Gd-Xrd100 X-ray Diffractometer Laboratory Dedicated Xrd Analyzer Is Used to Determine Crystal Parameters

An X-ray diffractometer is a scientific instrument used to analyze materials based on the principle that diffraction occurs when X-rays interact with matter. It is mainly composed of an X-ray generator, a goniometer, a detector, and other parts. Its working process is to irradiate the sample with X-rays, and the detector collects the diffraction signal and converts it into an electrical signal or a digital signal, which is then processed and analyzed by a computer. It can be used for phase analysis to determine the composition of a substance, for crystal structure determination to obtain information such as lattice parameters, and for performance research such as stress analysis and grain size measurement of materials. It plays an important role in many fields such as materials science, physics, chemistry, geology, biology, and archaeology, and is an important tool for studying the microstructure and properties of matter.

Phase analysis
Qualitative analysis: Each crystalline substance has its own unique crystal structure and diffraction pattern. By comparing the diffraction pattern of the sample with the standard diffraction pattern of the known substance, it is possible to determine which phases exist in the sample. For example, in geological exploration, the rock mineral composition can be analyzed to determine the various minerals contained in the ore, providing a basis for the evaluation and mining of mineral resources; in metal material research, it can determine whether the metal material has formed a new phase during processing or heat treatment, such as in steel production, whether cementite, martensite and other phases have been generated.
Quantitative analysis: According to the relationship between the intensity of the diffraction peak and the content of the phase, a certain method can be used to quantitatively calculate the content of each phase in the sample. In the preparation of ceramic materials, precise control of the content of each phase is crucial to ensure the performance of ceramics; in catalyst research, quantitative analysis of the content of active components and carriers in the catalyst helps to optimize the catalyst formulation and performance.
Crystal structure determination
Determine crystal parameters: By measuring information such as the position and intensity of the diffraction peak, the lattice constant, unit cell type and other parameters of the crystal can be calculated, thereby understanding the internal structure of the crystal. In the research of semiconductor materials, the precise determination of the structural parameters of semiconductor crystals such as silicon and germanium is of great significance for the manufacture of high-performance semiconductor devices; in drug development, the study of the crystal structure of drug molecules helps to understand the mechanism of action of drugs and design more effective drug dosage forms.
Study of molecular arrangement: For some organic compounds and biomacromolecules, X-ray diffractometers can reveal the arrangement and spatial configuration of molecules in crystals. For example, in the study of protein structure, the three-dimensional structure of proteins is analyzed by X-ray diffraction technology, providing key information for understanding the function of proteins, drug design and bioengineering; in the study of polymer materials, understanding the arrangement and crystal morphology of polymer chains is instructive for improving the performance and processing technology of materials.
Material performance research
Stress analysis: When a material is subjected to external force, stress will be generated inside, and the stress will cause the crystal lattice to distort, thereby changing the position and shape of the diffraction peak. By analyzing the changes in the diffraction peak, the stress state inside the material can be determined, providing a basis for the strength design and quality control of the material. In the field of aerospace, stress analysis is performed on key components such as aircraft engine blades to ensure their safety and reliability under complex working conditions; in construction projects, stress distribution in concrete and steel structures is detected to evaluate the stability of the structure.
Grain size measurement: According to the broadening degree of the diffraction peak, the size of the grains in the material can be calculated using methods such as the Scherrer formula. In the heat treatment process of metal materials, controlling the grain size is an important means to improve the performance of the material. By measuring the grain size, the heat treatment process parameters can be optimized; in the study of nanomaterials, accurately measuring the particle size and distribution of nanoparticles is of great significance for studying the performance and application of nanomaterials.

Structural design
θ-2θ linkage goniometer system: adopts the patented new θ-2θ linkage goniometer system, the single-axis drive mechanism is simple and accurate, and the performance is excellent.
Integrated Sola slit: without any moving adjustable parts, it enhances the reliability of the goniometer system and enables the instrument to be installed on a vehicle-mounted laboratory platform.
Air spring large window lifting door: it not only saves desktop space, but also effectively shields X-rays, and can also observe the in-situ analysis process without blind spots.
Compact and light: the instrument size is 580mm×450mm×680mm, weighs about 120kg, occupies little space, and is easy to place and move.

Functional application
Multiple sample analysis: Suitable for samples in various forms such as powder, block, film, etc., and can analyze polymer materials, metals, minerals, ceramics, etc., to achieve the functions of qualitative and quantitative analysis of the main phase, crystal structure analysis, material structure analysis and crystallinity determination.
Crystallinity analysis: Mainly using X-ray diffraction technology and full spectrum fitting method to analyze the crystallinity of polymer material samples, providing important data for material research and quality control.

Software and operation
Easy operation: With special CrystalX software, after obtaining diffraction data, it can automatically perform phase analysis and give the percentage of each component of the phase. The user only needs to click "Start Test" without complicated manual retrieval and data processing.
Safety protection: With automatic cut-off protection device and safety interlocking lock device, the sample chamber is fully closed after closing, and the operation interface has the function of closing the sample chamber to ensure the safety of the operator.
Real-time monitoring: With built-in water circulation cooling system, the software can display the water temperature, flow rate and other information of the X-ray tube in real time to ensure the stable operation of the instrument, and at the same time facilitate the operator to understand the status of the instrument in time.
Cloud service function: supports synchronized mobile application services, can perform card management of diffraction data and access to knowledge management systems, and facilitate data storage, sharing and remote operation.

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