Journal papers

1. Bohmian monitoring of dark soliton formation processes, J. Tounli and A. S. Sanz (submitted). Available at: arXiv:2210.13175.
   
   
2. Random Majorana constellations, A. Z. Goldberg, J. L. Romero, A. S. Sanz, A. B. Klimov, G. Leuchs and L. L. Sánchez-Soto (submitted). Available at: arXiv:2112.01612.
   
   
3. A Bohmian trajectory analysis of singular wave functions, A. S. Sanz, L. L. Sanchez-Soto and A. Aiello, Phys. Lett. A 504, 129428 (2024). Also available at: arXiv:2301.13207.
   
   
4. Exploring the nonclassical dynamics of the "classical" Schrödinger equation, D. Navia and A. S. Sanz, Ann. Phys. 463, 169637 (2024). Also available at: arXiv:2312.02977.
   
   
5. Exploring the dynamics of finite-energy Airy beams: A trajectory analysis perspective, A. S. Sanz and R. Martínez-Herrero, Opt. Express 34, 5592 (2024). Also available at: arXiv:2310.17020.
   
   
6. Young’s experiment with entangled bipartite systems: The role of underlaying quantum velocity fields, A. S. Sanz, Entropy 25, 1077 (2023). Also available at: arXiv.org:2306.10104.
   
   
7. Local characterization of the polarization state of three-dimensional electromagnetic fields: An alternative approach, R. Martínez-Herrero, D. Maluenda, M. Aviñoá, A. Carnicer, I. Juvells and A. S. Sanz, Photonics Res. 11, 1326 (2023). Also available at: www.researching.cn.
   
   
8. Partially coherent Airy beams: A cross-spectral density approach, R. Martínez-Herrero and A. S. Sanz, Phys. Rev. A 106, 053512 (2022). Also available at: arXiv:2211.01027.
   
   
9. Flux trajectory analysis of Airy-type beams, A. S. Sanz, J. Opt. Soc. Am. A 39, C79 (2022). Also available at: arXiv:2210.08240.
   
   
10. Analysis of the gradual transition from the near to the far field in single-slit diffraction, A. García-Sánchez and A. S. Sanz, Phys. Scr. 97, 055507 (2022). Also available at: arXiv:2110.06782.
    
    
11. Quantum-classical entropy analysis for nonlinearly-coupled continuous-variable bipartite systems, A. S. Sanz, Entropy 24, 190 (2022). Also vailable at: arXiv:2111.10165.
    
    
12. Taming singularities of the quantum Fisher information, A. Z. Goldberg, J. L. Romero, A. S. Sanz and L. L. Sánchez-Soto, Int. J. Quantum Inf. 19, 2140004 (2021). Also available at: arXiv:2108.05976.
    
    
13. Bohm's quantum "non-mechanics'': An alternative quantum theory with its own ontology?, A. S. Sanz, Ann. Fond. Louis de Broglie 46(1), 19 (2021). Also available at: arXiv:2105.06158.
    
    
14. Decoherence in quantum cavities: Environmental erasure of carpet-type structures, E. Honrubia and A. S. Sanz, Phys. Rev. A 103, 062210 (2021). Also available at: arXiv:2105.06157.
    
    
15. Quantum Zermelo problem for general energy resource bounds, J. M. Bofill, A. S. Sanz, G. Albareda, I. P. R. Moreira and W. Quapp, Phys. Rev. Research 2, 033492 (2020). Also available at: arXiv:2005.07304.
    
    
16. Uncertainty principle for axial power content of highly focused fields, R. Martínez-Herrero, A. Carnicer, I. Juvells and A. S. Sanz, Opt. Express 28, 29676 (2020). Also available at: arXiv:2009.04599.
    
    
17. Graph approach to quantum teleportation dynamics, E. Honrubia and A. S. Sanz, Quantum Reports 2, 352 (2020). Also available at: arXiv:1912.01133.
    
    
18. Bohmian-based approach to Gauss-Maxwell beams, A. S. Sanz, M. D. Davidović and M. Božić, Appl. Sci. 10, 1808 (2020). Also available at: arXiv:1912.01133.
    
