Giovanni Pennelli: Publications



[1] D. Prete, E. Dimaggio, V. Demontis, V. Zannier, M.J. Rodriguez-Douton, L. Guazzelli, F. Beltram, L. Sorba, G. Pennelli, and F. Rossella. Electrostatic control of the thermoelectric figure of merit in ion-gated nanotransistors. Advanced Functional Materials, 2021. cited By 1. [ bib | DOI | http ]
[2] N. Neophytou, V. Vargiamidis, S. Foster, P. Graziosi, L. de Sousa Oliveira, D. Chakraborty, Z. Li, M. Thesberg, H. Kosina, N. Bennett, G. Pennelli, and D. Narducci. Hierarchically nanostructured thermoelectric materials: challenges and opportunities for improved power factors. European Physical Journal B, 93(11), 2020. cited By 1. [ bib | DOI | http ]
[3] S. Magagna, D. Narducci, C. Alfonso, E. Dimaggio, G. Pennelli, and A. Charaï. On the mechanism ruling the morphology of silicon nanowires obtained by one-pot metal-assisted chemical etching. Nanotechnology, 31(40), 2020. cited By 2. [ bib | DOI | http ]
[4] S. Elyamny, E. Dimaggio, S. Magagna, D. Narducci, and G. Pennelli. High power thermoelectric generator based on vertical silicon nanowires. Nano Letters, 20(7):4748--4753, 2020. cited By 13. [ bib | DOI | http ]
[5] G. Calabrese, L. Pimpolari, S. Conti, F. Mavier, S. Majee, R. Worsley, Z. Wang, F. Pieri, G. Basso, G. Pennelli, K. Parvez, D. Brooks, M. MacUcci, G. Iannaccone, K.S. Novoselov, C. Casiraghi, and G. Fiori. Inkjet-printed graphene hall mobility measurements and low-frequency noise characterization. Nanoscale, 12(12):6708--6716, 2020. cited By 5. [ bib | DOI | http ]
[6] S. Elyamny, E. Dimaggio, and G. Pennelli. Seebeck coefficient of silicon nanowire forests doped by thermal diffusion. Beilstein Journal of Nanotechnology, 11:1707--1713, 2020. cited By 0. [ bib | DOI | http ]
[7] N. Neophytou, S. Foster, V. Vargiamidis, G. Pennelli, and D. Narducci. Nanostructured potential well/barrier engineering for realizing unprecedentedly large thermoelectric power factors. Materials Today Physics, 11, 2019. cited By 7. [ bib | DOI | http ]
[8] E. Dimaggio and G. Pennelli. Planar and vertical nanostructures for thermoelectric generation. volume 8, pages 600--606, 2019. cited By 1. [ bib | DOI | http ]
[9] E. Dimaggio, F. Rossella, and G. Pennelli. Management of the output electrical power in thermoelectric generators. Electronics (Switzerland), 8(12), 2019. cited By 3. [ bib | DOI | http ]
[10] M. Rocci, V. Demontis, D. Prete, D. Ercolani, L. Sorba, F. Beltram, G. Pennelli, S. Roddaro, and F. Rossella. Suspended inas nanowire-based devices for thermal conductivity measurement using the 3ω method. Journal of Materials Engineering and Performance, 27(12):6299--6305, 2018. cited By 10. [ bib | DOI | http ]
[11] E. Dimaggio, D. Narducci, and G. Pennelli. Fabrication of silicon nanowire forests for thermoelectric applications by metal-assisted chemical etching. Journal of Materials Engineering and Performance, 27(12):6279--6285, 2018. cited By 4. [ bib | DOI | http ]
[12] G. Pennelli, S. Elyamny, and E. Dimaggio. Thermal conductivity of silicon nanowire forests. Nanotechnology, 29(50), 2018. cited By 9. [ bib | DOI | http ]
[13] G. Pennelli, E. Dimaggio, and M. Macucci. Thermal conductivity reduction in rough silicon nanomembranes. IEEE Transactions on Nanotechnology, 17(3):500--505, 2018. cited By 11. [ bib | DOI | http ]
[14] E. Dimaggio and G. Pennelli. Potentialities of silicon nanowire forests for thermoelectric generation. Nanotechnology, 29(13), 2018. cited By 15. [ bib | DOI | http ]
