The present disclosure relates to a method of operating an SPM system including a landing procedure. The landing procedure comprises a first landing stage including a first translation over a first actuation distance by a coarse translation means to bring a probe tip held by an SPM head from an initial separation from a substrate to be probed to a second, more proximal, separation as defined by a characteristic transitional response of the probe tip in proximity to the substrate. Following the first stage a second translation is applied, over a second actuation distance by a fine translation means under feedback control to bring the probe tip to a working separation. Prior to applying the first (coarse) actuation distance an initial optical distance is determined which is indicative of the initial separation, using a detector, preferably a mark sensor. The measured initial optical distance is related to a reference distance so as to determine a deviation. The first actuation distance corresponds the reference distance and the deviation. The disclosure also relates to an SPM system and software product arranged to implement the landing method.

The present disclosure relates to a method of operating an SPM system including a landing procedure. The landing procedure comprises a first landing stage including a first translation over a first actuation distance by a coarse translation means to bring a probe tip held by an SPM head from an initial separation from a substrate to be probed to a second, more proximal, separation as defined by a characteristic transitional response of the probe tip in proximity to the substrate. Following the first stage a second translation is applied, over a second actuation distance by a fine translation means under feedback control to bring the probe tip to a working separation. Prior to applying the first (coarse) actuation distance an initial optical distance is determined which is indicative of the initial separation, using a detector, preferably a mark sensor. The measured initial optical distance is related to a reference distance so as to determine a deviation. The first actuation distance corresponds the reference distance and the deviation. The disclosure also relates to an SPM system and software product arranged to implement the landing method.

When a liquid surface is detected based on a detection signal from a photodetector during the approaching operation, a photodetector movement processor moves the photodetector to a position where reflected light from a cantilever is incident with the cantilever being in liquid. When the reflected light from the cantilever is incident on the photodetector during the approaching operation continued after the movement of the photodetector by the photodetector movement processor, an optical axis adjustment processor adjusts an optical axis of the reflected light incident on the photodetector. When a surface of a solid sample is detected based on a detection signal from the photodetector during the approaching operation continued after the adjustment of the optical axis by the optical axis adjustment processor, an approaching processor stops the approaching operation.

When a liquid surface is detected based on a detection signal from a photodetector during the approaching operation, a photodetector movement processor moves the photodetector to a position where reflected light from a cantilever is incident with the cantilever being in liquid. When the reflected light from the cantilever is incident on the photodetector during the approaching operation continued after the movement of the photodetector by the photodetector movement processor, an optical axis adjustment processor adjusts an optical axis of the reflected light incident on the photodetector. When a surface of a solid sample is detected based on a detection signal from the photodetector during the approaching operation continued after the adjustment of the optical axis by the optical axis adjustment processor, an approaching processor stops the approaching operation.

An apparatus and method of performing sample characterization with an AFM and a pulsed IR laser directed at the tip of a probe of the AFM. Gated laser pulsing and gated detection based on a lock-in amplifier, boxcar integrator or FFT may be employed in Peak force tapping operation. Nano-spectroscopic measurements with sub-20 nm, and even sub-10 nm resolution can be executed together with nano-mechanical and other property measurements.

An apparatus and method of performing sample characterization with an AFM and a pulsed IR laser directed at the tip of a probe of the AFM. Gated laser pulsing and gated detection based on a lock-in amplifier, boxcar integrator or FFT may be employed in Peak force tapping operation. Nano-spectroscopic measurements with sub-20 nm, and even sub-10 nm resolution can be executed together with nano-mechanical and other property measurements.

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.

The present invention relates to a cantilever or membrane comprising a body and an elongated beam attached to the body. The elongated beam includes a first layer comprising a first material, a second layer comprising a second material having an elastic modulus different to that of the first material, a third layer comprising a third material having an elastic modulus different to that of the first material, where the first layer is sandwiched between the second layer and the third layer.

The invention is directed at a fiducial marker design, a fiducial marker, a scanning probe microscopy device and a method of calibrating a position of a probe tip. The fiducial marker design may be used as a fiducial marker for providing a positioning reference, and comprises at least one first reference pattern including at least one first reference element for enabling determination of a relative position of the fiducial marker with respect to a first sensor. The first sensor is configured for operating at a first scale of dimension. The fiducial marker further comprises a second reference pattern, which comprises a regular arrangement of markings, structured or shaped such as to encode therein surface coordinate information. This enables determination of a relative position of each marking with respect to a second sensor configured for operating at a second scale of dimension smaller than the first scale of dimension.