Virginia Institute for Photovoltaics

The Virginia Institute of Photovoltaics (VIPV) exemplifies 鶹ý's leadership role in the field of solar energy research and will allow 鶹ý to fulfill a comprehensive mission while serving different stakeholders.

Mission

To increase scientific knowledge of and understanding in the field of Photovoltaics (PV).

About

The scope of the mission extends from the basics of the fundamental science of the materials and devices, through the fabrication processes and balance of systems, all the way to the knowledge and understanding of PV systems and complementary environmental policy and PV business development.

  1. Perform leading-edge Interdisciplinary and multi-institutional research.
  2. Recruit top faculty and exceptional graduate students.
  3. Educate undergraduate and graduate students.
  4. Support regional, national and international programs.
  5. Increase external funding and institutional visibility.

Research is central to the mission of 鶹ý and, as one of its distinguished Institutes, VIPV will fulfill its own mission by developing world-class research in the field of PV. Specifically, VIPV will:

  • Provide essential research and development in the PV field
  • Provide a broad research scope that will extend from the Nano-scale (Fundamental Sciences and Engineering) to the Giga-scale (Full System Installation and Testing)
  • Provide a dynamic research environment with close connections to National laboratories

- Addressing the needs of all stakeholders, notably DoE, NSF, Industry, and the Commonwealth

- Focusing on the unique requirements of DoD

- Facilitating access to funding from all of these entities

  • Partner with Industry, funding agencies, and the University to develop ideas addressing all steps from innovative product development to intellectual property generation.
  • This Research vision is based on the existing strengths of our group which:

- Has received extensive funding from NSF, DoE, DoD, Industries, and the State of Virginia (with more than $3M of funding in the last 3 years).

- Has skills and experience in all PV domains required for a fully integrated vision, starting at the fundamental sciences level and finishing at the installation and product development level.

Education is another central mission of 鶹ý and, as one of its leading Institutes, VIPV will fulfill its own mission by developing world-class education in the field of PV. Specifically, VIPV will:

  • Create a new generation of trained PV specialists by educating students, the general public, and members of the industry about the engineering and science of PV.
  • Educate members of the Department of Defense (DoD) about PV via undergraduate/graduate programs and certificates.
  • Teach topics that include subjects such as Fundamentals of PV, PV device fabrication and Materials Engineering, PV Systems, Power Electronics, and Smart Grids.

Notably, VIPV's education vision includes the development of specific programs for graduate and undergraduate students in PV.

ECE Undergraduate Courses:

ECE: 303, 323, 332, 403, 473, 486

ECE Graduate Courses:

ECE: 503, 558, 573, 623, 772, 773, 774, 795

Also central to 鶹ý's mission is outreach to the community. As one of its preeminent Institutes, VIPV will fulfill its own mission by interacting with the general public, the industry and the legislature to inform them about the research and development in the field of PV.

Specifically, VIPV will:

  • Enable VA to create better PV collaborations with industry, government, and the public
  • Create national recognition for VA
  • Incite more PV businesses to move to VA
  • Provide information to the public for any PV-related questions
  • Be the PV go-to place for DoD

  1. Perform leading-edge Interdisciplinary and multi-institutional research.
  2. Recruit top faculty and exceptional graduate students.
  3. Educate undergraduate and graduate students.
  4. Support regional, national and international programs.
  5. Increase external funding and institutional visibility.

Research is central to the mission of 鶹ý and, as one of its distinguished Institutes, VIPV will fulfill its own mission by developing world-class research in the field of PV. Specifically, VIPV will:

  • Provide essential research and development in the PV field
  • Provide a broad research scope that will extend from the Nano-scale (Fundamental Sciences and Engineering) to the Giga-scale (Full System Installation and Testing)
  • Provide a dynamic research environment with close connections to National laboratories

- Addressing the needs of all stakeholders, notably DoE, NSF, Industry, and the Commonwealth

- Focusing on the unique requirements of DoD

- Facilitating access to funding from all of these entities

  • Partner with Industry, funding agencies, and the University to develop ideas addressing all steps from innovative product development to intellectual property generation.
  • This Research vision is based on the existing strengths of our group which:

- Has received extensive funding from NSF, DoE, DoD, Industries, and the State of Virginia (with more than $3M of funding in the last 3 years).

