F. J. Duarte's Original Research

Derivation of Born's rule from transparent interferometric principles (2024) [1].
Design of N-slit quantum interferometers in the nanometer domain for femtophotonics applications (2023) [2].
Identified coherent emission from electrically-pumped organic semiconductors as intrinsic quantum coherence (2022) [3].
Derivation of the direct mathematical link between the probability amplitudes of quantum entanglement with Pauli matrices and Hadamard-class matrices (2019-2021) [4, 5, 6].
Generalization of the N-slit interferometric methodology to derive quantum entanglement probability amplitudes for n = N = 2, 4, 8, 16 ... and n = N = 3, 6, 9... (2017) [7].
Transparent physical description, without using Bell's theorem, neutralizing the EPR paradox (2013) [8].
Derivation of the probability amplitude for quantum entanglement from a transparent N-slit interferometric perspective (2013) [9].
Very large N-slit laser interferometers, in the 30-530 m range, and to superimpose fine diffraction profiles on propagating interferograms. These very large N-slit interferometers were applied to measure clear-air turbulence (2010-2013) [10, 11].
Extension of the generalized multiple-prism dispersion theory to high-order (4th, 5th,... 9th) dispersions applicable to laser-pulse compression and nonlinear optics (2009) [12].
Multiple-prism dispersion theory for positive and negative refraction (2006) [13].
First report on high-visibility coherent emission from an electrically-pumped organic semiconductor within an interferometric configuration (2005) [14].
Derivation of Heisenberg's Uncertainty Principle from the generalized N-slit quantum interferometric probability (2003) [15].
Organic polymer-nanoparticle laser emission (2003) [16].
Introduction of interferometric characters for secure space-to-space communications (2002) [17].
First lithium isotope separation using narrow-linewidth tunable diode lasers (2002) [18].
Single-longitudinal-mode tunable solid-state dye laser oscillator emitting at the limit allowed by Heisenberg's uncertainty principle (1999) [19].
Unified interference, diffraction, refraction, and reflection, via Dirac's notation (1997) [20].
Direct comparison of processing times between the N-slit quantum interferometer processor (less than 0.03 s) and a universal classical IBM mainframe computer (more than 3000 s), for N = 1500 (1996) [21].
Demonstration of the first single-longitudinal-mode solid-state tunable dye laser oscillator (1994) [22].
Ruggedized single-longitudinal-mode tunable laser oscillator in the visible (1991) [23].
Invention of the multiple-prism collinear polarization rotator (1989) [24].
Control of linewidth instabilities in narrow-linewidth tunable lasers (1988-1990) [25, 26].
Physics of the N-slit laser interferometer photon propagation via Dirac's quantum notation, applicable to single photons and ensembles of indistinguishable photons, leading to the generalized N-slit interferometric equation (1987-1991) [27-30].
Introduction of extremely-elongated laser Gaussian beams, width to height ratios of up to 3000:1, for imaging, microdensitometry, and microscopy applications. This class of illumination is also now known as light-sheet illumination (1987-1991) [29, 30].
Invention of the N-slit laser interferometer (1987) [27-30].
Extension of the multiple-prism dispersion theory to higher derivatives for laser-pulse compression (1987) [31].
Single-longitudinal-mode oscillation in long-pulse high-energy tunable lasers (1986) [32].
Multiple-prism grating and multiple-prism near grazing-incidence grating oscillators in high-power CO₂ laser cavities (1985) [33].
Variable linewidth narrow-linewidth high-power CO₂ laser (1985) [34].
Demonstration of single-longitudinal-mode laser oscillation using multiple-prism near grazing-incidence grating oscillators under high-repetition copper-laser excitation (1982-1984) [35].
Generelized multiple-prism grating dispersion theory (1982) [36].
Multiple-prism near grazing-incidence grating narrow-linewidth tunable laser oscillator (1981) [37].
Derivation of the correct Fourier-theory heat-transfer equation for radial heat-flow in a sphere (1979) [38].
References
1. F J Duarte and K M Vaeth, in Organic Lasers and Organic Photonics (Institute of Physics, Bristol, 2024) Chapter 16.
2. F J Duarte and I E Olivares, N-slit quantum interferometers in the nanometer domain Applied Physics B 129 88 (2023)
3. F J Duarte and T S Taylor, Quantum coherence in electrically-pumped organic interferometric emitters Applied Physics B 128 11 (2022)
4. F J Duarte and T S Taylor, Quantum Entanglement Engineering and Applications (Institute of Physics, Bristol, 2021)
