Assessing efficacy of standard impregnation techniques on die-cast aluminum alloys using X-ray micro-CT

Utilizing lightweight Al alloys in various industrial applications requires achieving precise pressure tightness and leak requirements.Vacuum pressure impregnation(VPI)with thermosetting polymers is commonly used to address leakage defects in die-cast Al alloys.In this study,the efficacy of the VPI technique in sealing alloy parts was investigated using a combination of nondestructive micro X-ray computed tomography(micro XCT)and a standard leak test.The results demonstrate that the commonly used water leak test is insufficient for determining the sealing performance.Instead,micro XCT shows distinct advantages by enabling more comprehensive analysis.It reveals the presence of a low atomic number impregnates sealant within casting defects,which has low grey contrast and allows for visualizing primary leakage paths in 3D.The effective atomic number of impregnated resin is 6.75 and that of Al alloy is 13.69 by dual-energy X-ray CT.This research findings will contribute to enhancing the standard VPI process parameters and the properties of impregnating sealants to improve quality assurance for impregnation in industrial metals.

A study on some elements and their phases in sediments of Changjiang Estuary by X-ray spectrometer and X-ray diffractometer

INTRODUCTIONThe studies on the quantitative distribution of the conventional elements and their phases in the sediments of the Changjiang Estuary are of great importance to the understanding of the chemical processes of ion exchange, absorption, desorption and flocculation in the estuary.

Effects of dry-wet cycles on three-dimensional pore structure and permeability characteristics of granite residual soil using X-ray micro computed tomography

Due to seasonal climate alterations,the microstructure and permeability of granite residual soil are easily affected by multiple dry-wet cycles.The X-ray micro computed tomography(micro-CT)acted as a nondestructive tool for characterizing the microstructure of soil samples exposed to a range of damage levels induced by dry-wet cycles.Subsequently,the variations of pore distribution and permeability due to drywet cycling effects were revealed based on three-dimensional(3D)pore distribution analysis and seepage simulations.According to the results,granite residual soils could be separated into four different components,namely,pores,clay,quartz,and hematite,from micro-CT images.The reconstructed 3D pore models dynamically demonstrated the expanding and connecting patterns of pore structures during drywet cycles.The values of porosity and connectivity are positively correlated with the number of dry-wet cycles,which were expressed by exponential and linear functions,respectively.The pore volume probability distribution curves of granite residual soil coincide with the χ^(2)distribution curve,which verifies the effectiveness of the assumption of χ^(2)distribution probability.The pore volume distribution curves suggest that the pores in soils were divided into four types based on their volumes,i.e.micropores,mesopores,macropores,and cracks.From a quantitative and visual perspective,considerable small pores are gradually transformed into cracks with a large volume and a high connectivity.Under the action of dry-wet cycles,the number of seepage flow streamlines which contribute to water permeation in seepage simulation increases distinctly,as well as the permeability and hydraulic conductivity.The calculated hydraulic conductivity is comparable with measured ones with an acceptable error margin in general,verifying the accuracy of seepage simulations based on micro-CT results.

Rietveld refinement of powder X-ray diffraction,microstructural and mechanical studies of magnesium matrix composites processed by high energy ball milling

This research reports the processing of magnesium matrix composites reinforced with silicon carbide(SiC)and aluminium oxide(Al_(2)O_(3))using powder metallurgy technique through high energy milling.Samples of Mg-SiC and Mg-Al_(2)O_(3)composites subjected to high energy ball milling for different vol%of secondary particles 20,30 and 40%of SiC and Al_(2)O_(3)are studied by X-Ray diffraction technique.The rietveld method as implemented in the Fullprof program is applied in order to determine the quantities of the resulting crystalline phases and amorphous phases at each stage of the mechanical treatment.Microstructural examination is carried out using Scanning Electron Microscope(SEM).In addition,crystal structural analysis using appropriate size and strain models is performed in order to handle the distinctive anistrophy that is observed in convinced crystallographic directions for the magnesium composite.The results are furnished in terms of crystalline domains size enlargement of the magnesium composites phases upon prolonged milling duration and discussed in the light of up to date views and theories on crystal growth of nanocrystaline materials.The hardness of the composite samples is calculated by Vickers’s Hardness tester.Further,dry sling wear test and corrosion test are performed for the fabricated composites.Composite with 30%secondary particles incorporated magnesium composites exhibits better wear and corrosion resistance than the other composites.