- Has skills and experience in all PV domains required for a fully integrated vision, starting at the fundamental sciences level and finishing at the installation and product development level.

Education is another central mission of 鶹ý and, as one of its leading Institutes, VIPV will fulfill its own mission by developing world-class education in the field of PV. Specifically, VIPV will:

  • Create a new generation of trained PV specialists by educating students, the general public, and members of the industry about the engineering and science of PV.
  • Educate members of the Department of Defense (DoD) about PV via undergraduate/graduate programs and certificates.
  • Teach topics that include subjects such as Fundamentals of PV, PV device fabrication and Materials Engineering, PV Systems, Power Electronics, and Smart Grids.

Notably, VIPV's education vision includes the development of specific programs for graduate and undergraduate students in PV.

ECE Undergraduate Courses:

ECE: 303, 323, 332, 403, 473, 486

ECE Graduate Courses:

ECE: 503, 558, 573, 623, 772, 773, 774, 795

Also central to 鶹ý's mission is outreach to the community. As one of its preeminent Institutes, VIPV will fulfill its own mission by interacting with the general public, the industry and the legislature to inform them about the research and development in the field of PV.

Specifically, VIPV will:

  • Enable VA to create better PV collaborations with industry, government, and the public
  • Create national recognition for VA
  • Incite more PV businesses to move to VA
  • Provide information to the public for any PV-related questions
  • Be the PV go-to place for DoD

Faculty

Associate Professor Mechanical & Aerospace Engineering
Professor Mechanical & Aerospace Engineering
Associate Professor Chemistry & Biochemistry
Professor Electrical & Computer Engineering

Professor Electrical & Computer Engineering
Professor Electrical & Computer Engineering
Professor Electrical & Computer Engineering

Professor & Chair Engineering Technology
Associate Professor Engineering Technology
Master Lecturer Engineering Technology

Professor & Interim Dean Department of Information Technology & Decision Sciences
Associate Dean for Faculty Affairs and Research Darden College of Education & Professional Studies

2019

  • Ava et al., T. (2019). A Review: Thermal Stability of Methylammonium Lead Halide Based Perovskite Solar Cells. Applied Sciences, 9(1).
  • Karki et al., S. (2019). Analysis of Recombination Mechanisms in RbF-Treated CIGS Solar Cells. IEEE Journal of Photovoltaics, 9 (1), pp. 313-318.
  • Karki et al., S. (2019). Degradation Mechanism in Cu(In,Ga)Se2 Material and Solar Cells Due to Moisture and Heat Treatment of the Absorber Layer. IEEE Journal of Photovoltaics, 9(4).
  • Rajan et al., G. (2019). Impact of post-deposition recrystallization by alkali fluorides on Cu (In, Ga) se2thin-film materials and solar cells. Thin Solid Films, 690.
  • Belfore et al., B. (2019). Modeling Diffusion of Impurities in Molybdenum Thin Films as a Function of Substrate Temperature. IEEE Journal of Photovoltaics, 9 (1), pp. 339-343.

2018

  • Deitz, J. I., Karki, S., Marsillac, S., Grassman, T. J., and McComb, D. W. (2018). Bandgap profiling in CIGS solar cells via valence electron energy-loss spectroscopy. Journal of Applied Physics, 123 (11), pp. 1-6.
  • Rajan et al., G. (2018). Characterization and Analysis of Ultrathin CIGS Films and Solar Cells Deposited by 3-Stage Process. Journal of Spectroscopy
  • Deitz, J. (2018). Characterization of Sub-Bandgap Energy States in CuInxGa(i-x)Se2 and Transparent Conducting Oxides with Electron Energy-Loss Spectroscopy. Microscopy and Microanalysis, 24 (S1), pp. 2.
  • Ibdah et al., A. Optical simulation of external quantum efficiency spectra of CuIn1-xGaxSe2 solar cells from spectroscopic ellipsometry inputs. Journal of energy chemistry, 27 (4), pp. 1151-1169.
  • Pradhan, P., Aryal, P., Attygalle, D., Ibdah, A., Koirala, P., Li, J., Bhandari, K. P., Liyanage, G. K., Ellingson, R. J., Heben, M. J., Marsillac, S., Collins, R. W., and Podraza, N. J. (2018). Real Time Spectroscopic Ellipsometry Analysis of First Stage CuIn1-xGaxSe2 Growth: Indium-Gallium Selenide Co-Evaporation. Materials, 11 (1).