    
19. A simple projective setup to study optical cloaking in the classroom, I. Marcos-Muñoz and A. S. Sanz, Eur. J. Phys. 41, 025303 (2020). Also available at: arXiv:1807.02276.
    
    
20. Wave-packet numerical investigation of thermal diffuse scattering: A time-dependent quantum approach to electron diffraction simulations, S. Rudinsky, A. S. Sanz and R. Gauvin, Micron 126, 102737 (2019). Also available at: arXiv:1801.05869.
    
    
21. Boundary bound diffraction: A combined spectral and Bohmian analysis, J. Tounli, A. Alvarado and A. S. Sanz, Phys. Scr. 94, 035202 (2019). Also available at: arXiv:1803.10363.
    
    
22. Bohm's approach to quantum mechanics: Alternative theory or practical picture?, A. S. Sanz, Front. Phys. 14, 11301 (2019). Also available at: arXiv:1707.00609.
    
    
23. Trajectory-based interpretation of laser light diffraction by a sharp edge, M. D. Davidović, M. D. Davidović, A. S. Sanz, M. Božić and D. Vasiljević, J. Russ. Laser Res. 39, 438 (2018). Also available at: arXiv:1711.09662.
    
    
24. Quantum Interference, Hidden Symmetries: Theory and Experimental Facts, A. S. Sanz, J. Phys.: Conf. Ser. 1071, 012018 (2018). Also available at: arXiv:1712.03702.
    
    
25. Atom-diffraction from surfaces with defects: A Fermatian, Newtonian and Bohmian joint view, A. S. Sanz, Entropy 20, 451 (2018). Also available at: arXiv:1805.00574.
    
    
26. A novel quantum dynamical approach in electron microscopy combining wave-packet propagation with Bohmian trajectories, S. Rudinsky, A. S. Sanz and R. Gauvin, J. Chem. Phys. 146, 104702 (2017). Also available at: arXiv:1701.08700.
    
    
27. Description of classical and quantum interference in view of the concept of flow line, M. Davidović, A. S. Sanz and M. Božić, J. Russ. Laser Res. 36, 329 (2015). Also available at: arXiv:1508.05194.
    
    
28. Investigating puzzling aspects of the quantum theory by means of its hydrodynamic representation, A. S. Sanz, Found. Phys. 45, 1153 (2015). Also available at: arXiv:1501.05783.
    
    
29. Nonclassical polarization dynamics in classical-like states, A. Luis and A. S. Sanz, Phys. Rev. A 92, 023832 (2015). Also available at: arXiv:1402.4997.
    
    
30. What dynamics can be expected for mixed states in two-slit experiments?, A. Luis and A. S. Sanz, Ann. Phys. 357, 95 (2015). Also available at: arXiv:1311.2612.
    
    
31. Full quantum mechanical analysis of atomic three-grating Mach-Zehnder interferometry, A. S. Sanz, M. Davidović and M. Božić, Ann. Phys. 353, 205 (2015). Also available at: arXiv:1402.3885.
    
    
32. Applied Bohmian mechanics, A. Benseny, G. Albareda, A. S. Sanz, J. Mompart and X. Oriols, Eur. Phys. J. D 68, 286 (2014). Also available at: arXiv:1406.3151.
    
    
33. Dissipative Bohmian mechanics within the Caldirola-Kanai framework: A trajectory analysis of wave-packet dynamics in viscid media, A. S. Sanz, R. Martínez-Casado, H. C. Peñate-Rodríguez, G. Rojas-Lorenzo, and S. Miret-Artés Ann. Phys. 347, 1 (2014). Also available at: arXiv:1306.6607.
    
    
34. Effective Markovian description of decoherence in bound systems, A. S. Sanz, Can. J. Chem. 92, 168 (2014). Also available at: arXiv:1402.3878.
    
    
35. Particles, waves and trajectories: 2010 years after Young's experiment, A. S. Sanz, J. Phys.: Conf. Ser. 504, 012028 (2014). Also available at: arXiv:1402.3877.
    
    
36. How does light move? - Determining the flow of light without destroying interference, M. Davidović and A. S. Sanz, EPN 44(6), 33 (2013). Also available at: arXiv:1403.0659.
    
