Cantilevers, SPM tips and nanomachining tools are created in the plane of wafers to obtain new and high performance parts. The method produces more parts for any given wafer, then conventional methods and allows every part on any given wafer to be different from any other, permitting great freedom in new SPM and nanomachining techniques and product development.

A microfabricated optical probe includes: a cantilever; an optical waveguide disposed at a periphery of the cantilever and including an optical loop, the optical loop being disposed coplanar with the cantilever; a mechanical support interposed between and interconnecting the cantilever and the optical waveguide with the mechanical support such that the cantilever and optical waveguide move together; and a substrate on which the cantilever is disposed and from which the cantilever and the optical loop protrude, wherein the cantilever and the optical waveguide flex independently of the substrate.

An optomechanical force sensor includes a substrate, a cantilevered beam anchored to the substrate, and a probe tip positioned near an end of the cantilevered beam distal to the substrate. A suspended waveguide is disposed on the cantilevered beam and is optically continuous with an input/output waveguiding structure. An optical cavity is defined within the suspended waveguide.

A probe for atomic force microscopy comprises a tip for atomic force microscopy oriented in a direction referred to as the longitudinal direction and protrudes from an edge of a substrate in the longitudinal direction, wherein the tip is arranged at one end of a shuttle attached to the substrate at least via a first and via a second structure, which structures are referred to as support structures, at least the first support structure being a flexible structure, extending in a direction referred to as the transverse direction, perpendicular to the longitudinal direction and anchored to the substrate by at least one mechanical linkage in the transverse direction, the support structures being suitable for allowing the shuttle to be displaced in the longitudinal direction. An atomic force microscope comprising at least one such probe is also provided.

A probe for atomic force microscopy comprises a tip for atomic force microscopy oriented in a direction referred to as the longitudinal direction and protrudes from an edge of a substrate in the longitudinal direction, wherein the tip is arranged at one end of a shuttle attached to the substrate at least via a first and via a second structure, which structures are referred to as support structures, at least the first support structure being a flexible structure, extending in a direction referred to as the transverse direction, perpendicular to the longitudinal direction and anchored to the substrate by at least one mechanical linkage in the transverse direction, the support structures being suitable for allowing the shuttle to be displaced in the longitudinal direction. An atomic force microscope comprising at least one such probe is also provided.

A method for aligning a first article relative to a second article. The second article is provided with at least one flexible structure fixed to the second article at one point while the first article includes at least one surface relief marking. A detector measures the interaction between the flexible structure and surface relief marking and generates detector signals relative to that interaction to achieve alignment between the first and second articles.

A method for aligning a first article relative to a second article. The second article is provided with at least one flexible structure fixed to the second article at one point while the first article includes at least one surface relief marking. A detector measures the interaction between the flexible structure and surface relief marking and generates detector signals relative to that interaction to achieve alignment between the first and second articles.

A photonic probe for atomic force microscopy includes: a cantilever including: a tip; a wing in mechanical communication with the tip; an extension interposed between the tip and the wing to synchronously communicate motion of the tip with the wing; an optical resonator disposed proximate to the cantilever and that: receives input light; and produces output light, such that: the cantilever is spaced by a gap distance from the optical resonator, wherein the gap distance varies as the cantilever moves relative to the optical resonator, and the output light differs from the input light in response to movement of the cantilever relative to the optical resonator; an optical waveguide in optical communication with the optical resonator and that: provides the input light to the optical resonator; and receives the output light from the optical resonator.

Methods and apparatuses are provided for automatically controlling and stabilizing aspects of a scanning probe microscope (SPM), such as an atomic force microscope (AFM), using Peak Force Tapping (PFT) Mode. In an embodiment, a controller automatically controls periodic motion of a probe relative to a sample in response to a substantially instantaneous force determined and automatically controls a gain in a feedback loop. A gain control circuit automatically tunes a gain based on separation distances between a probe and a sample to facilitate stability. Accordingly, instability onset is quickly and accurately determined during scanning, thereby eliminating the need of expert user tuning of gains during operation.

Methods and apparatuses are provided for automatically controlling and stabilizing aspects of a scanning probe microscope (SPM), such as an atomic force microscope (AFM), using Peak Force Tapping (PFT) Mode. In an embodiment, a controller automatically controls periodic motion of a probe relative to a sample in response to a substantially instantaneous force determined and automatically controls a gain in a feedback loop. A gain control circuit automatically tunes a gain based on separation distances between a probe and a sample to facilitate stability. Accordingly, instability onset is quickly and accurately determined during scanning, thereby eliminating the need of expert user tuning of gains during operation.