Cuts 30 k€ in operation costs
and 20 ton carbon emissions per year

Learn how GO-START helps our customers save operational costs while decreasing the use of Lead-based batteries.
What can GO-START do for you?
GO-START is the only supercapacitor module on the market capable of being installed in the battery compartment of a truck, without requiring new cabling or modifications to the vehicle.
Introducing GO-START Supercapacitor Module
A
We have developed a supercapacitor technology based on proprietary electrodes combined with an aqueous electrolyte for a low-environmental impact device.
From early on, we have avoided the use of toxic or flammable solvents in the slurry process, and our carbon materials are entirely derived from renewable sources.
Our modular technology allows for an array of specifications suitable for your application.
Serving the industry,
with a R&D mind set
LEARN MORE
We have developed an easy-to-install supercapacitor module for the automotive industry

EASY INSTALLATION

Plug and play solution
GO-START module can cut up to
30 k€ in operational costs per vehicle during its lifetime.

LOW OPERATIONAL COSTS

Up to 30 k€ cost reduction
Our cells have no Lead nor
flammable electrolyte inside.
No electronics are needed for
the cell balancing in the module.

SAFE

Aqueous electrolyte
GO-START replaces lead-acid
batteries to provide the power
peak to start the engine, even
at sub-zero temperatures.

NO DEAD STARTS

High power
A
Label

Go-Start replaces lead-acid
batteries to provide the power
peak to start the engine, even
at sub-zero temperatures.


NO DEAD STARTS

High Power

Our cells have no Lead nor
flammable electrolyte inside.
No electronics are needed for
the cell balancing in the module.


SAFE

Aqueous electrolyte

GO-START module can cut up to 30k € in operational costs per vehicle during its lifetime.


LOW OPERATIONAL COSTS

Up to 30k€ cost reduction

We have developed an easy-to-install supercapacitor module for the automotive industry


EASY INSTALLATION

Plug and Play solution
We have developed a supercapacitor technology based on proprietary electrodes combined with an aqueous electrolyte for a low-environmental impact device.
From early on, we have avoided the use of toxic or flammable solvents in the slurry process, and our carbon materials are entirely derived from renewable sources.
Our modular technology allows for an array of specifications suitable for your application.
Serving the industry, with a R&D mind set
LEARN MORE
GO-START is the only supercapacitor module on the market capable of being installed in the battery compartment of a truck, without requiring new cabling or modifications to the vehicle.
Introducing GO-START Supercapacitor Module
Learn how GO-START helps our customers save operational costs while decreasing the use of Lead-based batteries.
What can GO-START do for you?
Cuts 30 k€ in operation costs
and 20 Ton carbon emissions per year
A
Label
Cuts 30 k€ of operation costs and 20 Ton carbon emissions per year

Learn how GO-Start help our customers to save operation costs while decreasing Lead-based batteries.

What can GO-START do for you
Serving the industry, with a R&D mind set

We have developed a supercapacitor technology based on proprietary electrodes combined with an aqueous electrolyte for a low-environmental impact device.
From early on, we have avoided the use of toxic or flammable solvents in the slurry process, and our carbon materials are entirely derived from renewable sources.
Our modular technology allows for an array of specifications suitable for your application.

Go-Start replaces lead-acid
batteries to provide the power
peak to start the engine, even
at sub-zero temperatures.


NO DEAD STARTS

High Power

Our cells have no Lead nor
flammable electrolyte inside.
No electronics are needed for
the cell balancing in the module.


SAFE

Aqueous electrolyte

GO-START module can cut up to 30k € in operational costs per vehicle during its lifetime.


LOW OPERATIONAL COSTS

Up to 30k€ cost reduction

We have developed an easy-to-install supercapacitor module for the automotive industry


EASY INSTALLATION

Plug and Play solution
LEARN MORE

GO-START is the only supercapacitor module on the market capable of being installed in the battery compartment of a truck, without requiring new cabling or modifications to the vehicle.

Introducing GO-START Supercapacitor Module
Label
Cuts 30 k€ of operation costs and 20 Ton carbon emissions per year

Learn how GO-Start help our customers to save operation costs while decreasing Lead-based batteries.

What can GO-START do for you

We have developed a supercapacitor technology based on proprietary electrodes combined with an aqueous electrolyte for a low-environmental impact device.

From early on, we have avoided the use of toxic or flammable solvents in the slurry process, and our carbon materials are entirely derived from renewable sources.

Our modular technology allows for an array of specifications suitable for your application.

Serving the industry, with a R&D mind set

GO-START is the only supercapacitor module on the market capable of being installed in the battery compartment of a truck, without requiring new cabling or modifications to the vehicle.

Introducing Go-start Supercapacitor Module
LEARN MORE

Go-Start replaces lead-acid
batteries to provide the power
peak to start the engine, even
at sub-zero temperatures.


NO DEAD STARTS

High Power

Our cells have no Lead nor
flammable electrolyte inside.
No electronics are needed for
the cell balancing in the module.


SAFE

Aqueous electrolyte

GO-START module can cut up to 30k € in operational costs per vehicle during its lifetime.


LOW OPERATIONAL COSTS

Up to 30k€ cost reduction

We have developed an easy-to-install supercapacitor module for the automotive industry


EASY INSTALLATION

Plug and Play solution

Nickel-carbon supercapacitor technology
C2C-NewCap has several on-going collaborations to develop energy storage technologies ranging from TRL 5 to 7.
What else do we do?
C2C NewCap hybrid supercapacitors use a unique technology that combines proprietary nickel and carbon electrodes with a water-based electrolyte.

Our technology presents key performance parameters such as high-power, fast charging, extended life cycle, non-flammability, and low operating cost. Our product is a sustainable energy storage device that operates safely and efficiently even in severe environments.
CHECK OUT OUR PROJECTS
C2C-NewCap is designing high voltage modules for stationary applications together with leading European partners under the project HYFLOW.
Stationary applications
C2C-NewCap is testing plasma graphene technology for integration in energy storage devices, together with 5 leading European Universities under the PEGASUS project.
Graphene for energy storage
C2C-NewCap has been contributing to the development of redox supercapacitors. Our focus has been nickel-based materials, but we are also actively pursuing other metals and alloys.
Redox supercapacitors
C2C-NewCap has been developing coating procedures using electrospray deposition technology for precision thin coatings for faster response time of the active material.
Electrospray coating
Low-environmental impact aqueous electrolyte with high conductivity.
Aqueous electrolyte
Optimised cell design for minimum internal resistance and modular assembly for flexible solutions.
Nickel-carbon cells
With our expertise on carbon slurry formulation, we have developed carbon electrodes without flammable or toxic components.
Active materials
R2R coating
We run custom roll to roll (R2R) coating machines that give us extended flexibility to manufacture custom solutions.
Nickel-carbon Supercapacitor Technology
CHECK OUT OUR PROJECTS

C2C NewCap hybrid supercapacitors use a unique technology that combines proprietary nickel and carbon electrodes with a water-based electrolyte.

Our technology presents key performance parameters such as high-power, fast charging, extended life cycle, non-flammability, and low operating cost. Our product is a sustainable energy storage device that operates safely and efficiently even in severe environments.

C2C-NewCap has several on-going collaborations to develop energy storage technologies ranging from TRL 5 to 7.

What Else Do We Do?

C2C-NewCap is designing high voltage modules for stationary applications together with leading European partners under the project HYFLOW.

Stationary applications

C2C-NewCap is testing plasma graphene technology for integration in energy storage devices, together with 5 leading European Universities under project PEGASUS.

Graphene for energy storage

C2C-NewCap has been contributing for the development of redox supercapacitors. Our focus has been nickel-based materials, but we are also actively pursuing other metals and alloys.

Redox supercapacitors

With our expertise on carbon slurry formulation, we have developed carbon electrodes without flammable or toxic components.

Electrospray coating

Low-environmental impact aqueous electrolyte with high conductivity.

Aqueous electrolyte

Optimised cell design for minimum internal resistance and modular assembly for flexible solutions.

Nickel-carbon cells

We run custom roll to roll (R2R) coating machines that give us extended flexibility to manufacture custom solutions.

R2R coating

We have built -up expertise on the development of carbon slurry formulation, always avoiding the use of flammable and toxic components.

Active materials
Nickel-carbon supercapacitor technology
CHECK OUT OUR PROJECTS

C2C NewCap hybrid supercapacitors use a unique technology that combines proprietary nickel and carbon electrodes with a water-based electrolyte.

Our technology presents key performance parameters such as high-power, fast charging, extended life cycle, non-flammability, and low operating cost. Our product is a sustainable energy storage device that operates safely and efficiently even in severe environments.

C2C-NewCap has several on-going collaborations to develop energy storage technologies ranging from TRL 5 to 7.

What else do we do?

C2C-NewCap is designing high voltage modules for stationary applications together with leading European partners under the project HYFLOW.

Stationary applications

C2C-NewCap is testing plasma graphene technology for integration in energy storage devices, together with 5 leading European Universities under project PEGASUS.

Graphene for energy storage

C2C-NewCap has been contributing for the development of redox supercapacitors. Our focus has been nickel-based materials, but we are also actively pursuing other metals and alloys.

Redox supercapacitors

C2C-NewCap has been developing coating procedures using electrospray deposition technology for precision thin coatings for faster response time of the active material.

Electrospray coating

Low-environmental impact aqueous electrolyte with high conductivity.

Aqueous electrolyte

Optimised cell design for minimum internal resistance and modular assembly for flexible solutions.

Nickel-carbon cells

We run custom roll to roll (R2R) coating machines that give us extended flexibility to manufacture custom solutions.

R2R coating

With our expertise on carbon slurry formulation, we have developed carbon electrodes without flammable or toxic components.

Active materials
Nickel-carbon supercapacitor technology
CHECK OUT OUR PROJECTS
C2C NewCap hybrid supercapacitors use a unique technology that combines proprietary nickel and carbon electrodes with a water-based electrolyte.

Our technology presents key performance parameters such as high-power, fast charging, extended life cycle, non-flammability, and low operating cost. Our product is a sustainable energy storage device that operates safely and efficiently even in severe environments.
C2C-NewCap has several on-going collaborations to develop energy storage technologies ranging from TRL 5 to 7.
What else do we do?

C2C-NewCap is designing high voltage modules for stationary applications together with leading European partners under the project HYFLOW.

Stationary applications

C2C-NewCap is testing plasma graphene technology for integration in energy storage devices, together with 5 leading European Universities under project PEGASUS.

Graphene for energy storage

C2C-NewCap has been contributing for the development of redox supercapacitors. Our focus has been nickel-based materials, but we are also actively pursuing other metals and alloys.

Redox supercapacitors

C2C-NewCap has been developing coating procedures using electrospray deposition technology for precision thin coatings for faster response time of the active material.

Electrospray coating

Low-environmental impact aqueous electrolyte with high conductivity.

Aqueous electrolyte

Optimised cell design for minimum internal resistance and modular assembly for flexible solutions.

Nickel-carbon cells

We run custom roll to roll (R2R) coating machines that give us extended flexibility to manufacture custom solutions.

R2R coating

With our expertise on carbon slurry formulation, we have developed carbon electrodes without flammable or toxic components.

Active materials
Nickel-carbon supercapacitor technology
C2C-NewCap has several on-going collaborations to develop energy storage technologies ranging from TRL 5 to 7.
What else do we do?
C2C NewCap hybrid supercapacitors use a unique technology that combines proprietary nickel and carbon electrodes with a water-based electrolyte.

Our technology presents key performance parameters such as high-power, fast charging, extended life cycle, non-flammability, and low operating cost. Our product is a sustainable energy storage device that operates safely and efficiently even in severe environments.
CHECK OUT OUR PROJECTS
C2C-NewCap is designing high voltage modules for stationary applications together with leading European partners under the project HYFLOW.
Stationary applications
C2C-NewCap is testing plasma graphene technology for integration in energy storage devices, together with 5 leading European Universities under the PEGASUS project.
Graphene for energy storage
C2C-NewCap has been contributing to the development of redox supercapacitors. Our focus has been nickel-based materials, but we are also actively pursuing other metals and alloys.
Redox supercapacitors
C2C-NewCap has been developing coating procedures using electrospray deposition technology for precision thin coatings for faster response time of the active material.
Electrospray coating
Low-environmental impact aqueous electrolyte with high conductivity.
Aqueous electrolyte
Optimised cell design for minimum internal resistance and modular assembly for flexible solutions.
Nickel-carbon cells
With our expertise on carbon slurry formulation, we have developed carbon electrodes without flammable or toxic components.
Active materials
R2R coating
We run custom roll to roll (R2R) coating machines that give us extended flexibility to manufacture custom solutions.
Nickel-carbon Supercapacitor Technology
CHECK OUT OUR PROJECTS

C2C NewCap hybrid supercapacitors use a unique technology that combines proprietary nickel and carbon electrodes with a water-based electrolyte.