    
37. On the unique mapping relationship between initial and final quantum states, A. S. Sanz and S. Miret-Artés, Ann. Phys. 339, 11 (2013). Also available at: arXiv:1112.3830.
    
    
38. How does a magnetic trap work?, J. Pérez-Ríos and A. S. Sanz, Am. J. Phys. 81, 836 (2013). Also available at: arXiv:1310.6054.
    
    
39. Adsorbate surface diffusion: The role of incoherent tunneling in light particle motion, A. S. Sanz, R. Martínez-Casado and S. Miret-Artés, Surf. Sci. 617, 229 (2013). Also available at: arXiv:1207.3199.
    
    
40. Reconciling quantum trajectories and stationary quantum distributions in single-photon polarization states, A. Luis and A. S. Sanz, Phys. Rev. A 87, 063844 (2013). Also available at: arXiv:1304.1668.
    
    
41. Trajectory-based interpretation of Young's experiment, the Arago-Fresnel laws and the Poisson-Arago spot for photons and massive particles, M. Davidović, A. S. Sanz, M. Božić, D. Arsenović and D. Dimić, Phys. Scr. T153, 014015 (2013). Also available at: arXiv:1209.3809.
    
    
42. Quantum phase analysis with quantum trajectories: A step towards the creation of a Bohmian thinking, A. S. Sanz and S. Miret-Artés, Am. J. Phys. 80, 525 (2012). Also available at: arXiv:1104.1296.
    
    
43. Investigating transition state resonances in the time domain by means of Bohmian mechanics: The F+HD reaction, A. S. Sanz, D. López-Durán and T. González-Lezana, Chem. Phys. 399, 151 (2012). Also available at: arXiv:1105.1258.
    
    
44. Transmission properties in waveguides: An optical streamline analysis, A. S. Sanz, J. Campos-Martínez and S. Miret-Artés, J. Opt. Soc. Am. A 29, 695 (2012). Also available at: arXiv:1108.4964.
    
    
45. Coherence loss and revivals in atomic interferometry: A quantum-recoil analysis, M. Davidović, A. S. Sanz, M. Božić and D. Arsenović, J. Phys. A: Math. Theor. 45, 165303 (2012). Also available at: arXiv:1006.0450.
    
    
46. Quantum Zeno effect: Quantum shuffling and Markovianity, A. S. Sanz, C. Sanz-Sanz, T. González-Lezana, O. Roncero and S. Miret-Artés, Ann. Phys. 327, 1277 (2012). Also available at: arXiv:1112.3829.
    
    
47. Communication: Quantum Zeno-based control mechanism for molecular fragmentation, C. Sanz-Sanz, A. S. Sanz, T. González-Lezana, O. Roncero and S. Miret-Artés, J. Chem. Phys. 136, 121101 (2012). Also available at: arXiv:1106.4143.
    
    
48. Quantum Zeno and anti-Zeno effects in surface diffusion of interacting adsorbates, H. C. Peñate-Rodríguez, R. Martínez-Casado, G. Rojas-Lorenzo, A. S. Sanz and S. Miret-Artés, J. Phys.: Condens. Matter 24, 104013 (2012). Also available at: arXiv:1104.1294.
    
    
49. Temperature crossover of decoherence in chaotic and regular bath dynamics, A. S. Sanz, Y. Elran and P. Brumer, Phys. Rev. E 85, 036218 (2012). Also available at: arXiv:1203.4629.
    
    
50. Quantumness beyond quantum mechanics, A. S. Sanz, J. Phys.: Conf. Ser. 361, 012016 (2012). Also available at: arXiv:1202.5181.
    
    
51. Setting up tunneling conditions by means of Bohmian mechanics, A. S. Sanz and S. Miret-Artés, J. Phys. A: Math. Theor. 44, 485301 (2011). Also available at: arXiv:1104.1298.
    
    
52. Zeno dynamics in wave packet diffraction spreading, M. A. Porras, A. Luis, I. Gonzalo and A. S. Sanz, Phys. Rev. A 84, 052109 (2011). Also available at: arXiv:1110.4963.
    
    
53. On Wheeler's delayed-choice Gedankenexperiment and its laboratory realization, M. Božić, L. Vuškovi&#263, M. Davidović and A. S. Sanz, Phys. Scr. T143, 014007 (2011). Also available at: arXiv:1101.1511.
    
