The University of Southampton
×
Filter your search:
University of Southampton Institutional Repository

Using deep machine learning to understand the physical performance bottlenecks in novel thin-film solar cells

Using deep machine learning to understand the physical performance bottlenecks in novel thin-film solar cells
Using deep machine learning to understand the physical performance bottlenecks in novel thin-film solar cells

There is currently a worldwide effort to develop materials for solar energy harvesting which are efficient and cost effective, and do not emit significant levels of CO 2 during manufacture. When a researcher fabricates a novel device from a novel material system, it often takes many weeks of experimental effort and data analysis to understand why any given device/material combination produces an efficient or poorly optimized cell. It therefore takes the community tens of years to transform a promising material system to a fully optimized cell ready for production (perovskites are a contemporary example). Herein, developed is a new and rapid approach to understanding device/material performance, which uses a combination of machine learning, device modeling, and experiment. Providing a set of electrical device parameters (charge carrier mobilities, recombination rates, trap densities, etc.) in a matter of seconds thus offers a fast way to directly link fabrication conditions to device/material performance, pointing a way to further and more rapid optimization of light harvesting devices. The method is demonstrated by using it to understand annealing temperature and surfactant choice and in terms of charge carrier dynamics in organic solar cells made from the P3HT:PCBM, PBTZT-stat-BDTT-8:PCBM, and PTB7:PCBM material systems.

charge carrier mobility, drift diffusion, machine learning, organic solar cells, thin film solar cells
1616-301X
1-11
Saladina, Maria
65d9a019-aab8-4664-b0f0-09c26e5d01a1
Deibel, Carsten
05b427fd-8e81-46af-966e-e1220aa7014f
Krompiec, Michal
c5280165-053d-422d-8872-ae612852d773
Majeed, Nahdia
8b52d26c-64a3-4b43-be6c-38ced2050683
Greedy, Steve
e1ee11ad-c7a7-48c1-acfa-6d9b6fb2031f
MacKenzie, Roderick C.I.
7bde0564-7f46-4e9c-99a2-21a1f9b78b9c
Saladina, Maria
65d9a019-aab8-4664-b0f0-09c26e5d01a1
Deibel, Carsten
05b427fd-8e81-46af-966e-e1220aa7014f
Krompiec, Michal
c5280165-053d-422d-8872-ae612852d773
Majeed, Nahdia
8b52d26c-64a3-4b43-be6c-38ced2050683
Greedy, Steve
e1ee11ad-c7a7-48c1-acfa-6d9b6fb2031f
MacKenzie, Roderick C.I.
7bde0564-7f46-4e9c-99a2-21a1f9b78b9c

Saladina, Maria, Deibel, Carsten, Krompiec, Michal, Majeed, Nahdia, Greedy, Steve and MacKenzie, Roderick C.I. (2020) Using deep machine learning to understand the physical performance bottlenecks in novel thin-film solar cells. Advanced Functional Materials, 30 (7), 1-11, [1907259]. (doi:10.1002/adfm.201907259).

Record type: Article

Abstract

There is currently a worldwide effort to develop materials for solar energy harvesting which are efficient and cost effective, and do not emit significant levels of CO 2 during manufacture. When a researcher fabricates a novel device from a novel material system, it often takes many weeks of experimental effort and data analysis to understand why any given device/material combination produces an efficient or poorly optimized cell. It therefore takes the community tens of years to transform a promising material system to a fully optimized cell ready for production (perovskites are a contemporary example). Herein, developed is a new and rapid approach to understanding device/material performance, which uses a combination of machine learning, device modeling, and experiment. Providing a set of electrical device parameters (charge carrier mobilities, recombination rates, trap densities, etc.) in a matter of seconds thus offers a fast way to directly link fabrication conditions to device/material performance, pointing a way to further and more rapid optimization of light harvesting devices. The method is demonstrated by using it to understand annealing temperature and surfactant choice and in terms of charge carrier dynamics in organic solar cells made from the P3HT:PCBM, PBTZT-stat-BDTT-8:PCBM, and PTB7:PCBM material systems.

Text
mackenzie - Accepted Manuscript
Available under License University of Southampton Accepted Manuscript Licence.
Download (7MB)

More information

Accepted/In Press date: 15 December 2019
e-pub ahead of print date: 15 December 2019
Published date: 12 February 2020
Keywords: charge carrier mobility, drift diffusion, machine learning, organic solar cells, thin film solar cells
Learn more about School of Chemistry research

Identifiers

Local EPrints ID: 455491
URI: http://eprints.soton.ac.uk/id/eprint/455491
DOI: doi:10.1002/adfm.201907259
ISSN: 1616-301X
PURE UUID: 024f21cd-ac9b-4f42-bfbe-d7e52521f84e

Catalogue record

Date deposited: 23 Mar 2022 17:34
Last modified: 06 Jun 2024 04:10

Export record

Altmetrics

Contributors

Author: Maria Saladina
Author: Carsten Deibel
Author: Michal Krompiec
Author: Nahdia Majeed
Author: Steve Greedy
Author: Roderick C.I. MacKenzie

Download statistics

Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.

View more statistics

Library staff additional information
Atom RSS 1.0 RSS 2.0

Contact ePrints Soton: eprints@soton.ac.uk

ePrints Soton supports OAI 2.0 with a base URL of http://eprints.soton.ac.uk/cgi/oai2

This repository has been built using EPrints software, developed at the University of Southampton, but available to everyone to use.

We use cookies to ensure that we give you the best experience on our website. If you continue without changing your settings, we will assume that you are happy to receive cookies on the University of Southampton website.

×