Abstract: A method and apparatus for its practice are provided of differentiating at least one component of a heterogeneous sample from other component(s) using harmonic resonance imaging and of obtaining information regarding the sample from the differentiation. In a preferred embodiment, an image is created of a property of a harmonic or a combination of a harmonics producing a response having a contrast factor between the sample's constituent components. The desired harmonic(s) can be identified either in a preliminary data acquisition procedure on the sample or, if the sample's constituent components are known in advance, predetermined. The desired harnonic(s) may be identified directly by the user or automatically through, e.g., pattern recognition. A compositional map may then be generated and displayed and/or additional information about the sample may be obtained.

Abstract: The invention relates to a near-field antenna comprising a dielectric shaped body having a tip. The shaped body is characterized in that at least the surface of the tip is metallized, thereby enhancing the sensitivity of devices comprising the near-field antenna, for example, spectroscopes, microscopes or read-write heads.

Abstract: A surface position measuring method capable of measuring a position on a soft surface accurately and rapidly (real time), with low invasiveness. The method comprises the steps of measuring the spectrum of thermal oscillation of a cantilever with the distance between a cantilever tip and a sample surface being changed, extracting a fundamental mode component (spectrum area) from the obtained spectrum of thermal oscillation, and measuring a change in the spectrum area of thermal oscillation (spectrum area) with respect to the distance. A position at which the area of the cantilever thermal oscillation spectrum begins to change is evaluated as a position on the sample surface.

Abstract: A scanning probe microscope assembly that has an atomic force measurement (AFM) mode, a scanning tunneling measurement (STM) mode, a near-field spectrophotometry mode, a near-field optical mode, and a hardness testing mode for examining an object.

Abstract: An inching mechanism for a scanning probe microscope capable of performing measurement with high precision while enhancing the scanning speed by a probe furthermore, and a scanning probe microscope comprising it. The inching mechanism for a scanning probe microscope which is provided in a scanning probe microscope (SPM) (1) having a stage (16) for mounting a sample S, and a probe (20) approaching closely to or touching the surface of the sample S, characterized in that the inching mechanism comprises a first drive section and a second drive section provided independently, a probe inching mechanism (26) having the first drive section and inching, by the first drive section, the probe (20) in the X direction and Y direction parallel with the surface of the sample S and intersecting each other, and a stage inching mechanism (27) having the second drive section and inching, by the second drive section, the stage (16) in the Z direction perpendicular to the surface of the sample S.

Abstract: A displacement detection mechanism for a scanning probe microscope capable of performing measurement quickly with high precision even if an objective lens or an illumination system is arranged above or below a sample or a cantilever, and a scanning probe microscope comprising it.

Abstract: The invention relates to scanning magnetic microscope which has a photoluminescent nanoprobe implanted in the tip apex of an atomic force microscope (AFM), a scanning tunneling microscope (STM) or a near-field scanning optical microscope (NSOM) and exhibits optically detected magnetic resonance (ODMR) in the vicinity of impaired electron spins or nuclear magnetic moments in the sample material. The described spin microscope has demonstrated nanoscale lateral resolution and single spin sensitivity for the AFM and STM embodiments.

Abstract: A carbon nanotube detection system is disclosed. The detection system is suitable to detect carbon nanotube vibrations. Types of detection systems include but are not limited to: magnetic coupling to a magnetic particle attached at the distal end of the nanotube oscillator, current readout from the nanotube oscillator that has been exposed to electromagnetic radiation or a stress, inductive pick-up coil and corresponding tank circuit, capacitive readout element positioned next to the nanotube oscillator having a charged particle attached at its distal end, an optical beam illumination and detection of its scattering, or combination of any of the above means of detection.

Abstract: A scanner which includes a gradient index lens for passing and focusing beams from a radiation emitter to a cantilevered member reflective surface of a probe and from the reflective surface to a radiation detector. The lens also serves as a mechanical support for attachment of the radiation emitter and the radiation detector and is also attached to a support for the cantilevered member. The resulting fixed positions of the radiation emitter and the radiation detector relative to the reflective cantilevered member surface allows the scanner to be compact and factory focally alignable.

Abstract: A cantilever probe-based instrument is controlled to reduce the lateral loads imposed on the probe as a result of probe/sample interaction. In a preferred embodiment, the probe tip and/or sample are driven to move laterally relative to one another as a function of cantilever deflection in order to compensate for lateral tip motion that would otherwise be caused by cantilever deflection. In the case of a probe having a passive cantilever, the sample and/or the probe as a whole are driven to move laterally to obtain the desired magnitude of compensation as direct function of cantilever deflection. In the case of a probe having an active cantilever, the sample or probe may be moved as a function of cantilever drive signal, or the cantilever may be controlled to bend as a function of cantilever drive signal so that the tip moves to obtain the desired magnitude of compensation.

Abstract: The invention relates to scanning magnetic microscope which has a photoluminescent nanoprobe implanted in the tip apex of an atomic force microscope (AFM), a scanning tunneling microscope (STM) or a near-field scanning optical microscope (NSOM) and exhibits optically detected magnetic resonance (ODMR) in the vicinity of unpaired electron spins or nuclear magnetic moments in the sample material. The described spin microscope has demonstrated nanoscale lateral resolution and single spin sensitivity for the AFM and STM embodiments.

Abstract: In accordance with the invention, an estimator is used in the controller portion of a scanning probe microscope to provide precise position estimates of the probe tip which is controlled in the vertical direction by a microelectromechanical system (MEMS) actuator. The precise position estimates typically enhance the ability of the scanning probe microscope to follow the surface and typically provide improved measurements of the surface topography.

Abstract: There is provided a scanning probe microscope apparatus which has a high sensitivity for the interaction between the cantilever and the sample and comprises a cantilever that can oscillate stably in dynamic mode even when a mechanical Q value is low. A driving signal having a frequency close to the resonant frequency of the cantilever (4) is supplied from the signal generator (9) to the oscillation exciting means (10) to separately (forcibly) oscillate the cantilever (4). And the frequency of the driving signal or the resonant frequency of the cantilever is controlled (by adjusting the distance between the cantilever (4) and the sample (1)), such that the phase difference between the oscillation of the cantilever (4) detected by the oscillation detecting means (5) and the driving signal becomes zero, i.e. the frequency of the driving signal and the resonant frequency of the cantilever (4) match.

Abstract: A vibration-type cantilever holder holds a cantilever opposed to a sample. The holder supports a main body part of the cantilever at only its base end so that a probe at the free end of the cantilever can contact the sample. The holder has a cantilever-attaching stand on which the main body part is placed and fastened such that the cantilever is tilted at a predetermined angle with respect to the sample. A first vibration source is fastened to the cantilever-attaching stand and vibrates with a phase and an amplitude depending on a predetermined waveform signal, and the first vibration source is fastened at a first location to a holder main body. A second vibration source is fastened at a second location, which is spaced from the first location, to the holder main body and generates vibrations to offset vibrations traveling from the first vibration source to the cantilever-attaching stand and holder main body.

Abstract: An apparatus and technique for extracting information carried in higher eigenmodes or harmonics of an oscillating cantilever or other oscillating sensors in atomic force microscopy and related MEMs work is described.

Abstract: A displacement detector capable of making a measurement in two directions of measurement 180 degrees different from each other without the need of a switching operation has been disclosed.

Abstract: A probe for an atomic force microscope is adapted such that, as a sample is scanned, it experiences a biasing force urging the probe towards the sample. This improves probe tracking of the sample surface and faster scans are possible. This is achieved by either including a biasing element, which is responsive to an externally applied force, on the probe and/or reducing the quality factor of a supporting beam. This biasing element may, for example, be a magnet or an electrically-conducting element. The quality factor may be reduced by coating the beam with a mechanical-energy dissipating material.

