Publications

1) Papers

(+) corresponding author

(*) works published also in russian  

1.101) Paroli B, Martini G, Potenza MAC, Siano M, Mirigliano M, Milani P, Solving classification tasks by a receptron based on nonlinear optical speckle fields, Neural Networks 166, 634-644

1.100) Potenza MAC, Cremonesi L, An overview of the optical characterization of free microparticles and their radiative properties, Journal of Quantitative Spectroscopy and Radiative Transfer, 108773 INVITED (+)

https://doi.org/10.1016/j.jqsrt.2023.108773 

1.99) Melzi G, et al., Toxicological Profile of PM from Different Sources in the Bronchial Epithelial Cell Line BEAS-2B, Toxics 11 (5), 413

1.98) Scalcinati L, Paroli B, Zannoni M, Gervasi M, Potenza MAC, A Local Two-Port Interferometer to Detect Radio-Vortices at 30 GHz, Progress In Electromagnetics Research M 116, 119-128

1.97) Siano M., et al., FOCUS: fast Monte Carlo approach to coherence of undulator sources, JSR 30(2023)

https://doi.org/10.1107/S1600577522010748

1.96) Goy C., et al., Refractive Index of Supercooled Water Down to 230.3 K in the Wavelength Range between 534 and 675 nm, JPCL 13(2022)11872-11877 

1.95) B. Paroli, L. Cremonesi, M. SIano, M.A.C. Potenza, Hybrid OAM-Amplitude multiplexing and demultiplexing of incoherent optical states, Optics Communications, (2022)  524, 128808 

1.94) D. Ceratti, et al., Self-Healing and Light-Soaking in MAPbI3: The Effect of H2O, Advanced Materials (2022) 34,2110239; DOI: 10.1039/d1mh00006c 

1.93) D. Ceratti, et al.,  2D Pb-Halide Perovskites Can Self-Heal Photodamage Better than 3D Ones, Advanced Functional Materials, 2022, 32(24), 2113354 

1.92) M. Siano, et al., Two-dimensional electron beam size measurements with x-ray heterodyne near field speckles, Physical Review Accelerators and Beams, 2022, 25(5), 052801

1.91) C. Ravasio et al., Optical Characterization  of Mineral Dust from the EAIIST Project with Digital Holography, ACS Earth and Space Chemistry (2021)

1.90) Potenza M.A.C., Cremonesi L., On the quasi-universality of the forward light scattering lobe for micrometric objects J. Quant. Spectr. Rad. Transfer 278(2022)108028

1.89) B.Paroli, M. Siano and M.A.C. Potenza, Dense-code free space transmission by local demultiplexing optical states of a composed vortex, Opt. Expr. 29(2021)14412

1.88) D. Ceratti, et al., The pursuit of stability in halide perowskites: the monovalent cation and the key for surface and bulk self-healing, Materials Horizons 8(2021)1570.1586 

1.87) L. Cremonesi, et al., Light extinction and scattering from aggregates composed of submicron particles, Journal of Nanoparticle Research (2020) 22:344        DOI: 10.1007/s11051-020-05075-3

1.86) B. Paroli, M. Siano, M.A.C. Potenza, Measuring the topological charge of orbital angular momentum radiation in single-shot by means of the wavefront intrinsic curvature, Appl. Opt. 17(2020)5268   doi.org/10.1364/AO.392341

1.85) M.A.C. Potenza, An Extremely simplified optics laboratory for teaching the fundamentals of Fourier Analysis, Eur. J. Phys. 42(2021)035304  doi.org/10.1088/1361-6404/abd4c9

1.84) F. Simonetto, M. Marmonti, M.A.C. Potenza, Effects of radiation damage on the optical properties of glass, Journal of Astronomical Telescopes, Instruments and Systems 6(3)(2020)038004        DOI: 10.1117/1.JATIS.6.3.038004

1.83) L. Scalcinati, B. Paroli, M. Zannoni, M.A.C. Potenza, Measurement of the local intrinsic curvature of a l=1 radio vortex at 30 GHz, Progress in Electromagnetic Research M 94(2020)1-8        DOI: 10.2528/PIERM20041407