[15] F. Rossella, G. Pennelli, and S. Roddaro. Measurement of the thermoelectric properties of individual nanostructures. Semiconductors and Semimetals, 98:409--444, 2018. cited By 7. [ bib | DOI | http ]
[16] G. Pennelli, E. DImaggio, and M. Macucci. Note: Improvement of the 3 ω thermal conductivity measurement technique for its application at the nanoscale. Review of Scientific Instruments, 89(1), 2018. cited By 4. [ bib | DOI | http ]
[17] A. Porciatti, Z. Wang, P. Marconcini, G. Pennelli, G. Basso, D. Neumaier, and M. MacUcci. Flicker noise in graphene-based hall sensors. 2017. cited By 0. [ bib | DOI | http ]
[18] S. Battiston, S. Boldrini, M. Fabrizio, D. Narducci, and G. Pennelli. A special section on thermoelectrics. Journal of Nanoscience and Nanotechnology, 17(3):1543--1546, 2017. cited By 0. [ bib | DOI | http ]
[19] G. Pennelli, E. Dimaggio, and M. Macucci. Fabrication techniques for thermoelectric devices based on nanostructured silicon. Journal of Nanoscience and Nanotechnology, 17(3):1627--1633, 2017. cited By 2. [ bib | DOI | http ]
[20] M. Pancrazzi, F. Landini, M. Romoli, M. Totaro, and G. Pennelli. Scout: Small chamber for optical uv tests. volume 10564, 2017. cited By 0. [ bib | DOI | http ]
[21] E. Dimaggio and G. Pennelli. Reliable fabrication of metal contacts on silicon nanowire forests. Nano Letters, 16(7):4348--4354, 2016. cited By 13. [ bib | DOI | http ]
[22] G. Pennelli and M. Macucci. High-power thermoelectric generators based on nanostructured silicon. Semiconductor Science and Technology, 31(5), 2016. cited By 12. [ bib | DOI | http ]
[23] G. Pennelli. Top-down fabrication of silicon nanowire devices for thermoelectric applications: properties and perspectives. European Physical Journal B, 88(5), 2015. cited By 13. [ bib | DOI | http ]
[24] G. Pennelli, A. Nannini, and M. Macucci. Indirect measurement of thermal conductivity in silicon nanowires. Journal of Applied Physics, 115(8), 2014. cited By 19. [ bib | DOI | http ]
[25] G. Pennelli. Review of nanostructured devices for thermoelectric applications. Beilstein Journal of Nanotechnology, 5(1):1268--1284, 2014. cited By 62. [ bib | DOI | http ]
[26] M. Piotto, F. Butti, G. Pennelli, and P. Bruschi. Smart flow sensors based on advanced packaging techniques applied to single chip sensing devices. Lecture Notes in Electrical Engineering, 162 LNEE:57--62, 2014. cited By 1. [ bib | DOI | http ]
[27] G. Pennelli and M. MacUcci. Optimization of the thermoelectric properties of nanostructured silicon. Journal of Applied Physics, 114(21), 2013. cited By 16. [ bib | DOI | http ]
[28] G. Pennelli, M. Totaro, M. Piotto, and P. Bruschi. Seebeck coefficient of nanowires interconnected into large area networks. Nano Letters, 13(6):2592--2597, 2013. cited By 24. [ bib | DOI | http ]
[29] G. Pennelli, M. Totaro, and A. Nannini. Correlation between surface stress and apparent young's modulus of top-down silicon nanowires. ACS Nano, 6(12):10727--10734, 2012. cited By 12. [ bib | DOI | http ]
[30] M. Piotto, M. Dei, F. Butti, G. Pennelli, and P. Bruschi. Smart flow sensor with on-chip cmos interface performing offset and pressure effect compensation. IEEE Sensors Journal, 12(12):3309--3317, 2012. cited By 25. [ bib | DOI | http ]
[31] M. Totaro, P. Bruschi, and G. Pennelli. Top down fabricated silicon nanowire networks for thermoelectric applications. Microelectronic Engineering, 97:157--161, 2012. cited By 16. [ bib | DOI | http ]