    
54. Quantum interference within the complex quantum Hamilton-Jacobi formalism, C.-C. Chou, A. S. Sanz, S. Miret-Artés and R.E. Wyatt, Ann. Phys. 325, 2193 (2010). Also available at: arXiv:0909.0045.
    
    
55. On the influence of resonance photon scattering on atom interference, M. Božić, D. Arsenović, A. S. Sanz and M. Davidović, Phys. Scr. T140, 014017 (2010). Also available at: arXiv:0910.2979.
    
    
56. Phonon lineshapes in atom-surface scattering, R. Martínez-Casado, A. S. Sanz and S. Miret-Artés, J. Phys.: Condens. Matter 22, 304017 (2010). Also available at: arXiv:1003.0790.
    
    
57. Linear response theory of activated surface diffusion with interacting adsobates, R. Martínez-Casado, A. S. Sanz, J. L. Vega, G. Rojas-Lorenzo and S. Miret-Artés, Chem. Phys. 370, 180 (2010). Also available at: arXiv:0909.0719 .
    
    
58. Understanding interference experiments with polarized light through photon trajectories, A. S. Sanz, M. Davidović, M. Božić and S. Miret-Artés, Ann. Phys. 325, 763 (2010). Also available at: arXiv:0907.2667.
    
    
59. Erratum to "Understanding chemical reactions within a generalized Hamilton-Jacobi framework" [Chem. Phys. Lett. 478, 89 (2009)], A. S. Sanz, X. Giménez, J. M. Bofill and S. Miret-Artés, Chem. Phys. Lett. 488, 235 (2010).
    
    
60. Generalized Arago-Fresnel laws: The EME-flow-line description, M. Božić, M. Davidović, T. L. Dimitrova, S. Miret-Artés, A. S. Sanz and A. Weiss, J. Russ. Laser Res. 31, 117 (2010). Also available at: arXiv:1003.2729.
    
    
61. Two-bath model for activated surface diffusion of interacting adsorbates, R. Martínez-Casado, A. S. Sanz, G. Rojas-Lorenzo and S. Miret-Artés, J. Chem. Phys. 132, 054704 (2010). Also available at: arXiv:0810.1826.
    
    
62. Femtosecond response in rare gas matrices doped with NO impurities: A stochastic approach, G. Rojas-Lorenzo, A. S. Sanz, J. Rubayo-Soneira and S. Miret-Artés, Chem. Phys. Lett. 484, 349 (2010). Also available at: arXiv:0906.4637.
    
    
63. Contextuality, decoherence and quantum trajectories, A. S. Sanz and F. Borondo, Chem. Phys. Lett. 478, 301 (2009). Also available at: arXiv:0803.2581.
    
    
64. Understanding chemical reactions within a generalized Hamilton-Jacobi framework, A. S. Sanz, X. Giménez, J. M. Bofill and S. Miret-Artés, Chem. Phys. Lett. 478, 89 (2009). Also available at: arXiv:0906.0074.
    
    
65. Electromagnetic energy flow lines as possible paths of photons, M. Davidović, A. S. Sanz, D. Arsenović, M. Božić and S. Miret-Artés, Phys. Scr. T135, 14009 (2009). Also available at: arXiv:0805.3330.
    
    
66. Evolution of the wave function of an atom hit by a photon in a three-grating interferometer, D. Arsenović, M. Božić, A. S. Sanz and M. Davidović, Phys. Scr. T135, 14025 (2009). Also available at: arXiv:0905.2405.
    
    
67. Hydrodynamic view of wave-packet interference: Quantum caves, C.-C. Chou, A. S. Sanz, S. Miret-Artés and R.E. Wyatt, Phys. Rev. Lett. 102, 250401 (2009). Also available at: arXiv:0810.1825.
    
    
68. Quantum Markovian activated surface diffusion of interacting adsorbates, R. Martínez-Casado, A. S. Sanz and S. Miret-Artés, J. Chem. Phys. 129, 184704 (2008). Also available at: arXiv:0803.0535.
    