1.82) L. Cremonesi, M. Siano, B. Paroli, M.A.C. Potenza, Near Field Scattering under Forced Flow, Review of Scientific Instruments 91(2020)075108   https://aip.scitation.org/doi/10.1063/1.5138694

1.81) B. Paroli, M. Siano, M.A.C. Potenza, A composite beam of radiation with orbital angular momentum allows effective local, single shot measurement of topological charge, Opt. Comm. 459(2020)125049

1.80) L. Cremonesi, et al., Multiparametric optical characterization of airborne dust with single particle extinction and scattering, Aerosol Science and Technology 54:4(2020)353-366 DOI: 10.1080/02786826.2019.1699896

1.79) B. Paroli, M. Siano, L. Teruzzi, M.A.C. Potenza, Single-shot measurement of phase and topological properties of orbital angular momentum radiation through asymmetric lateral coherence, Phys. Rev. Accel. Beams 22(2019)032901

1.78) L. Serafini, et al., MariX, an advanced MHz-calss repetition rate X-ray source for linear regime time-resolved spectroscopy and photon scattering,  Nucl. Instr. Meth. A 930(2019)167

1.77) C. Minnai, L. Cremonesi, P. Milani, M.A.C. Potenza, A very simple scheme for spectrally resolved imaging by means of curved polymeric gratings, Mater. Res. Express 6(2019)065044

1.76) S. Maiorana, et al., Phytotoxicity of wear debris from traditional and innovative brake pads, Environment International 123(2019)156-163

1.75) M.A.C. Potenza, S.J. Veen, P. Shall and G.H. Wegdam, Nucleation of weakely attractive aggregates in microgravity, EPL 124(2018)28002; doi: 10.1209/0295-5075/124/28002

1.74) B. Paroli, M. Siano and M.A.C. Potenza, Asymmetric lateral coherence allows precise wavefront characterization, EPL 122(2018)44001; DOI: 10.1209/0295-5075/122/44001

1.73) B. Paroli , A. Cirella, I. Drebot, V. Petrillo, M. Siano and M.A.C. Potenza, Asymmetric lateral coherence of OAM radiation reveals topological charge and local curvature, J. Opt. 20 (2018) 075605; DOI: 10.1088/2040-8986/aac936

1.72) M.F. Simonsen, et al. Particle Shape accounts for instrumental discrepancy in ice core dust size distributions, Climate of the Past 14(2018)601; DOI: https://cp.copernicus.org/articles/14/601/2018/

1.71) V. Galbiati, et al., In vitro assessment of silver nanoparticles immunotoxicity, Food and Chemical Toxicology 122(2018)363-374; https://doi.org/10.1016/j.fct.2017.12.023

1.70) C. Goy, et al. Shrinking of Rapidly Evaporating Water Microdroplets Reveals their Extreme Supercooling, PRL 120(2018)015501

1.70) D. R. Ceratti, et al. Self-Healing Inside APbBr3 Halide Perovskite Crystals, Advanced Materials (2018)1706273; DOI: 10.1002/adma.201706273

1.68) T. Sanvito, et al. Single particle extinction and scattering optical method unveils in real time the influence of the blood components on polymeric nanoparticles, Nanomedicine (2017) (+) DOI: 10.1016/j.nano.2017.07.008

1.67) F. Mariani, et al. Single Particle Extinction and Scattering allows novel optical characterization of aerosols, JNR 19(2017)291 (+) DOI 10.1007/s11051-017-3995-3

1.66) M.A.C. Potenza, et al. Single-Particle Extinction and Scattering Method Allows for Detection and Characterization of Aggregates of Aeolian Dust Grains in Ice Cores, Earth and Space Chemistry 1(2017)261; DOI: 10.1021/acsearthspacechem.7b00018