Our technology presents key performance parameters such as high-power, fast charging, extended life cycle, non-flammability, and low operating cost. Our product is a sustainable energy storage device that operates safely and efficiently even in severe environments.

C2C-NewCap has several on-going collaborations to develop energy storage technologies ranging from TRL 5 to 7.

What Else Do We Do?

C2C-NewCap is designing high voltage modules for stationary applications together with leading European partners under the project HYFLOW.

Stationary applications

C2C-NewCap is testing plasma graphene technology for integration in energy storage devices, together with 5 leading European Universities under project PEGASUS.

Graphene for energy storage

C2C-NewCap has been contributing for the development of redox supercapacitors. Our focus has been nickel-based materials, but we are also actively pursuing other metals and alloys.

Redox supercapacitors

With our expertise on carbon slurry formulation, we have developed carbon electrodes without flammable or toxic components.

Electrospray coating

Low-environmental impact aqueous electrolyte with high conductivity.

Aqueous electrolyte

Optimised cell design for minimum internal resistance and modular assembly for flexible solutions.

Nickel-carbon cells

We run custom roll to roll (R2R) coating machines that give us extended flexibility to manufacture custom solutions.

R2R coating

We have built -up expertise on the development of carbon slurry formulation, always avoiding the use of flammable and toxic components.

Active materials
Nickel-carbon supercapacitor technology
CHECK OUT OUR PROJECTS

C2C NewCap hybrid supercapacitors use a unique technology that combines proprietary nickel and carbon electrodes with a water-based electrolyte.

Our technology presents key performance parameters such as high-power, fast charging, extended life cycle, non-flammability, and low operating cost. Our product is a sustainable energy storage device that operates safely and efficiently even in severe environments.

C2C-NewCap has several on-going collaborations to develop energy storage technologies ranging from TRL 5 to 7.

What else do we do?

C2C-NewCap is designing high voltage modules for stationary applications together with leading European partners under the project HYFLOW.

Stationary applications

C2C-NewCap is testing plasma graphene technology for integration in energy storage devices, together with 5 leading European Universities under project PEGASUS.

Graphene for energy storage

C2C-NewCap has been contributing for the development of redox supercapacitors. Our focus has been nickel-based materials, but we are also actively pursuing other metals and alloys.

Redox supercapacitors

C2C-NewCap has been developing coating procedures using electrospray deposition technology for precision thin coatings for faster response time of the active material.

Electrospray coating

Low-environmental impact aqueous electrolyte with high conductivity.

Aqueous electrolyte

Optimised cell design for minimum internal resistance and modular assembly for flexible solutions.

Nickel-carbon cells

We run custom roll to roll (R2R) coating machines that give us extended flexibility to manufacture custom solutions.

R2R coating

With our expertise on carbon slurry formulation, we have developed carbon electrodes without flammable or toxic components.

Active materials
Nickel-carbon supercapacitor technology
CHECK OUT OUR PROJECTS
C2C NewCap hybrid supercapacitors use a unique technology that combines proprietary nickel and carbon electrodes with a water-based electrolyte.

Our technology presents key performance parameters such as high-power, fast charging, extended life cycle, non-flammability, and low operating cost. Our product is a sustainable energy storage device that operates safely and efficiently even in severe environments.
C2C-NewCap has several on-going collaborations to develop energy storage technologies ranging from TRL 5 to 7.
What else do we do?

C2C-NewCap is designing high voltage modules for stationary applications together with leading European partners under the project HYFLOW.

Stationary applications

C2C-NewCap is testing plasma graphene technology for integration in energy storage devices, together with 5 leading European Universities under project PEGASUS.

Graphene for energy storage

C2C-NewCap has been contributing for the development of redox supercapacitors. Our focus has been nickel-based materials, but we are also actively pursuing other metals and alloys.

Redox supercapacitors

C2C-NewCap has been developing coating procedures using electrospray deposition technology for precision thin coatings for faster response time of the active material.

Electrospray coating

Low-environmental impact aqueous electrolyte with high conductivity.

Aqueous electrolyte

Optimised cell design for minimum internal resistance and modular assembly for flexible solutions.

Nickel-carbon cells

We run custom roll to roll (R2R) coating machines that give us extended flexibility to manufacture custom solutions.

R2R coating

With our expertise on carbon slurry formulation, we have developed carbon electrodes without flammable or toxic components.

Active materials