    
69. A trajectory based understanding of quantum interference, A. S. Sanz and S. Miret-Artés, J. Phys. A: Math. Theor. 41, 435303 (2008). Also available at: arXiv:0806.2105.
    
    
70. Should particle trajectories comply with the transverse momentum distribution?, M. Davidović, D. Arsenović, M. Božić, A. S. Sanz and S. Miret-Artés, Eur. Phys. J. - Special Topics 160, 95 (2008). Also available at: arXiv:0803.2606.
    
    
71. Interplay of causticity and vorticality within the complex Hamilton-Jacobi formalism, A. S. Sanz and S. Miret-Artés, Chem. Phys. Lett. 458, 239 (2008). Also available at: arXiv:0710.2841.
    
    
72. Comment on "Reduced coherence in double-slit diffraction of neutrons" [Phys. Rev. A 75, 055602 (2007)], A. S. Sanz and F. Borondo, Phys. Rev. A Phys. Rev. A 77, 057601 (2008).
    
    
73. Stochastic theory of line-shape broadening in quasi-elastic He atom scattering with interacting adsorbates, R. Martínez-Casado, J. L. Vega, A. S. Sanz and S. Miret-Artés, Phys. Rev. B 77, 115414 (2008). Also available at: arXiv:0710.3266.
    
    
74. Comment on "Bohmian mechanics with complex action: A new trajectory-based formulation of quantum mechanics" [J. Chem. Phys. 125, 231103 (2006)], A. S. Sanz and S. Miret-Artés, J. Chem. Phys. 127, 197101 (2007).
    
    
75. Selective adsorption resonances: Quantum and stochastic approaches, A. S. Sanz and S. Miret-Artés, Phys. Rep. 451, 37 (2007).
    
    
76. Aspects of nonlocality from a quantum trajectory perspective: A WKB approach to Bohmian mechanics, A. S. Sanz and S. Miret-Artés, Chem. Phys. Lett. 445, 350 (2007). Also available at: quant-ph/0703161.
    
    
77. Quasielastic He atom scattering from surfaces: A stochastic description of the dynamics of interacting adsorbates, R. Martínez-Casado, J. L. Vega, A. S. Sanz and S. Miret-Artés, J. Phys.: Condens. Matter. 19, 305002 (2007). Also available at: arXiv:0707.2335.
    
    
78. A quantum trajectory description of decoherence, A. S. Sanz and F. Borondo, Eur. Phys. J. D 44, 319 (2007). Also available at: quant-ph/0310096.
    
    
79. A causal look into the quantum Talbot effect, A. S. Sanz and S. Miret-Artés, J. Chem. Phys. 126, 234106 (2007). Also available at: quant-ph/0702224.
    
    
80. Line shape broadening in surface diffusion of interacting adsorbates with quasielastic He atom scattering, R. Martínez-Casado, J. L. Vega, A. S. Sanz and S. Miret-Artés, Phys. Rev. Lett. 98, 216102 (2007). Also available at: cond-mat/0702219.
    
    
81. Generalized Chudley-Elliott vibration-jump model in activated surface diffusion, R. Martínez-Casado, J. L. Vega, A. S. Sanz and S. Miret-Artés, J. Chem. Phys. 126, 194711 (2007). Also available at: cond-mat/0609249.
    
    
82. Surface diffusion and low vibrational motion with interacting adsorbates: A shot noise description, R. Martínez-Casado, J. L. Vega, A. S. Sanz and S. Miret-Artés, Phys. Rev. E 75, 051128 (2007). Also available at: cond-mat/0608723.
    
    
83. Quasi-elastic peak lineshapes in adsorbate diffusion on nearly flat surfaces at low coverages: The motional narrowing effect in Xe on Pt(111), R. Martínez-Casado, J. L. Vega, A. S. Sanz and S. Miret-Artés, J. Phys.: Condens. Matter 19, 176006 (2007). Also available at: cond-mat/0608724.
    
    
84. Overlapping resonances in the control of intramolecular vibrational redistribution, D. Gerbasi, A. S. Sanz, P.S. Christopher, P. Brumer and M. Shapiro, J. Chem. Phys. 126, 124307 (2007). Also available at: quant-ph/0703263.
    
