Alison Walker (scientist)

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Alison Walker
Alma mater University of Oxford
Scientific career
Institutions University of Bath
Michigan State University
University of East Anglia
Cambridge Display Technology
Thesis Studies of disorder in fastionics and of a nuclear quadrupole interaction in ordered markets  (1980)
Website Device Modelling

Alison Bridget Walker is a physicist who is a professor at the University of Bath. Her research considers computational modelling of printed electronic devices and the development of perovskite solar cells. She is best known for her work on the Kinetic Monte Carlo method.

Contents

Early life and Education

Walker was born in Sarawak.[ citation needed ] She completed her undergraduate and postgraduate studies at the University of Oxford. [1] Her doctoral research considered nuclear quadrupole interactions and fast ionic conductors. [2] After earning her doctorate, Walker moved to the United States, where she joined Michigan State University as a postdoctoral fellow. She moved to the Daresbury Laboratory as a research fellow.[ citation needed ]

Research and career

Walker started her independent scientific career at the University of East Anglia. [3] She joined the University of Bath in 1998, where she was awarded a Royal Society Industry Fellowship to work at Cambridge Display Technology. [3]

At Bath, Walker is a team leader for the Centre of Excellence, EoCoE (Energy Oriented Centre of excellence, 2015-2018)] Walker works alongside Saiful Islam and Rob Scheichl, who are also funded by the EoCoE. Walker is the Academic Director for the Centre for Doctoral Training in New Sustainable PV (CDT-PV). This council is funded by the EPSRC, which has 7 universities and is headed by Ken Durose at the University of Liverpool.

Walker has developed kinetic Monte Carlo (KMC) approaches to better understand the electronic processes of printed electronic devices. [3] In particular, she has considered photovoltaics and light emitting diodes (LEDs). Several different electronic processes take place in these devices, such as charge injection, the formation of excitons (bound electron – hole pairs), charge and exciton migration, and charge recombination/separation (dissociation). [3] The KMCs developed by Walker take into account the complex three-dimensional morphology of the organic active layer and allow for investigations into how device architectures impact device performance. Beyond KMCs, Walker has developed drift-diffusion models to understand the movement of charge and energy in one-dimension. [3]

In her efforts to understand the mechanisms that underpin device operation in OFETs, OLEDs and OPVs, Walker uses optical models that solve Maxwell's equations. These equations can be used to understand the variations in fields associated with photon absorption and generation. Such models can be used to understand the luminance, quantum efficiencies and current-voltage characteristics. [3] A combination of the three models can be used to identify and optimize the positions of the dissociation and recombination zones. [4] In 2013 Walker was made Academic Director of the Centre for Doctoral Training in New and Sustainable Photovoltaics, as well as co-leading the University of Bath SuperSolar network. [4] [5]

Walker has worked with Petra Cameron to investigate perovskite solar cells, hybrid devices that contain organic and inorganic materials. The active layers of these devices contain perovskite crystal structures, which strongly absorb solar radiation. Electrons within the perovskite are excited across the material bandgap, creating mobile charge carriers that migrate to electron and hole transport layers. Walker was made coordinator of the Horizon 2020 program making perovskite truly exploitable (Maestro). [6] Walker has created protein simulations to understand the structure and function of biologically-relevant molecules. [3]

Selected publications

Related Research Articles

<span class="mw-page-title-main">Photovoltaics</span> Method to produce electricity from solar radiation

Photovoltaics (PV) is the conversion of light into electricity using semiconducting materials that exhibit the photovoltaic effect, a phenomenon studied in physics, photochemistry, and electrochemistry. The photovoltaic effect is commercially used for electricity generation and as photosensors.

In the 19th century, it was observed that the sunlight striking certain materials generates detectable electric current – the photoelectric effect. This discovery laid the foundation for solar cells. Solar cells have gone on to be used in many applications. They have historically been used in situations where electrical power from the grid was unavailable.

The photovoltaic effect is the generation of voltage and electric current in a material upon exposure to light. It is a physical phenomenon.

<span class="mw-page-title-main">Solar cell</span> Photodiode used to produce power from light on a large scale

A solar cell or photovoltaic cell is an electronic device that converts the energy of light directly into electricity by means of the photovoltaic effect. It is a form of photoelectric cell, a device whose electrical characteristics vary when it is exposed to light. Individual solar cell devices are often the electrical building blocks of photovoltaic modules, known colloquially as "solar panels". Almost all commercial PV cells consist of crystalline silicon, with a market share of 95%. Cadmium telluride thin-film solar cells account for the remainder. The common single-junction silicon solar cell can produce a maximum open-circuit voltage of approximately 0.5 to 0.6 volts.

Hybrid solar cells combine advantages of both organic and inorganic semiconductors. Hybrid photovoltaics have organic materials that consist of conjugated polymers that absorb light as the donor and transport holes. Inorganic materials in hybrid cells are used as the acceptor and electron transporter in the structure. The hybrid photovoltaic devices have a potential for not only low-cost by roll-to-roll processing but also for scalable solar power conversion.

<span class="mw-page-title-main">Quantum dot solar cell</span> Type of solar cell based on quantum dot devices

A quantum dot solar cell (QDSC) is a solar cell design that uses quantum dots as the captivating photovoltaic material. It attempts to replace bulk materials such as silicon, copper indium gallium selenide (CIGS) or cadmium telluride (CdTe). Quantum dots have bandgaps that are adjustable across a wide range of energy levels by changing their size. In bulk materials, the bandgap is fixed by the choice of material(s). This property makes quantum dots attractive for multi-junction solar cells, where a variety of materials are used to improve efficiency by harvesting multiple portions of the solar spectrum.