Time-resolved ultra-small-angle X-ray scattering beamline(BL10U1)at SSRF

The construction of a new beamline,BL10U1,was completed at the Shanghai synchrotron radiation facility in 2020.This multipurpose beamline was designed to provide X-ray scattering techniques such as ultra-small-angle X-ray scattering(USAXS),small-angle X-ray scattering(SAXS),wide-angle X-ray scattering,and microfocus SAXS(μSAXS)for a broad user community.To realize fast time-resolved USAXS experiments,the beamline adopted an in-vacuum undulator with a total length of 1.6 m as the photon source.An in-house cryogenic-cooled double multilayer monochromator was installed to deliver a photon flux of approximately 10^(13) photons/s at a photon energy of 10 keV.The three-year successful operation of this beamline demonstrated that the monochromator operated smoothly,as expected.BL10U1 has three end stations in succession:USAXS end station,μSAXS end station,and end station for industrial applications.The minimum scattering vector q~0.0042 nm^(-1) at 10 keV can be achieved at the USAXS end station equipped with a 28 m-long and 1.8 m-diameter vacuum flight tube.At theμSAXS end station,a beam spot of less than 10×8μm was achieved for micro-SAXS experiments.In contrast,in situ experimental instruments up to 5 m high and 8 m wide can be mounted at the industrial application end station,which offers industrial scientists the opportunity to use their large industrial equipment.BL10U1 opens up a new capability to investigate phenomena such as non-equilibrium and dynamic processes of materials with a wide length scale from angstroms to micrometers with millisecond time resolution.In this paper,we also report beamline design considerations and commissioning results.

Multi-modality measurement and comprehensive analysis of hepatocellular carcinoma using synchrotron-based microscopy and spectroscopy

The visualization and data mining of tumor multidimensional information may play a major role in the analysis of the growth,metastasis,and microenvironmental changes of tumors while challenging traditional imaging and data processing techniques.In this study,a general trans-scale and multi-modality measurement method was developed for the quantitative diagnosis of hepatocellular carcinoma(HCC)using a combination of propagation-based phase-contrast computed tomography(PPCT),scanning transmission soft X-ray microscopy(STXM),and Fourier transform infrared micro-spectroscopy(FTIR).Our experimental results reveal the trans-scale micro-morpho-logical HCC pathology and facilitate quantitative data analysis and comprehensive assessment.These results include some visualization features of PPCT-based tissue microenvironments,STXM-based cellular fine structures,and FTIR-based bio-macromolecular spectral characteris-tics during HCC tumor differentiation and proliferation.The proposed method provides multidimensional feature data support for constructing a high-accuracy machine learning algorithm based on a gray-level histogram,gray-gradient co-occurrence matrix,gray-level co-occurrence matrix,and back-propagation neural network model.Multi-dimensional information analysis and diagnosis revealed the morphological pathways of HCC pathological evolution and we explored the relationships between HCC-related feature changes in inflammatory microenviron-ments,cellular metabolism,and the stretching vibration peaks of biomolecules of lipids,proteins,and nucleic acids.Therefore,the proposed methodology has strong potential for the visualization of complex tumors and assessing the risks of tumor differentiation and metastasis.

Micro porosity and its effect on fatigue performance of 7050 aluminum thick plates

Micro porosity in aluminum alloys may contribute to fatigue life degradation, which can largely limit the application of alloys. Therefore, the fatigue life of a commercial 7050-T7451 thick plate and an experimental plate with different porosities was compared in this study. The X-ray computed tomography(XCT) was utilized to characterize the size, number density and spatial distribution of porosity inside various samples, and the fracture surface of fatigued specimens was compared by using scanning electron microscope(SEM). The results showed that the fatigue cracks prefer to initiate from constituent particles in the commercial alloy. Whereas the micro porosity is the predominant site for crack nucleation and subsequent failure in the experimental one. The presence of micro porosity in experimental7050-T7451 thick plate may reduce the fatigue life by an order of magnitude or more compared with the defect-free alloy. The pores close to sample surface are the main fatigue crack initiation site, among which larger and deeper pore leads to a shorter fatigue life. The crack initiation is also affected by the pore geometry and direction. Besides, the overall porosity inside the bulk can affect the crack propagation during fatigue tests.

