RESOURCE FACILITY

PROPOSING STATE-OF-THE-ART EQUIPMENT

IPVF owns and operates infrastructure comprising over 70 different types of equipment at the cutting edge of technology.
This equipment offers the opportunity, amongst others to:

  • Create materials with photovoltaic properties. An extensive range of physical and/or chemical pathways are available including deposition, growth, spraying, evaporation and chemical synthesis techniques.
  • Assemble these materials in photovoltaic cells. This consists in modifying the properties of the materials based on needs, and in adding functional layers to them (anti-reflection, protection barriers, light-trapping, electrical charge collection, etc.)
  • Characterize these materials and cells. This means running them through a battery of tests (optical, electrical, chemical, morphological, etc.) to assess their characteristics and to better understand the physical phenomena involved, at a scale ranging from cm (10-2 m) to nm (10-9 m), in an effort to ensure continuous improvement.

This experimental equipment is complemented by substantial and varied modelling resources. Modelling is used for simulating the behavioural patterns of the materials and cells from atomic level (ab-initio) through to macroscopic level.

The creation/characterization/modelling trio accelerate the development of high-performing photovoltaic systems.

PROPOSING STATE-OF-THE-ART EQUIPMENT

IPVF owns and operates infrastructure comprising over 70 different types of equipment at the cutting edge of technology.
This equipment offers the opportunity, amongst others to:

  • Create materials with photovoltaic properties. An extensive range of physical and/or chemical pathways are available including deposition, growth, spraying, evaporation and chemical synthesis techniques.
  • Assemble these materials in photovoltaic cells. This consists in modifying the properties of the materials based on needs, and in adding functional layers to them (anti-reflection, protection barriers, light-trapping, electrical charge collection, etc.)
  • Characterize these materials and cells. This means running them through a battery of tests (optical, electrical, chemical, morphological, etc.) to assess their characteristics and to better understand the physical phenomena involved, at a scale ranging from cm (10-2 m) to nm (10-9 m), in an effort to ensure continuous improvement.

This experimental equipment is complemented by substantial and varied modelling resources. Modelling is used for simulating the behavioural patterns of the materials and cells from atomic level (ab-initio) through to macroscopic level.

The creation/characterization/modelling trio accelerate the development of high-performing photovoltaic systems.

EXAMPLE OF A CREATION PROCESS

EXAMPLE OF A CREATION PROCESS

PVD

  • MBE (molecular beam epitaxy) (III-V and Ge)
  • Co-evaporation (CIGS)
  • Cathode pulverization of oxides and metals

CVD

  • Atomic Layer Deposition
  • Plasma-Enhanced CVD
  • Low-temperature epitaxy of crystalline silicon

THERMAL TREATMENTS, CLEANING AND IMAGING

  • Boron and phosphorus diffusion
  • Annealing
  • Miscellaneous chemical dips
  • Versatile laser platform
EXAMPLE OF A CHARACTERIZATION PROCESS
EXAMPLE OF A CHARACTERIZATION PROCESS

ELECTRO-OPTICS

  • Near-field scanning optical microscopy: AFM, KPFM, STM
  • Luminescence platforms: TRPL, EL, TRFLIM, in-situ PL
  • Solar simulators, EQE, weathering benches

CHEMICAL AND STRUCTURAL

  • XPS (X-Ray Photoelectron Spectroscopy) and GD-OES (Glow Discharge – Optical Emission Spectro) coupling
  • Raman spectroscopy X-ray diffraction

IPVF PARTNERS

L’INSTITUT PHOTOVOLTAÏQUE D’ÎLE-DE-FRANCE (IPVF)

18, Boulevard Thomas Gobert
91120 Palaiseau
FRANCE