Ethyl Isopropyl Sulfone:

Use ethyl-iso-propyl sulfone (EiPS) when experimenting with electrolytes requiring increased performance under extended thermal stress.

EiPS is a high boiling polar solvent with low vapor pressure, is chemically inert and has low viscosity. EiPS is especially suitable where inorganic ionic species need to remains in solution while minimizing the evaporation of the electrolyte solvent which makes it particularly suitable for electrolyte investigations of systems requiring flexibility under extended thermal stress.

Specifications:

FK 102 C0 (II) PF6 Salt:

Use cobalt complexes to increase photovoltages of liquid electrolyte cells significantly or to achieve ultrahigh performance with solid state photovoltaic devices.

FK102 cobalt complexes offer guaranteed performance, high reproducibility, consistent results, and are of highest purity. In comparison to triiodide-based redox electrolytes, cobalt complexes in general increase photovoltages and, particularly at lower light levels, significantly increase device power output.

Specifications:

FK 102 Co (II) TFSI Salt:

Use cobalt complexes to increase photovoltages of liquid electrolyte cells significantly or to achieve ultrahigh performance with solid state photovoltaic devices.

FK102 cobalt complexes offer guaranteed performance, high reproducibility, consistent results, and are of highest purity. In comparison to triiodide-based redox electrolytes, cobalt complexes in general increase photovoltages and, particularly at lower light levels, significantly increase device power output.

Specifications:

FK 102 C0 (III) PF6 Salt:

Use cobalt complexes to increase photovoltages of liquid electrolyte cells significantly or to achieve ultrahigh performance with solid state photovoltaic devices.

FK102 cobalt complexes offer guaranteed performance, high reproducibility, consistent results, and are of highest purity. In comparison to triiodide-based redox electrolytes, cobalt complexes in general increase photovoltages and, particularly at lower light levels, significantly increase device power output.

Specifications:

FK 102 Co (III) TFSI Salt:

Use cobalt complexes to increase photovoltages of liquid electrolyte cells significantly or to achieve ultrahigh performance with solid state photovoltaic devices.

FK102 cobalt complexes offer guaranteed performance, high reproducibility, consistent results, and are of highest purity. In comparison to triiodide-based redox electrolytes, cobalt complexes in general increase photovoltages and, particularly at lower light levels, significantly increase device power output.

Specifications:

FK 209 Co (II) PF6 Salt:

Use cobalt complexes to increase photovoltages of liquid electrolyte cells significantly or to achieve ultrahigh performance with solid state photovoltaic devices.

FK209 cobalt complexes offer guaranteed performance, high reproducibility, consistent results, and are of highest purity.

Specifications:

FK 209 Co (II) TFSI Salt:

Use cobalt complexes to increase photovoltages of liquid electrolyte cells significantly or to achieve ultrahigh performance with solid state photovoltaic devices.

FK209 cobalt complexes offer guaranteed performance, high reproducibility, consistent results, and are of highest purity.

Specifications:

FK 209 Co (III) TFSI Salt:

Use cobalt complexes to increase photovoltages of liquid electrolyte cells significantly or to achieve ultrahigh performance with solid state photovoltaic devices.

FK209 cobalt complexes offer guaranteed performance, high reproducibility, consistent results, and are of highest purity.

Specifications:

FK 269 Co (II) PF6 Salt:

Use cobalt complexes to increase photovoltages of liquid electrolyte cells significantly or to achieve ultrahigh performance with solid state photovoltaic devices.

FK269 cobalt complexes offer guaranteed performance, high reproducibility, consistent results, and are of highest purity. In comparison to triiodide-based redox electrolytes, cobalt complexes in general increase photovoltages and, particularly at lower light levels, significantly increase device power output.

Specifications:

FK 269 Co (II) TFSI Salt:

Use cobalt complexes to increase photovoltages of liquid electrolyte cells significantly or to achieve ultrahigh performance with solid state photovoltaic devices.

FK269 cobalt complexes offer guaranteed performance, high reproducibility, consistent results, and are of highest purity. In comparison to triiodide-based redox electrolytes, cobalt complexes in general increase photovoltages and, particularly at lower light levels, significantly increase device power output.

Specifications:

FK 269 Co (III) PF6 Salt:

Use cobalt complexes to increase photovoltages of liquid electrolyte cells significantly or to achieve ultrahigh performance with solid state photovoltaic devices.

FK269 cobalt complexes offer guaranteed performance, high reproducibility, consistent results, and are of highest purity. In comparison to triiodide-based redox electrolytes, cobalt complexes in general increase photovoltages and, particularly at lower light levels, significantly increase device power output.

Specifications:

EL-HPE High Performance Electrolyte:

Use EL-HPE High Performance Electrolyte with any of Dyesol’s dyes to get optimum voltage and current performance. Particularly suitable for glass, metal/glass substrate based DSC systems.

EL-HPE High Performance Electrolyte is a low viscosity, high ionic conductivity liquid electrolyte and therefore provides highest performance. Due to the low boiling point of the main solvent and the chemistry of the electrolyte mixture, EL-HPE will not provide best long term stability under standard solar conditions and/or under elevated temperature testing.

Specifications:

EL-HSE High Stability Electrolyte:

Use EL-HSE High Stability Electrolyte to achieve ultra-long life in normal operating conditions. Particularly suitable for glass or metal/glass substrate based DSC systems.

EL-HSE High Stability Electrolyte is a low toxicity liquid electrolyte. This is the “work horse” electrolyte system for long term stability testing.

Specifications:

EL-HTE High Temperature Electrolyte:

Use EL-HTE – High Temperature Electrolyte to achieve ultra-long life in DSC systems while minimizing solvent evaporation.

EL-HTE High Temperature Electrolyte is particularly suitable for flexible DSC, where transparent flexible substrates do not offer the same hermetic barrier properties such as glass or metal substrates.

EL-HTE High Temperature Electrolyte has a lower vapor pressure than EL-HSE High Stability Electrolyte but is otherwise chemically very similar.

Specifications:

Ultra High Stability Electrolyte:

Use EL-UHSE – Ultra High Stability Electrolyte to achieve ultra-long life in DSC systems while minimizing solvent evaporation.

EL-UHSE Ultra High Stability Electrolyte is based on a low toxicity liquid electrolyte. EL-UHSE – Ultra High Stability Electrolyte is particularly suitable for flexible DSC, where transparent flexible substrates do not offer the same hermetic barrier properties such as glass or metal substrates. EL-UHSE – Ultra High Stability Electrolyte has a lower vapor pressure than other electrolytes and is particularly suitable for long term stability testing.

Specifications: