Dr James Ryan

Uchafbwyntiau Ymchwil

1. O’Kelly, C., Nakayama, T., & Ryan, J. (2020). Organic Memristive Devices Based on Squaraine Nanowires. ACS Applied Electronic Materials, 2(10), 3088-3092.

   https://doi.org/10.1021/acsaelm.0c00652, SU Repository: https://cronfa.swan.ac.uk/Record/cronfa55749
2. Khadka, D., Shirai, Y., Yanagida, M., Ryan, J., & Miyano, K. (2017). Exploring the effects of interfacial carrier transport layers on device performance and optoelectronic properties of planar perovskite solar cells. Journal of Materials Chemistry C, 5(34), 8819-8827.

   https://doi.org/10.1039/c7tc02822a, SU Repository: https://cronfa.swan.ac.uk/Record/cronfa53746
3. Nolasco, J., Ryan, J., Rodríguez, M., Castro-Carranza, A., Maldonado, J., Ramos-Ortiz, G., Barbosa-Garcia, O., Gutowski, J., Palomares, E., & Parisi, J. (2018). Organoboron donor-π-acceptor chromophores for small-molecule organic solar cells. Journal of Materials Science: Materials in Electronics, 29(19), 16410-16415.

   https://doi.org/10.1007/s10854-018-9732-6, SU Repository: https://cronfa.swan.ac.uk/Record/cronfa53750
4. Fernandez, D., Viterisi, A., Challuri, V., Ryan, J., Martinez-Ferrero, E., Gispert-Guirado, F., Martinez, M., Escudero, E., Stenta, C., Marsal, L., & Palomares, E. (2017). Understanding the Limiting Factors of Solvent-Annealed Small-Molecule Bulk-Heterojunction Organic Solar Cells from a Chemical Perspective. ChemSusChem, 10(15), 3118-3134.

   https://doi.org/10.1002/cssc.201700440, SU Repository: https://cronfa.swan.ac.uk/Record/cronfa53751
5. Wang, S., Ryan, J., Singh, A., Beirne, J., Palomares, E., & Redmond, G. (2016). Encapsulation of MEH-PPV:PCBM Hybrids in the Cores of Block Copolymer Micellar Assemblies: Photoinduced Electron Transfer in a Nanoscale Donor–Acceptor System. Langmuir, 32(1), 329-337.

   https://doi.org/10.1021/acs.langmuir.5b04053, SU Repository: https://cronfa.swan.ac.uk/Record/cronfa53752
6. Malgras, V., Tominaka, S., Ryan, J., Henzie, J., Takei, T., Ohara, K., & Yamauchi, Y. (2016). Observation of Quantum Confinement in Monodisperse Methylammonium Lead Halide Perovskite Nanocrystals Embedded in Mesoporous Silica. Journal of the American Chemical Society, 138(42), 13874-13881.

   https://doi.org/10.1021/jacs.6b05608, SU Repository: https://cronfa.swan.ac.uk/Record/cronfa53754
7. Ryan, J. & Palomares, E. (2017). Photo-Induced Charge Carrier Recombination Kinetics in Small Molecule Organic Solar Cells and the Influence of Film Nanomorphology. Advanced Energy Materials, 7(10), 1601509

   https://doi.org/10.1002/aenm.201601509, SU Repository: https://cronfa.swan.ac.uk/Record/cronfa53755
8. Li, S., Li, Z., Nakagawa, T., Ryan, J., Matsuo, Y., & Gao, X. (2015). Approach to High Open-Circuit Voltage in Organic Solar Cells Utilizing a Structural Change of the Oxazolino-C70Derivative. Chemistry - A European Journal, 21(5), 1894-1899.

   https://doi.org/10.1002/chem.201405890, SU Repository: https://cronfa.swan.ac.uk/Record/cronfa53756

   http://dx.doi.org/10.1002/chem.201405890
9. Stetsovych, O., Todorović, M., Shimizu, T., Moreno, C., Ryan, J., León, C., Sagisaka, K., Palomares, E., Matolín, V., Fujita, D., Perez, R., & Custance, O. (2015). Atomic species identification at the (101) anatase surface by simultaneous scanning tunnelling and atomic force microscopy. Nature Communications, 6(1)

   https://doi.org/10.1038/ncomms8265, SU Repository: https://cronfa.swan.ac.uk/Record/cronfa53757

   http://dx.doi.org/10.1038/ncomms8265
10. Ryan, J. & Matsuo, Y. (2015). Increased Efficiency in Small Molecule Organic Solar Cells Through the Use of a 56-π Electron Acceptor – Methano Indene Fullerene. Scientific Reports, 5(1)

    https://doi.org/10.1038/srep08319, SU Repository: https://cronfa.swan.ac.uk/Record/cronfa53758