Characterization of the Thermo-Microstructural Analysis of Raffia Palm Fibers Proposed for Roofing Sheet Production

Raffia fibres are made from fibrous branches and leaves of Raffia palm. The membrane on the underside of each individual frond leaf is taken off to create a long thin fiber. They are usually waste materials which cause a great environmental degradation. The characterization of Raffia palm fibers/ particles was investigated through X-ray diffractometer (XRD), thermogravimetric analysis (TGA/DTA), Fourier transform infrared spectrometry (FTIR), Scanning electron mi croscope with energy dispersive spectrometer (SEM/EDS) and Atomic force microscope (AFM). The various results obtained are equivalent to those of other agro-waste materials generally used in roofing sheets composites production. Hence, this work shows that Raffia palm fibers/particles can be a useful material for cement mortar composites production which can be used for production of roofing sheets.

Effect of Water Content on Crystalline Structure of Ionic Liquids Mixture Pretreated Microcrystalline Cellulose (MCC)

Microcrystalline cellulose (MCC) was pretreated by using ionic liquids (ILs)-water mixtures solvent with solid acid catalysts. Different amount of water was considerate as the main variable. The peak shift of pretreated sample was determined by FT-IR related to the water content. The XRD was applied to characterize the change in MCC crystalline structure. Thermal decomposition technique was applied to investigate the thermal stability of pretreated MCC. The result indicated that three state of samples were occurred in pretreated MCC sample which was related the amount of water in ILs mixture system. XRD result suggested that the raw sample was distorted and transformed into a less ordered intermediate structure and the smaller crystallite size in lump state sample was obtained which could lead to lower thermal stability. This study revealed the physical chemicals properties, characteristic of molecular structures in MCC using ILs-water mixtures.

Radiological and X-Ray Diffraction Characterization of Bauxite and Rutile Ore Contaminated Environment in Kanam and Wase Mineral Exploration Sites, Plateau State-Nigeria

Two non-destructive analytical techniques (gamma spectrometer and X-ray diffractometer) were employed in the analysis of bauxite and rutile ore and their vicinity soil and control sourced within the Kanam and Wase mineral exploration sites. The activity concentrations of natural radionuclides 238U, 232Th, and 40K in the soil samples received from bauxite and rutile mineral mining vicinities revealed high concentrations of 238U, 232Th, and 40K compared to the control soil samples sourced 500 m away from the mineral exploration vicinities. Radiological detriments RLI, AUI, Hin and Hex unveiled values exceeding the radiation standard concentration (>1) for soil. X-ray diffraction characterization of bauxite ore revealed the interlocking minerals of Bauxite (18)%, Albite (11)%, Garnet (15)%, Illite (6)% and Muscovite (43)% in various proportions obtained within the 2θ range (9.18 to 64.4) and a peak value (intensity, cps) of 3400. Pure bauxite percentage in the ore meets metallurgical grade (15 - 25)%. X-ray diffraction of rutile ore revealed the minerals of rutile (40)%, quartz (21.4)%, ilmenite (27)% and garnet (11.8)% found within the 2θ range (27.5 to 35.6) and a peak value intensity of 31.1 - 100.0 cps also meeting the metallurgical grade of 15% - 25%. The major environmental concern associated with the mineral-sands industry is the radiation hazards, pollution of ground-water sources from heavy metals, mineral transport with heavy equipment’s, dredging operations in fragile coastal area and clearing of vegetation.

清代红绿彩瓷器无损分析研究

红绿彩瓷器是我国陶瓷史上一种重要的釉上彩瓷器,分析其彩料的化学组成和物相结构对其烧制工艺的研究有很重要的意义。但由于瓷器表面的不平整和彩料分布的不均匀性,导致其不满足传统的1 mm×10 mm线光源的X射线衍射仪对样品的测试要求。而毛细管聚焦的X射线衍射仪采用点光源的方式照射样品,毛细管X光透镜对Cu-K_(α)的能量有高达3个数量级的放大倍数,同时具有低的发散度,能实现样品直径100μm的微区和直径3 mm的常规X射线衍射分析,非常适合古陶瓷类样品矿物结构的无损分析的研究。因此,应用毛细管聚焦的微束X射线荧光谱仪和毛细管聚焦的X射线衍射谱仪对江西景德镇出土的清代红绿彩瓷的白釉和釉上彩料的化学成分和物相结构进行分析,并对红绿彩瓷彩料中2 mm×2 mm感兴趣区域内多元素分布和矿物相的分布进行了二维扫描分析。结果表明,Cu为绿彩的主要着色元素,在绿彩中的含量为0.02%,部分以Pb_(8)Cu(Si_(2)O_(7))_(3)(PDF 31-0464)晶相形式存在;Fe为红彩的主要着色元素,Fe含量为1.63%,部分Fe元素以Fe_(2)O_(3)(PDF 47-1409)的晶相形式存在;其中Pb在绿彩和红彩中的含量分别为41.49%和6.29%,其主要作用是使彩料的熔点降低,部分Pb在700~800℃的烧制过程中与Cu元素和Si元素相结合以Pb_(8)Cu(Si_(2)O_(7))_(3)(PDF 31-0464)晶相形式存在。从扫描区域内的元素分布图和晶相分布图可以看出,彩料原料中着色元素Cu和Fe的矿物晶相与Cu和Fe的元素分布不一致,表明原料中原有的Cu和Fe的矿物晶相在烧制过程中基本上都消失了,仅剩余或生成部分Fe_(2)O_(3)晶相;白釉中存在莫来石晶相,说明白釉是在高温下烧制而成;其中Pb_(8)Cu(Si_(2)O_(7))_(3)晶相的形成温度在750℃左右,因此可以进一步说明清代红绿彩的绿彩料是在低温下烧制而成。以上结果说明,毛细管聚焦的微束X射线荧光和毛细管聚焦的微束X射线衍射谱仪在文物的科技研究中有着重要的应用前景。

锥形束显微CT技术在颞骨成像中的应用及发展

颞骨及其内部中、内耳结构细小复杂,各种颞骨疾病如先天性中耳畸形或中耳炎症等都可能导致不同程度的听力损失,认识颞骨内结构的精细解剖是疾病诊疗的第一步。显微计算机断层成像技术是一种新兴影像技术,分辨率达微米量级,可得到颞骨活体或标本的中、内耳结构,较目前临床CT观察到更加精细的中、内耳结构以及复杂的毗邻关系,尤其为认识中耳生理、病理传声机制提供帮助。

宣城网纹红土成分与微结构的定量研究

网纹红土红色基质和白色网纹的成分和结构差异性影响并控制着工程特性。文章通过扫描电子显微镜(scanning electron microscope,SEM)实验和数字图像处理技术定量研究原状网纹红土的微孔隙特征,进而基于能量色散谱仪(energy dispersive spectrometer,EDS)和X射线衍射仪(X-ray diffractometer,XRD)分析了红色基质和白色网纹的化学成分和黏土矿物构成,以探讨网纹红土微结构和成分与其力学特征的内在联系。研究得出,网纹红土孔隙主要为小于0.5μm2面积的微孔隙,而面积超过50μm2的大孔隙则较少,但红色基质颗粒表面粗糙、棱角分明,主要由绿泥石/蒙脱石混层和伊利石以及少量的绿泥石和高岭石构成,而白色网纹颗粒则较为圆滑,由伊利石/蒙脱石混层和伊利石构成,且红色基质中Fe元素质量分数高于白色网纹,而两者中的Ti元素质量分数稳定。研究结果可为深入分析网纹红土工程特征提供依据。

天然矿物Wadsleyite在我国首次发现

对于在毫县陨石中发现的X矿物，本文用电子探针获得了其化学成分：（Mg1.6271Fe0.3729）2SiO4，用X射线微区衍射得到了其结构参数。该矿物属斜方晶系，晶胞参数α＝0．8264，b＝1．1448，c＝0.5704nm。这些结果证明了它是Wadsleyite，是橄榄石的高压相──β（Mg，Fe）2SiO4由冲击变质作用形成的。该矿物呈包裹体产出，在我国属首次发现。

X射线衍射仪微机化升级改造的讨论与实践

介绍一种旧型号的X射线衍射仪微机化的升级改造技术以及相应的数据采集与分析系统 (XRDS)。该系统将采集的衍射数据以文件形式存盘 ,并对该数据文件进行分析处理。结果可用图谱显示、打印、生成峰数据表、或扫描数据表等多种形式输出。原仪器记录系统仍可独立工作。系统结构简单 ,能充分利用仪器的机械精度 ,改造工作只需连接几对信号线便可完成 ,价格低廉 ,适用于任何旧型号的X射线衍射仪。

