An example embodiment includes a large observation device that observes the object using a quantum beam; a reproduction device that is installed in the large observation device and reproduces an input to the object in a state where the object can be observed by the large observation device; a dynamic state observation device that observes a dynamic state of a functional object functioning by a combination of a plurality of elements; a first information acquisition unit that functionally decomposes the functional object up to an element corresponding to the object and acquires first information that is input information to the element corresponding to the object; and a transmission unit that transmits the first information to the reproduction device, in which the reproduction device reproduces the input to the object on the basis of the first information.

A method for calculating a laminate state of a CFRP laminate according to an embodiment includes acquiring a plurality of images of a cross section of the CFRP laminate orthogonal to a lamination direction by imaging the CFRP laminate with X-rays at a plurality of different positions in the lamination direction, the CFRP laminate including first layers including carbon fibers oriented in a first direction orthogonal to the lamination direction and second layers including carbon fibers oriented in a second direction orthogonal to the lamination direction and different from the first direction, and calculating a parameter correlated with a quantity of voids formed in the first layers and the second layers from the plurality of acquired images, and distinguishing between the first layers and the second layers using the calculated parameter.

The invention provides a device for immobilizing and shipping crystals and for data collection via serial crystallography, the device having a first planar substrate defining a first transversely extending aperture, opening, wherein the first substrate has a first laterally facing surface; a second planar substrate defining a second transversely extending aperture coaxial with the first aperture, wherein the second substrate has a second laterally facing surface; a third planar substrate and a fourth planar substrate positioned between the first and second substrate such that the first planar substrate, the second planar substrate, the third planar substrate and the fourth planar substrate are parallel; and a means for reversibly applying axial pressure to the first and second laterally facing surfaces so as to compress the third and fourth substrates together.

A method for calculating a laminate state of a CFRP laminate according to an embodiment includes acquiring a plurality of images of a cross section of the CFRP laminate orthogonal to a lamination direction by imaging the CFRP laminate with X-rays at a plurality of different positions in the lamination direction, the CFRP laminate including first layers including carbon fibers oriented in a first direction orthogonal to the lamination direction and second layers including carbon fibers oriented in a second direction orthogonal to the lamination direction and different from the first direction, and calculating a parameter correlated with a quantity of voids formed in the first layers and the second layers from the plurality of acquired images, and distinguishing between the first layers and the second layers using the calculated parameter.

A diffraction system for determining a crystalline structure of a sample collects a series of diffraction frames from a crystal sample illuminated by a beam of photonic or particulate radiation, such as X-rays. A plurality of software modules for processing the detected diffraction frames perform different tasks in refining the collected diffraction data, such as harvesting, indexing, scaling, integration, and structure determination. Output parameters from certain modules are used as input parameters in others, and are exchanged between the modules as they become available. The modules operate simultaneously, and generate successive versions of output parameters as corresponding input parameters are changed until a final result is achieved. This provides a system of structure determination that is fast and efficient.

The present disclosure introduces methods for characterizing iron core carbohydrate colloid drug products, such as iron sucrose drug products. Disclosed methods enable the characterization of the iron core size of the iron core nanoparticles in iron carbohydrates as they exist in the formulation in solution, such as e.g. iron sucrose drug products, and more particularly, the average particle diameter size and size distribution(s) of the iron core nanoparticles. The disclosed methods apply small-angle X-ray scattering (SAXS) in parallel beam transmission geometry, with a sample mounted inside a capillary and centered in the X-ray beam, to iron carbohydrates, such as iron sucrose, in solution without the need to modify the sample, such as to remove unbound carbohydrates, dilute, or dry the sample, to accurately characterize the average iron core particle diameter size of the iron core nanoparticles. An example application of the disclosed method is to perform SAXS measurements under identical instrument settings on two samples of the same type of iron core nanoparticle colloid drug product for the purpose of comparing their iron core structures. Such comparisons are typically performed during the iron core carbohydrate colloid drug development process, and can include comparisons of samples that have been manipulated.

The invention provides a device for immobilizing and shipping crystals and for data collection via serial crystallography, the device having a first planar substrate defining a first transversely extending aperture, wherein the first substrate has a first laterally facing surface; a second planar substrate defining a second transversely extending aperture coaxial with the first aperture, wherein the second substrate has a second laterally facing surface; a third planar substrate and a fourth planar substrate positioned between the first and second substrates such that the first planar substrate, the second planar substrate, the third planar substrate and the fourth planar substrate are parallel; and a means for reversibly applying axial pressure to the first and second laterally facing surfaces so as to compress the third and fourth substrates together.

A device keeps an electrochemical cell under current and at operating temperature during an X-ray beam diffraction analysis of a first electrode, the cell comprising a solid electrolyte interposed between the electrodes. The device comprises: first and second interconnectors having contact faces contacting the electrodes, which allow a gas flow and exchange between the interconnectors and the electrodes. The contact face of the first interconnector allows an X-ray beam to pass to the first electrode. A thermal and atmospheric containment chamber has an inner cavity housing a stack formed from the cell between the interconnectors and a cover closing the cavity, provided with a window allowing X-rays to pass through, the first interconnector being intended to be arranged facing the cover. The contact face of each interconnector is a slotted element; slotted portions of the slotted element are uniformly arranged and form 30% to 80% of the element's surface area.

Disclosed is a sulfate corrosion-resistant concrete, a method for optimizing proportion and application thereof. The concrete is formed by mixing and stirring base stocks, aggregates, admixtures, external additives and water. The base stock of the concrete is 17.4-17.5 parts of Portland cement; the aggregates include 38.9 parts of basalt with aggregate size of 5-10 mm and 33.1-33.2 parts of basalt medium sand; the admixtures are 1.9-1.95 parts of silica fume or fly ash, and further including 0.23-0.24 part of polycarboxylate water reducer and 1.34-1.35 part of sulfate corrosion-resistant liquid preservative. Optimized proportion method: according to the corrosion characteristics of sulfate and corrosion environment parameters, determine the composition and proportion of basic samples and comparison samples, make and cure sample components, test the deep components of the samples, and obtain the optimal composition and proportion according to the test results.

Systems and methods inspect a fastener installed at least partially through a hole in a part, by measuring fastener concentricity, measuring fastener flushness with a surface, and/or detecting foreign object debris near the fastener. Systems include an x-ray imaging system, a first camera device, a second camera device, a first support structure, and at least one processing unit. The first camera device produces a first image of the fastener from a first vantage point, and the second camera device produces a second image of the fastener from a second vantage point, such that a 3D image of the fastener can be created from the first image and the second image. The system inspects the fastener based on the x-ray image and/or the 3D image, to determine concentricity and/or flushness of the fastener. Systems may be automated and mounted on robot arms to be positioned relative to the fasteners being inspected.