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Theoretical Physics (From 2020)

 2023:

 Textbook (English): Relativistic and Non-Relativistic Quantum Mechanics: Both at Once, Springer Nature, 2023.

 Libro de Texto (Español):  Mecánica Cuántica Relativista y No-Relativista: las dos a la vez, BookBaby, 2023.

 2022:

13.  "About the asymmetry between matter and antimatter," L. Grave de Peralta, Journal of Modern Physics 13, 1099-1116 (2022).

12. "A pedagogical approach to relativity effects in quantum mechanics" L. Grave de Peralta, K. C. Webb, and H. Farooq, European Journal of Physics, 43, 045402 (2022).

11. "Hamilton-Jacobi and Lagrange formulation of relativistic quantum mechanics wave equations with solutions with only-positive and only-negative kinetic energies," L. Grave de Peralta and A. Ruiz Columbié, J. Modern Phys. 13, 432-441 (2022).

10. "A non-relativistic approach to relativistic quantum mechanics: the case of the harmonic oscillator," L. A. Poveda, L. Grave de Peralta, J. Pittman, and B. Poirier, Foundations of Physics,  https://doi.org/10.1007/s10701-022-00541-5 ( 2022).

2021:

9. "Some consecuences of a simple approach for constructing a theory of a relativistic Fermi gas," R. Lopez-Boada and L . Grave de Peralta,  Journal of Modern Physics, 12, 1966-1974 (2021).

8. "Making relativistic quantum mechanics simple," L . Grave de Peralta, J. L. Poveda, and B. Poirier, European Journal of Physics, 42, 055404 (2021).

7. "Direct relativistic extension of the Madelung-De Broglie-Bohm reformulation of quantum mechanics and quantum hydrodinamics," A. Ruiz-Columbie and L. Grave de Peralta, Journal of Modern Physics, 12, 1358-1374 (2021).

6. "A notable quasi-relativistic wave equation and its relation to the Schrödinger, Klein-Gordon, and Dirac equations," L. Grave de Peralta, Journal of Modern Physics 12, 1145-1159 (2021).

2020:

5. "Did Schrödinger have other options?" L. Grave de Peralta, European Journal of Physics, 41, 065404 (2020).

4. "Exact quasi-relativistic wave functions for Hydrogen-like atoms," L. Grave de Peralta, Scientific Reports 10, 14925 (2020).

3. "Quasi-relativistic description of a quantum particle moving through one-dimensional piecewise constant potentials," L. Grave de Peralta, Results in Physics 18, 103318 (2020).

2. "Quasi-relativistic description of Hydrogen-like atoms," L. Grave de Peralta, Journal of Modern Physics 11, 788-802 (2020).

1. "Natural extension of the Schrödinger equation to quasi-relativistic speeds," L. Grave de Peralta, Journal of Modern Physics 11, 196-213 (2020).

 

Tenured, Full Professor:
 
2019:

71. "Coherent illumination-direction-multiplexing dual-space and Fourier ptychographic microscopy," H. Farooq, S. Skinner-Ramos, H. Alghasham, A. A. Bernussi, and L. Grave de Peralta, Journal of Modern Optics  66, 868-878 (2019).

2018:

70. "Scanning diffracted-light photography using white-light and thermal sources," H. Alghasham, H. Farooq, Ceren Uzun, S. Skinner-Ramos, A. A. Bernussi, and L. Grave de Peralta, Applied Optics 57, 9997-10003 (2018).

69. "Scanning diffracted-light microscopy," H. Farooq, S. Skinner-Ramos, H. Alghasham, A. A. Bernussi, and L. Grave de Peralta, Applied Optics 57, 7329-7337 (2018).

68. "Subwavelength resolution scanning diffracted-light microscopy using plasmonic ultrathin condensers," S. Skinner-Ramos, H. Farooq, H. Alghasham, A. A. Bernussi, and L. Grave de Peralta, Optics Express 26, 19718-17728 (2018).

