A SPM head incorporates a probe and a cantilever on which the probe is mounted. The cantilever has a planar reflecting surface proximate a free end of the cantilever. The cantilever extends from a mechanical mount and a single-mode optical fiber is supported by the mechanical mount to provide a beam. A micromirror is mounted to reflect the beam substantially 90° to the planar reflecting surface.

An apparatus and method of operating an atomic force profiler (AFP), such as an AFM, using a feedforward control signal in subsequent scan lines of a large area sample to achieve large throughput advantages in, for example, automated applications.

An apparatus and method of operating an atomic force profiler (AFP), such as an AFM, using a feedforward control signal in subsequent scan lines of a large area sample to achieve large throughput advantages in, for example, automated applications.

A method of detecting the positions of a plurality of probes. An input beam is directed into an optical device and transformed into a plurality of output beamlets which are not parallel with each other. Each output beamlet is split into a sensing beamlet and an associated reference beamlet. Each of the sensing beamlets is directed onto an associated one of the probes with an objective lens to generate a reflected beamlet which is combined with its associated reference beamlet to generate an interferogram. Each interferogram is measured to determine the position of an associated one of the probes. A similar method is used to actuate a plurality of probes. A scanning motion is generated between the probes and the sample. An input beam is directed into an optical device and transformed into a plurality of actuation beamlets which are not parallel with each other.

A method of detecting the positions of a plurality of probes. An input beam is directed into an optical device and transformed into a plurality of output beamlets which are not parallel with each other. Each output beamlet is split into a sensing beamlet and an associated reference beamlet. Each of the sensing beamlets is directed onto an associated one of the probes with an objective lens to generate a reflected beamlet which is combined with its associated reference beamlet to generate an interferogram. Each interferogram is measured to determine the position of an associated one of the probes. A similar method is used to actuate a plurality of probes. A scanning motion is generated between the probes and the sample. An input beam is directed into an optical device and transformed into a plurality of actuation beamlets which are not parallel with each other.

System and method for optical alignment of a near-field system, employing reiterative analysis of amplitude (irradiance) and phase maps of irradiated field obtained in back-scattered light while adjusting the system to arrive at field pattern indicative of and sensitive to a near-field optical wave produced by diffraction-limited irradiation of a tip of the near-field system. Demodulation of optical data representing such maps is carried out at different harmonics of probe-vibration frequency. Embodiments are operationally compatible with methodology of chemical nano-identification of sample utilizing normalized near-field spectroscopy, and may utilize suppression of background contribution to collected data based on judicious coordination of data acquisition with motion of the tip. Such coordination may be defined without knowledge of separation between the tip and sample. Computer program product with instructions effectuating the method and operation of the system.

System and method for optical alignment of a near-field system, employing reiterative analysis of amplitude (irradiance) and phase maps of irradiated field obtained in back-scattered light while adjusting the system to arrive at field pattern indicative of and sensitive to a near-field optical wave produced by diffraction-limited irradiation of a tip of the near-field system. Demodulation of optical data representing such maps is carried out at different harmonics of probe-vibration frequency. Embodiments are operationally compatible with methodology of chemical nano-identification of sample utilizing normalized near-field spectroscopy, and may utilize suppression of background contribution to collected data based on judicious coordination of data acquisition with motion of the tip. Such coordination may be defined without knowledge of separation between the tip and sample. Computer program product with instructions effectuating the method and operation of the system.

The present application relates to an apparatus for a scanning probe microscope, said apparatus having: (a) at least one first measuring probe having at least one first cantilever, the free end of which has a first measuring tip; (b) at least one first reflective area arranged in the region of the free end of the at least one first cantilever and embodied to reflect at least two light beams in different directions; and (c) at least two first interferometers embodied to use the at least two light beams reflected by the at least one first reflective area to determine the position of the first measuring tip.

The present application relates to an apparatus for a scanning probe microscope, said apparatus having: (a) at least one first measuring probe having at least one first cantilever, the free end of which has a first measuring tip; (b) at least one first reflective area arranged in the region of the free end of the at least one first cantilever and embodied to reflect at least two light beams in different directions; and (c) at least two first interferometers embodied to use the at least two light beams reflected by the at least one first reflective area to determine the position of the first measuring tip.

A cantilever has a probe at a tip end. An optical system emits laser light to the cantilever and detects the laser light reflected by the cantilever. A measurement unit measures characteristics of a sample based on a displacement of the cantilever obtained by a change in a position of the laser light detected by the optical system. The laser light adjustment unit adjusts, when adjusting the optical axis of the laser light, a spot diameter of the laser light to be larger than the spot diameter when measuring the characteristics of a sample. The imaging unit captures an image of a range including the position of the probe when adjusting the optical axis of the laser light. The display unit displays the captured image.