An atomic-force-microscope-based apparatus and method including hardware and software, configured to collect, in a dynamic fashion, and analyze data representing mechanical properties of soft materials on a nanoscale, to map viscoelastic properties of a soft-material sample. The use of the apparatus as an addition to the existing atomic-force microscope device.

Active cantilever probes having a thin coating incorporated into their design are disclosed. The probes can be operated in opaque and/or chemically harsh environments without the need of a light source or optical system and without being significantly negatively impacted by corrosion. The probes include a substrate that has a cantilever, a thermomechanical actuator associated with the cantilever, a piezoresistive stress sensor disposed on the cantilever, and a thin coating disposed on the cantilever and the piezoresistive stress sensor. The coating is bonded to the substrate, is thermally conductive, and has a low thermal resistance. Further, the thin coating is configured to have little to no impact on one or more of a mass of the active probe, a residual stress of the cantilever, or a stiffness of the active probe. Techniques for performing topography and making other measurements in an opaque and/or chemically harsh environment are also provided.

Active cantilever probes having a thin coating incorporated into their design are disclosed. The probes can be operated in opaque and/or chemically harsh environments without the need of a light source or optical system and without being significantly negatively impacted by corrosion. The probes include a substrate that has a cantilever, a thermomechanical actuator associated with the cantilever, a piezoresistive stress sensor disposed on the cantilever, and a thin coating disposed on the cantilever and the piezoresistive stress sensor. The coating is bonded to the substrate, is thermally conductive, and has a low thermal resistance. Further, the thin coating is configured to have little to no impact on one or more of a mass of the active probe, a residual stress of the cantilever, or a stiffness of the active probe. Techniques for performing topography and making other measurements in an opaque and/or chemically harsh environment are also provided.

A sensor device includes a carrier, a force feedback sensor, and a probe containing a spin defect, the probe being connected to the force feedback sensor either directly or indirectly via a handle structure. In order to couple the spin defect to a microwave field in an efficient and robust manner, the sensor device includes an integrated microwave antenna arranged at a distance of less than 500 micrometers from the spin defect. The sensor device can be configured as a self-contained exchangeable cartridge that can easily be mounted in a sensor mount of a scanning probe microscope.

A sensor device includes a carrier, a force feedback sensor, and a probe containing a spin defect, the probe being connected to the force feedback sensor either directly or indirectly via a handle structure. In order to couple the spin defect to a microwave field in an efficient and robust manner, the sensor device includes an integrated microwave antenna arranged at a distance of less than 500 micrometers from the spin defect. The sensor device can be configured as a self-contained exchangeable cartridge that can easily be mounted in a sensor mount of a scanning probe microscope.

An atomic-force-microscope-based apparatus and method including hardware and software, configured to collect, in a dynamic fashion, and analyze data representing mechanical properties of soft materials on a nanoscale, to map viscoelastic properties of a soft-material sample. The use of the apparatus as an addition to the existing atomic-force microscope device.

An atomic-force-microscope-based apparatus and method including hardware and software, configured to collect, in a dynamic fashion, and analyze data representing mechanical properties of soft materials on a nanoscale, to map viscoelastic properties of a soft-material sample. The use of the apparatus as an addition to the existing atomic-force microscope device.

A micromechanical sensor includes a movable micromechanical element and an optical resonator of disk or ring type, wherein the optical resonator has at least one interruption; and in that the movable micromechanical element is mechanically coupled to the optical resonator in such a way that a movement of the movable micromechanical element induces a modification of the width of the interruption of the optical resonator by moving at least one edge of the interruption in a direction substantially parallel to a direction of propagation of the light in the resonator at the interruption.

A micromechanical sensor includes a movable micromechanical element and an optical resonator of disk or ring type, wherein the optical resonator has at least one interruption; and in that the movable micromechanical element is mechanically coupled to the optical resonator in such a way that a movement of the movable micromechanical element induces a modification of the width of the interruption of the optical resonator by moving at least one edge of the interruption in a direction substantially parallel to a direction of propagation of the light in the resonator at the interruption.

An atomic-force-microscope-based apparatus and method including hardware and software, configured to collect, in a dynamic fashion, and analyze data representing mechanical properties of soft materials on a nanoscale, to map viscoelastic properties of a soft-material sample. The use of the apparatus as an addition to the existing atomic-force microscope device.