1.65) D. Biganzoli, M.A.C. Potenza, M. Robberto, Radiative Transfer in a Translucent Cloud Illuminated by an Extended Background Source, APJ 840:55(2017); https://doi.org/10.3847/1538-4357/aa6bf9

1.64) M.A.C. Potenza, et al. Hyperspectral imaging with deformable gratings fabricated with metal-elastomer nanocomposites, RSI 88(2017)113105; https://doi.org/10.1063/1.5009180 (+)

1.63) Z. Krpetic, et al. Detecting the Shape of Anisotropic Gold Nanoparticles in Dispersion With Single Particle Extinction and Scattering, Nanoscale (2016); DOI: 10.1039/C6NR08977A 

1.62) Potenza, M. A. C. et al. Shape and size constraints on dust optical properties from the Dome C ice core, Antarctica. Sci. Rep. 6, 28162; doi: 10.1038/srep28162 (2016). (+)

1.61) S. Villa, T. Sanvito, B. Paroli, A. Pullia, B. Delmonte and M.A.C. Potenza, Measuring shape and size of micrometric particles from the analysis of the forward scattered field, Journal of Applied Physics 119(2016)224901 (+) http://dx.doi.org/10.1063/1.4953332 (+)

1.60) B. Paroli, E. Chiadroni, M. Ferrario, and M.A.C. Potenza, A systematic study of the asymmetric lateral coherence of radiation emitted by ultrarelativistic particles in laser-driven accelerators, NIMA 59330; DOI: http://dx.doi.org/10.1016/j.nima.2016.09.032

1.59) M. Siano, B. Paroli, E. Chiadroni, M. Ferrario, and M.A.C. Potenza, Nanosecond LED-based source for optical modeling of scintillators illuminated by particlaly coherent X-ray radiation, RSI  87(2016)126104; doi: 10.1063/1.4972891

1.58) B. Paroli, E. Bravin, S. Mazzoni, G. Trad and M.A.C. Potenza, A modified two-slit interferometer for characterizing the asymmetric lateral coherence of undulator radiation, EPL 115(2016)14004; doi: 10.1209/0295-5075/115/14004

1.57) B. Paroli and M.A.C. Potenza, Two-dimensional mapping of the asymmetric lateral coherence of thermal light, Optics Express 24,22(2016)25676

1.56) M.A.C. Potenza, T. Sanvito, A. Pullia, Accurate sizing of ceria oxide nanoparticles in slurries by the analysis of the optical forward-scattered field, JNR 17(2015)110 (+)

1.55) M. Siano, et al. Measurement of power spectral density of broad-spectrum visible light with Heterodyne Near Field Scattering and its scalability to betatron radiation, Optics Express (2015)

1.54) B. Paroli, E. Chiadroni, M. Ferrario, M.A.C. Potenza, Analog optical simulation of the asymmetric lateral coherence of betatron radiation, Optics Express 23(2015)29912-29920    DOI:10.1364/OE.23.029912

1.53) Potenza, M. A. C. et al. Single particle optical extinction and scattering allows real time quantitative characterization of drug payload and degradation of polymeric nanoparticles. Sci. Rep. 5, 18228; doi: 10.1038/srep18228 (2015).  (+)

1.52) M.A.C. Potenza, T. Sanvito, F.P. Mariani, P.G. Vekilov, D. Maes, Confocal Depolarized Dynamic Light Scattering: a Novel technique for the Characterization of Nanoparticles in Complex Fluids, MRA Medical Advances 2(2015) (+)

1.51) M.A.C. Potenza, T. Sanvito, G. Fazio, Optical characterization of industries slurries, KONA Particle and Particle Journal review (2015) (+) INVITED PAPER

1.50) M.A.C. Potenza, T. Sanvito, A. Pullia, Measuring the complex field scattered by single submicron particles, AIP Advances 5(2015)117222 (+)     DOI: 10.1063/1.4935927

1.49) M.A.C. Potenza, The daylight sky and Avogadro’s number, European Journal of Physics 36(2015)065040 (+)