2017

  • Adhikari, D., Junda, M. M., Marsillac, S., Collins, R. W., and Podraza, N. J. (2017). Nanostructure evolution of magnetron sputtered hydrogenated silicon thin films. Journal of Applied Physics, 122 (7), pp. 075302.
  • Ibdah, A., Koirala, P., Aryal, P., Pradhan, P., Marsillac, S., Rockett, A. A., Podraza, N. J., and Collins, R. W. (2017). Spectroscopic ellipsometry for analysis of polycrystalline thin-film photovoltaic devices and prediction of external quantum efficiency. Applied Surface Science, 421, pp. 601 - 607.
  • Ibdah, A. R., Koirala, P., Aryal, P., Pradhan, P., Heben, M. J., Podraza, N. J., Marsillac, S., and Collins, R. W. (2017). Optical simulation of external quantum efficiency spectra of cuin1- xgaxse2 solar cells from spectroscopic ellipsometry inputs. Journal of Energy Chemistry

2016

  • Bailey, C. G., McNatt, J., Babcock, S., Lichty, M., Rajan, G., Ashrafee, T., Marsillac, S., Maximenko, S., Walters, R. J., McClure, E., Smith, B. L., and Hubbard, S. M. (2016). Thin-film vapor-liquid-solid growth of InP for III-V photovoltaics. SPIE Photonic West Conference

2015

  • Huang, Z., Dalal, L. R., Junda, M. M., Aryal, P., Marsillac, S., Collins, R. W., and Podraza, N. J. (2015). Characterization of Structure and Growth Evolution for nc-Si:H in the Tandem Photovoltaic Device Configuration. IEEE Journal of Photovoltaics, 5 (6), pp. 1516-1522.
  • Erkaya, Y., Moses, P., Flory Iv, I. L., and Marsillac, S. (2015). Development of a Solar Photovoltaic Module Emulator. 42nd IEEE Photovoltaic Specialists Conference
  • Paul, P. K., Cardwell, D. W., Jackson, C. M., Galiano, K., Aryal, K., Pelz, J. P., Marsillac, S., Ringel, S. A., Grassman, T. J., and Arehart, A. R. (2015). Direct nm-scale spatial mapping of traps in CIGS. IEEE Journal of Photovoltaics, 5 (5), pp. 1482-1486.
  • Pradhan, P., Aryal, P., Ibdah, A., Koirala, P., Li, J., Podraza, N. J., Rockett, A., Marsillac, S., and Collins, R. W. (2015). Effect of Molybdenum Deposition Temperature on the Performance of CuIn1-xGaxSe2 Based Solar Cells. 42nd IEEE Photovoltaic Specialists Conference
  • Ashrafee, T., Aryal, K., Rajan, G., Karki, S., Ranjan, V., Rockett, A., Collins, R. W., and Marsillac, S. (2015). Effect of Substrate Temperature on Sputtered Molybdenum Film as a Back Contact for Cu(In,Ga)Se2 Solar Cells. 42nd IEEE Photovoltaic Specialists Conference
  • Rajan, G., Aryal, K., Ashrafee, T., Karki, S., Ibdah, A., Ranjan, V., Collins, R. W., and Marsillac, S. (2015). Optimization of Antireflective coatings for CIGS solar cells via Real Time Spectroscopic Ellipsometry. 42nd IEEE Photovoltaic Specialists Conference
  • Weiru, C., Wei, C., Talaat, H., Marsillac, S., and Elsayed-Ali, H. (2015). Properties of Cu(In,Ga,Al)Se2 thin films fabricated by pulsed laser deposition. Journal of Materials Science - Materials in Electronic, 26 (3), pp. 1743-1747.