67. "Fourier plane imaging and illumination-direction-multiplexing using a rotating diffracting element for Fourier ptychographic microscopy," S. Skinner-Ramos, H. Farooq, A. A. Bernussi, and L. Grave de Peralta, Optics Communications 427, 231-237 (2018).

66. "Improving the resolution of an optical microscope using ring-like illumination and scanning the direction of the diffracted light with a slit," H. Farooq, S. Skinner-Ramos, H. Alghasham, and L. Grave de Peralta, Optics Communications 426, 201-205 (2018).

65. "Imaging photonic crystals using hemispherical digital condensers and phase-recovery techniques," M. Alotaibi, S. Skinner-Ramos, H. Farooq, H. Alghasham, N. Alharbi, and L. Grave de Peralta, Applied Optics 57, 3756-3760 (2018).

Tenured, Associate Professor:

2017:

64. "Toward phase-recovery optical nanoscopes," S. Skinner-Ramos, H. Farooq, H. Alghasham, and L. Grave de Peralta, Journal of Physical Science and Application 7, 19-27 ( 2017).

63. "Photo-induced heat localization on nanostructured metallic glasses," C. Uzun, N. Kahler, L. Grave de Peralta, G. Kumar, and A. A. Bernussi, Journal of Applied Physics 122, 094306 (2017).

62. "Fourier Ptychographic Microscopy at communication wavelengths using a femtosecond laser," A. Ishtiaque, M. Alotaibi, S. Skinner-Ramos, D. Dominguez, A. A. Bernussi, and L. Grave de Peralta, Optics Communications 405, 363-367 (2017).

61. "Laser-based dual-space microscopy," M. Alotaibi, R. Gedies, A. Alzayed, F. Aldawsary, D. Dominguez, and L. Grave de Peralta, Optics Communications 402, 662-667 (2017).

 

60. "Illumination direction multiplexing Fourier ptychographic microscopy using hemispherical digital condensers," M. Alotaibi, S. Skinner-Ramos, A. Alamri, B. Alharbi, M. Alfarraj, and L. Grave de Peralta, Applied Optics 56, 4052-4057 (2017).

 

2016:

 

59. "Imaging photonic crystals using Fourier plane imaging and Fourier ptychographic microscopy techniques implemented with a computer-controlled hemispherical digital condenser," S. Sen, D. B. Desai, M. H. Alsubaie, M. V. Zhelyeznyakov, L. Molina, H. Sari-Sarraf, A. A. Bernussi, and L. Grave de Peralta, Optics Communications 383 500-507 (2016).

 

58. "Simulation study of dual-space microscopy," D. B. Desai, M. V. Zhelyeznyakov, S. A. S. Alanzi, and L. Grave de Peralta, Applied Optics 55, 7294-7300 (2016).

 

 57. "Fourier ptychographic microscopy using an infrared-emitting hemispherical digital condenser," S. Sen, A. Ishtiaque, B. Aljubran, A. A. Bernussi, and L. Grave de Peralta, Applied Optics 55, 6421-6427 (2016).

 

56. "Super-resolution imaging of photonics crystals using the dual-space microscopy technique," D. B. Desai, S. Sen, M. V. Zhelyeznyakov, W. Alenazy, and L. Grave de Peralta, Applied Optics 55, 3929-3934 (2016).

 

2015:

 

55. "Comprehensive study of unexpected microscope condensers formed in sample arrangements commonly used in optical microscopy," D. B. Desai, M. M. S. Aldawsari, B. M. H. Alharbi, S. Sen, and L. Grave de Peralta, Applied Optics 54, 7781-7788 (2015).

54. "Metal slab superlens-negative refractive index versus inclined illumination: discussion," L. Grave de Peralta, JOSA A 32, 1729-1735 (2015). 

53. “Fourier plane imaging microscopy for detection of plasmonic crystals with periods beyond the optical diffraction limit,” D. Dominguez, M. Alhusain, N. Alharbi, A. A. Bernussi, and L. Grave de Peralta, Plasmonic DOI 10.1007/s11468-015-9938-x (2015).

 

52. “Optical condensers formed in wet-mounting setup,” D. B. Desai, and L. Grave de Peralta, Applied Optics 54, 3580-3587(2015).

 

51. “Versatile optical microscopy using a reconfigurable hemispherical digital condenser,” S. Sen, L. Molina, D. Cao, D. B. Desai, A. A. Bernussi, and L. Grave de Peralta, Biomedical Optics Express 6, 658-667 (2015).

 

2014:

 

50. “Fourier plane imaging microscopy,” D. Dominguez, M. Alhusain, N. Alharbi, A. A. Bernussi, and L. Grave de Peralta, J. of Appl. Phys. 116, 103102 (2014).

Featured in: Physics Today 67, pag. 20, November 2014.

 

49. “Hemispherical digital optical condensers with no lenses, mirrors, or moving parts,” D. Dominguez, L. Molina, D. B. Desai, T. O’Loughlin, A. A. Bernussi, and L. Grave de Peralta, Opt. Express 22, 6948-6957 (2014).

Selected for: Virtual Journal of Biomedical Optics 9, Issue 5 (2014).

 

48. “Ultra-thin condensers for optical subwavelength resolution microscopy,” D. B. Desai, D. Dominguez, A. A. Bernussi, and L. Grave de Peralta, J. Appl. Phys. 115, 093103(2014).

 

47. “Observation of coherence-related phenomena in experiments with surface plasmon polaritons excited by fluorescence,” D. Dominguez, C. J. Regan, R. Lopez-Boada, A. A. Bernussi, and L. Grave de Peralta, Opt. Commun. 315, 270-274 (2014).

 

2013:

 

46. “Fundaments of optical far-field subwavelength resolution based on illumination with surface waves,” R. Lopez-Boada, C. J. Regan, D. Dominguez, A. A. Bernussi, and L. Grave de Peralta, Opt. Express 21, 11928-11942 (2013).

Selected for: Virtual Journal of Biomedical Optics 8, Issue 6 (2013).

 

45. “Far-field optical superlens without metal,” C. J. Regan, D. Dominguez, L. Grave de Peralta, and A.A. Bernussi, J. Appl. Phys. 113, 183105 (2013).

 

44. “Toward surface plasmon polariton quantum state tomography,” D. Dominguez, C. J. Regan, A. A. Bernussi, and L. Grave de Peralta, J. Appl. Phys. 113, 073102 (2013).

 

43. “SPP tomography experiments with surface plasmon polariton standing waves,” L. Grave de Peralta, and D. Domìnguez, Opt. Commun. 286, 151-155 (2013).

 

42. “SPP tomography: a simple wide-field nanoscope,” L. Grave de Peralta, C. J. Regan, and A. A. Bernussi, Scanning, 35, 246-252 (2013).

 

2012:

 

41. “Two-dimensional Bessel-like surface plasmon-polariton beams,” C. J. Regan, L. Grave de Peralta, and A. A. Bernussi, Journal of Appl. Phys. 112, 103107 (2012).

 

40.Imaging nanoscale features with plasmon-coupled leakage radiation far-field superlenses,” C. J. Regan, R. Rodriguez, S. Gourshetty, L. Grave de Peralta, and A.A. Bernussi, Optics Express 20, 20827-20834 (2012).

Selected for: Virtual Journal of Biomedical Optics 7, Issue 11 (2012).

 

39. “Equifrequency curve dispersion in dielectric-loaded plasmonic crystals,” C. J. Regan, L. Grave de Peralta, and A.A. Bernussi, Journal of Applied Physics 111, 073105 (2012).

 

38. “Probing photonic Bloch wavefunctions with plasmon-coupled leakage radiation,” C. J. Regan, O. Thiabgoh, L. Grave de Peralta, and A.A. Bernussi, Optics Express 20, 8658 (2012).

