Summary
This project aims at developing and disseminating a new class of ultrasensitive and vectorial force field sensors to build the
next generation of scanning probes with improved sensitivity and vectorial readout capacity. The vibrations of a singly
clamped silicon carbide nanowire (NW) are readout by optical techniques. Its vibrating extremity oscillates in both
transverse directions with quasi-degenerated frequencies due to its quasi-cylindrical geometry. When approaching the NW
above a sample surface it experiences an additional force field due to the sample-NW interaction which modifies its
mechanical properties. The force field can be fully derived by monitoring frequency shifts and eigenmode rotations.
The measurement principle was demonstrated during the HQNOM ERC project by monitoring the perturbation of the NW
Brownian motion, its random thermal noise in 2D induced by a voltage biased electrostatic tip. An impressive sensitivity to
force field gradients varying by less than 1e-18N over the nanometer sized Brownian motion was demonstrated, as well as
a fully vectorial readout capacity which is unaccessible to existing 1D force probes.
This vectorial sensitivity, combined with the one-millon-fold improvement in force sensitivity over commercial atomic force
microscopes is the starting point of the POC project. The objective is to ensure a wide dissemination of this extraordinary
vectorial force field sensors and to progress towards an industrial outreach of the apparatus.
To do so, a demonstration prototype will be developed and will serve as a workhorse for the second step, the dissemination
phase of the apparatus towards a broader scientific and industrial community.
next generation of scanning probes with improved sensitivity and vectorial readout capacity. The vibrations of a singly
clamped silicon carbide nanowire (NW) are readout by optical techniques. Its vibrating extremity oscillates in both
transverse directions with quasi-degenerated frequencies due to its quasi-cylindrical geometry. When approaching the NW
above a sample surface it experiences an additional force field due to the sample-NW interaction which modifies its
mechanical properties. The force field can be fully derived by monitoring frequency shifts and eigenmode rotations.
The measurement principle was demonstrated during the HQNOM ERC project by monitoring the perturbation of the NW
Brownian motion, its random thermal noise in 2D induced by a voltage biased electrostatic tip. An impressive sensitivity to
force field gradients varying by less than 1e-18N over the nanometer sized Brownian motion was demonstrated, as well as
a fully vectorial readout capacity which is unaccessible to existing 1D force probes.
This vectorial sensitivity, combined with the one-millon-fold improvement in force sensitivity over commercial atomic force
microscopes is the starting point of the POC project. The objective is to ensure a wide dissemination of this extraordinary
vectorial force field sensors and to progress towards an industrial outreach of the apparatus.
To do so, a demonstration prototype will be developed and will serve as a workhorse for the second step, the dissemination
phase of the apparatus towards a broader scientific and industrial community.
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More information & hyperlinks
| Web resources: | https://cordis.europa.eu/project/id/767579 |
| Start date: | 01-11-2017 |
| End date: | 30-04-2019 |
| Total budget - Public funding: | 150 000,00 Euro - 150 000,00 Euro |
Cordis data
Original description
This project aims at developing and disseminating a new class of ultrasensitive and vectorial force field sensors to build thenext generation of scanning probes with improved sensitivity and vectorial readout capacity. The vibrations of a singly
clamped silicon carbide nanowire (NW) are readout by optical techniques. Its vibrating extremity oscillates in both
transverse directions with quasi-degenerated frequencies due to its quasi-cylindrical geometry. When approaching the NW
above a sample surface it experiences an additional force field due to the sample-NW interaction which modifies its
mechanical properties. The force field can be fully derived by monitoring frequency shifts and eigenmode rotations.
The measurement principle was demonstrated during the HQNOM ERC project by monitoring the perturbation of the NW
Brownian motion, its random thermal noise in 2D induced by a voltage biased electrostatic tip. An impressive sensitivity to
force field gradients varying by less than 1e-18N over the nanometer sized Brownian motion was demonstrated, as well as
a fully vectorial readout capacity which is unaccessible to existing 1D force probes.
This vectorial sensitivity, combined with the one-millon-fold improvement in force sensitivity over commercial atomic force
microscopes is the starting point of the POC project. The objective is to ensure a wide dissemination of this extraordinary
vectorial force field sensors and to progress towards an industrial outreach of the apparatus.
To do so, a demonstration prototype will be developed and will serve as a workhorse for the second step, the dissemination
phase of the apparatus towards a broader scientific and industrial community.
Status
CLOSEDCall topic
ERC-2017-PoCUpdate Date
27-04-2024
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