A near-field scanning probe includes: a measurement probe that relatively scans a test sample; an excitation light irradiation system; a near-field light generation system that generates near-field light in a region including the measurement probe in response to irradiation with excitation light from the excitation light irradiation system; and a scattered light detection system that detects Rayleigh scattering and Ramen scattered light of the near-field light from the sample, generated between the measurement probe and the sample, and the near-field scanning probe is characterized in that the near-field light generation system includes a cantilever with a chip coated with a noble metal, and a tip of the chip is provided with a thin wire group including a plurality of carbon nanowires with a noble metal provided at ends thereof.

A debris collection and metrology system for collecting and analyzing debris from a tip used in nanomachining processes, the system including an irradiation source, an irradiation detector, an actuator, and a controller. The irradiation source is operable to direct incident irradiation onto the tip, and the irradiation detector is operable to receive a sample irradiation from the tip, the sample irradiation being generated as a result of the direct incident irradiation being applied onto the tip. The controller is operatively coupled to an actuator system and the irradiation detector, and the controller is operable to receive a first signal based on a first response of the irradiation detector to the sample irradiation, and the controller is operable to effect relative motion between the tip and at least one of the irradiation source and the irradiation detector based on the first signal.

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.

Provided is a composite metal-wide-bandgap semiconductor tip for scanning tunneling microscopy and/or scanning tunneling lithography, a method of forming, and a method for using the composite metal-wide-bandgap semiconductor tip.

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.

The present invention provides a cantilever for a scanning type probe microscope, the cantilever including a support portion, a lever portion extending from the support portion, a protrusion portion formed on a free end side of the lever portion, an apex angle of the protrusion portion being an acute angle, and a probe in which a fine wire formed at a distal end of the protrusion portion is coated with a functional film, and a major axis/minor axis ratio of a cross-sectional shape of the probe is smaller than a major axis/minor axis ratio of a cross-sectional shape of the fine wire.

Provided is a composite metal-wide-bandgap semiconductor tip for scanning tunneling microscopy and/or scanning tunneling lithography, a method of forming, and a method for using the composite metal-wide-bandgap semiconductor tip.

A laser and a minimally invasive dental surgical procedure using the laser to stimulate periodontal tissue formation.

A scanning probe microscope includes a cantilever that has a first attachment surface and a cantilever attachment portion that has a second attachment surface to which the first attachment surface of the cantilever is attached. Columnar elements including nanofibers or nanotubes are formed on the second attachment surface, and the second attachment surface adheres to the first attachment surface by using the columnar element.

The present invention relates to a biomolecular measurement system (1), which enables to measure the intermolecular forces arising from the interaction between two biomolecules or the intramolecular forces within a single biomolecule by using an atomic force microscope (AFM). In the present invention, the cantilever (2) is moved only when the actuator (4) moves the magnetic nanowire (3) and thus moves the molecule attached to the end of the magnetic nanowire (3). Since the cantilever (2) is not moved, fluctuation and disturbance is not created in the liquid containing the biomolecules. Thus, the measurements are made more accurately and with higher resolution. Additionally, by means of the actuator (4), the biomolecules are enabled to be moved upon exertion of magnetic force at any coordinate on x, y and z axes on the nanowire (3), or exertion of torque on two axes.