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Summary

Citation record

Unfortunately, ResearcherID.org changed for Publons.com, where citation record is no longer indexed on WebOfScience.

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Journal references - OUTDATED LIST

1. Gnilitskyi, I.; Derrien, T. J.-Y.; Levy, Y.; Bulgakova, N. M.; Mocek, T.; Orazi, L.;

2. High-speed manufacturing of highly regular laser-induced periodic surface structures on metals: physical origin of the regularity,

3. Scientific Reports (accepted for publication)

4. IF: 5.23

5. T. J.-Y. Derrien, N. M. Bulgakova

6. Modeling of silicon in femtosecond laser-induced modification regimes: accounting for ambipolar diffusion

7. Proceedings of SPIE 10228, Nonlinear Optics and Applications X, 102280E (2017)

8. IF: 0.37

9. S. Maragkaki, T. J.-Y. Derrien, Y. Levy, N. M. Bulgakova, A. Ostendorf, E.L. Gurevich

10. Wavelength Dependence of Picosecond Laser-Induced Periodic Surface Structures on Copper,

11. Applied Surface Science 417, 88 (2017)

12. IF: 2.711

13. Featured article in MRS Bulletin

    1. M. V. Shugaev, C. Wu, O. Armbruster, A. Naghilou, N. Brouwer, D. S. Ivanov, T. J.-Y. Derrien, N. M. Bulgakova, W. Kautek, B. Rethfeld, L.V. Zhigilei

    2. Fundamentals of ultrafast laser–material interaction

    3. MRS Bulletin 41, 960 (2016)

    4. IF: 1.8

14. T. J.-Y. Derrien, J. Krüger, J. Bonse

15. Properties of Surface Plasmon Polaritons on lossy materials: Lifetimes, periods and excitation conditions,

16. Journal of Optics 18, 115007 (2016)

17. IF: 1.8

18. Y. Levy, T.J.-Y. Derrien, N.M. Bulgakova, E.L. Gurevich, T. Mocek

19. Relaxation dynamics of femtosecond-laser-induced temperature modulation on the surfaces of metals and semiconductors,.

20. Applied Surface Science 374, 157 (2016)

21. IF: 2.711

• 1. N. M. Bulgakova, V. Zhukov, A. Collins, D. Rostohar, T. J.-Y. Derrien, T. Mocek

  2. How to optimize ultrashort pulse laser interaction with glass surfaces in cutting regimes?

  3. Applied Surface Science 336, 364 (2015)

  4. IF: 2.711

22. Featured article in Cover of Journal of Applied Physics Vol. 116, Issue 7.

23. T. J.-Y. Derrien, R. Koter, J. Krüger, S. Höhm, A. Rosenfeld, J. Bonse,

24. Plasmonic formation mechanism of periodic 100-nm-structures upon femtosecond laser irradiation of silicon in water,

25. Journal of Applied Physics 116, 074902 (2014). DOI: 10.1063/1.4887808

26. IF: 2.185

27. T.J.-Y. Derrien, J. Krüger, T.E. Itina, S. Höhm, A. Rosenfeld, J. Bonse,

28. Rippled area formed by surface plasmon polaritons upon femtosecond laser double-pulse irradiation of silicon: the role of carrier generation and relaxation processes

• 1. Applied Physics A 117, 77 (2014) PDF.

  2. IF: 1.694

29. T.J.-Y. Derrien, J. Krüger, T.E. Itina, S. Höhm, A. Rosenfeld, J. Bonse,

30. Rippled area formed by surface plasmon polaritons upon femtosecond laser double-pulse irradiation of silicon

31. Optics Express 21, 29643 - 29655 (Dec. 2013), PDF

• 1. IF: 3.525

32. T. J.-Y. Derrien, T. E. Itina, R. Torres, T. Sarnet, M. Sentis,

• 1. Possible surface plasmon polariton excitation under femtosecond laser irradiation of silicon,

  2. Journal of Applied Physics 114, 083104 (2013), PDF

  3. IF: 2.185

33. T.J.Y. Derrien, R. Torres, T. Sarnet, M. Sentis, T.E. Itina,

34. Formation of femtosecond laser induced surface structures on silicon: insights from numerical modeling and single pulse experiments,

35. Applied Surface Science Vol. 258, Issue 23, pp.9487-9490 (2012), PDF

36. IF: 2.711

37. T. JY. Derrien, T. Sarnet, M. Sentis, T. E. Itina,

38. Application of a two-temperature model for the investigation of the periodic structure formation on Si surface in femtosecond laser interaction,

