Nano-indentation test to determine mechanical properties of reservoir rock can be implemented as multi-stage or single-stage tests. An experimental nano-indentation test (multi-stage or single-stage) is performed on a solid sample. A numerical nano-indentation test (multi-stage or single-stage) is performed on a numerical model of the solid sample. One or more experimental force-displacement curves obtained in response to performing the experimental nano-indentation test and one or more numerical force-displacement curves obtained in response to performing the numerical test are compared. Multiple mechanical properties of the solid sample are determined based on a result of the comparing.

Nano-indentation test to determine mechanical properties of reservoir rock can be implemented as multi-stage or single-stage tests. An experimental nano-indentation test (multi-stage or single-stage) is performed on a solid sample. A numerical nano-indentation test (multi-stage or single-stage) is performed on a numerical model of the solid sample. One or more experimental force-displacement curves obtained in response to performing the experimental nano-indentation test and one or more numerical force-displacement curves obtained in response to performing the numerical test are compared. Multiple mechanical properties of the solid sample are determined based on a result of the comparing.

This invention relates to a microelectromechanical device for mechanical characterization of a specimen. In one embodiment the device may incorporate a substrate, at least one first flexure bearing and at least one second flexure bearing, both being supported on the substrate. First and second movable shuttles may be used which are supported above the substrate by the flexure bearings so that each is free to move linearly relative to the substrate. Ends of the movable shuttles are separated by a gap. A thermal actuator may be connected to one end of the first movable shuttle, and operates to cause the first movable shuttle to move in a direction parallel to the surface of the substrate in response to a signal applied to the thermal actuator. A first capacitive sensor may be formed between the first movable shuttle and the substrate, and a second capacitive sensor formed between the second movable shuttle and the substrate.

The invention relates to a system (10) adapted to measure multiple biophysical characteristics of cells, the system (10) comprising: a microfluidic chip (12) provided with a microfluidic channel (14) which allows cells to flow through, the microfluidic channel (14) having an inlet (14a), an outlet (14b), and a lateral opening (14c) situated between the inlet (14a) and the outlet (14b); and a capacitive sensor (30) integrated in the microfluidic chip, adapted to obtain biophysical characteristics of a single cell in the microfluidic channel (14) by directly manipulating the single cell by sensor elements (31, 32) through the lateral opening (14c) of the microfluidic channel (14), the sensor (30) comprising a stationary part and an electrostatically driven movable part which is movable relative to the stationary part, the stationary part being fixed to the microfluidic chip (12), the movable part being arranged in the lateral opening (14c) of the microfluidic channel (14), wherein a portion of the sensor elements (31, 32) provides an interface between fluid and air in the system.

Surface measurement probe comprising: a hollow probe body extending along a longitudinal axis and comprising a proximal end adapted to be mounted to a test apparatus and a distal end; a retaining arrangement situated inside the probe body and extending along said longitudinal axis, the retaining arrangement being arranged to maintain the surface measurement probe in an assembled state; a probe tip supported at the distal end of the probe body and arranged to contact a sample; a bead situated inside the probe body and interposed between the probe tip and the retaining arrangement, the bead comprising a thermally-insulating material.

A rock sample is nano-indented from a surface of the rock sample to a specified depth less than a thickness of the rock sample. While nano-indenting, multiple depths from the surface to the specified depth and multiple loads applied to the sample are measured. From the multiple loads and the multiple depths, a change in load over a specified depth is determined, using which an energy associated with nano-indenting rock sample is determined. From a Scanning Electron Microscope (SEM) image of the nano-indented rock sample, an indentation volume is determined responsive to nano-indenting, and, using the volume, an energy density is determined. It is determined that the energy density associated with the rock sample is substantially equal to energy density of a portion of a subterranean zone in a hydrocarbon reservoir. In response, the physical properties of the rock sample are assigned to the portion of the subterranean zone.

This invention relates to a microelectromechanical device for mechanical characterization of a specimen. In one embodiment the device may incorporate a substrate, at least one first flexure bearing and at least one second flexure bearing, both being supported on the substrate. First and second movable shuttles may be used which are supported above the substrate by the flexure bearings so that each is free to move linearly relative to the substrate. Ends of the movable shuttles are separated by a gap. A thermal actuator may be connected to one end of the first movable shuttle, and operates to cause the first movable shuttle to move in a direction parallel to the surface of the substrate in response to a signal applied to the thermal actuator. A first capacitive sensor may be formed between the first movable shuttle and the substrate, and a second capacitive sensor formed between the second movable shuttle and the substrate.

Nano-level evaluation of kerogen-rich reservoir rock is described. A nano-scale beam is formed from kerogen-rich reservoir rock. The nano-scale beam includes reservoir rock and kerogen having polymeric properties. A mechanical experiment is performed on the nano-scale beam. The mechanical experiment is imaged using a scanning electron microscope (SEM) or a transmission electron microscope (TEM). A material parameter of the kerogen in the nano-scale beam is determined based on the mechanical experiment and images obtained responsive to the imaging.

In a method and device for setting one or more measuring points on a specimen in a specimen holder for automated hardness testing in a hardness-testing device, the hardness-testing device has a table, a tool holder with a penetrator and at least one lens. The specimen holder with the specimen is positioned on the table in the x- and y-directions. The table and/or tool holder can be moved in the z-direction, relative to one another. A virtual three-dimensional model of the specimen holder and specimen is selected from data storage, and the model and/or an overview image of the specimen is depicted on a screen. Then, a point is marked in the image, and one or more measuring point is/are automatically defined based on the measuring method selected. To each measuring point, the z-coordinate is automatically assigned in the hardness-testing device based on its x- and y-coordinates and virtual model.

A two-dimensional nanoindentation measurement apparatus includes a first actuator that imparts a first force in a first direction, and a second actuator that imparts a second force in a second direction orthogonal to the first direction. A first elongate member has a first end attached to the first actuator and a second end attached to an indenter tip that engages the surface of the sample. A second elongate member includes a first end attached to the second actuator and a second end connected to the second end of the first elongate member. The first elongate member is rigid in the first direction and compliant in the second direction, and the second elongate member is rigid in the second direction and compliant in the first direction. The first force is imparted to the indenter tip in the first direction through the first elongate member, and the second force is imparted to the indenter tip in the second direction through the second elongate member.