2014

  • Erkaya, Y., Illa, H., Conway, C., Dhali, S. K., and Marsillac, S. (2014). Development of a String Level Fault Detection System for Solar Tracking Applications. 40th IEEE Photovoltaic Specialists Conference
  • Erkaya, Y., Flory Iv, I. L., and Marsillac, S. (2014). Development of a String Level I-V Curve Tracer. 40th IEEE Photovoltaic Specialists Conference
  • Koirala, P., Huang, Z., Tan, X., Junda, M., Podraza, N. J., Marsillac, E., Rockett, A., and Collins, R. W. (2014). Doped a-Si1-xCx:H:B as Contact Materials for Improved Performance CdTe Solar Cells. 40th IEEE Photovoltaic Specialists Conference
  • Aryal, K., Rajan, G., Ashrafee, T., Ranjan, V., Rockett, A., Collins, R. W., and Marsillac, S. (2014). Effect of selenium evaporation rate on ultrathin Cu(In,Ga)Se2 films. 40th IEEE Photovoltaic Specialists Conference
  • Ashrafee, T., Erkaya, Y., Aryal, K., Rajan, G., Rockett, A., Collins, R. W., and Marsillac, S. (2014). Growth Studies and Characterization of Atomic Layer Deposited (Zn,Mg)S Thin Films for Solar cell Applications. 40th IEEE Photovoltaic Specialists Conference
  • Rockett, A., Erickson, T., Wang, Z., Aryal, K., Marsillac, S., Koirala, P., and Collins, R. W. (2014). Nitrogen Doped Chalcopyrites as Contacts to CdTe Photovoltaics. 40th IEEE Photovoltaic Specialists Conference
  • Ranjan, V., Begou, T., Little, S., Collins, R. W., and Marsillac, S. (2014). Non-destructive optical analysis of band gap profile, crystalline phase, and grain size for Cu(In,Ga)Se2 solar cells deposited by 1-, 2-, and 3-stage co-evaporation. Progress in Photovoltaics: Research and Applications, 22 (1), pp. 77-82.
  • Aryal, K., Rajan, G., Ashrafee, T., Ranjan, V., Aryal, P., Rockett, A., Collins, R., and Marsillac, S. (2014). Real time Spectroscopic Ellipsometry Studies of ultrathin CIGS films deposited by 1-stage, 2-stage and 3-stage co-evaporation process. 40th IEEE Photovoltaic Specialists Conference
  • Aryal, P., Pradhan, P., Attygalle, D., Ibdah, A., Aryal, K., Ranjan, V., Marsillac, S., Podraza, N. J., and Collins, R. W. (2014). Real-Time, In-Line, and Mapping Spectroscopic Ellipsometry for Applications in Cu(In1-xGax)Se2 Metrology. IEEE Journal of Photovoltaics, 4 (1), pp. 333-339.
  • Herndon, C., Erkaya, Y., Xin, C., Dhali, S. K., and Marsillac, S. (2014). Smart Combiner for Fixed Commercial Photovoltaic Systems Using Power Line Communication. 40th IEEE Photovoltaic Specialists Conference
  • Koirala, P., Attygalle, D., Aryal, P., Pradhan, P., Chen, J., Marsillac, S., Ferlauto, A. S., Podraza, N. J., and Collins, R. W. (2014). Real time spectroscopic ellipsometry for analysis and control of thin film polycrystalline semiconductor deposition in photovoltaics. Thin Solid Films, 571 (3), pp. 442-446.

2013

  • Aryal, K., Erkaya, Y., Rajan, G., Ashrafee, T., Rockett, A., Collins, R. W., and Marsillac, S. (2013). Comparative study of ZnS thin films deposited by CBD and ALD as a buffer layer for CIGS solar cell. 39th IEEE Photovoltaic Specialists Conference
  • Dahal, L. R., Huang, Z., Attygalle, D., Salupo, C., Marsillac, S., Podraza, N. J., and Collins, R. W. (2013). Correlations between mapping spectroscopic ellipsometry results and solar cell performance for evaluations of nonuniformity in thin-film silicon photovoltaics. IEEE J. Photovolt., 3 (1), pp. 387-393.
  • Aryal, P., Attygalle, D., Pradhan, P., Podraza, N. J., Marsillac, S., and Collins, R. W. (2013). Large-area compositional mapping of Cu(In1-xGax)Se2 materials and devices with spectroscopic ellipsometry. IEEE J. Photovolt., 3 (1), pp. 359-363.
  • Rajan, G., Ibdah, A. A., Aryal, K., Collins, R. W., and Marsillac, S. (2013). Multi layered anti-reflective coatings for ultra-thin CIGS solar cells. 39th IEEE Photovoltaic Specialists Conference
  • Koirala, P., Chen, P., Tan, X., Podraza, N. J., Marsillac, S., Rockett, A. A., and Collins, R. W. (2013). Multichannel Spectroscopic Ellipsometry for CdTe Photovoltaics: From Real-Time Monitoring to Large-Scale Mapping. 39th IEEE Photovoltaic Specialists Conference
  • Rockett, A., Erickson, T., Wang, Z., Aryal, K., Marsillac, S., and Collins, R. W. (2013). Nitrogen Doped Chalcopyrites as Contacts to CdTe Photovoltaics. 39th IEEE Photovoltaic Specialists Conference
  • Attygalle, D., Ranjan, V., Aryal, P., Pradhan, P., Marsillac, S., Podraza, N. J., and Collins, R. W. (2013). Optical Monitoring and Control of Three-Stage Coevaporated Cu(In1-xGax)Se2 by Real-Time Spectroscopic Ellipsometry. IEEE J. Photovolt., 3 (1), pp. 375-80.