 

Tenure-track, Assistant Professor:

 

2011:

 

37. “Directivity and isotropic band-gap in 12-fold plasmonic quasi-crystals with small index contrast,” C. J. Regan, L. Grave de Peralta, and A.A. Bernussi, Applied Physics Letters 99, 181104 (2011).

 

36. “Study of plasmonic crystals using Fourier-plane images obtained with plasmon tomography far-field superlenses,” R. Rodriguez, C. J. Regan, A. Ruiz-Columbié, W. Agutu, A.A. Bernussi, and L. Grave de Peralta, Journal of Applied Physics 110, 083109 (2011).

35. “Study of interference in a double-slit without walls by plasmon tomography techniques,”  J. Ajimo, C. J. Regan, A. C. Bernussi, S. Park, R. Lopez-Boada , A. A. Bernussi, and L. Grave de Peralta, Opt. Commun. 284, 4752 (2011).

 

34. “Direct Observation of Photonic Fermi Surfaces by Plasmon Tomography,”  C. J. Regan, A. Krishnan, R. Lopez-Boada, L. Grave de Peralta, and A.A. Bernussi, Applied Physics Letters 98, 151113 (2011).

Comment on “Does the leakage radiation profile mirror the intensity profile of surface plasmon polaritons?” L. Grave de Peralta, Optics Letters 36, 2516 (2011).

 

33. Erratum: “Some consequences of experiments with a plasmonic quantum eraser for plasmon tomography,” A. Houk,  R. Lopez-Boada, A. Ruiz-Columbie, S. Park, and A. A. Bernussi, and L. Grave de Peralta, J. of Appl. Phys. 109, 119901 (2011).

 

33. “Some consequences of experiments with a plasmonic quantum eraser for plasmon tomography,”  L. Grave de Peralta,  R. Lopez-Boada, A. Ruiz-Columbie, S. Park, and A. A. Bernussi, J. of Appl. Phys. 109, 023101 (2011).

 

2010:

 

32. “Resonant Coupling in Dielectric Loaded Plasmonic Waveguide Devices” A. Krishnan, C. J. Regan, L. Grave de Peralta, and A.A. Bernussi, Applied Physics Letters, 97, 231110 (2010).

 

31. “Phenomenological quantum description of the ultra fast response of arrayed waveguide gratings,” L. Grave de Peralta, J. of Appl. Phys. 108, 103110 (2010).

Selected for: Virtual Journal of Ultrafast Science, Vol 9, Issue 12 (2010).

 

30. “Plasmonic implementation of a quantum eraser for imaging applications,” J. Ajimo, M. Marchante, A. Krishnan, A.A. Bernussi, and L. Grave de Peralta, J. of Appl. Phys. 108, 063110 (2010).

Selected for: Virtual Journal of Quantum Information, Vol 10, Issue 10 (2010).

 

29. “Characterization of polarization states of surface plasmon polaritons modes by Fourier-plane leakage microscopy,” S.P. Frisbie, C. Chesnutt, J. Ajimo, A.A. Bernussi, and L. Grave de Peralta, Opt. Commun. 283, 5255 (2010).

 

28. “Study of interference between surface plasmon polaritons by leakage radiation microscopy,” L. Grave de Peralta, J. Opt. Soc. Am. B 27, 1513 (2010).

 

27. “Plasmon Stimulated Emission in Arrays of Bimetallic Structures Coated with Dye-Doped Dielectric,” A. Krishnan, S.P. Frisbie, L. Grave de Peralta, and A.A. Bernussi, Applied Physics Letters, 96 111104, (2010).

 

2009:

 

26. “Image formation in wide-field microscopes based on leakage of surface plasmon-coupled fluorescence,” S. P. Frisbie, C. Chesnutt, M. E. Holtz, A. Krishnan, L. Grave de Peralta, and A. A. Bernussi, IEEE Photonics Journal, 1, 153-162 (2009).

 

25. “Optical reflectivity of asymmetric dielectric-metal-dielectric planar structures,” S. P. Frisbie, A. Krishnan, X. Xu, L. Grave de Peralta, S.A. Nikishin , M.W. Holtz and A. A. Bernussi, Journal of Lightwave Technology, 27, 2964-2968 (2009).

