A method for generating a high-intensity light source at a probe tip, the method includes exciting a TM.sub.0 mode of a surface plasmon polariton (SPP) in a sharp-tip metal nanowire (AgNW) waveguide with a linearly-polarized mode (LP.sub.01) in a tapered optical fiber (OF); and compressing the TM.sub.0 mode through a chemically-sharpened taper to a tip apex of the sharp-tip silver nanowire (AgNW).

Example embodiments relate to methods for producing a probe suitable for scanning probe microscopy. One embodiment includes a method for producing a probe tip suitable for scanning probe microscopy. The method includes producing a probe tip body that includes at least an outer layer of a probe material. The method also includes, during the production of the probe tip body or after the production, forming a mask layer on the outer layer of probe material. Further, the method includes subjecting the probe tip body to a plasma etch procedure. The mask layer acts as an etch mask for the plasma etch procedure. The plasma etch procedure and the etch mask are configured to produce one or more tip portions formed of the probe material. The one or more tip portions are smaller and more pointed than the probe tip body prior to the plasma etch procedure.

A numerically controlled rotary probe switching device based on an environment-controllable atomic force microscope (AFM) includes a cavity upper cover and a probe switching structure. The cavity upper cover is provided with an irregular rectangular boss, an inner groove, a rectangular optical window structure and a sealing flange structure. The irregular rectangular boss is provided with the rectangular optical window structure; a front end of the boss is provided with the sealing flange structure; and a lower portion of the boss is provided with an inner groove for accommodating the probe switching structure and a transition groove for matching with a linear movement of a sample carrier and a rotary switching of probes. The probe switching structure is configured inside the inner groove, and the probe switching structure is provided with at least one probe assembly.

A numerically controlled rotary probe switching device based on an environment-controllable atomic force microscope (AFM) includes a cavity upper cover and a probe switching structure. The cavity upper cover is provided with an irregular rectangular boss, an inner groove, a rectangular optical window structure and a sealing flange structure. The irregular rectangular boss is provided with the rectangular optical window structure; a front end of the boss is provided with the sealing flange structure; and a lower portion of the boss is provided with an inner groove for accommodating the probe switching structure and a transition groove for matching with a linear movement of a sample carrier and a rotary switching of probes. The probe switching structure is configured inside the inner groove, and the probe switching structure is provided with at least one probe assembly.

A numerically controlled rotary probe switching device based on an environment-controllable atomic force microscope (AFM) includes a cavity upper cover and a probe switching structure. The cavity upper cover is provided with an irregular rectangular boss, an inner groove, a rectangular optical window structure and a sealing flange structure. The irregular rectangular boss is provided with the rectangular optical window structure; a front end of the boss is provided with the sealing flange structure; and a lower portion of the boss is provided with an inner groove for accommodating the probe switching structure and a transition groove for matching with a linear movement of a sample carrier and a rotary switching of probes. The probe switching structure is configured inside the inner groove, and the probe switching structure is provided with at least one probe assembly.

A numerically controlled rotary probe switching device based on an environment-controllable atomic force microscope (AFM) includes a cavity upper cover and a probe switching structure. The cavity upper cover is provided with an irregular rectangular boss, an inner groove, a rectangular optical window structure and a sealing flange structure. The irregular rectangular boss is provided with the rectangular optical window structure; a front end of the boss is provided with the sealing flange structure; and a lower portion of the boss is provided with an inner groove for accommodating the probe switching structure and a transition groove for matching with a linear movement of a sample carrier and a rotary switching of probes. The probe switching structure is configured inside the inner groove, and the probe switching structure is provided with at least one probe assembly.

The present invention relates to a device for measuring and/or modifying a surface of a sample, including a sample holder, including a first area configured to receive the sample fixedly mounted relative to the first area, a support, a first probe configured to detect a first parameter at a point of the surface and to generate a first measurement signal representative of the first parameter, and a second probe configured to detect a second parameter at a point of the surface, and to generate a second measurement signal representative of the second parameter, the first parameter being different from the second parameter, or one of the first probe and the second probe being configured to modify a third parameter of the surface at the point of the surface.

A polymeric micro-arm apparatus and method to use the same. The apparatus comprises of an elongated hollow polymeric structure with a distal end and a proximal end, an opening near the distal end, a main body attached to the polymeric structure means to move the polymeric structure, means to generate fluid flow through the opening, means to measure a flowrate of the fluid flow through the opening; and an element embedded in the polymeric structure, wherein the element is configured to detect when the polymeric structure contacts an object and measures the force that the object exerts upon the polymeric structure.

A polymeric micro-arm apparatus and method to use the same. The apparatus comprises of an elongated hollow polymeric structure with a distal end and a proximal end, an opening near the distal end, a main body attached to the polymeric structure means to move the polymeric structure, means to generate fluid flow through the opening, means to measure a flowrate of the fluid flow through the opening; and an element embedded in the polymeric structure, wherein the element is configured to detect when the polymeric structure contacts an object and measures the force that the object exerts upon the polymeric structure.

A method for interrogating a surface of a sample bathed in electrolyte solution using SICM, comprising: controlling the potential between first and second electrodes bathed in the electrolyte solution to induce an ion current in the electrolyte solution, a submerged portion of the first electrode being contained within a micropipette and the second electrode being external to the micropipette; recording the ion current whilst controlling the micropipette to move with respect to a stage supporting the sample; and determining, from the ion current and calibration data, the surface height profile of the sample. Said potential can be controlled according to a spread spectrum modulated signal. Said micropipette motion can be according to an AC mode pattern having a modulation frequency greater than a resonant frequency of an assembly of the micropipette, first electrode and a first piezoelectric actuator configured to control z-axis motion of said micropipette.