1.48) B. Paroli, et al., Asymmetric lateral coherence of betatron radiation emitted in laser-driven light sources, Eur. Phys. Lett. 111(2015)44003

1.47) B. Paroli, E. Chiadroni, M. Ferrario, A. Mostacci, V. Petrillo, M. A. C. Potenza, A. R. Rossi, and L. Serafini, Coherence properties and diagnostics of betatron radiation emitted by an externally-injected electron beam propagating in a plasma channel, Nucl. Instr. Meth. Phys. Res. B 355, 217-220 (2015)

1.46) D. Maes, M.A. Vorontsova, M.A.C: Potenza, T. Sanvito, M. Sleutel, M. Giglio, P. Vekilov, Do Protein Crystals Nucleate within Dense Liquid Clusters?  Acta Cryst. F71 (2015)815-822

1.45) M.A.C. Potenza, T. Sanvito, A. Pullia, Accurate Sizing of  Ceria Oxide Nanoparticles in Slurries by the Analysis of the Optical Forward Scattered Field, Journal of Nanoparticle Research 17(2015)110(+); DOI: 10.1007/s11051-015-2925-5

1.44) M. Morelli, A. Masini, F. Ruffini, M.A.C. Potenza, Web tools concerning analysis and planning support for solar Energy plants starting from remotely sensed optical images, Environ. Impact Asses Rev 52(2015) 18-23    DOI http://dx.doi.org/10.1016/j.e.iar.2014.10.003

1.43) M. Manfredda, M.D. Alaimo, M. Giglio, M.A.C. Potenza, Probing Transverse Coherence with the Heterodyne Speckle Approach: Overview and Perspectives, Physics Procedia 62(2015)59-64

1.42) M. Alaimo, et al. Mapping the transverse coherence of the Self Amplified Spontaneous Emission of a Free-Electron Laser with the heterodyne speckle method, Optics Express 22(2014) 30013-30023 

1.41) M.A.C. Potenza, P. Milani, Free nanoparticle characterization by optical scattered field analysis: opportunities and perspectives, Journal of Nanoparticle Research 16, 2640 (2014) (+); DOI: 10.1007/s11051-014-2680-z 

1.40) M. A. C. Potenza, A. Manca, S. J. Veen, B. Weber, S. Mazzoni, P. Schall and G. H. Wegdam, Dynamics of colloidal aggregation in microgravity by critical Casimir forces, Europh. Lett. 106 68005 (2014) (+)    doi:10.1209/0295-5075/106/68005

1.39) C. Ghisleri, M. A. C. Potenza, L. Ravagnan, A. Bellacicca, and P. Milani, A simple scanning spectrometer based on a stretchable elastomeric reflective grating, Appl. Phys. Lett. 104, 061910 (2014) / DOI 10.1063/1.4865427

1.38) C. Ghisleri, M. Siano, L. Ravagnan, M.A.C. Potenza, P. Milani, Nanocomposite-based stretchable optics, Laser Photonics Rev., 1-7(2013)  / DOI 10.1002/lpor.201300078

1.37) T. Sanvito, F. Zocca, A. Pullia and M.A.C. Potenza, A method for characterizing the stability of light sources, Optics Express 21 (2013) 24630-24635 

1.36) S. Mazzoni, et al., SODI-COLLOID: a combination of static and dynamic light scattering on board the International Space Station,Rev. Sci. Instrum. 84, 043704 (2013)

1.35) S. Veen, O. Antoniuk, B. Weber, M.A.C. Potenza, S. Mazzoni, P. Shall, G. Wegdam, Colloidal aggregation in microgravity by critical Casimir forces, PRL 109, 248302(2012)

1.34) A. Pullia, T. Sanvito, M.A.C. Potenza, and F. Zocca, A Low-Noise Large Dynamic-Range Readout Suitable for Laser Spectroscopy with PIN Diodes, Rev. Sci. Instrum 83, 104704 (2012)

1.33) A. Miotello, M. Robberto, M.A.C. Potenza, L. Ricci, Evidence of photoevaporation and spatial variation of grain sizes in the Orion 114-426 protoplanetary disk, Astro Phys. J. 757:78(2012)