 

24. “Finite element analysis of lossless propagation in surface plasmon polariton waveguides with nanoscale spot-sizes,” A. Krishnan, L. Grave de Peralta, M. Holtz and A.A. Bernussi, Journal of Lightwave Technology, 27, 1114 (2009).

 

23. “Interference in wave-front-division-based spectrometers illuminated with ultra fast pulses of light,” L. Grave de Peralta, Journal of Applied Physics, 105, 013111 (2009).

Selected for: Virtual Journal of Ultrafast Science, Vol 8, Issue 2 (2009).

 

2008:

 

22. “Reconfigurable add-drop optical filter based on arrays of digital micromirrors,” M. Knapczyk, L. Grave de Peralta, A.A. Bernussi, and H. Temkin, Journal of Lightwave Technology, 26,  237, (2008).

 

2007:

 

 21. Ultrafast response of arrayed waveguide grating pulse shapers with digital amplitude and phase modulation,” Grave de Peralta L., Bernussi A. A., and Temkin H., IEEE Journal of Lightwave Technology, 25, 2410, (2007).

 

Patent # 7, 280, 722 B2: “Temperature Compensated Optical Multiplexer,” H. Temkin, L. Grave de Peralta, A.A. Bernussi, and V. Gorbounov, October 9, 2007.

 

20. “Ultra fast response of arrayed waveguide gratings,” L. Grave de Peralta, A.A. Bernussi and H. Temkin, IEEE Journal of Quantum Electronics, 43, 473 (2007).

 

19. “Generation of Arbitrary Sequences of Ultrafast Pulses With Integrated-Optic Space-to-Time Optical Processors And Phase-Only Masks ,”A. Krishnan, L. Grave de Peralta, V. Kuryatkov, A. A. Bernussi, and H.Temkin, IEEE Photonics Technology Letters, 19, 194 (2007).

 

Senior Research Assistant:

 

2006:

 

 18. “Generation of ultrafast pulse sequences with arrayed waveguide grating multiplexers subjected to modulated external stress,” A. Krishnan, L. Grave de Peralta, H. Temkin, and A.A. Bernussi, IEEE Photonics Technology Letters, 18, 1158 (2006).

 

17. “Direct space-to-time pulse shaper with reflective arrayed waveguide gratings and phase masks,”A. Krishnan, L. Grave de Peralta, V. Kuryatkov, A. A. Bernussi, and H. Temkin, Optics Letters 31, 640 (2006).

Selected for: Virtual Journal of Ultrafast Science, Vol 5, Issue 6 (2006).

 

2005:

 

16. “High-Resolution Pulse Shaper Based on Arrays of Digital Micromirrors,” M. Knapczyk, A. Krishnan, L. Grave de Peralta, A. A. Bernussi, and H. Temkin, IEEE Photonics Technology Letters 17, 2200, (2005).

 

15. “Reconfigurable Direct Space-to-Time Pulse-Shaper Based on Arrayed Waveguide Grating Multiplexers and Digital Micromirrors,” A. Krishnan, M. Knapczyk, L. Grave de Peralta, A. A. Bernussi, and H. Temkin, IEEE Journal of Lightwave Technology 17, 1959, (2005).

 

14. “Reconfigurable Optical Filter Based on Digital Mirror Arrays,” M. Knapczyk, A. Krishnan, L. Grave de Peralta, A. A. Bernussi, and H. Temkin, IEEE Photonics Technology Letters, 17, 1743,  (2005).

 

2004:

 

13. “Control of center wavelength in reflective arrayed waveguide grating multiplexers,” L. Grave de Peralta, A. A. Bernussi, V. Gorbounov, J. M. Berg, and H. Temkin, IEEE Journal of Quantum Electronics, 40, 1725 (2004).