2012

  • S. A. Little, T. Begou, R. W. Collins, and S. Marsillac "Optical detection of melting point depression for silver nanoparticles via in situ real time spectroscopic ellipsometry" Applied Physics Letters 100 (2012) 051107
  • V. Ranjan, R.W. Collins, and S. Marsillac "Real time analysis of the evolution of the microstructure and optical properties of Cu(In,Ga)Se2 thin films as a function of Cu content" Physica Status Solidi RRL 6, No. 1 (2012) 10-12.
  • S. Marsillac, H. Khatri, K. Aryal, R.W. Collins "Properties of Cu(In,Ga)Se2 Thin Films and Solar Cells deposited by Hybrid Process" International Journal of Photoenergy vol. 2012 (2012) 385185.
  • K. Aryal, H. Khatri, R.W. Collins and S. Marsillac "In-situ and ex-situ studies of molybdenum thin films deposited by rf and dc magnetron sputtering as a back contact for CIGS solar cells" International Journal of Photoenergy vol. 2012 (2012) 723714.
  • Khatri, H., and Marsillac, S. (2012). In-situ and ex-situ studies of molybdenum thin films deposited by rf and dc magnetron sputtering. 35th IEEE Photovoltaic Specialists Conference Honolulu, USA, June 20-25 2010
  • Little, S., Ranjan, V., Begou, T., Collins, R. W., and Marsillac, S. (2012). In situ real time spectroscopic ellipsometry analysis of Ag nanoparticle layers for back contact reflector applications. 38th IEEE Photovoltaic Specialists Conference Austin, USA, June 3-8 2012
  • Little, S., Ranjan, V., Collins, R. W., and Marsillac, S. (2012). Growth analysis of (Ag,Cu)InSe2 thin films via real time spectroscopic ellipsometry. Applied Physics Letters
  • Khatri, H., Aryal, K., Collins, R. W., and Marsillac, S. (2012). Electronic and structural properties of copper selenide (Cu2-xSe) thin films as determined by in-situ real-time and ex-situ characterization. 38th IEEE Photovoltaic Specialists Conference Austin, USA, June 3-8 2012
  • Dahal, L. R., Huang, Z., Attygalle, D., Salupo, C., Marsillac, S., Podraza, N. J., and Collins, R. W. (2012). Correlations between Mapping Spectroscopic Ellipsometry Results and Solar Cell Performance for Evaluations of Non-Uniformity in Thin Film Silicon Photovoltaics. 38th IEEE Photovoltaic Specialists Conference Austin, USA, June 3-8 2012
  • Erkaya, Y., Hegde, N., Aryal, K., Rajan, G., Boland, P., Ranjan, V., Baumgart, H., Collins, R. W., and Marsillac, S. (2012). Characterization of ZnS films deposited by ALD for CIGS solar cells. 38th IEEE Photovoltaic Specialists Conference Austin, USA, June 3-8 2012
  • Aryal, K., Rajan, G., Erkaya, Y., Hegde, N., Boland, P., Ranjan, V., Collins, R. W., and Marsillac, S. (2012). Characterization of TCO deposition for CIGS solar cells. 38th IEEE Photovoltaic Specialists Conference Austin, USA, June 3-8 2012
  • Little, S., Ranjan, V., Collins, R. W., and Marsillac, S. (2012). Analysis of (Ag,Cu)(In,Ga)Se2 solar cells deposited by a hybrid process. 38th IEEE Photovoltaic Specialists Conference Austin, USA, June 3-8 2012