39. Journal of Optoelectronics and Advanced Materials, vol. 12, no. 3, pp. 610-615 (2010), PDF

40. IF: 0.5

41. A.V. Kabashin, T. Sarnet, D. Grojo, Ph. Delaporte, L. Charmasson, P. Blandin, R. Torres, T. J-Y. Derrien, M. Sentis,

42. Laser-ablative nanostructuring of Surfaces,

43. International Journal of Nanoetchnology, 9 (3-7), pp. 230-245 (2011) DOI

44. IF: 1.09

• 1. X. Sedao,T. J.-Y. Derrien, Gert-Willem RBE Romer, Belavendram Pathiraj,

  2. A.J Huis in‘t Veld

  3. Parallel laser surface texturing by a simple transportable micro-sphere arrays.

  4. Journal of Applied Physics 112, 103111 (2012), DOI

  5. IF: 2.185

  6. X. Sedao, T. J-Y Derrien, G.R.B.E. Romer, B. Pathiraj, A.J Huis in‘t Veld

  7. Laser surface micro-/nano-structuring by a simple transportable micro-sphere lens array

     1. Applied Physics A 111, 701-709 (2013) DOI

     2. IF: 1.694

Conference proceedings

1. Thierry Sarnet, T. J.-Y. Derrien, R. Torres, Ph. Delaporte, F. Torregrosa, M.-J. Sher, Y.-T. Lin, B. Franta, G. Deng, and Eric Mazur,

2. Black Silicon for Photovoltaic Cells: Towards a high-efficiency silicon solar cells, Proceedings of EUPVSec (2013)

3. Nikita S Shcheblanov, Thibault JY Derrien, Tatiana E Itina,

   1. • 1. Femtosecond laser interactions with semiconductor and dielectric materials

• 1. AIP Conference Proceedings, Vol. 1464, p. 79 (2012) PDF

4. R. Torres, T. E. Itina, V. Vervisch, M. Halbwax, T. Derrien, T. Sarnet, M. Sentis, J. Ferreira, F. Torregrosa, L. Roux, Cl.Phipps,

5. Study On Laser-Induced Periodic Structures And Photovoltaic Application,

6. Aip Conference Proceedings, ISSN: 0094243X, Vol: 1278, Issue: 1, Date: 2010-10-08, Start page: 576 (2010)

7. T. E. Itina, N. Shcheblanov, J.-Ph. Colombier, R. Stoian, E. Audouard, T. JY. Derrien, R. Torres, J. Hermann, M. E. Povarnitsyn, K. V. Khishchenko,

8. Laser Applications for Nanotechnology : Insights From Numerical Modeling,

9. Aip Conference Proceedings, ISSN: 0094243X, Vol: 1278, Issue: 1, Date: 2010-10-08, 38 (2010)

Thesis manuscript

Thibault J.-Y. Derrien,

Fr: Nanostructuration de cellules photovoltaiques par impulsion laser ultracourte. Étude numérique des mécanismes de formation.

English title: "Nanostructuring of photovoltaic cells induced by ultrashort laser pulses. Numerical study of formation mechanisms."

Ecole Doctorale des Sciences de la Matière,

Aix-Marseille Université, Février 2012 (In french). PDF link.

Research activities

My research is focused on understanding the physical mechanisms resulting from ultrashort laser interaction with matter. Such processes lead to the formation of periodic structures for microstructuration and functionalization of materials.

For example, one can improve the efficiency of solar cells, and also leads to atom by atom evaporation on nanoscopic tips.

I develop models and numerical methods to reveal the underlying mechanisms of various laser processes. The results allow to optimize the efficiency of existing processes, and to propose new techniques.

My current activities are focused on:

1. Explaining the formation of periodic surface structures due to surface electromagnetic wave generation, and capillary wave generation

2. Explaining the mechanisms of atomic evaporation of laser-assisted field emission

For example, the Figure presents the typical structures formed after several pulsed laser irradiations of a metal, semiconductor or dielectric sample, at an energy near from the modification threshold.

In details, the proposed methods consist in:

1. modeling and calculate the laser light absorption due to the generation of free-carriers and their transport;

2. model the phase transitions, such as melting, ablation and resolidification of the laser irradiated materials;

3. calculate the types of generated surface waves (plasmon polaritons, phonon polaritons),

4. confirm the observed processes by performing theoretical analysis in electrodynamic and hydrodynamic description

Profiles in professionnal engines

• ORCID

• ResearcherID

• Scholar Google

• Research Gate

• arXiv.org

• Academia.edu

• Linked In

Links

• Laser-induced ripples on Wikipedia.

• Black Silicon on Wikipedia.

• "Atom Probe Tomography" on Wikipedia, Cameca (company in Rouen)

• Find myself in the press: INTERfaces, July 2009, page 2.