Printed Solar Cells on Steel
Lead Research Organisation:
Swansea University
Department Name: College of Engineering
Abstract
Background
Tata Steel would like to understand the potential of adding photoactive energy generation materials to a portfolio of steel products to achieve added value. This entails the sequential deposition of functional layers onto pre-existing architectural products culminating in a completed photovoltaic product appropriate for direct integration into the built environment.
Project Aims
The proposed technology of choice is that of the perovskite solar cell. Perovskite solar cells (PSCs) as solid-state devices have demonstrated the highest efficiency of all printed solar cell technologies. The current record for a small area PSC now stands at 25%. These small area devices are often processed with an evaporated gold or silver top electrode which can add significantly to the cost of the devices and render the device stack inappropriate for mounting onto an opaque substrate. This means that generally speaking most perovskite cell architectures are inappropriate for metal or steel-based substrates. The world's first perovskite solar cell made using a metal substrate was developed and published by Swansea University (see Troughton et al, Highly efficient, flexible, indium-free perovskite solar cells employing metallic substrates, J Mat Chem A 2015, 3, 9141).
There are two possible approaches for deploying a PV product onto a steel substrate:
1.Direct application of layers sequentially onto the metal itself, whereby the metal substrate acts as an electrode in the device stack. This could be a metal foil material that is then subsequently laminated to a more appropriate architectural steel.
2.Application of an electrically insulating layer to an organically coated steel product that is then further functionalised with an electrically conducting layer and then sequentially applied photoactive materials. The device is then completed with a transparent conducting layer and barrier film.
These approaches will be considered alongside working with the existing research team to develop a pathway to a printed solar cell demonstrator on steel substrates.
Tata Steel would like to understand the potential of adding photoactive energy generation materials to a portfolio of steel products to achieve added value. This entails the sequential deposition of functional layers onto pre-existing architectural products culminating in a completed photovoltaic product appropriate for direct integration into the built environment.
Project Aims
The proposed technology of choice is that of the perovskite solar cell. Perovskite solar cells (PSCs) as solid-state devices have demonstrated the highest efficiency of all printed solar cell technologies. The current record for a small area PSC now stands at 25%. These small area devices are often processed with an evaporated gold or silver top electrode which can add significantly to the cost of the devices and render the device stack inappropriate for mounting onto an opaque substrate. This means that generally speaking most perovskite cell architectures are inappropriate for metal or steel-based substrates. The world's first perovskite solar cell made using a metal substrate was developed and published by Swansea University (see Troughton et al, Highly efficient, flexible, indium-free perovskite solar cells employing metallic substrates, J Mat Chem A 2015, 3, 9141).
There are two possible approaches for deploying a PV product onto a steel substrate:
1.Direct application of layers sequentially onto the metal itself, whereby the metal substrate acts as an electrode in the device stack. This could be a metal foil material that is then subsequently laminated to a more appropriate architectural steel.
2.Application of an electrically insulating layer to an organically coated steel product that is then further functionalised with an electrically conducting layer and then sequentially applied photoactive materials. The device is then completed with a transparent conducting layer and barrier film.
These approaches will be considered alongside working with the existing research team to develop a pathway to a printed solar cell demonstrator on steel substrates.
People |
ORCID iD |
| Trystan Watson (Primary Supervisor) | |
| Elin Worsley (Student) |
Studentship Projects
| Project Reference | Relationship | Related To | Start | End | Student Name |
|---|---|---|---|---|---|
| EP/S02252X/1 | 01/10/2019 | 31/03/2028 | |||
| 2886161 | Studentship | EP/S02252X/1 | 01/10/2023 | 30/09/2027 | Elin Worsley |