2011

  • S. Marsillac, S.A. Little, R.W. Collins "A broadband analysis of the optical properties of silver nanoparticle films by in situ real time spectroscopic ellipsometry" Thin Solid Films 519 (2011) 2936-2940.
  • S. Marsillac, M. N. Sestak, Jian Li, and R. W. Collins "Spectroscopic ellipsometry for solar cells" In "Handbook of advanced characterization techniques for solar cells". Eds Uwe Rau, Daniel Abou-Ras, Thomas Kirchartz. Wiley, (2011) 125-150.
  • T. Begou. J. Walker, D. Attygalle, V. Ranjan, R.W. Collins, S. Marsillac "Real time spectroscopic ellipsometry of CuInSe2: Growth dynamics, dielectric function, and its dependence on temperature" Physica Status Solidi - Rapid Research Letters 5 (2011) 217-219.
  • R.W. Collins, J. Li, M. Sestack, S. Marsillac "Polarized Light Metrology for Thin Film Photovoltaics:Research and Development Scale Processes" Photovoltaic International 12 (2011) 94-103.
  • R.W. Collins, L.R. Dahal, N. Podraza, K. Kormanyos, S. Marsillac "Polarized light metrology for thin-film photovoltaics: manufacturing-scale processes" Photovoltaic International 13 (2011) 134-148 .
  • D. Abou-Ras, R. Caballero, C.-H. Fischer, C.A. Kaufmann, I. Lauermann, R. Mainz, H. Mönig, A. Schöpke, C. Stephan, C. Streeck, S. Schorr, A. Eicke, M. Döbeli, B. Gade, J. Hinrichs, T. Nunney, H. Dijkstra, V. Hoffmann, D. Klemm, V. Efimova, A. Bergmaier, G. Dollinger, T. Wirth, W. Unger, A.A. Rockett, A. Perez-Rodriguez, J. Alvarez-Garcia, V. Izquierdo-Roca, T. Schmid, P.-P. Choi, M. Müller, F. Bertram, J. Christen, H. Khatri, R.W. Collins, S. Marsillac and I. Kötschau "Comprehensive Comparison of Various Techniques for the Analysis of Elemental Distributions in Thin Films" Microscopy and Microanalysis 17(05) (2011) 728-751.
  • S. Marsillac, N. Mangale, V. Gade, S.V. Khare "Structural and electronic properties of beta-In(2)X(3) (X = O, S, Se, Te) using ab initio Calculations" Thin Solid Films 519 (2011) 5679-5683.
  • S.A. Little, R.W. Collins, S. Marsillac "Analysis of interband, intraband, and plasmon polariton transitions in silver nanoparticle films via in situ real-time spectroscopic ellipsometry" Applied Physics Letters 98 (2011) 101910.
  • A. Desireddy, C. Joshi, M. Sestak, S. Little, S. Kumar, S. Marsillac, R.W. Collins, T.P. Bigioni "Wafer-Scale Self Assembled plasmonic thin films" Thin Solid Films, 519 (2011) 6077-6084.
  • L. Dahal, D. Sainju, N.J. Podraza, S. Marsillac, R.W. Collins "Real time spectroscopic ellipsometry of Ag/ZnO and Al/ZnO interfaces for back-reflectors in thin film Si:H photovoltaics" Thin Solid Films 519 (2011) 2682-2687.

2010

  • Y.C. Kang, R. Khanal, J.Y. Park, R.D. Ramsier, H. Khatri, S. Marsillac "XPS Investigation of Oxidation States in Molybdenum Thin Films for CIGS Applications" Journal of Vacuum Science and Technology, B 28 (2010) 545-548.
  • K.P. Acharya, H. Khatri, N.N. Hewa-Kasakarage, S. Marsillac, B. Ulrich, P. Anzenbacher, M. Zamkov "Pulsed-laser deposition of graphite counter electrodes for dye-sensitized solar cells" Applied Physics Letters 97 (2010) 201108.

2009

  • J.D. Walker, H. Khatri, V. Ranjan, Jian Li, R.W. Collins, S. Marsillac "Electronic and structural properties of molybdenum thin films as determined by real-time spectroscopic ellipsometry" Applied Physics Letters, 94 (2009) 141908.

