A large radius probe for a surface analysis instrument such as an atomic force microscope (AFM). The probe is microfabricated to have a tip with a hemispherical distal end or apex. The radius of the apex is the range of about a micron making the probes particularly useful for nanoindentation analyses. The processes of the preferred embodiments allow such large radius probes to be batch fabricated to facilitate cost and robustness.

A probe assembly is provided, which is applied to an electrical testing device. The probe assembly includes a probe body, which includes a testing end configured to contact with a to-be-tested device and a connection end opposite to the testing end; an elastic connection structure configured to be deformed when the probe body is subjected to a pressure; and a fixing base. The connection end is fixedly connected to the fixing base via the elastic connection structure. A testing device is further provided.

A probe assembly is provided, which is applied to an electrical testing device. The probe assembly includes a probe body, which includes a testing end configured to contact with a to-be-tested device and a connection end opposite to the testing end; an elastic connection structure configured to be deformed when the probe body is subjected to a pressure; and a fixing base. The connection end is fixedly connected to the fixing base via the elastic connection structure. A testing device is further provided.

A method for designing and processing a microcantilever-based probe with an irregular cross section applied in the ultra-low friction coefficient measurement at a nanoscale single-point contact includes: first, establishing a universal theoretical model of the friction coefficient measurement; then, combined with the structural features of the microcantilever-based probe with the irregular cross section, establishing a specific theoretical model of the friction coefficient measurement suitable for the microcantilever-based probe with the irregular cross section; and based on above, combined with constraint conditions such as the friction coefficient resolution, the loadable maximum positive pressure or the measurable minimum friction force, and the atomic force microscope characteristics, etc., designing the microcantilever-based probe with the irregular cross section meeting the measurement requirements.

A method for designing and processing a microcantilever-based probe with an irregular cross section applied in the ultra-low friction coefficient measurement at a nanoscale single-point contact includes: first, establishing a universal theoretical model of the friction coefficient measurement; then, combined with the structural features of the microcantilever-based probe with the irregular cross section, establishing a specific theoretical model of the friction coefficient measurement suitable for the microcantilever-based probe with the irregular cross section; and based on above, combined with constraint conditions such as the friction coefficient resolution, the loadable maximum positive pressure or the measurable minimum friction force, and the atomic force microscope characteristics, etc., designing the microcantilever-based probe with the irregular cross section meeting the measurement requirements.

The present disclosure provides a tip-enhanced Raman spectroscope system. The system includes a laser emitting unit, a laser excitation unit, a first dichroic beam splitter, a first Raman spectrometer, and a confocal detecting unit. The laser excitation unit includes a sample stage and a first scanning probe. The sample stage is configured to have a sample disposed thereon such that a first incident laser beam emitted from the laser emitting unit is transmitted to the sample to excite first scattered light. The first dichroic beam splitter is configured to split a first Raman scattered light from the first Rayleigh scattered light. The first Raman spectrometer is disposed on a first Raman optical path of the first Raman scattered light. The confocal detecting unit is disposed on a first Rayleigh optical path of the first Rayleigh scattered light to image the sample.

The present disclosure provides a scanning probe, a method and an apparatus for manufacturing the scanning probe. The scanning probe includes a base and a micro-tip disposed on an end of the base, wherein at least a section of the micro-tip comprises a lateral surface with a concavely curved generatrix. In the method, an end of a probe precursor is immersed in a corrosive solution by having a length direction of the probe precursor inclined with a liquid surface of the corrosive solution. The probe precursor is corroded by the corrosive solution while a corrosion current of the corroding is monitored. The probe precursor is moved away from the corrosive solution after a magnitude of the corrosion current has a plunge. The apparatus includes a container containing the corrosive solution, and a driving device configured to move the probe precursor in the container through a fastener.

A cantilever used in a scanning probe microscope includes a supporting section, a lever section, and a protrusion section, which is a probe. A crystalline carbon composite layer including a crystalline carbon nanomaterial and a metal material, a melting point of which is 420 C. or lower, is deposited on a distal end portion of the protrusion section.

A cantilever used in a scanning probe microscope includes a supporting section, a lever section, and a protrusion section, which is a probe. A crystalline carbon composite layer including a crystalline carbon nanomaterial and a metal material, a melting point of which is 420 C. or lower, is deposited on a distal end portion of the protrusion section.

The invention relates to a measuring device for a scanning probe microscope including a measuring probe a first probe holding device on which the measuring probe is arranged, a detection device including a measurement light source which is adapted to provide light beams directed toward the measuring probe, a sensor device which is adapted, during the operation to receive measurement light beams reflected from the measuring probe. A first measuring arrangement in which the first probe holding device with the measuring probe is arranged in a first position spaced from the detection device, and a second measuring arrangement is formed in which a lengthening device is changeably arranged between the detection device and the measuring probe which lengthens the respective optical beam path for the light beams and the measurement light beams in such a manner that the first probe holding device or a second probe holding device which is different from the first probe holding device is arranged with the measuring probe at a second position spacing from the detection device which is greater than the first position spacing.