Holl Ymchwil

• Augmented chemical biology for solar hydrogen generation (cyfredol)

  PhD

  Goruchwyliwr arall: Dr Moritz Kuehnel

• Design and development of organic semiconducting materials for solar cells (cyfredol)

  PhD

  Goruchwyliwr arall: Dr Francisco Martin-Martinez

• Developing organic electronic materials and devices for neuromorphic computing (cyfredol)

  PhD

  Goruchwyliwr arall: Prof Paul Meredith

• CH-126 Chemical Reactions 2

  This module will continue the discussion of the fundamentals of the physical aspects of chemical reactions, both thermodynamic and kinetic. These and other previously-understood concepts will then be applied to the study of substitution and elimination and an introduction to redox reactions, both organic and inorganic. This module will build on existing understanding and will employ mathematics taught in other modules (CH-122) to conceptualise some of the material taught in this module. The module will have a variety of formative assessment opportunities and summative assessments that include writing of technical reports, a presentation, homework, workshops, and an exam.

• CH-127 Chemical Practice

  This module will introduce students to the three broad employment areas for chemistry: research, teaching or industrial positions. The lecture portion will cover fundamental aspects of being a professional chemist including safety, report writing, project management, and teaching skills. Students will attend research seminars and workshops, industrial field trips, and supervise school pupils in the laboratory. Assessment will be by coursework and a written report.

• CH-237 Further Physical Chemistry

  This module will advance students¿ studies in Physical Chemistry. The module provides a more in-depth look at thermodynamics from both the classical and molecular viewpoints, the thermodynamics of mixing and chemical equilibrium. Electrochemistry is covered from a fundamental and applied view and serves is used to further discuss thermodynamics, non-ideal behaviour and equilibrium. A deeper look at kinetics is then included that builds on prior knowledge and highlights the importance of kinetics in chemical reactions and processes. The module will build on existing understanding, further developing mathematical skills to explore the material covered in this module. In the laboratory students will undertake more advanced investigative experiments to explore the physical concepts. Material, techniques and skills covered in the course of this module will build on and therefore require understanding of all prior modules. The module will be assessed by coursework (laboratory experiments, laboratory report and assignments) and by examination.

• CH-343 Advanced Laboratory Experience

  This last formal lab module for those on the M Chem course consists of "project practicals" which can last from 3 to 10 weeks. These are intended to lay the groundwork for the more extensive research project carried out in the final year. The practicals change from one year to the next based on the current research of the department. They may be synthetic, analytical or purely involve extensive data treatment.

• CH-345 Materials Chemistry Project

  3rd year projects are the opportunity to bring all you've learnt during your degree together and apply that knowledge to solve a problem. In Swansea these projects can be embedded in active research groups across the colleges of science, engineering or medicine, allowing you to build a network and experience in your chosen specialism within the chemical sciences. These projects are your opportunity to demonstrate to employers that you have a full understanding of your course and are able to direct your own studies, manage an independent research project and effectively communicate your findings. This selection suggests an interest in a project embedded within a research group in engineering, focusing on materials chemistry or chemical engineering

• CH-414 Scientific innovation and entrepreneurship

  This is a seminar-based module that provides an introduction to the world of research, innovation and entrepreneurship, where students apply their chemical knowledge to tackle important scientific, societal and industrial challenges. Seminars and workshops will be provided partly by departmental staff and partly by invited external speakers including academics, industry professionals, grant-writing advisors, technology transfer officers, patent lawyers, venture capitalists, accomplished entrepreneurs and start-up CEOs and CTOs. The seminars will cover a broad range of complementary topics that are required to fund, manage and grow an academic or entrepreneurial project. Speakers will share their career path, failures, successes and how they and others have used their skills and ingenuity to have an impact on worldwide and local problems that society is facing. Some speakers could also provide a challenge or a case study for the students to work on and share with classmates. From these seminars, students will build up a strong portfolio of knowledge and transferable skills that they will then use it to write a impact analysis and business model canvas on a topic of their choosing, guided by mentor meetings to (1) discuss the broad topics before the specific problem is picked, (2) discuss the chosen problem before the exercises are done, and (3) discuss students¿ progress on the work. At the end of the module, they will pitch their project to a panel, where they will be questioned on their science, originality, business plan, budget, and impact.

• SC-M03 Processable Electronics

  Since the 1970s, plastic electronics has expanded into a multitude of technologies and products incorporating flexible and transparent electronic circuits. Polymers or inks can be used as printable inks onto polymer-based substrates using various printing technologies, spin coating or vacuum deposition. Plastic electronics can use printed inks on plastic substrates, or it can consist of organic conductive polymers. Applications of plastic electronics will be discussed.