    
85. Aspects of quantum coherence in the optical Bloch equations, A. S. Sanz, H. Han and P. Brumer, J. Chem. Phys. 124, 214106 (2006). Also available at: quant-ph/0604082.
    
    
86. A Bohmian approach to quantum fractals, A. S. Sanz, J. Phys. A: Math. Theor. 38, 6037 (2005). Also available at: quant-ph/0412050.
    
    
87. Loss of coherence in double-slit diffraction experiments, A. S. Sanz, F. Borondo and M. Bastiaans, Phys. Rev. A 71, 42103 (2005). Also available at: quant-ph/0310095.
    
    
88. Quantum trajectories in elastic atom-surface scattering: Threshold and selective adsorption resonances, A. S. Sanz and S. Miret-Artés, J. Chem. Phys. 122, 014702 (2005).
    
    
89. Quantum trajectories in atom-surface scattering with single adsorbates: The role of quantum vortices, A. S. Sanz, F. Borondo and S. Miret-Artés, J. Chem. Phys. 120, 8794 (2004).
    
    
90. Role of quantum vortices in atomic scattering from single adsorbates, A. S. Sanz, F. Borondo and S. Miret-Artés, Phys. Rev. B 69, 115413 (2004).
    
    
91. Atom-surface diffraction: A trajectory description, R. Guantes, A. S. Sanz, J. Margalef-Roig and S. Miret-Artés, Surf. Sci. Rep. 53, 199 (2004).
    
    
92. Particle diffraction studied using quantum trajectories, A. S. Sanz, F. Borondo and S. Miret-Artés, J. Phys. C: Condens. Matter 14, 6109 (2002).
    
    
93. On the classical limit in the atom-surface diffraction, A. S. Sanz, F. Borondo and S. Miret-Artés, Europhys. Lett. 55, 303 (2001).
    
    
94. Causal trajectories description of atom diffraction by surfaces, A. S. Sanz, F. Borondo and S. Miret-Artés, Phys. Rev. B 61, 7743 (2000).
    
    

Conference papers

1. Local Stokes parameters: description of highly focused radially polarized fields with a topological charge, R. Martínez-Herrero, D. Maluenda, M. Aviñoá, A. Carnicer, I. Juvells, and A. S. Sanz, in Frontiers in Optics + Laser Science 2023 (FiO, LS), Technical Digest Series (Optica Publishing Group, 2023), paper FD1.6.
   
   
2. Trajectory analysis of phase effects associated with truncated Airy beams, A. S. Sanz and R. Martínez-Herrero, EPJ Web of Conferences 287, 11009 (2023).
   
   
3. On polarization characteristics of highly focused fields concentrated along the axis, R. Martínez-Herrero, A. Carnicer, I. Juvells and A. S. Sanz, EPJ Web of Conferences 255, 12010 (2021).
   
   
4. Axial power content and uncertainty principle for highly focused fields, R. Martínez-Herrero, A. Carnicer, I. Juvells, and A. S. Sanz, in Frontiers in Optics / Laser Science, B. Lee, C. Mazzali, K. Corwin, and R. Jason Jones, eds., OSA Technical Digest (Optica Publishing Group, 2020), paper JTh4A.16.
   
   

Books & Book Chapters

Books

1. A Trajectory Description of Quantum Processes. II. Applications, A. S. Sanz and S. Miret-Artés, Lecture Notes in Physics 831, Springer-Verlag (Berlin, 2014).
   
   
2. A Trajectory Description of Quantum Processes. I. Fundamentals, A. S. Sanz and S. Miret-Artés, Lecture Notes in Physics 850, Springer-Verlag (Berlin, 2012).
   
   

Book Chapters

1. Neutron Matter-Wave Diffraction: A Computational Perspective, A. S. Sanz, in Advances in Neutron Optics: Fundamentals and Applications in Material, Nuclear Sciences and Biomedicine, M. L. Calvo and R. F. Álvarez‐Estrada (Eds.), CRC Press (Singapore, 2019), pp. 79-122.
   
   
2. Bohmian pathways into chemistry: A brief overview, A. S. Sanz, in Applied Bohmian Mechanics: From Nanoscale Systems to Cosmology (2nd Ed.), X. Oriols and J. Mompart (Eds.), Pan Standford Publishing (Singapore, 2019), pp. 257-330. Also available at: arXiv:1801.04781.
   
