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Opendata, web and dolomites

MicroMOUPE SIGNED

Microscopy - Making optimal use of photons and electrons

Total Cost €

EC-Contrib. €

Partnership

Views

Outcomes and
results

MicroMOUPE project word cloud

Explore the words cloud of the MicroMOUPE project. It provides you a very rough idea of what is the project "MicroMOUPE" about.

single probe optical plate enhancement fast self ponderomotive shape generator scattered pass sub resolution sensitivity temporal landscapes electrons particles times photons shot switch realized created sensitive metal imaging quadratic accuracy optically potentials microscopy university specimen signal aberration post microscope arbitrary creation blanking optimize proof overcoming electro cells dna spatial designed of coherent adaptive free linear cavities technologically limited stanford multiple optics modern optimal molecules interact microscopes tool proteins detection intense bright nanoparticles interactions specimens nanometric dark noise evading laser vienna zernike experiment feasible introducing pattern tested pulses demonstrated particle beam limits electron limit fundamental correction

Project "MicroMOUPE" data sheet

The following table provides information about the project.

Coordinator	UNIVERSITAT WIEN Organization address address: UNIVERSITATSRING 1 city: WIEN postcode: 1010 website: www.univie.ac.at contact info title: n.a. name: n.a. surname: n.a. function: n.a. email: n.a. telephone: n.a. fax: n.a.
Coordinator Country	Austria [AT]
Project website	https://imaging.univie.ac.at/
Total cost	1˙672˙752 €
EC max contribution	1˙672˙752 € (100%)
Programme	1. H2020-EU.1.1. (EXCELLENT SCIENCE - European Research Council (ERC))
Code Call	ERC-2017-STG
Funding Scheme	ERC-STG
Starting year	2018
Duration (year-month-day)	from 2018-03-01 to 2023-02-28

Partnership

Take a look of project's partnership.

#	participants	country	role	EC contrib. [€]
1	UNIVERSITAT WIEN UNIVERSITAT WIEN Organization address address: UNIVERSITATSRING 1 city: WIEN postcode: 1010 website: www.univie.ac.at contact info title: n.a. name: n.a. surname: n.a. function: n.a. email: n.a. telephone: n.a. fax: n.a.	AT (WIEN)	coordinator	1˙672˙752.00

Map

Project objective

The sensitivity of modern microscopy is limited by shot-noise. It limits the accuracy of measurements of specimen properties as well as the spatial resolution of electron microscopes when imaging sensitive specimens, such as proteins or DNA. But the shot-noise limit is not a fundamental limit. A technologically feasible and optimal approach to overcoming the shot-noise limit is to have each probe particle interact with the specimen multiple times. We recently introduced this concept to microscopy using self-imaging cavities. Within this project, I want to demonstrate post-selection free sub-shot noise microscopy with both photons and electrons. Optically this will be possible by introducing a fast electro-optical switch into a multi-pass microscope, evading the need for temporal post-selection. After this proof-of principle experiment, the sensitivity enhancement offered by multi-pass microscopy shall be applied to the detection of nanometric particles, such as single molecules, proteins and metal nanoparticles. Linear signal enhancement with the number of interactions is expected for bright-field microscopy. For dark-field microscopy a quadratic enhancement is expected, due to coherent build-up of scattered fields. Finally, adaptive optics will be used to optimize multi-pass microscopy for the study of cells. Multi-pass electron microscopy will be realized in collaboration with Stanford University. It will require several novel electron optical elements that will be designed and tested both at Stanford University and at the University of Vienna. One of these elements will be a pattern generator for electrons based on ponderomotive potentials. The required potential landscapes will be created using adaptive optics to shape intense laser pulses. With this novel electron optics tool fast beam-blanking, a phase plate for Zernike phase microscopy, arbitrary pattern creation and aberration correction will be demonstrated.

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The information about "MICROMOUPE" are provided by the European Opendata Portal: CORDIS opendata.