2008

  • S. Marsillac, N. Barreau, H. Khatri, J. Li, D. Sainju, A. Parikh, N.J. Podraza, R.W. Collins "Spectroscopic ellipsometry studies of top window and back contacts in chalcopyrite photovoltaics technology" Physica status solidi (c), 5 (2008) 1244-1248.
  • H. Khatri, S. Marsillac "Effect of deposition parameters on r.f. sputtered molybdenum thin films" Journal of Physics: Condensed Matter, 20 (2008) 055206-055210.
  • S.K.R. Patil, N.S. Mangale, S.V. Khare, S. Marsillac "Super hard cubic phases of period VI transition metal nitrides: First principles investigation" Thin Solid Films, 517 (2008) 824-827.

2007

  • S. Marsillac, V.Y. Parikh, A.D. Compaan "Ultrathin CdTe solar cell" Solar Energy Materials and Solar Cells, 91 (2007) 1398-1402.

2005

  • R. Robles, N. Barreau, A. Vega, S. Marsillac, J.C. Bernede, A. Mokrani "Optical properties of large band gap β-In2S3-3xO3x compounds obtained by physical vapour deposition" Optical Materials 27 (2005) 647-653.
  • E. Halgand, J.C. Bernede, S. Marsillac, J. Kessler "Physico-chemical characterization of Cu(In,Al)Se2 thin films for solar cells obtained by selenization" Thin Solid Films 480 (2005) 443-446.

2004

  • S. Marsillac, S. Dorn, R. Rocheleau, E. Miller "Low-temperature deposition of Cu(InGa)Se2 solar cells on various substrates" Solar Energy Materials and Solar Cells 82 (2004) 45-52.

2003

  • H. Maliki, J. C. Bernède, S. Marsillac, J. Pinel, X. Castel, J. Pouzet "Study of the influence of annealing on the properties of CBD-CdS thin films" Applied Surface Science 205 (2003) 65-79.
  • N. Barreau, J. C. Bernède, S. Marsillac, C. Amory, W. N. Shafarman "New Cd-free buffer layer deposited by PVD: In2S3 containing Na compounds" Thin Solid Films 432 (2003) 326-329.
  • C. Amory, J.C. Bernede, S. Marsillac "Study of a growth instability of In2Se3" Journal of Applied Physics 94 (2003) 6945-6948
  • N. Barreau, S. Marsillac, J.C. Bernede, L. Assmann "Evolution of the band structure of beta -In2S3-3xO3x buffer layer with its oxygen content" Journal of Applied Physics, 93 (2003) 5456-5460.
  • C. Amory, J. C. Bernède, E. Halgand, S. Marsillac "Cu(In,Ga)Se2 films obtained from -In2Se3 thin film" Thin Solid Films 431 (2003) 22-25.
  • L. Barkat, M. Morsli, C. Amory, S. Marsillac, A. Khelil, J. C. Bernède, C. Moctar "Study on the fabrication of n-type CuAlSe2 thin films" Thin Solid Films 431 (2003) 99-104.
  • S. Marsillac, M.C. Zouaghi, J.C. Bernède, T. Ben Nasrallah, S. Belgacem "Evolution of the properties of spray-deposited CuInS2 thin films with post-annealing treatment" Solar Energy Materials and Solar Cells 76 (2003) 125-134.