[32] G. Pennelli, M. Totaro, and M. Piotto. Selective doping of silicon nanowires by means of electron beam stimulated oxide etching. Nano Letters, 12(2):1096--1101, 2012. cited By 4. [ bib | DOI | http ]
[33] F. Landini, M. Pancrazzi, M. Totaro, G. Pennelli, and M. Romoli. Scout: A small vacuum chamber for nano-wire grid polarizer tests in the ultraviolet band. volume 8335, 2011. cited By 0. [ bib | DOI | http ]
[34] M. Piotto, P. Bruschi, F. Butti, and G. Pennelli. 2d anemometer based on multichannel single chip flow sensor. Lecture Notes in Electrical Engineering, 91 LNEE:279--283, 2011. cited By 0. [ bib | DOI | http ]
[35] M. Fanciulli, A. Vellei, C. Canevali, S. Baldovino, G. Pennelli, and M. Longo. Electrically detected magnetic resonance of donors and interfacial defects in silicon nanowires. Nanoscience and Nanotechnology Letters, 3(4):568--574, 2011. cited By 7. [ bib | DOI | http ]
[36] G. Pennelli, M. Totaro, and P. Bruschi. Surface roughness and electron backscattering in high aspect ratio silicon nanowires. Microelectronic Engineering, 88(8):2368--2371, 2011. cited By 1. [ bib | DOI | http ]
[37] M. Piotto, G. Pennelli, and P. Bruschi. Fabrication and characterization of a directional anemometer based on a single chip mems flow sensor. Microelectronic Engineering, 88(8):2214--2217, 2011. cited By 24. [ bib | DOI | http ]
[38] M. Totaro, G. Pennelli, and M. Piotto. Investigation of silicon nanowire breakdown properties for the realization of one-time programmable memories. Microelectronic Engineering, 88(8):2413--2416, 2011. cited By 1. [ bib | DOI | http ]
[39] G. Pennelli. Stackable devices based on chaotic conduction. pages 251--254, 2010. cited By 0. [ bib | DOI | http ]
[40] S. Lenci, L. Tedeschi, C. Domenici, C. Lande, A. Nannini, G. Pennelli, F. Pieri, and S. Severi. Protein patterning on polycrystalline silicon-germanium via standard uv lithography for biomems applications. Materials Science and Engineering C, 30(8):1221--1226, 2010. cited By 10. [ bib | DOI | http ]
[41] G. Pennelli. Devices based on random conduction with in plane gates: A possibility for three-dimensional integration. Journal of Applied Physics, 107(2), 2010. cited By 2. [ bib | DOI | http ]
[42] G. Pennelli and M. Piotto. Metal nanojunctions on silicon single nanowire devices. pages 295--298, 2009. cited By 1. [ bib | http ]
[43] G. Pennelli. Top down fabrication of long silicon nanowire devices by means of lateral oxidation. Microelectronic Engineering, 86(11):2139--2143, 2009. cited By 46. [ bib | DOI | http ]
[44] M. Piotto, M. Dei, G. Pennelli, and P. Bruschi. A miniaturized 2d solid state anemometer based on thermal flow sensors. volume 1, pages 1463--1466, 2009. cited By 9. [ bib | DOI | http ]
[45] S. Lenci, I. Caponigri, C. Lande, A. Nannini, G. Pennelli, F. Pieri, S. Severi, and L. Tedeschi. Selective organic functionalization of polycrystalline silicon-germanium for biomems applications. volume 1, pages 252--255, 2009. cited By 3. [ bib | DOI | http ]
[46] G. Pennelli and A. Nannini. Nanostructured multimetal granular thin films: How to control chaos. e-Journal of Surface Science and Nanotechnology, 7:503--506, 2009. cited By 2. [ bib | DOI | http ]
[47] G. Pennelli. Fast, high bit number pattern generator for electron and ion beam lithographies. Review of Scientific Instruments, 79(3), 2008. cited By 2. [ bib | DOI | http ]
