Disclosed is a multipurpose scanning microscopy probe comprising a probe holder, a cantilever connected to the probe holder, and a probe tip connected to the cantilever, wherein the probe tip is a three-dimensional geometry, and wherein the probe tip is a 3D printed part. In some embodiments the probe is made from SU8 epoxy-based resin. In some embodiments the probe is made from a combination of SU8 and nanomaterial such as carbon nanotubes. In some embodiments the probe includes cavities and voids. In some embodies the probe includes fluidic features and elements. Scanning microscopy probe methods are also disclosed.

An article of manufacture includes a support structure including a cladding material and defining therein a plurality of substantially parallel cores. The article also includes a plurality of conically-shaped spikes protruding from a first side of the support structure. Each respective conically-shaped spike of the plurality of conically-shaped spikes includes a core material (i) extending through a corresponding core of the plurality of substantially parallel cores and (ii) comprising an axial protrusion that protrudes axially from the cladding material at the first side of the support structure. The axial protrusion of the core material is tapered to form the respective conically-shaped spike. The article also includes a refractory metal layer coating at least a portion of each respective conically-shaped spike and one or more electrodes connected to the refractory metal layer and configured to apply a voltage to the refractory metal layer.

An atomic force microscope has dual probes composed of a hinge structure, two cantilever beams and needle tips arranged on free ends of the cantilever beams. The hinge structure is a U-shaped body having two ends respectively extended with a first cantilever beam and a second cantilever beam. The free end of the first cantilever beam and the free end of the second cantilever beam are respectively provided with a first needle tip and a second needle tip. The integrated dual probes is operated by the driving function of the probe clamp. Therefore, only a set of motion control and measurement system of the atomic force microscope is required to realize the rapid in-situ switching function of the dual probes.

An atomic force microscope has dual probes composed of a hinge structure, two cantilever beams and needle tips arranged on free ends of the cantilever beams. The hinge structure is a U-shaped body having two ends respectively extended with a first cantilever beam and a second cantilever beam. The free end of the first cantilever beam and the free end of the second cantilever beam are respectively provided with a first needle tip and a second needle tip. The integrated dual probes is operated by the driving function of the probe clamp. Therefore, only a set of motion control and measurement system of the atomic force microscope is required to realize the rapid in-situ switching function of the dual probes.

The invention is directed to an arrangement for detecting the intensity distribution of components of the electromagnetic field in beams of radiation. The object of the invention is met, according to the invention, in that a high-resolution two-dimensional intensity sensor array and a field vector detector array comprising different regions with individual detector structures for two transverse and longitudinal field vector components E.sub.x, E.sub.y, E.sub.z are combined, wherein the detector structures are formed as nanostructures, metallic jacket-shaped tips with different apices, for utilization of localized plasmon resonance (LPR) of the individual detector structures and localized surface plasmons (LSP) excited through LPR for a polarization selection of the field distribution according to field vector components E.sub.x, E.sub.y, E.sub.z and transmission thereof to associated sensor elements by means of surface plasmon polaritons (SPP) and wave guiding (WGM).

The invention is directed to an arrangement for detecting the intensity distribution of components of the electromagnetic field in beams of radiation. The object of the invention is met, according to the invention, in that a high-resolution two-dimensional intensity sensor array and a field vector detector array comprising different regions with individual detector structures for two transverse and longitudinal field vector components E.sub.x, E.sub.y, E.sub.z are combined, wherein the detector structures are formed as nanostructures, metallic jacket-shaped tips with different apices, for utilization of localized plasmon resonance (LPR) of the individual detector structures and localized surface plasmons (LSP) excited through LPR for a polarization selection of the field distribution according to field vector components E.sub.x, E.sub.y, E.sub.z and transmission thereof to associated sensor elements by means of surface plasmon polaritons (SPP) and wave guiding (WGM).

Disclosed is a multipurpose scanning microscopy probe comprising a probe holder, a cantilever connected to the probe holder, and a probe tip connected to the cantilever, wherein the probe tip is a three-dimensional geometry, and wherein the probe tip is a 3D printed part. In some embodiments the probe is made from SU8 epoxy-based resin. In some embodiments the probe is made from a combination of SU8 and nanomaterial such as carbon nanotubes. In some embodiments the probe includes cavities and voids. In some embodies the probe includes fluidic features and elements. Scanning microscopy probe methods are also disclosed.

The present invention relates to methods and devices for extending a time period until changing a measuring tip of a scanning probe microscope. In particular, the invention relates to a method for hardening a measuring tip for a scanning probe microscope, comprising the step of: Processing the measuring tip with a beam of an energy beam source, the energy beam source being part of a scanning electron microscope.

A light emitting diode (LED) array is formed by bonding an LED substrate to a backplane substrate via fitted nanotube interconnects. The backplane substrate may include circuits for driving the LED array. The LED substrate may be a chip or wafer, and may include one or more LED devices. The LED substrate is positioned above the backplane substrate, such that a LED device of the LED substrate is aligned to a corresponding circuit in the backplane substrate. Each of the fitted interconnects electrically connect a LED device to the corresponding circuit of the backplane substrate.

The present invention relates to a method for examining a measuring tip of a scanning probe microscope, wherein the method includes the following steps: (a) generating at least one test structure before a sample is analyzed, or after said sample has been analyzed, by the measuring tip; and (b) examining the measuring tip with the aid of the at least one generated test structure.