., DOI : 10.1038/s44160-023-00422-3
P. Tamarat et al, Nature Comm., 14, 229 (2023)
A. Fehr et al, Nature Comm., 14, 3797 (2023)
S. Liu et al, Sci. Adv., 9, eadh2255 (2023)
C. Zhu et al, Adv. Mat. 2208354 (2023)
A. Abhervé et al, Adv. Mat. 2305784 (2023)
I. Metcalf et al, Chem. Rev., 123, 9565 (2023)
D. Dirin et al, Nano Letters (2023)
M. Zacharias et al, Phys. Rev. B, 108, 035155 (2023)
M. Zacharias et al, npj Comp. Mat., 9, 153 (2023)
P. Fu et al, J. Am. Chem. Soc. 145, 15997 (2023)
Z.G. Li et al, ACS Ener.Lett., 8, 3016 (2023)
B. Cucco et al, ACS. Mat. Lett. 5, 52 (2023)
C. Quarti et al, Adv. Opt. Mat. 2202801 (2023)
Z. Tang et al, Adv. Opt. Mat. 2301282 (2023)
A. Matuhina et al, Nanoscale, 15, 14764 (2023)
P. Basera et al, Nanoscale, 15, 11884 (2023)
Book Chapters (J. Even et al) in :
"Unconventional Thin Film Photovoltaics", RCS Publishing (2016)
"Semiconductor Nanocrystals and Metal Nanoparticles: Physical Properties and Device Applications", CRC Press (2016)
"Theoretical Modeling of Organohalide Perovskites for Photovoltaic Appl.", CRC Press (2017)
"Halide Perovskites - Photovoltaics, Light Emitting Devices and Beyond", Wiley (2018)
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Demonstration of a Low Threshold Current in 1.54 µm InAs/InP(311)B Quantum Dot Laser with Reduced Quantum Dot StacksJapanese Journal of Applied Physics, part 1 : Regular papers, Short Notes, 2007, 46 (10A), pp.6903-6905. ⟨10.1143/JJAP.46.6903⟩
Article dans une revue
hal-00493021v1
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QD laser on InP substrate for 1.55 µm emission and beyondSPIE Photonics West - OPTO 2010, Jan 2010, San Francisco, United States. pp.76081B, ⟨10.1117/12.848398⟩
Communication dans un congrès
hal-00485660v1
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Analysis of carriers dynamics and laser emission in 1.55 μm InAs/InP(113)B quantum dot lasersSPIE Photonics Europe 2010, Apr 2010, Bruxelles, Belgium. pp.77202F, ⟨10.1117/12.863580⟩
Communication dans un congrès
hal-00492346v1
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Lasers à boites quantiques sur InP pour les applications télécom à 1,55 µmSéminaire PONANT 2010, Jul 2010, Rennes, France
Communication dans un congrès
hal-00662947v1
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Threshold current density and emitting wavelength evolution with stack number in InAs quantum dash lasers at 1.55 μmIndium Phosphide and Related Materials, IPRM, May 2008, Versailles, France. pp.1-3, ⟨10.1109/ICIPRM.2008.4703027⟩
Communication dans un congrès
hal-00492842v1
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Comparative study of Single- and Double-capped InAs/InP (311)B QD lasers: effects on lasing characteristicsLWQD (International Workshop on Long Wavelength Quantum Dots : Growth and Applications), Jul 2007, Rennes, France. pp.1
Communication dans un congrès
hal-00491814v1
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A theoretical and experimental study of lambda>2 µm luminescence of quantum dots on InP substrate28th International Conference on the Physics of Semiconductors - ICPS 2006, Jul 2006, Vienne, Austria. pp.889, ⟨10.1063/1.2730177⟩
Communication dans un congrès
hal-00491466v1
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Influence of the number of quantum dots stacks on the threshold current density of 1.55 µm InAs/InP(311)B semiconductor lasersESLW 2006 (European Semiconductor Laser Workshop), Sep 2006, Nice, France. pp.1
Communication dans un congrès
hal-00491806v1
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InAs(Sb)/InP(100) quantum dots for mid-infrared emitters: observation of 2.35 μm photoluminescence4th International Conference on Semiconductor Quantum Dots (QD 2006), May 2006, Chamonix, France. pp.3920, ⟨10.1002/pssc.200671622⟩
Communication dans un congrès
hal-00491729v1
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First observation of 2.4 microns photoluminescence of InAsSb/InP quantum dots on (100) InP substrateNarrow Gap Semiconductors conference, Jul 2005, Toulouse, France. pp.1
Communication dans un congrès
hal-00504441v1
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InAsSb/InP quantum dots for midwave infrared emitters : a theoretical studyMid Infrared Optoelectronics : Materials and Devices : MIOMD conference, 2005, Lancaster, United Kingdom. pp.1
Communication dans un congrès
hal-00504452v1
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InAsSb/InGaAs quantum nanostructures on InP (100)substrate: observation of 2.35 μm photoluminescence32nd International Symposium on Compound Semiconductors, Sep 2005, Rust, Germany. pp.524, ⟨10.1002/pssc.200564132⟩
Communication dans un congrès
hal-00491737v1
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First observation of wavelength greater than 2 microns photoluminescence of quantum dots on InP (100) substrate"Mid Infrared Optoelectronics : Materials and Devices" conference, Lancaster, UK, September (2005)., Sep 2005, Lancaster, United Kingdom. pp.1
Communication dans un congrès
hal-00504462v1
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