[48] C. Baratto, S. Todros, E. Comini, G. Faglia, M. Ferroni, G. Sberveglieri, G. Marrazza, G. Andreano, L. Cellai, A. Flamini, A. Nannini, G. Pennelli, and M. Piotto. Sno2 nanowire bio-transistor for electrical dna sensing. pages 1132--1135, 2007. cited By 1. [ bib | DOI | http ]
[49] G. Pennelli and B. Pellegrini. Fabrication of silicon nanostructures by geometry controlled oxidation. Journal of Applied Physics, 101(10), 2007. cited By 22. [ bib | DOI | http ]
[50] G. Faglia, C. Baratto, E. Comini, M. Ferroni, G. Sberveglieri, G. Andreano, L. Cellai, A. Flamini, G. Marrazza, A. Nannini, G. Pennelli, and M. Piotto. Towards bio-nanotransistors for electrical dna sensing. pages 370--373, 2006. cited By 0. [ bib | DOI | http ]
[51] G. Pennelli. Lateral reduction of random percolative networks formed by nanocrystals: Possibilities for a new concept electronic device? Applied Physics Letters, 89(16), 2006. cited By 5. [ bib | DOI | http ]
[52] G. Pennelli and M. Piotto. Fabrication and characterization of silicon nanowires with triangular cross section. Journal of Applied Physics, 100(5), 2006. cited By 32. [ bib | DOI | http ]
[53] A. Molfese, A. Nannini, G. Pennelli, and F. Pieri. Analysis, testing and optimisation of electrostatic comb-drive levitational actuators. Analog Integrated Circuits and Signal Processing, 48(1):33--40, 2006. cited By 8. [ bib | DOI | http ]
[54] G. Pennelli, M. Piotto, and G. Barillaro. Silicon single-electron transistor fabricated by anisotropic etch and oxidation. Microelectronic Engineering, 83(4-9 SPEC. ISS.):1710--1713, 2006. cited By 13. [ bib | DOI | http ]
[55] G. Pennelli and M. Piotto. A fabrication process for a silicon tunnel barrier with self-aligned gate. Microelectronic Engineering, 83(4-9 SPEC. ISS.):1559--1562, 2006. cited By 3. [ bib | DOI | http ]
[56] L. Valentini, I. Armentano, L. Ricco, J. Alongi, G. Pennelli, A. Mariani, S. Russo, and J.M. Kenny. Selective interaction of single-walled carbon nanotubes with conducting dendrimer. Diamond and Related Materials, 15(1):95--99, 2006. cited By 16. [ bib | DOI | http ]
[57] L. Valentini, I. Armentano, F. Mengoni, D. Puglia, G. Pennelli, and J.M. Kenny. Chemical gating and photoconductivity of cf4 plasma-functionalized single-walled carbon nanotubes with adsorbed butylamine. Journal of Applied Physics, 97(11), 2005. cited By 17. [ bib | DOI | http ]
[58] G. Barillaro, F. D'Angelo, G. Pennelli, and F. Pieri. Fabrication of self-aligned gated silicon microtip array using electrochemical silicon etching. Physica Status Solidi (A) Applications and Materials Science, 202(8):1427--1431, 2005. cited By 3. [ bib | DOI | http ]
[59] A.C. Walker, S.J. Fancey, M.P.Y. Desmulliez, M.G. Forbes, J.J. Casswell, G.S. Buller, M.R. Taghizadeh, J.A.B. Dines, C.R. Stanley, G. Pennelli, A.R. Boyd, J.L. Pearson, P. Horan, D. Byrne, J. Hegarty, S. Eitel, H.-P. Gauggel, K.-H. Gulden, A. Gauthier, P. Benabes, J.-L. Gutzwiller, M. Goetz, and J. Oksman. Operation of an optoelectronic crossbar switch containing a terabit-per-second free-space optical interconnect. IEEE Journal of Quantum Electronics, 41(7):1024--1036, 2005. cited By 4. [ bib | DOI | http ]
[60] S. Ciucci, F. D'Angelo, A. Diligenti, B. Pellegrini, G. Pennelli, and M. Piotto. Silicon nanowires fabricated by means of an underetching technique. Microelectronic Engineering, 78-79(1-4):338--342, 2005. cited By 14. [ bib | DOI | http ]