5. F J Duarte, T S Taylor, J C Slaten, On the probability amplitude of quantum entanglement and the Pauli matrices Optics and Quantum Electronics 52 106 (2020)
6. F J Duarte, Fundamentals of Quantum Entanglement (Institute of Physics, Bristol, 2019)
7. F J Duarte and T S Taylor, Quantum entanglement probability amplitudes in multiple propagation channels: an interferometric approach Optik 139 222-230 (2017)
8. F J Duarte, Quantum Optics for Engineers (CRC, New York, 2014)
9. F J Duarte, The probability amplitude for entangled polarizations: an interferometric approach Journal of Modern Optics 60 1585-1587 (2013)
10. F J Duarte, T S Taylor, A M Black, I E Olivares, Diffractive patterns superimposed over propagating N-slit interferograms Journal of Modern Optics 60 136-140 (2013)
11. F J Duarte, T S Taylor, A M Black, W E Davenport, P G Varmette, N-slit interferometer for secure free-space optical communications: 527 m intra interferometric path length Journal of Optics 13 035710 (2011)
12. F J Duarte, Generalized multiple-prism dispersion theory for laser pulse compression: higher order phase derivatives Applied Physics B 96 809-814 (2009)
13. F J Duarte, Multiple-prism dispersion equations for positive and negative refraction, Applied Physics B 82 35-38 (2006)
14. F J Duarte, L S Liao, K M Vaeth, Coherence characteristics of electrically excited tandem organic light-emitting diodes Optics Letters 30 3072-3074 (2005)
15. F J Duarte, Tunable Laser Optics (Elsevier Academic, New York, 2003)
16. F J Duarte and R O James, Tunable solid-state lasers incorporating dye-doped polymer-nanoparticle gain media Optics Letters 28 2088-2090 (2003)
17. F J Duarte, Secure interferometric communications in free space Optics Communications 205 313-319 (2002)
18. I. E. Olivares, A. E. Duarte, E. A. Saravia, F. J. Duarte, Lithium isotope separation with tunable diode lasers Applied Optics 41 2973-2977 (2002)
19. F J Duarte, Multiple-prism grating solid-state dye laser oscillator: optimized architecture Applied Optics 38 6347-6349 (1999)
20. F J Duarte, Interference, diffraction, and refraction, via Dirac's notation American Journal of Physics 65 637-640 (1997)
21. F J Duarte, Generalized interference equation and optical processing, in Proceedings of the International Conference on Lasers '95 (STS Press, McLean, 1996) pp 615-617 (and also described in Tunable Laser Optics (Elsevier-Academic, New York, 2003))
22. F J Duarte, Solid-state multiple-prism grating dye-laser oscillators Applied Optics 33 3857-3860 (1994)
23. F J Duarte, W E Davenport, J J Ehrlich, T S Taylor, Ruggedized narrow-linewidth dispersive dye laser oscillator Optics Communications 84 310-316 (1991)
24. F J Duarte, Optical device for rotating the polarization of a light beam US Patent 4822150 (1989)
25. F J Duarte, J J Ehrlich, W E Davenport, T S Taylor, Flashlamp pumped narrow-linewidth dispersive dye laser oscillators: very low amplified spontaneous emission levels and reduction of linewidth instabilities Applied Optics 29 3176-3179 (1990)
26. F J Duarte, J J Ehrlich, S P Patterson, S D Russell, J E Adams, Linewidth instabilities in narrow-linewidth flashlamp-pumped dye laser oscillators Applied Optics 27 843-846 (1988)
27. F J Duarte, in High Power Dye Lasers (Springer, Berlin, 1991) Chapter 2
28. F J Duarte, On a generalized interference equation and interferometric measurements Optics Communications 103 8-14 (1993)
29. F J Duarte, Electro-optical interferometric microdensitometer system US Patent 5255069 (1993)
30. F J Duarte, Beam shaping with telescopes and multiple-prism beam expanders Journal of the Optical Society of America A 4 P30 (1987)
31. F. J. Duarte, Generalized multiple-prism dispersion theory for pulse compression in ultrafast dye lasers Optics and Quantum Electronics 19 223-229 (1987)
32. F J Duarte and R W Conrad, Single-mode flashlamp-pumped dye laser oscillators Applied Optics 25 663-665 (1986)
33. F J Duarte, Multiple-prism Littrow and grazing-incidence pulsed CO₂ lasers Applied Optics 24 1244-1245 (1985)
34. F J Duarte, Variable linewidth high-power TEA CO₂ laser Applied Optics 24 34-37 (1985)
35. F J Duarte and J A Piper, Narrow-linewidth high prf copper laser-pumped dye-laser oscillators Applied Optics 23 1391-1394 (1984)
36. F J Duarte and J A Piper, Dispersion theory of multiple-prism beam expanders for pulsed dye lasers Optics Communications 43 303-307 (1982)
37. F J Duarte and J A Piper, Prism pre-expanded grazing-incidence grating cavity for pulsed dye lasers Applied Optics 20 2113-2116 (1981)
38. J Unsworth and F J Duarte, Heat diffusion in a solid sphere and fourier theory: an elementary practical example American Journal of Physics 47 981-983 (1979)
  
  Published on the 9th of January, 2015; updated on the 1st of March, 2025.

F. J. Duarte's Original Research

References