A modular Atomic Force Microscope that allows ultra-high resolution imaging and measurements in a wide variety of environmental conditions is described. The instrument permits such imaging and measurements in environments ranging from ambient to liquid or gas or extremely high or extremely low temperatures.

A modular Atomic Force Microscope that allows ultra-high resolution imaging and measurements in a wide variety of environmental conditions is described. The instrument permits such imaging and measurements in environments ranging from ambient to liquid or gas or extremely high or extremely low temperatures.

The present invention relates to an apparatus and method for generating a three-dimensional image of a polymer substance. The three-dimensional image generating apparatus of the present invention comprises: a specimen state adjustor for adjusting a temperature or pressure of a solid specimen in order to maintain, in a solid state, the solid specimen including a plurality of polymer substances; an image collector for collecting a partial image of the plurality of polymer substances exposed on a surface of the solid specimen; a low molecule image database for storing an image of an element low molecule substance; and an image processor for generating a three-dimensional image of the polymer substance by matching the collected partial image with an image in the low molecule image database.

The invention relates to a top-cover for a controlled environmental system (CES) for use with a measurement technique that requires introducing a probe to a sample placed on a sample holder, a CES and a procedure to control the environment for a sample in a system in particular a CES during a measurement with a probe based technique.

A scanning probe microscope is provided comprising a scanning probe (10), a holder (5) for holding a sample (SMP) in an environment free from liquid. A scanning arrangement (20) is provided therein for inducing a relative motion of the scanning probe (10) with respect to said sample (SMP) along a surface of the sample (SMP). A driver (30) generates a drive signal (Sd) to induce an oscillating motion of the scanning probe (10) relative to the surface of the sample to be scanned. A measuring unit (40) measure a deflection of the scanning probe (10), and provides a deflection signal (S) indicative for said deflection. An amplitude detector (50) detects an amplitude of the oscillating motion as indicated by the deflection signal (S) and provides an amplitude signal (Sa) indicative for the amplitude. The scanning probe (10) is at least partly arranged in a liquid (L) to dampen motion of said scanning probe, and therewith has a quality factor Q which is less than or equal than 5. The scanning probe (10) is accommodated in a casing (90) comprising said liquid (L), the scanning probe (10) comprising a flexible carrier (11), the flexible carrier having a movable part provided with a tip (12), which tip (12) extends through an opening (91) in said casing.

Disclosed herein is a scanning probe microscope including a cantilever, a three-dimensional moving mechanism moving a sample stage in three dimensions, and a measurement chamber sealed not to be exposed to external air. At least the cantilever, the sample stage, and the three-dimensional moving mechanism are accommodated in the measurement chamber. The measurement chamber is provided with a pair of guide rails used to transport the sample stage. The sample stage has an engagement portion. The three-dimensional moving mechanism is disposed in the vicinity of a predetermined position and between the guide rails. The three-dimensional moving mechanism can be moved to above the guide rails and below the guide rails. When the sample stage is transported to the predetermined position in a horizontal direction, the three-dimensional moving mechanism is lifted up to the bottom surface of the sample stage so that the scanning probe microscope can perform measurement.

Disclosed herein is a scanning probe microscope including a cantilever, a three-dimensional moving mechanism moving a sample stage in three dimensions, and a measurement chamber sealed not to be exposed to external air. At least the cantilever, the sample stage, and the three-dimensional moving mechanism are accommodated in the measurement chamber. The measurement chamber is provided with a pair of guide rails used to transport the sample stage. The sample stage has an engagement portion. The three-dimensional moving mechanism is disposed in the vicinity of a predetermined position and between the guide rails. The three-dimensional moving mechanism can be moved to above the guide rails and below the guide rails. When the sample stage is transported to the predetermined position in a horizontal direction, the three-dimensional moving mechanism is lifted up to the bottom surface of the sample stage so that the scanning probe microscope can perform measurement.

A modular Atomic Force Microscope that allows ultra-high resolution imaging and measurements in a wide variety of environmental conditions is described. The instrument permits such imaging and measurements in environments ranging from ambient to liquid or gas or extremely high or extremely low temperatures.

A method and apparatus is provided for studying the reaction (chemical or physical) of a sample with a gas in the active atmosphere of an instrument such as an Environmental Transmission Electron Microscope (ETEM), optical microscope, X-ray microscope or scanning probe microscope. The sample is exposed to inert gas at a desired temperature before exchanging the inert gas to the active gas to reduce to avoid, or at least minimize, sample drift during image acquisition.

A method and apparatus is provided for studying the reaction (chemical or physical) of a sample with a gas in the active atmosphere of an instrument such as an Environmental Transmission Electron Microscope (ETEM), optical microscope, X-ray microscope or scanning probe microscope. The sample is exposed to inert gas at a desired temperature before exchanging the inert gas to the active gas to reduce to avoid, or at least minimize, sample drift during image acquisition.