1.32) D. Cenadelli, M.A.C. Potenza, M. Zeni, Stellar Temperatures via Wien's Law: So Basic, Amer. J. Physics 80:5, 931-398 (2012)

1.31) M.A.C. Potenza, T. Sanvito, V. Degiorgio and M. Giglio, Confocal Depolarized Dynamic Light Scattering, Adv. Chem. Phys. 151, 61-77 (2012) (+)

1.30) M.A.C. Potenza, K.P.V. Sabareesh, M. D. Alaimo, M. Carpineti, M. Giglio, How to measure the optical thickness of scattering particles from the phase delay of scattered waves: Application to turbid samples, Phys. Rev. Lett. 105, 193901 (2010)

1.29) M.A.C. Potenza, T. Sanvito, M. Alaimo, V. Degiorgio, M. Giglio, Confocal, zero-angle dynamic depolarized scattering EPJ E 31, 69-72(2010) (+)

1.28) M.D. Alaimo, M.A.C. Potenza, M. Manfredda, G. Geloni, M. Szutcki, T. Narayanan and M. Giglio, Probing the transverse coherence of an Undulator X-Ray Beam Using Brownian Particles, Phys. Rev. Lett. 109, 194805 (2009)

1.27) V. Degiorgio, M.A.C. Potenza, M. Giglio, Scattering from anisotropic particles: A challenge for the optical theorem?, EPJE 29, 379-382 (2009) (+) 

1.26) A. Campagnoli, et al., Feed particle size evaluation: conventional approach versus digital holography based image analysis, Italian Journal of Animal Science 8 (2009) 283-285

1.25) S. Minardi, J. Trull, M.A.C. Potenza, Holographic Properties of Parametric Image Conversion for Spatiotemporal Imaging of Ultra Short Pulses, Journal of Holography And Speckles 5, 85-93 (2009) (+) (Invited)

 1.24) D. Magatti, M.D. Alaimo , M.A.C. Potenza and F. Ferri, Dynamic Near Field Scattering, Appl. Phys. Lett. 92, 241101 (2008)

1.23) R. Cerbino, L. Peverini, M.A.C. Potenza, A. Robert, P. Bösecke, M. Giglio, X-Ray-Scattering Information Obtained From Near-Field Speckle, Nature Physics 4, 238 (2008)

1.22) M.D. Alaimo, D. Magatti, M.A.C. Potenza, F. Ferri, Heterodyne Speckle Velocimetry of Poiseuille Flow, Journal of Applied Physics 102,1,(2007)

1.21) M.D. Alaimo, M.A.C. Potenza, D. Magatti, F. Ferri, Heterodyne Speckle Velocimetry, Appl. Phys. Lett. 88(2006)191101 (+)

1.20) M.A.C. Potenza, M.D. Alaimo, D. Magatti, D. Pescini, F. Ferri, M. Giglio, A new technique for fluid velocimetry, Optics and lasers in Engineering 44(2006)722-731 (+)

1.19) M.A.C. Potenza, D. Pescini, D. Magatti, F. Ferri, M. Giglio, A new particle sizing technique based on near field scattering, Nucl. Phys. B, 150 (2006) 334-338 (+)

1.18) M.A.C. Potenza, D. Brogioli, M. Giglio, Total Internal Reflection Scattering, Appl. Phys. Lett. 85(2004)2730 (+)

1.17) F. Ferri, D. Magatti, M.A.C. Potenza, M. Giglio, Heterodyne Near Field Scattering: a new technique for complex fluids, Phys. Rev. E, 70(2004)041405

1.16) D. Brogioli, A. Vailati, M. Giglio, M.A.C. Potenza, Near Field Scattering, Physical Chemistry and Chemical Physics 7(2004)1547-1550

1.15) M.A.C. Potenza et al., Three Dimensional Imaging of Ultrashort Pulses, Opt. Comm. 229(2004)381-390 (+)