[61] L. Valentini, V. Bavastrello, I. Armentano, F. D'Angelo, G. Pennelli, C. Nicolini, and J.M. Kenny. Synthesis and electrical properties of cds langmuir-blodgett multilayers nanoparticles on self-assembled carbon nanotubes. Chemical Physics Letters, 392(1-3):214--219, 2004. cited By 8. [ bib | DOI | http ]
[62] S. Chowdhury, A.R. Long, E. Skuras, J.H. Davies, K. Lister, G. Pennelli, and C.R. Stanley. Inverse flux quantum periodicity in the amplitudes of commensurability oscillations in two-dimensional lateral surface superlattices. Physical Review B - Condensed Matter and Materials Physics, 69(3), 2004. cited By 8. [ bib | DOI | http ]
[63] G. Barillaro, A. Diligenti, A. Nannini, and G. Pennelli. A thick silicon dioxide fabrication process based on electrochemical trenching of silicon. Sensors and Actuators, A: Physical, 107(3):279--284, 2003. cited By 34. [ bib | DOI | http ]
[64] G. Pennelli, F. D'Angelo, M. Piotto, G. Barillaro, and B. Pellegrini. A low cost high resolution pattern generator for electron-beam lithography. Review of Scientific Instruments, 74(7):3579--3582, 2003. cited By 13. [ bib | DOI | http ]
[65] H.S. Eisenberg, R. Morandotti, Y. Silberberg, J.M. Arnold, G. Pennelli, and J.S. Aitchison. Optical discrete solitons in waveguide arrays. i. soliton formation. Journal of the Optical Society of America B: Optical Physics, 19(12):2938--2944, 2002. cited By 83. [ bib | DOI | http ]
[66] M. Macucci, B. Pellegrini, G. Pennelli, and M. Piotto. Electrical and noise characterization of suspended silicon wires. Microelectronic Engineering, 61-62:701--705, 2002. cited By 8. [ bib | DOI | http ]
[67] E. Skuras, G. Pennelli, A.R. Long, and C.R. Stanley. Molecular-beam epitaxy growth of ingaas-inalas high electron mobility transistors with enhanced electron densities and measurement of inalas surface potential. Journal of Vacuum Science and Technology B: Microelectronics and Nanometer Structures, 19(4):1524--1528, 2001. cited By 2. [ bib | DOI | http ]
[68] S. Chowdhury, E. Skuras, C.J. Emeleus, A.R. Long, J.H. Davies, G. Pennelli, and C.R. Stanley. Switching of guiding center-drift direction in asymmetric two-dimensional lateral surface superlattices. Physical Review B - Condensed Matter and Materials Physics, 63(15), 2001. cited By 6. [ bib | DOI | http ]
[69] A.C. Walker, S.J. Fancey, M.G. Forbes, G.S. Buller, M.R. Taghizadeh, M.P.Y. Desmulliez, J.A.B. Dines, C.R. Stanley, G. Pennelli, A. Boyd, J.L. Pearson, P. Horan, D. Byrne, J. Hegarty, and S. Eitel. Towards terabit/s input to silicon vlsi - a demonstrator experiment. volume 4089, pages 460--464, 2000. cited By 0. [ bib | http ]
[70] S. Chowdhury, C. Emeleus, B. Milton, E. Skuras, A. Long, J. Davies, G. Pennelli, and C. Stanley. Importance of symmetry breaking in two-dimensional lateral-surface superlattices. Physical Review B - Condensed Matter and Materials Physics, 62(8):R4821--R4824, 2000. cited By 19. [ bib | DOI | http ]
[71] G. Pennelli. Conduction of metal-isolator-semiconductor structures with granular silicon thin films. Thin Solid Films, 348(1):157--164, 1999. cited By 4. [ bib | DOI | http ]
[72] A.C. Walker, M.P.Y. Desmulliez, M.G. Forbes, S.J. Fancey, G.S. Buller, M.R. Taghizadeh, J.A.B. Dines, C.R. Stanley, G. Pennelli, A.R. Boyd, P. Horan, D. Byrne, J. Hegarty, S. Eitel, H.-P. Gauggel, K.-H. Gulden, A. Gauthier, P. Benabes, J.-L. Gutzwiller, and M. Goetz. Design and construction of an optoelectronic crossbar switch containing a terabit per second free-space optical interconnect. IEEE Journal on Selected Topics in Quantum Electronics, 5(2):236--249, 1999. cited By 33. [ bib | DOI | http ]