A definition in semiconductor physics, carrier lifetime is defined as the average time it takes for a minority carrier to recombine. The process through which this is done is typically known as minority carrier recombination.

Organic photovoltaic devices (OPVs) are fabricated from thin films of organic semiconductors, such as polymers and small-molecule compounds, and are typically on the order of 100 nm thick. Because polymer based OPVs can be made using a coating process such as spin coating or inkjet printing, they are an attractive option for inexpensively covering large areas as well as flexible plastic surfaces. A promising low cost alternative to conventional solar cells made of crystalline silicon, there is a large amount of research being dedicated throughout industry and academia towards developing OPVs and increasing their power conversion efficiency.

<span class="mw-page-title-main">Organic solar cell</span> Type of photovoltaic

An organic solar cell (OSC) or plastic solar cell is a type of photovoltaic that uses organic electronics, a branch of electronics that deals with conductive organic polymers or small organic molecules, for light absorption and charge transport to produce electricity from sunlight by the photovoltaic effect. Most organic photovoltaic cells are polymer solar cells.

<span class="mw-page-title-main">Thin-film solar cell</span> Type of second-generation solar cell

Thin-film solar cells are made by depositing one or more thin layers of photovoltaic material onto a substrate, such as glass, plastic or metal. Thin-film solar cells are typically a few nanometers (nm) to a few microns (μm) thick–much thinner than the wafers used in conventional crystalline silicon (c-Si) based solar cells, which can be up to 200 μm thick. Thin-film solar cells are commercially used in several technologies, including cadmium telluride (CdTe), copper indium gallium diselenide (CIGS), and amorphous thin-film silicon.

<span class="mw-page-title-main">Solar cell research</span> Research in the field of photovoltaics

There are currently many research groups active in the field of photovoltaics in universities and research institutions around the world. This research can be categorized into three areas: making current technology solar cells cheaper and/or more efficient to effectively compete with other energy sources; developing new technologies based on new solar cell architectural designs; and developing new materials to serve as more efficient energy converters from light energy into electric current or light absorbers and charge carriers.

<span class="mw-page-title-main">Nanocrystal solar cell</span>

Nanocrystal solar cells are solar cells based on a substrate with a coating of nanocrystals. The nanocrystals are typically based on silicon, CdTe or CIGS and the substrates are generally silicon or various organic conductors. Quantum dot solar cells are a variant of this approach which take advantage of quantum mechanical effects to extract further performance. Dye-sensitized solar cells are another related approach, but in this case the nano-structuring is a part of the substrate.

Thermodynamic efficiency limit is the absolute maximum theoretically possible conversion efficiency of sunlight to electricity. Its value is about 86%, which is the Chambadal-Novikov efficiency, an approximation related to the Carnot limit, based on the temperature of the photons emitted by the Sun's surface.

<span class="mw-page-title-main">Perovskite solar cell</span> Alternative to silicon-based photovoltaics

A perovskite solar cell (PSC) is a type of solar cell that includes a perovskite-structured compound, most commonly a hybrid organic–inorganic lead or tin halide-based material as the light-harvesting active layer. Perovskite materials, such as methylammonium lead halides and all-inorganic cesium lead halide, are cheap to produce and simple to manufacture.

Laura Maria Herz is a professor of physics at the University of Oxford. She works on femtosecond spectroscopy for the analysis of semiconductor materials.

There are many practical applications for solar panels or photovoltaics. From the fields of the agricultural industry as a power source for irrigation to its usage in remote health care facilities to refrigerate medical supplies. Other applications include power generation at various scales and attempts to integrate them into homes and public infrastructure. PV modules are used in photovoltaic systems and include a large variety of electrical devices.

Oxford Photovoltaics Limited is an Oxford University spin-off company in the field of perovskite photovoltaics and solar cells.

Giulia Grancini is an Italian physicist who is a Professor of Chemistry at the University of Pavia. Her work considers new materials for photovoltaic devices, including perovskites and polymer-based materials. In 2020, Grancini was named the Royal Society of Chemistry Journal of Materials Chemistry Lecturer.

Libai Huang is a Chinese-American chemist who is a professor at Purdue University. She is interested in unravelling the structure-property relationships of next-generation solar materials.

Annamaria Petrozza is an American chemist who is a professor at the Istituto Italiano di Tecnologia. Her research considers sustainable materials for optoelectronic devices. She was awarded the 2022 Materials Research Society Award in Innovation in Materials Characterization.

References

  1. "Alison Walker". The Conversation. Retrieved 2021-02-08.
  2. Walker, A. B. (Alison Bridget) (1980), Studies of disorder in fastionics and of a nuclear quadrupole interaction in ordered markets, OCLC   229017488, Wikidata   Q28911952
  3. 1 2 3 4 5 6 7 "Alison Walker Home Page". people.bath.ac.uk. Retrieved 2021-02-08.
  4. 1 2 "CDTPV". www.cdt-pv.org. Retrieved 2021-02-08.
  5. "SUPERGEN SuperSolar" . Retrieved 2021-02-08.
  6. "MAESTRO - The European Training Network". MAESTRO - The European Training Network. Retrieved 2021-02-08.