Printed functional ionic polymer-metal nanocomposites for large-scale optics and biomedical implants
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Ionic polymer-metal composites (IPMCs) have been shown to demonstrate high deformations under low voltage bias. The aim of the project here is to develop a new route to the printing of IPMCs which can be integrated into different soft-polymer devices. Using suspensions of Nafion (and related materials) which can be aerosol-jet printed into microscale configurations, as well as metal nanoparticle-based electrical tracks, the scaling of such IPMC bending functionality will be explored. Creating nanocomposites with IPMC-nanoparticle blends will allow tuning the charge transport and swelling which is at the heart driving bending functionalities in soft robotics. Target devices include voltage-switched snake-like reptating inserts capable of navigating themselves into tissues (such as soft cochlea implants). Other devices are voltage-controlled roll-up optical metamaterial devices, as well as low-cost tuneable microcavities capable of acting as pixelated filters on CCD detectors for optimised hyperspectral imaging.
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Potential Impact:
Our main impacts will be:
- a new generation of interdisciplinary nano researchers with expertise across science and innovation, fluent in the combination of approaches and technologies
- strategic developments in the study and control of nano-interfaces connecting complex architectures, for advances in emerging scientific grand challenges across vital areas of energy, health and ICT
- integration of new functional nanotechnologies together by harnessing nano-interfaces within larger application systems, and their translation into innovative products and services through our industry partners and student-led spin-outs
- a paradigm change of collaborative outlook in this science and technology
- a strong interaction with stakeholders including outreach and public engagement with cutting edge nano research
- improved use of interdisciplinary working tools including management, discipline bridging and IT
Economic impact of the new CDT is focused through our industrial engagement programme, as well as our innovation training. Our partner companies include - NPL, Hitachi, Oxford Nanopore, TWI, ARM, Eight19, Mursla, Britvic, Nokia Bell Labs, IBM, Merck, Oxford Instruments, Aixtron, Cambridge Display Technologies, Fluidic Analytics, Emberion, Schlumberger, Applied Materials and others. Such partnerships are crucial for the UK to revive high value manufacturing as the key pillar to lead for future technologies. We evidence this via the large number of CDT projects resulting in patents, with their exploitation supported by Cambridge Enterprise and our Industry Partners, and direct economic impact has also resulted from the large proportion of our students/alumni joining industry (a key outcome), or founding startups including: Echion Technologies (battery materials), Inkling Cambridge (Graphene inks and composites), HexagonFab (2D materials), Simprints (low-cost biometrics), Cortirio (rapid diagnosis of brain injury).
Training impact emerges through not just the vast array of Nano techniques and ideas that our cohorts and associated students are exposed to, but also the interdisciplinary experience that accrues to all the academics. In particular the younger researchers coming into the University are plugged into a thriving programme that connects their work to many other sciences, applications, and societal challenges. Interactions with external partners, including companies, are also strong and our intern programme will greatly strengthen training outcomes.
Academic impact is fostered by ensuring strong coherent plans for research in the early years, and also the strong focus of the whole CDT on study and control of nano-interfaces connecting complex architectures. Our track record for CDT student-led publications is already strong, including 4 Nature/Science, 6 Nature Chem/Nano/Mat, 13 Nat. Comm., with student publications receiving >6000 citations in total, including 16 papers with >100 citations each and high altmetric scores. Students have also given talks and posters at international conferences and won numerous awards/fellowships for research excellence.
Societal impacts arise from both the progression of our cohorts into their careers as well as their interaction with the media, public, and sponsors. We directly encourage a wide variety of engagement, including interaction with >5000 members of the public each year (mostly pre-university) through Nano exhibits during public events such as the Cambridge Science Festival and Royal Society Summer Science Exhibition, and also art-science collaborations to reach new audiences. We also run public policy and global challenges workshops, and will further develop this aspect with external partners. Our efforts to bring societal challenges to students' awareness frames their view of what a successful career looks like. Longer term societal impact comes directly from our engagement with partner companies creating jobs and know-how in the UK.
| University of Cambridge | LEAD_ORG |
| Cambridge Trusts | STUDENT_PP_ORG |
| Sohini Kar-Narayan | SUPER_PER |
| Jeremy Baumberg | SUPER_PER |
Subjects by relevance
- Nanotechnology
- Exhibition publications
- Technology
- Optimisation
- Partnership
- Public health service
- Technological development
- Innovations
Extracted key phrases
- Functional ionic polymer
- New functional nanotechnology
- Polymer device
- Metal nanocomposite
- Metal composite
- Metal nanoparticle
- Soft cochlea implant
- Large application system
- Interdisciplinary nano researcher
- Long term societal impact
- Low voltage bias
- Biomedical implant
- New CDT
- Edge nano research
- CDT student
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