[73] S.J. Fancey, M.G. Forbes, M.R. Taghizadeh, J.A.B. Dines, G.S. Buller, A.C. Walker, M.P.Y. Desmulliez, G. Pennelli, J.H. Marsh, C.R. Stanley, P. Horan, D. Byrne, J. Hegarty, S. Eitel, and K.H. Gulden. Free-space optoelectronic crossbar interconnect with terabit/s communication to silicon electronics. page 50, 1998. cited By 0. [ bib | http ]
[74] C. Ciofi, A. Diligenti, A. Nannini, G. Pennelli, N. Vannucci, F. Fuso, and M. Allegrini. Thin films of granular silicon: Electrical, structural and optical characterization. Solid State Phenomena, 54:109--118, 1997. cited By 4. [ bib | DOI | http ]
[75] A. Iembo, F. Fuso, E. Arimondo, C. Ciofi, G. Pennelli, G.M. Currò, F. Neri, and M. Allegrini. Pulsed laser deposition and characterization of conductive ruo2 thin films. Journal of Materials Research, 12(6):1433--1436, 1997. cited By 27. [ bib | DOI | http ]
[76] A. Diligenti, A. Nannini, G. Pennelli, and F. Pieri. Current transport in free-standing porous silicon. Applied Physics Letters, 68(5):687--689, 1996. cited By 33. [ bib | DOI | http ]
[77] G. Pennelli. Transient voltage behavior of free-standing porous silicon layers. Journal of Applied Physics, 80(9):5116--5120, 1996. cited By 5. [ bib | DOI | http ]
[78] A. Diligenti, A. Nannini, G. Pennelli, F. Pieri, V. Pellegrini, F. Fuso, and M. Allegrini. Current-voltage characteristics of porous-silicon structures. Il Nuovo Cimento D, 18(10):1197--1204, 1996. cited By 0. [ bib | DOI | http ]
[79] A. Diligenti, A. Nannini, G. Pennelli, V. Pellegrini, F. Fuso, and M. Allegrini. Electrical characterization of metal schottky contacts on luminescent porous silicon. Thin Solid Films, 276(1-2):179--182, 1996. cited By 9. [ bib | DOI | http ]
[80] A. Diligenti, A. Nannini, G. Pennelli, F. Pieri, V. Pellegrini, F. Fuso, and M. Allegrini. Current-voltage characteristics of porous-silicon structures. Nuovo Cimento della Societa Italiana di Fisica D - Condensed Matter, Atomic, Molecular and Chemical Physics, Biophysics, 18(10):1197--1204, 1996. cited By 0. [ bib | DOI | http ]
[81] S. Puccini, V. Pellegrini, M. Labardi, F. Fuso, M. Allegrini, A. Diligenti, A. Nannini, and G. Pennelli. Red- and blue-light emission from free-standing porous silicon. Nuovo Cimento della Societa Italiana di Fisica D - Condensed Matter, Atomic, Molecular and Chemical Physics, Biophysics, 18(10):1149--1157, 1996. cited By 3. [ bib | DOI | http ]
[82] M. Allegrini, C. Ciofi, A. Diligenti, F. Fuso, A. Nannini, V. Pellegrini, and G. Pennelli. Photoluminescence from ion-beam cosputtered si/sio2 thin films. Solid State Communications, 100(6):403--406, 1996. cited By 3. [ bib | DOI | http ]
[83] P.E. Bagnoli, C. Ciofi, B. Neri, and G. Pennelli. Electromigration in al based stripes: Low frequency noise measurements and mtf tests. Microelectronics Reliability, 36(7-8 SPEC. ISS.):1045--1050, 1996. cited By 9. [ bib | DOI | http ]
[84] A. Diligenti, A. Nannini, G. Pennelli, and F. Pieri. Current transport in free-standing porous silicon. Applied Physics Letters, page 687, 1995. cited By 3. [ bib | DOI | http ]
[85] V. Pellegrini, F. Fuso, G. Lorenzi, M. Allegrini, A. Diligenti, A. Nannini, and G. Pennelli. Improved optical emission of porous silicon with different postanodization processes. Applied Physics Letters, 67:1084, 1995. cited By 26. [ bib | DOI | http ]

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