Abstract: A cantilever probe-based instrument is controlled to counteract the lateral loads imposed on the probe as a result of probe sample interaction. The probe preferably includes an active cantilever, such as a so-called bimorph cantilever. Force counteraction is preferably achieved by monitoring a lateral force-dependent property of probe operation such as cantilever free end deflection angle and applying a voltage to at least one of the cantilever and one or more separate actuators under feedback to maintain that property constant as the probe-sample spacing decreases. The probe could further uses at least one of contact flexural and torsional resonances characteristics to determine contact and release points. With the knowledge of the tip profile, quantitative mechanical data for probe sample interaction can be obtained.

Abstract: A spin-torque probe microscope and methods of using the same are described. The spin-torque probe microscope includes a cantilever probe body, a magnetic tip disposed at a distal end of the cantilever probe body, an electrically conductive sample disposed proximate to the magnetic tip, an electrical circuit providing a spin-polarized electron current to the electrically conductive sample, and a vibration detection element configured to sense vibration frequency of the cantilever probe body. The spin-polarized electron current is sufficient to alter a local electron spin or magnetic moment within the electrically conductive sample and be sensed by the magnetic tip.

Abstract: Exchanging data between an Atomic Force Microscopy (AFM) measuring device and an external controlling device using a wireless link. The wireless link replaces cables leading to the AFM measuring device and thereby mitigates mechanical noise vibrations. The controlling device can be an AFM controller, a PC workstation, a keyboard or a pointing device. A power supply and cables to provide power to the measuring device can be replaced with a battery power source to further mitigate mechanical noise. The AFM measuring device can reside in a vibration isolation chamber along with the power source and AFM controller to further isolate noise.

Abstract: An optical-encoded force sensor is disclosed. The optical-encoded force sensor includes a cantilever probe having a probe tip, a set of reflective phase gratings and multiple nano-photonic displacement sensors. The reflective phase gratings are mechanically coupled to the cantilever probe, and the nano-photonic displacement sensors are mechanically coupled to the reflective phase gratings. In response to a load being applied to the probe tip, the reflective phase gratings can be compressed such that a diffraction order of the reflective phase gratings changes according to the force of the applied load.

Abstract: A rough road detection system includes an engine speed module, a feature space module, a normalization module, and a rough road module. The engine speed module generates an engine speed signal based on a crank signal. The feature space module generates a feature space signal based on the engine speed signal. The normalization module generates a normalized signal. The normalized signal is based on the feature space signal and a normalization value that varies in accordance with the engine speed signal. The rough road module determines whether a rough road condition exists based on the normalized signal.

Abstract: A surface shape of a member to be measured is measured by reflecting measuring light at a reflection surface of a probe and utilizing an atomic force exerting between the probe and utilizing an atomic force exerting between the probe and the member to be measured. In addition to a first scanner for driving the probe, a second scanner for moving a focus position of an optical system is provided. Position conversion data representing a correlation between amounts of control of the first scanner and the second scanner are obtained in advance. By synchronously driving the first scanner and the second scanner, the focus position of the optical system is caused to follow the probe to improve measurement accuracy.

Abstract: Dynamic nanomechanical analysis of a sample is performed by using a cantilever probe that interacts with the sample using a force applied across a wide range of frequencies that includes frequencies greater than 300 Hz. The motion of the cantilever probe is detected in response to the applied force over the range of frequencies and analyzed over at least a portion of the wide range of frequencies to determine a mechanical response of the sample, preferably including quality factor and modulus of the sample. The analysis of the motion of the cantilever probe is preferably performed in terms of amplitude, phase, and frequency of both the probe and the sample and preferably, where the applied force is analyzed to determine both a real and an imaginary modulus of a mechanical response of the sample. Preferably, the force is applied so as to produce a minimum of phase and amplitude response variation in the absence of the sample.

