The present invention relates to an atomic force microscope for evaluating a surface of a sample, comprising a sample holder, having a first zone suitable for receiving the sample mounted in a stationary manner, a probe having a tip able to be positioned facing the surface of the sample, the microscope being configured to allow an adjustment of a position of the tip relative to the surface, and a support, the sample holder having at least one second zone, separate from the first zone and stationary relative to the support, the sample holder being deformable so as to allow a relative movement of the first zone with respect to the second zone, and the microscope comprising a detector able to detect a movement of the first zone relative to the second zone.

The present invention relates to an atomic force microscope for evaluating a surface of a sample, comprising a sample holder, having a first zone suitable for receiving the sample mounted in a stationary manner, a probe having a tip able to be positioned facing the surface of the sample, the microscope being configured to allow an adjustment of a position of the tip relative to the surface, and a support, the sample holder having at least one second zone, separate from the first zone and stationary relative to the support, the sample holder being deformable so as to allow a relative movement of the first zone with respect to the second zone, and the microscope comprising a detector able to detect a movement of the first zone relative to the second zone.

A scanning probe microscope system. A sample stage is provided along with a microscope arranged to collect data with a probe carried by the microscope from a sample carried by the sample stage. A probe/sample exchange mechanism is arranged to exchange the probe carried by the microscope with a new probe, and is also arranged to exchange the sample carried by the sample stage with a new sample. The probe/sample exchange mechanism comprises a transport structure which can move relative to the microscope and the sample stage; a probe carrier carried by the transport structure and adapted to carry the probe or the new probe when the probe is exchanged with the new probe; a sample carrier carried by the transport structure, wherein the sample carrier is adapted differently from the probe carrier to carry the sample or the new sample when the sample is exchanged with the new sample; and a drive system arranged to move the transport structure relative to the microscope and the sample stage when the probe is exchanged with the new probe and the sample is exchanged with the new sample.

A scanning probe microscope system. A sample stage is provided along with a microscope arranged to collect data with a probe carried by the microscope from a sample carried by the sample stage. A probe/sample exchange mechanism is arranged to exchange the probe carried by the microscope with a new probe, and is also arranged to exchange the sample carried by the sample stage with a new sample. The probe/sample exchange mechanism comprises a transport structure which can move relative to the microscope and the sample stage; a probe carrier carried by the transport structure and adapted to carry the probe or the new probe when the probe is exchanged with the new probe; a sample carrier carried by the transport structure, wherein the sample carrier is adapted differently from the probe carrier to carry the sample or the new sample when the sample is exchanged with the new sample; and a drive system arranged to move the transport structure relative to the microscope and the sample stage when the probe is exchanged with the new probe and the sample is exchanged with the new sample.

A method for detecting a thickness of bonded rubber of a carbon black in a natural rubber based for reinforcement performance is provided. An ultra-thin frozen microtome to prepare a sample, a tapping mode of the atomic force microscope is used, and when characterizes the carbon black and rubber composite material, the difference of imaging characteristics between morphological and phase diagrams is used, the characteristics of bonded rubber of carbon black reinforced composite material can be observed to obtain the thickness of bonded rubber, and then influence of bonded rubber on rubber performance and the reinforcement performance of the carbon black in the rubber are analyzed. The method has advantages of simple operation, no need for excessive sample processing, high detection efficiency, clear detection images and high detection accuracy, thereby having better applicability and providing a new method and idea for studying reinforcements of fillers.

The present invention relates to sample holders for holding a sample, particularly for an atomic force microscope. Such a sample holder comprising a sample dish (1) comprising a bottom (2), and an opening (3) arranged in said bottom (2) for receiving and holding the sample (15). Furthermore the present invention relates to a sample holder system and to a method for transferring an e.g. biological sample (15) from a biopsy tool (18) to a sample holder.

The present invention relates to sample holders for holding a sample, particularly for an atomic force microscope. Such a sample holder comprising a sample dish (1) comprising a bottom (2), and an opening (3) arranged in said bottom (2) for receiving and holding the sample (15). Furthermore the present invention relates to a sample holder system and to a method for transferring an e.g. biological sample (15) from a biopsy tool (18) to a sample holder.

An object of the present invention is to provide a method for comparatively simply selecting polycrystalline silicon suitably used for stably producing single crystal silicon in high yield. According to the present invention, polycrystalline silicon having a maximum surface roughness (Peak-to-Valley) value Rpv of 5000 nm or less, an arithmetic average roughness value Ra of 600 nm or less and a root mean square roughness value Rq of 600 nm or less, the surface roughness values being measured by observing with an atomic force microscope (AFM) the surface of a collected plate-shaped sample, is selected as a raw material for producing single crystal silicon.

An object of the present invention is to provide a method for comparatively simply selecting polycrystalline silicon suitably used for stably producing single crystal silicon in high yield. According to the present invention, polycrystalline silicon having a maximum surface roughness (Peak-to-Valley) value Rpv of 5000 nm or less, an arithmetic average roughness value Ra of 600 nm or less and a root mean square roughness value Rq of 600 nm or less, the surface roughness values being measured by observing with an atomic force microscope (AFM) the surface of a collected plate-shaped sample, is selected as a raw material for producing single crystal silicon.

The invention relates to the field of probe measurements of objects after micro- and nano-sectioning. The essence of the invention consists in that in a wide-field scanning probe microscope combined with an apparatus for modifying an object, said microscope comprising a base on which a piezo-scanner unit having a piezo scanner, a probe unit having a probe holder, and a punch unit having a punch are movably mounted, a punch actuator is configured as a three-axis actuator, allowing the punch to move along a first axis X, a second axis Y and a third axis Z; and the probe unit is mounted on the punch actuator. The invention is aimed at simplifying the structure of the device by combining into one unit means for measuring and means for modifying an object. The technical result of the invention consists in increasing measurement resolution.