   
3. How far can a pragmatist go into quantum theory? A critical view of our current understanding of quantum phenomena, A. S. Sanz, in Particle and Astroparticle Physics, Gravitation and Cosmology: Predictions, Observations and New Projects, Proceedings of the XXXth International Workshop on High Energy Physics, V. Petrov and R. Ryutin (Eds.), World Scientific (Singapore, 2015), pp. 161-171.
   
   
4. Bohmian mechanics in quantum chemistry, A. S. Sanz and S. Miret-Artés, in Applied Bohmian Mechanics: From Nanoscale Systems to Cosmology, X. Oriols and J. Mompart (Eds.), Pan Standford Publishing (Singapore, 2012), pp. 149-194.
   
   
5. An account on quantum interference from a hydrodynamical perspective, A. S. Sanz, in Quantum Trajectories, K. H. Hughes and G. Parlant (Eds.), CCCP6 (Daresbury Laboratory, UK, 2011), pp. 111-115.
   
   
6. An account of quantum interference from a hydrodynamical perspective, A. S. Sanz and S. Miret-Artés, in Quantum Trajectories, P. K. Chattaraj (Ed.), Taylor and Francis/CRC Press (New York, 2010), pp. 197-221.
   
   
7. Time-dependent density functional theory from a Bohmian perspective, A. S. Sanz, X. Giménez, J. M. Bofill and S. Miret-Artés, in Chemical Reactivity Theory: A Density Functional View, P. K. Chattaraj (Ed.), Taylor and Francis/CRC Press (New York, 2008), pp. 105-119.
   
   
8. Stochastic theory of lineshape broadening in quasielastic He atom scattering with interacting adsorbates, R. Martínez-Casado, J. L. Vega, A. S. Sanz and S. Miret-Artés, in Frontiers in Quantum Systems in Chemistry and Physics, S. Wilson, P. J. Grout, J. Maruani, G. Delgado-Barrio and P. Piecuch (Eds.), Progress in Theoretical Chemistry and Physics 18, Springer-Verlag (Berlin, 2008), pp. 363-386.
   
   
9. Atom-surface diffraction: A quantum trajectory description, A. S. Sanz and S. Miret-Artés, in Quantum Dynamics of Complex Molecular Systems, D. A. Micha and I. Burghardt (Eds.), Springer Series in Chemical Physics 83, Springer-Verlag (Berlin, 2006), pp. 343-368.
   
   
   
   

Other Publications (in Spanish language)

Books

1. Prácticas de laboratorio de Física, R. M. Benito, J. C. Losada, J. Ablanque y A. S. Sanz, Ariel (Madrid, 2001).
   
   
2. Números y símbolos: Del cálculo simple al álgebra abstracta, en Libros Básicos de Ciencia, Vol. 1. Traducción de Numbers and Symbols: From Simple Calculus to Abstract Algebra, Roy McWeeny (www.learndev.org).
   
   
3. Espacio y tiempo: De Euclídes a Einstein, en Libros Básicos de Ciencia, Vol. 2. Traducción de Space and Time: From Euclides to Einstein, Roy McWeeny (www.learndev.org).
   
   

Articles / News & Views

1. Hacia un mundo cuántico, A. S. Sanz, Acta Científica y Tecnológica 26, 18 (2016).
   
   
2. Mecánica bohmiana: ¿Una teoría de variables ocultas?, A. S. Sanz, Revista Española de Física 29(2), 21 (2015).
   
   
3. 50 cosas que hay que saber sobre física cuántica, A. S. Sanz, Revista Española de Física 28(2), 60 (2014).
   
   
4. Quantum dynamics with trajectories, A. S. Sanz, Revista Española de Física 22(4), 62 (2008).
   
   
5. Descripción de la difracción de partículas mediante trayectorias cuánticas bohmianas, A. S. Sanz y S. Miret-Artés, Revista Española de Física 21(1), 25 (2007).
   
   
6. Madrid Workshop on Bohmian Mechanics, A. S. Sanz, Revista Española de Física 20(4), 66 (2006).
   
   
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