Abstract: A surface texture measuring probe (60) includes a probe head (65), a first supporting body (61), a second supporting body (62), a piezoelectric element (63) and a balancer (64). The first supporting body includes a first supporter (611) having an inner space, and a plurality of beams (613) respectively extending from equiangular arrangement positions of the first supporter toward the center and supporting the probe head (65) at the tip end thereof. The second supporting body (62) includes a second supporter (621) and a holder (622) supported by a plurality of beams (623) respectively extending from equiangular arrangement positions of the second supporter towards the center. The piezoelectric element (63) is disposed between the probe head and the holder, and formed to vibrate in an axial direction.

Abstract: A scanning probe microscope system comprising a hollow probe 3, a tube 4 connected to a rear end 32 of the hollow probe 3, a support table 1 provided under the hollow probe 3, and a substrate 2 and a means 5 for washing the hollow probe 3 that are fixed to the support table 1, a sample S passing through the tube 4 and the hollow probe 3, and the substrate 2 and the washing means 5 being moved by the support table 1 such that each of them opposes the hollow probe 3.

Abstract: A scanning probe microscope's probe tip dimensions as they exist or existed for a certain data or measurement are inferred based on probe activity taking place since a probe characterization procedure was performed. The inferred probe tip dimensions can be used to correct nanoscale measurements taken by the probe to account for changes in the probe's geometry such as wear.

Abstract: A method of operating a scanning probe microscope includes using a probe having a cantilever, and oscillating the probe at a torsional resonance frequency thereof. In addition, the method includes substantially increasing torsional drive efficiency with dual actuators disposed on the probe or the probe base. First and second actuators may be driven by corresponding first and second drive signals, the first and second drive signals being about 180° out of phase. The maximizing step includes altering at least one of the amplitudes of the first and second drive signals to maximize torsional oscillation. Torsional and flexural oscillation of the cantilever probe can be excited concurrently, sequentially or independently by adjusting the phase of the corresponding drive signals. A pair of cantilever components can be used to form a nanotweezer by rotating the respective arms having corresponding tip portions at the distal ends.

Abstract: A sample working/observing apparatus possesses a sample holding mechanism. The sample holding mechanism possesses a sample holder holding a sample, and a base detachably supporting the sample holder. Between these, there are detachably provided a rotation support part supporting so as to be rotatable, a slide support part supporting so as to be slidable from a rotation center toward an X-direction, and a butting support part supporting so as to be slidable in the X-direction and a Y-direction. In an upper face, there are provided an X-direction positioning pin and a Y-direction positioning pin, which are disposed along the Y-direction and the X-direction from the rotation center, and butt against one side and the other side of the sample.

Abstract: An opaque defect is processed by scanning with a high load or height fixed mode using a probe harder than a pattern material of a photomask at the time of going scanning, and is observed by scanning with a low load or intermittent contact mode at the time of returning scanning so as to detect an ending point of the opaque defect by the height information. When there is a portion reaching to a glass substrate as an ending point, this portion is not scanned by the high load or height fixed mode in the next processing, and only a portion not reaching to the ending point is scanned by the high load or height fixed mode.

Abstract: A scanning probe where the micromachined pyramid tip is extended by the growth of an epitaxial nanowire from the top portion of the tip is disclosed. A metallic particle, such as gold, may terminate the nanowire to realize an apertureless near-field optical microscope probe.

Abstract: A micro-object is affixed to a mounting structure at a desired relative orientation. The micro-object may be a tool tip optimized to work with particular microscope objectives permitting the tip to be imaged along with the object surface and used to make measurements or modifications through a travel range along the microscope imaging axis equal to or nearly equal to the working distance of the given objective. The tool tip may have a lengths exceeding 80 microns, say up to several millimeters; even the longest tips can have widths of tens of microns.

Abstract: In a scanning probe apparatus capable of always effectively canceling an inertial force to suppress vibration even in repetitive use while replacing a sample holding table or a probe, a stage for a sample or the probe includes a drive element for moving the sample holding table and movable portions movable in a direction in which an inertial force generated during movement of the sample holding table. The stage is configured so that the drive element, the movable portions, and the sample holding table or the probe are integrally detachably mountable to a main assembly of the scanning probe apparatus.

