The present invention provides a scanner capable of achieving both a wide range of measurements and a high-speed and high-precision measurement.

A scanner comprising: an outer frame; a first inner frame disposed inside the outer frame; a wide range Y actuator for moving the first inner frame relative to the outer frame in the Y direction; a second inner frame disposed inside the first inner frame; a wide range X actuator for moving the second inner frame relative to the first inner frame in the X direction orthogonal to the Y direction; a third inner frame disposed inside the second inner frame; a narrow range Y actuator for moving the third inner frame relative to the second inner frame in the Y direction; a movable foundation disposed inside the third inner frame; and a narrow range X actuator for moving the movable foundation relative to the third inner frame in the X direction.

A method of carrying out sub-resonant tapping in an atomic force microscope includes causing a probe that is disposed above a sample to be translated in a direction parallel to a horizontal plane defined by the sample and to oscillate in a vertical direction that is perpendicular to the horizontal plane about an equilibrium line that is separated from the horizontal plane by a vertical offset. As a result, the probe repeatedly taps a surface of the sample. Each tap begins with a first contact of the probe on the surface followed by a progressive increase in force exerted by the sample on the probe until a peak force is attained. The vertical offset is controlled by relying at least in part on a feature other than the peak force as a basis for controlling the vertical offset.

A method of carrying out sub-resonant tapping in an atomic force microscope includes causing a probe that is disposed above a sample to be translated in a direction parallel to a horizontal plane defined by the sample and to oscillate in a vertical direction that is perpendicular to the horizontal plane about an equilibrium line that is separated from the horizontal plane by a vertical offset. As a result, the probe repeatedly taps a surface of the sample. Each tap begins with a first contact of the probe on the surface followed by a progressive increase in force exerted by the sample on the probe until a peak force is attained. The vertical offset is controlled by relying at least in part on a feature other than the peak force as a basis for controlling the vertical offset.

The present disclosure relates to a method of operating an SPM system including a landing procedure. The landing procedure comprises a first landing stage including a first translation over a first actuation distance by a coarse translation means to bring a probe tip held by an SPM head from an initial separation from a substrate to be probed to a second, more proximal, separation as defined by a characteristic transitional response of the probe tip in proximity to the substrate. Following the first stage a second translation is applied, over a second actuation distance by a fine translation means under feedback control to bring the probe tip to a working separation. Prior to applying the first (coarse) actuation distance an initial optical distance is determined which is indicative of the initial separation, using a detector, preferably a mark sensor. The measured initial optical distance is related to a reference distance so as to determine a deviation. The first actuation distance corresponds the reference distance and the deviation. The disclosure also relates to an SPM system and software product arranged to implement the landing method.

The present disclosure relates to a method of operating an SPM system including a landing procedure. The landing procedure comprises a first landing stage including a first translation over a first actuation distance by a coarse translation means to bring a probe tip held by an SPM head from an initial separation from a substrate to be probed to a second, more proximal, separation as defined by a characteristic transitional response of the probe tip in proximity to the substrate. Following the first stage a second translation is applied, over a second actuation distance by a fine translation means under feedback control to bring the probe tip to a working separation. Prior to applying the first (coarse) actuation distance an initial optical distance is determined which is indicative of the initial separation, using a detector, preferably a mark sensor. The measured initial optical distance is related to a reference distance so as to determine a deviation. The first actuation distance corresponds the reference distance and the deviation. The disclosure also relates to an SPM system and software product arranged to implement the landing method.

A three-dimensional fine movement device includes a moving body, a fixation member to which the moving body is fixed, a three-dimensional fine movement unit, to which the fixation member is fixed, and which allows for three-dimensional fine movement of the moving body with the fixation member interposed therebetween, a base member to which the three-dimensional fine movement unit is fixed, and movement amount detecting means that is fixed to the base member to detect a movement amount of the fixation member.

According to this invention, a scanning probe microscope for scanning a surface of a sample with a probe by bringing the probe into contact with the surface of the sample, comprises a cantilever having the probe at its tip; a displacement detection unit to detect both a bending amount and a torsion amount of the cantilever; and a contact determination unit to determine a primary contact of the probe with the surface of the sample, based on the bending amount and the torsion amount detected by the displacement detection unit in all directions from an undeformed condition of the cantilever.

According to this invention, a scanning probe microscope for scanning a surface of a sample with a probe by bringing the probe into contact with the surface of the sample, comprises a cantilever having the probe at its tip; a displacement detection unit to detect both a bending amount and a torsion amount of the cantilever; and a contact determination unit to determine a primary contact of the probe with the surface of the sample, based on the bending amount and the torsion amount detected by the displacement detection unit in all directions from an undeformed condition of the cantilever.

Disclosed herein are devices, systems and methods for in-line, nanoscale metrology. One system comprises monolithic flexure mechanisms with integrated actuators that allow movement and positioning in two axes, with an extremely high degree of accuracy, of a structure comprising one or more scanning probes. This structure is suspended to prevent any destructive interference from a sample, which can be stationary or moving at a nonzero rate, and rigid or flexible in mechanical behavior. This system can be activated at startup and quickly actuate the structure to approach the surface of the sample. Once the system achieves the desired proximity between the one or more probes and the sample, the system maintains that position of the structure to a high degree of accuracy regardless of any disturbances. This array can be moved at varying speeds laterally to match the velocity of any continually moving substrates, thus enabling scanning of moving substrates.

Disclosed herein are devices, systems and methods for in-line, nanoscale metrology. One system comprises monolithic flexure mechanisms with integrated actuators that allow movement and positioning in two axes, with an extremely high degree of accuracy, of a structure comprising one or more scanning probes. This structure is suspended to prevent any destructive interference from a sample, which can be stationary or moving at a nonzero rate, and rigid or flexible in mechanical behavior. This system can be activated at startup and quickly actuate the structure to approach the surface of the sample. Once the system achieves the desired proximity between the one or more probes and the sample, the system maintains that position of the structure to a high degree of accuracy regardless of any disturbances. This array can be moved at varying speeds laterally to match the velocity of any continually moving substrates, thus enabling scanning of moving substrates.