Provided herein are new methods of analyzing release-resistant water in materials, such as geologic materials. The methods of the invention typically comprise removal of extraneous water, e.g., by drying, preparing the material for the release of release-resistant water (e.g., by crushing the material, but typically not so greatly as to cause the release of fluid from hermetically sealed components, such as fluid inclusions), and then analyzing the amount of release-resistant water in the sample, either directly in-situ or by the additional step of extracting the release-resistant water and measuring the extraction. The invention also provides new devices and/or systems useful in the performance of such methods.

Provided herein are new methods of analyzing release-resistant water in materials, such as geologic materials. The methods of the invention typically comprise removal of extraneous water, e.g., by drying, preparing the material for the release of release-resistant water (e.g., by crushing the material, but typically not so greatly as to cause the release of fluid from hermetically sealed components, such as fluid inclusions), and then analyzing the amount of release-resistant water in the sample, either directly in-situ or by the additional step of extracting the release-resistant water and measuring the extraction. The invention also provides new devices and/or systems useful in the performance of such methods.

A device includes a capacitive sensor having a hydrogel structure that includes a first surface and a second surface. A first electrode is provided at the first surface of the hydrogel structure, the first electrode including a network of conductive nanoparticles extending into the hydrogel structure. A second electrode is provided at the second surface of the hydrogel structure.

A pressure difference sensor for providing a pressure measurement signal, comprising: a pressure difference measuring cell, which is suppliable with first and second pressures and which outputs the pressure measurement signal; first and second ceramic stiffening elements, each of which is joined with the pressure difference measuring cell and has a duct, via which the first, respectively the second, pressure is suppliable to the pressure difference measuring cell; a platform with first and second pressure input openings, each of which extends from a first surface to a second surface of the platform, wherein the pressure input openings are sealed on the first surface, each with its own isolating diaphragm, and first and second pressures tubes, which are arranged between the stiffening elements and the platform, and wherein each of the first pressure tube and the second pressure tube has at least one bend in a region between the platform and a first, respectively second, connecting area of the corresponding pressure tube.

A pressure sensing apparatus which utilizes an electrolytic droplet retained between a first and second sensing electrode within a housing. Contact between the electrolyte droplet and the electrodes form electric double layers (EDL) having interfacial EDL capacitance proportional to interface contact area which varies in response to mechanical pressure applied to deform exterior portions of the housing. The electrolyte contains a sufficient percentage of glycerol to prevent evaporative effects. Preferably, the sensing electrodes are modified with depressions, hydrophilic and/or hydrophobic portions to increase central anchoring of the electrolyte droplet within the housing. The inventive pressure sensor provides high sensitivity and resolution which is beneficial to numerous applications, and is particularly well-suited for medical sensing applications.

A micro electro-mechanical system (MEMS) acoustic sensor is disclosed. The acoustic sensor comprises a backplate and a diaphragm. The acoustic sensor further comprises a flexible member and optional spacer member disposed between the backplate and the diaphragm resulting in a gap between the backplate and the diaphragm. The gap can vary in response to impinging pressure on the diaphragm based on the design of the flexible member and resulting in a variable capacitance between the backplate and the diaphragm. The change in the gap can result in a change in an electrical characteristic associated with the variable capacitance and can be converted to an electrical output signal corresponding to the impinging pressure on the diaphragm. The flexible member can be part of the backplate or diaphragm.

A pressure sensing apparatus which utilizes an electrolytic droplet retained between a first and second sensing electrode within a housing. Contact between the electrolyte droplet and the electrodes form electric double layers (EDL) having interfacial EDL capacitance proportional to interface contact area which varies in response to mechanical pressure applied to deform exterior portions of the housing. The electrolyte contains a sufficient percentage of glycerol to prevent evaporative effects. Preferably, the sensing electrodes are modified with depressions, hydrophilic and/or hydrophobic portions to increase central anchoring of the electrolyte droplet within the housing. The inventive pressure sensor provides high sensitivity and resolution which is beneficial to numerous applications, and is particularly well-suited for medical sensing applications.

Provided herein are new methods of analyzing release-resistant water in materials, such as geologic materials. The methods of the invention typically comprise removal of extraneous water, e.g., by drying, preparing the material for the release of release-resistant water (e.g., by crushing the material, but typically not so greatly as to cause the release of fluid from hermetically sealed components, such as fluid inclusions), and then analyzing the amount of release-resistant water in the sample, either directly in-situ or by the additional step of extracting the release-resistant water and measuring the extraction. The invention also provides new devices and/or systems useful in the performance of such methods.

Provided herein are devices for the collection and analysis of geologic materials (e.g., drill cuttings) at a well or drilling site, such as at the drilling of a petroleum well. The devices are specifically adapted to rapidly collect a sample of such materials, e.g., from a petroleum drill flow line, to analyze the rock volatile content of such materials, and then collect a next sample of such materials for future analysis, such that the information collected from use of the device can be used for real time direction of drilling or fracking operations or for other uses.