Very-high-frequency probes for atomic force microscopy with silicon optomechanics

Schwab, Lucien; Allain, Pierre; Mauran, Nicolas; Dollat, Xavier; Mazenq, Laurent; Lagrange, Denis; Gély, M.; Hentz, Sébastien; Jourdan, G.; Favero, Iván; Legrand, Bernard

doi:10.1038/s41378-022-00364-4

Cited by 14 publications

(5 citation statements)

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“…Recently, cavity optomechanical sensors have been studied for use as ultrasensitive chemical and biological sensors [9]- [14] and high-frequency rheometers [15] in liquid environments. To perform highly sensitive detection of mechanical motion in a liquid environment, it is of utmost Motoki Asano, Hiroshi Yamaguchi, and Hajime Okamoto are with the NTT Basic Research Laboratories, 3-1 Morinosato Wakamiya, Atsugi-shi, Kanagawa 243-0198, Japan.…”

Section: Introductionmentioning

confidence: 99%

Free-access optomechanical liquid probes using a twin-microbottle resonator

2022

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Cavity optomechanics provides high-performance sensor technology, and the scheme is also applicable to liquid samples for biological and rheological applications. However, previously reported methods using fluidic capillary channels and liquid droplets are based on fixed-by-design structures and therefore do not allow an active free access to the samples. Here, we demonstrate an alternate technique using a probe-based architecture with a twin-microbottle resonator. The probe consists of two microbottle optomechanical resonators, where one bottle (for detection) is immersed in liquid and the other bottle (for readout) is placed in air, which retains excellent detection performance through the high optical Q (~10 7 ) of the readout bottle. The scheme allows the detection of thermomechanical motion of the detection bottle as well as optomechanical drive and frequency tracking with a phase-locked loop. This technique could lead to in situ metrology at the target location in arbitrary media and could be extended to ultrasensitive biochips and rheometers.

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Section: Introductionmentioning

confidence: 99%

Free-access optomechanical liquid probes using a twin-microbottle resonator

2022

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“…The integrated resonator used for motion detection also provides a potentially quantum-limited approach to motion detection. It is difficult to make a complete and detailed comparison of AFM force sensors using a microwave resonator with those using an optical cavity to detect motion [ 10 , 43 ] because of numerous differences in the entire measurement apparatus. However, in comparison to optical resonators, the ability of microwave resonators to easily operate in the sideband-resolved regime allows for additional and potentially more efficient schemes of sensing force with minimal back-action from motion detection.…”

Section: Discussionmentioning

confidence: 99%

Design, fabrication, and characterization of kinetic-inductive force sensors for scanning probe applications

Roos,

Scarano,

Arvidsson

et al. 2024

Beilstein J. Nanotechnol.

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We describe a transducer for low-temperature atomic force microscopy based on electromechanical coupling due to a strain-dependent kinetic inductance of a superconducting nanowire. The force sensor is a bending triangular plate (cantilever) whose deflection is measured via a shift in the resonant frequency of a high-Q superconducting microwave resonator at 4.5 GHz. We present design simulations including mechanical finite-element modeling of surface strain and electromagnetic simulations of meandering nanowires with large kinetic inductance. We discuss a lumped-element model of the force sensor and describe the role of an additional shunt inductance for tuning the coupling to the transmission line used to measure the microwave resonance. A detailed description of our fabrication is presented, including information about the process parameters used for each layer. We also discuss the fabrication of sharp tips on the cantilever using focused electron beam-induced deposition of platinum. Finally, we present measurements that characterize the spread of mechanical resonant frequency, the temperature dependence of the microwave resonance, and the sensor’s operation as an electromechanical transducer of force.

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“…In addition, high-frequency cantilevers can contribute to shorter measuring times due to their smaller dimensions [57] and the use of multi-cantilever arrays [58], which can contribute to shorter measuring/fabrication times.…”

Section: Discussionmentioning

confidence: 99%

Investigations on tip-based large area nanofabrication and nanometrology using a planar nanopositioning machine (NFM-100)

Stauffenberg,

Belkner,

Dontsov

et al. 2024

Meas. Sci. Technol.

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This paper explores large area application of tip-based nanofabrication by field emission scanning probe lithography and showcases the simultaneous possibility of atomic force microscopy on macroscopic scales. This is made possible by the combination of tip-based technology and a planar nanopositioning and nanomeasuring machine. Using long range atomic force microscopy measurement of regular grating structures, the performance of the machine is thoroughly characterized over the full 100 mm range of motion of the positioning machine, which was confirmed by repeated measurements. After initially focussing on achieving the minimum line width of < 40 nm in microscopic areas, a grating with a pitch of 1 μm is additionally fabricated over a total length of 10 mm, whereby the dimensions and deviations are also considered.

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Very-high-frequency probes for atomic force microscopy with silicon optomechanics

Cited by 14 publications

References 50 publications

Free-access optomechanical liquid probes using a twin-microbottle resonator

Free-access optomechanical liquid probes using a twin-microbottle resonator

Design, fabrication, and characterization of kinetic-inductive force sensors for scanning probe applications

Investigations on tip-based large area nanofabrication and nanometrology using a planar nanopositioning machine (NFM-100)

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