D/max-A型X射线衍射仪升级改造研究

D／max－A型X射线衍射仪升级改造项目采用工业控制机原理，设计了与IBM兼容计算机相配的通用接口和相应的软件，实现了在日本理学D／max－A型X射线衍射仪上用IBM－PC机取代原单片机和操作台的升级改造。由此建立的JA型X射线衍射仪微机控制系统对测角仪转角控制精密、准确、可靠，数据采集实时、准确。它不仅保留了原系统的所有功能，保持了仪器原有的精度和分辨率，而且还增加了自动光路零位校正功能，由于采用了IBM兼容计算机，其图形和数据功能更强、更方便，并可按用户要求进行扩展。新建立的系统同时适用D／max－B和C型机以及任何以步进马达驱动的X射线衍射仪的升级改造。这对我国现有1000名台D／max系列X射线行射仪进行升级改造，以IBM－PC机彻底取代与之不相兼容的早期的日本CASIO计算机（单片机式和二级计算机式）控制系统，在X射线衍射仪控制技术上摆脱对原生产厂家的依赖，实现控制系统的国产化、经济化、实用化具有重要的意义和可观的经济效益。

一种毛细管聚焦的微束X射线衍射仪

微区X射线衍射(micro-X-ray diffraction)分析在测量小样品或样品微区结构方面有着独特的优势.介绍了实验室自行研发的台式毛细管聚焦的微束X射线衍射仪(μ-Hawk),其主要由微焦斑X射线管、毛细管X光透镜、接收狭缝、SDD X射线探测器、θ-θ测角仪、三维样品台,以及在Lab VIEW语言环境下开发的计算机控制程序等部分组成.控制程序的主界面具备微区X射线衍射分析和微区能量色散X射线荧光分析两种分析模式.为了验证设备的可行性,分别对一枚人民币五角硬币上"角"字第一划中央处的微区和直径为140μm的铜质导线进行微区点分析;对苹果手机主板焊锡接触点上1.0 mm×0.6 mm区域内的物相分布进行二维扫描分析,具体方式为在二维待测区域内逐点自动执行θ-θ角度扫描,由程序控制的4个电机来实现此过程.分析结果表明,μ-Hawk所具备的微区能量色散X射线荧光分析模式,为物相结构的识别提供了元素种类的参考信息;与常规的X射线衍射仪相比较,μ-Hawk所采集的衍射图整体本底较低,并且所测得的衍射峰位置基本一致;μ-Hawk能适应小样品或样品微区物相结构的分析和物相分布的二维扫描分析,在材料科学、地球科学和文物保护等领域有着广泛的应用前景.

一种微束X射线衍射仪及其应用研究

本文研究了一种微束X射线衍射仪,并对其硬件、软件和性能进行了介绍。该衍射仪采用毛细管X光透镜将X射线束会聚到μm量级,并通过由PLC和步进电机等组成的闭环运动控制系统调节三维样品台来实现对样品微区的物相分析和物相的二维扫描分析。利用自行开发的控制软件实现了微区X射线衍射分析和微区能量色散X射线荧光分析两种模式。为了验证设备的可行性,采用本微束X射线衍射仪以微区X射线衍射的方式扫描了苹果手机主板的焊锡接触点上1.0 mm×0.6 mm的区域,得到了区域内SnO2(312)的晶相分布图。此外,利用本微束X射线衍射仪分析了1片清代红绿彩瓷表面的白色瓷釉和彩料中钾长石和钙长石等主要的晶相,这些实验数据可为古代瓷器的烧制工艺提供有益的参考。因此,这种微束X射线衍射仪在材料、文物保护等研究领域具有广泛的应用前景。

XRD测试材料表面微区残余应力

残余应力是影响材料尤其是复合结构件连接强度的主要因素。选用X射线衍射仪测试样品的残余应力具有无损、检测区域小、可测量材料中的三类残余应力等优点。采用TZM合金(钼锆钛合金)与Ti 2 AlNb合金扩散焊界面为研究对象,Ni箔作为中间层材料,利用Bruker D8 advance X射线衍射仪(XRD)采用侧倾法测试中间层厚度不同对材料接头处残余应力的影响。利用X射线衍射仪测量微区样品表面残余应力为高校利用常见X射线衍射仪测试微区试样的残余应力提供了实验指导。