2002

  • N. Barreau, V. Jousseaume, S. Marsillac, J.C. Bernède, L. Assman "Morphological study by XPS and AFM of wide band gap -In2S3 thin films synthesized by a dry physical process" Journal of Materials Science: Materials in Electronics 13 (2002) 95-100.
  • P.D. Paulson, M.W. Hambodi, S. Marsillac, W.N. Shafarman, RW. Birkmire "CuInAlSe2 Thin Films and Solar Cells" Journal of Applied Physics 91 (2002) 10153-10156.
  • J.C. Bernède, N. Barreau, S. Marsillac, L. Assman "Band alignment at -In2S3/TCO interface" Applied Surface Science 9154 (2002) 1-7.
  • N. Barreau, J. C. Bernède, C. Deudon, L. Brohan, S. Marsillac "Study of the new -In2S3 containing Na thin films Part I: Synthesis and structural characterization of the material" Journal of Crystal Growth 241 (2002) 4-14.
  • N. Barreau, J. C. Bernède, S. Marsillac "Study of the new -In2S3 containing Na thin films. Part II: Optical and electrical characterization of thin films" Journal of Crystal Growth 241 (2002) 51-56.
  • F. Brovelli, J.C. Bernède, S. Marsillac, F.R. Diaz, M.A. DelValle, C. Beaudoin, "Study of the (I-V) characteristics of Organic Light-Emitting Diodes based on Thiophene Vynilic Derivatives" Journal of Applied Polymer Science 86 (2002) 1128-1137.
  • S. Marsillac, P. D. Paulson, M. W. Haimbodi, R. W. Birkmire, W. N. Shafarman "High-efficiency solar cells based on Cu(InAl)Se2 thin films" Applied Physics Letters 81 (2002) 1350-1352.
  • N. Barreau, J. C. Bernède, S. Marsillac, A. Mokrani "Study of low temperature elaborated tailored optical band gap -In2S3-3xO3x thin films" Journal of Crystal Growth 235 (2002) 439-449.
  • N. Barreau, J. C. Bernède, H. Maliki, S. Marsillac, X. Castel, J. Pinel "Recent studies on In2S3 containing oxygen thin films" Solid State Communications 122 (2002) 445-450.
  • N. Barreau, S. Marsillac, D. Albertini, J.C. Bernède, "Structural, optical and electrical properties of -In2S3-3xO3x thin films obtained by PVD" Thin Solid Films 403 (2002) 331-334.

2001

  • K. D'Almeida, J.C. Bernede, S. Marsillac, A. Godoy, F.R. Diaz "Carbazole based electroluminescent devices obtained by vacuum evaporation" Synthetic Metals 122 (2001) 127-129
  • M.C. Zouaghi, T. Ben Nasrallah, S. Marsillac, J.C. Bernède and S. Belgacem, "Physico-chemical characterization of spray-deposited CuInS2 thin films" Thin Solid Films 382 (2001) 39-46.
  • H. Maliki, S. Marsillac, J.C. Bernède, E. Faulques, J. Wery, "Influence of the substitution of Se by Te on the photoconductivity properties of In2Se3 xTe3x thin films" Journal of Physics: Condensed Matter 13 (2001) 1839-1850.
  • S. Marsillac, T.B. Wahiba, C. Moctar, J.C. Bernède, A. Khellil "Evolution of the properties of CuAlSe2 thin films with the oxygen content" Solar Energy Materials and Solar Cells 71(2001) 425-434.

2000

  • C. Moctar, K. Kambas, S. Marsillac, A. Anagnostopoulos, J.C. Bernède, K. Benchouk. "Optical properties of CuAlX2 (X = Se, Te) thin films obtained by annealing of copper, aluminium and chalcogen layers sequentially deposited" Thin Solid Films 371 (2000) 195-200.
  • S. Ouro Djobo, J.C. Bernède, S. Marsillac, "Poly(N-vinylcarbazole) (PVK) deposited by evaporation for light emitting diodes thin films structures" Synthetic Metals 122 (2000) 131-133.
  • N. Barreau, S. Marsillac, J.C. Bernède, A. Barreau, "Investigation of -In2S3 growth on different transparent conductive oxides" Applied Surface Science 161 (2000) 20-26.
  • N. Barreau, S. Marsillac, J.C. Bernède, T. Ben Nasrallah and S. Belgacem, "Optical properties of wide band gap indium sulphide thin films obtained by physical vapor deposition" Physica Status Solidi (a) 184 (2000) 179-186.
  • K. Benchouk , E. Benseddik, C. El Moctar, JC Bernede, S. Marsillac, J Pouzet, A Khellil "New buffer layers, large band gap ternary compounds: CuAlTe2" European Physical Journal- Applied Physics 1 (2000) 9-14.
  • E. Gourmelon, J.C. Bernède, J. Pouzet and S. Marsillac. "Textured MoS2 thin films obtained on tungsten. Electrical properties of the W/MoS2 contact" Journal of Applied Physics 87 (2000) 1182-1186.
  • J.C. Bernède, S. Marsillac, C. Moctar, K. Benchouk, A. Khellil. "On the influence of oxygen contamination on the properties of CuAlX2 (X=Se, Te)" Journal of Materials Science 36 (2000) 87-92.