 

12. “Reconfigurable Sampling of the Electric Field at the Reflecting Surface of Folded Arrayed Waveguide Grating Multiplexers,” A.A. Bernussi, L. Grave de Peralta, M. Knapczyk, R. Gale, and H. Temkin, IEEE Photonics Technology Letters 16, 2257,  (2004).

 

11. “Mirror quality and the performance of reflective arrayed waveguide grating multiplexers,” A. A. Bernussi,  L. Grave de Peralta, V. Gorbounov, J. A. Linn, S. Frisbie, R. Gale, and H. Temkin, IEEE Journal of Lightwave Technology 22, 1828, (2004).

 

10. “Temperature insensitive reflective arrayed waveguide grating multiplexers,” L. Grave de Peralta, A. A. Bernussi, V. Gorbounov, and H. Temkin, IEEE Photonics Technology Letters, 16, 831,  (2004).

 

9. “Electric field distribution in a grating of a folded arrayed-waveguide multiplexer,”A. A. Bernussi, L. Grave de Peralta, and H. Temkin, IEEE Photonics Technology Letters 16, 488, (2004).

 

2003:

 

8. "Effects of power truncation on the insertion loss and crosstalk of arrayed-waveguide grating devices,"A. A. Bernussi, L. Grave de Peralta, S. Frisbie, and H Temkin, Applied Physics Letters 75, 1695 (2003).

 

 7. “Reflective Arrayed Waveguide Grating Multiplexer,” L. Grave de Peralta, A. A. Bernussi, S. Frisbie, R. Gale, and H. Temkin, IEEE Photonics Technology Letters 15, 1398 (2003).

 

6. “Silicon Dioxide Waveguides With Low Birefringence,” L. Grave de Peralta, A. A. Bernussi, H. Temkin, IEEE Journal of Quantum Electronics 39, 874 (2003).

 

5. “High-Precision Characterization of Single-Mode Optical Fiber Arrays,” A. A. Bernussi,  L. Grave de Peralta, and H. Temkin, IEEE Journal of Lightwave Technology 21, 1557 (2003).

 

4. “Improved Fourier Method for Thickness Determination by X-Ray Reflectivity,” L. Grave de Peralta, H. Temkin, Journal of Applied Physics  93, 1974, (2003).

 

Before Ph.D:

 

3. “Gas source molecular beam epitaxy of high quality AlxGa1-xN (0 <= x <= 1) on Si(111),” Nikishin S, Kipshidze G, Kuryatkov V, Choi K, Gherasoiu I, de Peralta LG, Zubrilov A, Tretyakov V, Copeland K, Prokofyeva T, Holtz M, Asomoza R, Kudryavtsev Y, Temkin H, Journal of Vacuum Science & Technology B 19, 1409 (2001).

 

2. “Single-Mode Operation from an External Cavity Controlled Vertical-Cavity Surface-Emitting Laser,” G.E. Giudice, D. V.Kuksenkov, L.Grave de Peralta, and H. Temkin, IEEE Photonics Technology Letters 11, 1545 (1999).

 

1."High quality GaN grown on Si(111) by gas source molecular beam epitaxy with ammonia," S. A. Nikishin N. N. Faleev, V.G. Antipov, S. Francoeur, L. Grave de Peralta, G.A. Seryogin, H Temkin, T.I. Prokofyeva, M. Holtz, S.N.G. Chu, Applied Physics Letters 75, 2073 (1999).

 

Cuba:

 

3. “Par electrónico relativista en el átomo multielectrónico,” J.Parera, E. Roca, L. Grave de Peralta, R. L. Boada, Revista Cubana de Física, 5, 51 (1986).

 

2. “Sobre la formulación y aplicación del método de los seudopotenciales en átomos alcalinos,” L. Grave de Peralta, R. L. Boada, Revista Cubana de Física, 6, 65 (1986).

 

1.“Colección de problemas resueltos de ecuaciones en derivadas parciales”, J.Parera, E. Roca, L. Grave de Peralta, R. L. Boada, Editorial de la Universidad de Oriente, Cuba (1984).

 




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