Abstract: Provided is an apparatus for automatically inspecting a road surface pavement condition, includes: a road surface photographing unit; a road surface rutting measuring unit; a flatness measuring unit; a data analysis and storage unit; a traveling noise measuring unit; and an auxiliary unit for supplying electric power. The automatic road surface pavement condition inspection apparatus is equipped in a vehicle and thus automatically inspects a road surface pavement condition and a state of surrounding circumstances of a road, when the vehicle runs along the road, to thereby make up and offer objective data that everyone can easily grasp and thus provide a road inspector with the objective data for maintenance and repair and post-control and pre-control of the road.

Abstract: A scanning probe microscope capable of measuring accurate 3-D shape information of a sample with high through-put without damaging a sample. In a method for acquiring an accurate 3-D shape of a sample without imparting damage to the sample by bringing a probe into contact at only a measurement point, once pulling up and retracting the probe when it moves towards a next measurement point, moving the probe towards the next measurement point and allowing it to approach, a deflection signal of the probe and its twist signal area analyzed so that measurement can be made at a minimum necessary retraction distance. Control for minimizing residual oscillation at the time of transverse movement is made so that a measurement frequency can be raised and high speed measurement can be accomplished.

Abstract: Determination of non-linearity of a positioning scanner of a measurement tool is disclosed. In one embodiment, a method may include providing a probe of a measurement tool coupled to a positioning scanner; scanning a surface of a first sample with the surface at a first angle relative to the probe to attain a first profile; scanning the surface of the first sample with the surface at a second angle relative to the probe that is different than the first angle to attain a second profile; repeating the scannings to attain a plurality of first profiles and a plurality of second profiles; and determining a non-linearity of the positioning scanner using the different scanning angles to cancel out measurements corresponding to imperfections due to the surface of the sample. The non-linearity may be used to calibrate the positioning scanner.

Abstract: A scanning probe microscope includes a cantilever, a scanning mechanism which relatively scans the cantilever and a sample which exist in liquid, and an application mechanism which applies photolytic light to a caged compound existing in the liquid or the sample.

Abstract: A system and method for measuring sample material properties by coherently averaging cantilever free-decay signals in a scanning probe microscope is described.

Abstract: A scanner for probe microscopy that avoids low resonance frequencies and accounts better for piezo nonlinearities. The x, y and z axes of a linear stack scanner are partially decoupled from each other while maintaining all mechanical joints stiff in the direction of actuation. The scanning probe microscope comprises a probe, a housing, at least two actuators, each coupled to the housing, and a support coupled to the housing and to at least a first of the actuators at a position spaced from the point at which the actuator is coupled to the housing. The support constrains the motion of the first actuator along a first axis while permitting translation along a second axis. The actuators are preferably orthogonally arranged linear stacks of flat piezos, preferably in push-pull configuration. The support can take different forms in different embodiments of the invention.

Abstract: Glide test systems and associated methods are described. A glide test system includes a glide test head that is flown over the surface of a recording disk to detect asperities on the recording disk. The glide test head includes a detection pad on the trailing end of the head. Heating elements are fabricated proximate to the detection pad. The heating elements are independently controllable to control the amount of protrusion of different regions of the detection pad. The heating elements thus provide a way to substantially flatten the detection surface of the detection pad, and compensate for an uneven topography on a detection surface.

Abstract: In accordance with an embodiment of the invention, there is a force sensor for a probe based instrument. The force sensor can comprise a detection surface and a flexible mechanical structure disposed a first distance above the detection surface so as to form a gap between the flexible mechanical structure and the detection surface, wherein the flexible mechanical structure is configured to deflect upon exposure to an external force, thereby changing the first distance.

Abstract: A system containing a micro-mechanical or nano-mechanical device and a method of operating the same is provided. The device includes a resonator and a piezoresistive element connected to the resonator. The method includes AC biasing the piezoresistive element at a first frequency, driving the resonator at a second frequency different from the first frequency, and detecting a mechanical response of the resonator at one or both of a difference frequency and a sum frequency of the first and second frequencies.