1.14) A. Andreoni, M. Bondani, M. A. C. Potenza, Y. N. Denisyuk, E. Puddu, Boolean algebra operations performed on optical bits by the generation of holographic fields through second-order nonlinear interactions, Rev. Sci. Instr. 72(2001)2525 (+)

1.13) A. Andreoni, M. Bondani, M. A. C. Potenza, Combinational tasks performed by second-harmonic-generated holograms , Opt. Lett 25(2000)1570-1572 (+)

1.12) Y. N. Denisyuk, A. Andreoni, M. Bondani, M. A. C. Potenza, Real time holograms generated by second harmonic cross correlation of object and reference optical fields, Opt. Lett 25(2000)890-892

1.11) Yu. N. Denisyuk, A. Andreoni, M. A. C. Potenza, Formation of the holographic image of a diffuse object in second harmonic radiation generated by a nonlinear medium, Opt. & Spectr. 89(2000)476-483 (Invited) (*)

1.10) Yu. N. Denisyuk, A. Andreoni, M. Bondani, M. A. C. Potenza, Holographic properties of the second harmonic cross-correlation of object and reference wave fields, JOSA B 17,6(2000) 966-972 (+)

1.9) Yu. N. Denisyuk, A. Andreoni, M. A. C. Potenza, Recording of a hologram by using the second-order nonlinearity, Opt. & Spectr. 89(2000)113-120 (Invited) (*)

1.8) Yu. N. Denisyuk, A. Andreoni, M. Bondani, M. A. C. Potenza, Transformation of holographic wave-fields under the influence of the second order non-linearity of a nonlinear material, Opt. Mem. Neural Netw. 9(2000) 201-207 (Invited) (*)

1.7) A. Andreoni, M. Bondani, M.A.C. Potenza, F. Villani, “Viewing” objects hidden in scattering media by frequency-doubling the Fourier-transform of the image, Opt. Comm. 174 (2000) 487-497

1.6) A. Andreoni, M. Bondani, M.A.C. Potenza, F. Villani, Relevance of temporal coherence in the second-harmonic cross-correlation measurement of a multiply scattered laser pulse: European Physics Journal D 8, 111-116 (2000) (Invited)

1.5) A. Andreoni, M. Bondani, M.A.C. Potenza, Control of the effects of crystal dispersion at different orders in the mixing of free phase-matched waves on a 5- to 100- fs time scale, J. Telecomm. Inf. Techn. 1,2 (1999) 16

1.4) Yu. N. Denisyuk, A. Andreoni, M. A. C. Potenza, Holographic properties of the effect of second order harmonic cross-correlation of optical wavefields, Optical Memory and Neural Network 8, 3 (1999)123-137 (*)

1.3) A. Andreoni, M. Bondani, M.A.C. Potenza, F. Villani, Phase-selection of image-bearing field components by frequency up-conversion in non-linear crystals, Journal of Non linear Optical Physics and Materials, 8, 1, 55-70 (1998) (Invited)

1.2) A. Andreoni, M. Bondani, M.A.C. Potenza, Ultra-broadband and chirp-free frequency doubling in b-barium borate, Opt. Comm. 154, 376 – 382 (1998) (+)

1.1) G. Boella, M. Gervasi, M.A.C. Potenza, P.G. Rancoita and I. Usoskin, Modulated antiproton fluxes for interstellar production models, Astroparticle Physics 9, 3, 261 – 267 (1998)

2) Collected papers

2.2) S. Minardi, M.A.C. Potenza, J. Trull, Intensity mapping of three-dimensional optical wave packets: holographic properties and applications, Trends in Laser and of Electro-Optics Research, pp. 151-182, W.T. Arkin Ed., Nova Science Publisher Inc. (2006), New York (USA) - ISBN 1-59454-498-0 (Invited)

2.1) Yu.N. Denisyuk, A. Andreoni, M. Bondani, M. A. C. Potenza, Optical Information Processes,  38-45, SPIE press 2002, Bellingham (USA) (Invited)