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ASPIRE

financed

Angular studies of photoelectrons in innovative research environments

In the ASPIRE project, whose academic and industrial beneficiaries are world leading in their complementary fields of expertise, the overarching research goal is the measurement of photoelectron angular distributions (PADs) in the... see more

29/02/2020

THE UNIVERSITY OF...

3M€

Project Budget: 3M€

Project leader

THE UNIVERSITY OF NOTTINGHAM No se ha especificado una descripción o un objeto social para esta compañía.

TRL 4-5

PARTICIPATION DEPralty Sin fecha límite de participación.

Ver 16 Participantes

Financing granted El organismo H2020 notifico la concesión del proyecto The day 2020-02-29

MSCA-ITN-2015-ETN: Marie Skłodowska-Curie Innovative T... Scope:European Training Networks (ETN)

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Este proyecto no cuenta con búsquedas de partenariado abiertas en este momento.

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16 Participantes

THE UNIVERSITY OF NOTTINGHAM

546.58K€ | Leader

INDIGO JEWELRY

CNRS

262.88K€ | participant

DESY

N.D. | participant

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Project duration: 54 months Date Start: 2015-08-04
End date: 2020-02-29

Project leader

THE UNIVERSITY OF NOTTINGHAM No se ha especificado una descripción o un objeto social para esta compañía.

TRL 4-5

Project Budget 3M€

participation deadline Sin fecha límite de participación.

Project description In the ASPIRE project, whose academic and industrial beneficiaries are world leading in their complementary fields of expertise, the overarching research goal is the measurement of photoelectron angular distributions (PADs) in the molecular frame (MF) of systems of biological relevance. These MF-PADs can be interpreted as electron diffraction patterns, achieved by illuminating the molecule from within, and enable the shapes and motions of individual molecules to be interrogated. Such knowledge is needed for the development of new medicines (the shapes of drug molecules dictate their function) and new materials (efficient solar cells can be constructed if energy dissipation processes in molecules are understood). Progress in this area is highly technologically driven, requiring high repetition rate, short wavelength light sources and fast detectors. The input of private sector beneficiaries is therefore critical to the scientific objectives, as well as to the enhanced training environment. Work packages on advanced light source and detector developments will feed into the overall goal through secondments, regular virtual meetings and face-to-face network meetings. The symbiosis of the developments that will take place in ASPIRE will create a research and training environment that is world-leading and optimally tailored to capitalise, for example, on the investment that has been made in the European XFEL facility. The ESRs will be trained in world-leading laboratories and will benefit from the exchange of best practice among beneficiaries and partners, and from unique training events. ASPIRE will therefore ensure that European research remains competitive in the global market, and that the trained researchers will be uniquely well-placed to contribute to the development of novel instrumentation in the future.

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