Abstract: In the case of measuring a pattern having a steep side wall, a probe adheres to the side wall by the van der Waals forces acting between the probe and the side wall when approaching the pattern side wall, and an error occurs in a measured profile of the side wall portion. When a pattern having a groove width almost equal to a probe diameter is measured, the probe adheres to both side walls, the probe cannot reach the groove bottom, and the groove depth cannot be measured. When the probe adheres to a pattern side wall in measurements of a microscopic high-aspect ratio pattern using an elongated probe, the probe is caused to reach the side wall bottom by detecting the adhesion of the probe to the pattern side wall, and temporarily increasing a contact force between the probe and the sample. Also, by obtaining the data of the amount of torsion of a cantilever with the shape data of the pattern, a profile error of the side wall portion by the adhesion is corrected by the obtained data of the amount of torsion.

Abstract: A glide head having a portion thereof that is selectively extendable toward the rotating disk by the application of an electrical signal thereto. The extendable portion may be located on a side wing extending from a slider main body. The side wing may include a piezoelectric transducer with a relatively durable contact layer provided on the bottom portion thereof. The slider can be flown relatively close to the rotating media and the transducer can be activated to actuate the contact layer into a closer position relative to the rotating disk. The distance at which physical contact occurs may be measured.

Abstract: Provided is near-field optical probe including: a cantilever arm support portion that is formed of a lower silicon layer of a silicon-on-insulator (SOI) substrate, the cantilever arm support portion having a through hole formed therein at a side of the lower silicon layer; and a cantilever arm forming of a junction oxidation layer pattern and an upper silicon layer pattern on the SOI substrate that are supported on an upper surface of the lower silicon layer and each have a smaller hole than the through hole, a silicon oxidation layer pattern having a tip including an aperture at a vertical end, corresponding with the hole on the upper silicon layer pattern, and an optical transmission prevention layer that is formed on the silicon oxidation layer pattern and does not cover the aperture.

Abstract: This is a probe that can be used to measure any curl on a stack of sheets in a sheet stacking tray. In printing systems including electrophotographic systems, sheets tend to curl on edge portions. This curl can adversely affect the final copy and copies fed to finishing stations. This probe lightly contacts the upper stack surface and detects sheet curl especially on the edge portions of the stack. The probe measures deviations of the surface as compared to a starting point defined on the terminal edge of the stack. The information provided by the probe is then fed to a user or controlled for transmission to a correcting apparatus.

Abstract: An Atomic Force Microscope (AFM) using a cantilevered probe containing a slider of a kind useable in a disk drive. The AFM may use a test surface similar to a disk surface in the disk drive and measure friction, lubricant depletion, and/or scratch test in the AFM to estimate the same under conditions experienced in the disk drive. The AFM may also include a Peltier plate thermally coupled to test object to maintain test surface at controlled test temperature. Refinements of the measurements are disclosed.

Abstract: A scan data collection operation includes performing a scanning operation using a scan path that includes a directional component that is additional to a data collection directional component. The collected scan data is mapped to another set of locations, thus allowing for detection of surface features using fewer scans.

Abstract: In a probe apparatus that intermittently irradiates a sample with excitation light to observe the sample while subjecting a cantilever including a probe arranged to face a surface of the sample to self-excited vibration at a predetermined frequency, the sample is irradiated with the excitation light at a predetermined timing when a distance between the probe and the sample is not greater than a predetermined distance.

Abstract: A carbon thin line probe having a carbon thin line selectively formed at a projection-like terminal end portion thereof by means of an irradiation of high-energy beam, the carbon thin line internally containing a metal. Thereby achieved is a carbon thin line probe suitable for example for the probe of SPM cantilever, which has a high aspect ratio and high durability and reliability, capability of batch processing based on a simple manufacturing method, and to which magnetic characteristic can be imparted.