Illustrative embodiments provide an apparatus comprising a substrate comprising a cantilever, a bottom electrode on the substrate, a bottom piezoelectric transducer on the bottom electrode such that the bottom electrode is between the substrate and the bottom piezoelectric transducer, a middle electrode on the bottom piezoelectric transducer such that the bottom piezoelectric transducer is between the bottom electrode and the middle electrode, a top piezoelectric transducer on the middle electrode such that the middle electrode is between the bottom piezoelectric transducer and the top piezoelectric transducer, and a top electrode on the top piezoelectric transducer, such that the top piezoelectric transducer is between the middle electrode and the top electrode. Illustrative embodiments also provide a method of making the apparatus and a method of using the apparatus for atomic force microscopy.

Illustrative embodiments provide an apparatus comprising a substrate comprising a cantilever, a bottom electrode on the substrate, a bottom piezoelectric transducer on the bottom electrode such that the bottom electrode is between the substrate and the bottom piezoelectric transducer, a middle electrode on the bottom piezoelectric transducer such that the bottom piezoelectric transducer is between the bottom electrode and the middle electrode, a top piezoelectric transducer on the middle electrode such that the middle electrode is between the bottom piezoelectric transducer and the top piezoelectric transducer, and a top electrode on the top piezoelectric transducer, such that the top piezoelectric transducer is between the middle electrode and the top electrode. Illustrative embodiments also provide a method of making the apparatus and a method of using the apparatus for atomic force microscopy.

Illustrative embodiments provide an apparatus comprising a substrate comprising a cantilever, a bottom electrode on the substrate, a bottom piezoelectric transducer on the bottom electrode such that the bottom electrode is between the substrate and the bottom piezoelectric transducer, a middle electrode on the bottom piezoelectric transducer such that the bottom piezoelectric transducer is between the bottom electrode and the middle electrode, a top piezoelectric transducer on the middle electrode such that the middle electrode is between the bottom piezoelectric transducer and the top piezoelectric transducer, and a top electrode on the top piezoelectric transducer, such that the top piezoelectric transducer is between the middle electrode and the top electrode. Illustrative embodiments also provide a method of making the apparatus and a method of using the apparatus for atomic force microscopy.

A method for commanding a tip of a probe is disclosed, wherein a command signal, representative of the force applied by said tip on the surface of a sample to be analyzed, includes at least one cycle successively defined by: a first step where the value of said command signal decreases from a maximum value (Smax) to a minimum value (Smin) so as to move said tip away from said surface at a predetermined distance called detachment height; a second step where the value of the command signal is maintained constant at said minimum value so as to maintain the tip at said detachment height; a third step where the value of the command signal increases from the minimum value up to said maximum value so as to bring the tip closer towards the surface to be analyzed until the tip comes into contact with the surface; and a fourth step where the value of the command signal is maintained constant at said maximum value to maintain the tip in contact with the surface to be analyzed under a constant force between the tip and the surface to be analyzed; the command signal being controlled between two successive steps to avoid any oscillation of the tip.

A method for commanding a tip of a probe is disclosed, wherein a command signal, representative of the force applied by said tip on the surface of a sample to be analyzed, includes at least one cycle successively defined by: a first step where the value of said command signal decreases from a maximum value (Smax) to a minimum value (Smin) so as to move said tip away from said surface at a predetermined distance called detachment height; a second step where the value of the command signal is maintained constant at said minimum value so as to maintain the tip at said detachment height; a third step where the value of the command signal increases from the minimum value up to said maximum value so as to bring the tip closer towards the surface to be analyzed until the tip comes into contact with the surface; and a fourth step where the value of the command signal is maintained constant at said maximum value to maintain the tip in contact with the surface to be analyzed under a constant force between the tip and the surface to be analyzed; the command signal being controlled between two successive steps to avoid any oscillation of the tip.

Device and system for characterizing samples using multiple integrated tips scanning probe microscopy. Multiple Integrated Tips (MiT) probes are comprised of two or more monolithically integrated and movable AFM tips positioned to within nm of each other, enabling unprecedented micro to nanoscale probing functionality in vacuum or ambient conditions. The tip structure is combined with capacitive comb structures offering laserless high-resolution electric-in electric-out actuation and sensing capability and novel integration with a Junction Field Effect Transistor for signal amplification and low-noise operation. This platform-on-a-chip approach is a paradigm shift relative to current technology based on single tips functionalized using stacks of supporting gear: lasers, nano-positioners and electronics.

A scanning probe microscope includes a case, an actuator, at least one elastic body, and a probe. The actuator includes a piezoelectric scanner having a cylindrical shape and a sample holder. The piezoelectric scanner is disposed inside the case to be coaxial with the case such that the first end is fixed to the bottom portion. The sample holder is provided at a second end of the piezoelectric scanner. At least one elastic body is disposed so as to be sandwiched between the case and at least one of the piezoelectric scanner and the sample holder.

A scanning probe microscope includes a case, an actuator, at least one elastic body, and a probe. The actuator includes a piezoelectric scanner having a cylindrical shape and a sample holder. The piezoelectric scanner is disposed inside the case to be coaxial with the case such that the first end is fixed to the bottom portion. The sample holder is provided at a second end of the piezoelectric scanner. At least one elastic body is disposed so as to be sandwiched between the case and at least one of the piezoelectric scanner and the sample holder.

An apparatus comprising: a void; an interferometer detector; and light guide means for guiding a light signal along a light path to the interferometer detector wherein the light path comprises a cantilever light guide that is supported such that a free-end can move within the void and the interferometer detector is configured to detect a deflection of the free-end of the cantilever light guide; and a reflector, wherein the cantilever light guide comprises a light outcoupler configured to out-couple the light signal to extend the light path from the cantilever light guide to the reflector.

When a liquid surface is detected based on a detection signal from a photodetector during the approaching operation, a photodetector movement processor moves the photodetector to a position where reflected light from a cantilever is incident with the cantilever being in liquid. When the reflected light from the cantilever is incident on the photodetector during the approaching operation continued after the movement of the photodetector by the photodetector movement processor, an optical axis adjustment processor adjusts an optical axis of the reflected light incident on the photodetector. When a surface of a solid sample is detected based on a detection signal from the photodetector during the approaching operation continued after the adjustment of the optical axis by the optical axis adjustment processor, an approaching processor stops the approaching operation.