28 October 2025, Volume 45 Issue 10
    

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  • Revealing the technology evolution of inductively coupled plasma atomic emission spectrometry through bibliometrics and knowledge mapping
    MAO Yueying
    Metallurgical Analysis. 2025, 45(10): 1-7. https://doi.org/10.13228/j.boyuan.issn1000-7571.012940
    Abstract ( ) Download PDF ( )   Knowledge map   Save
    The research landscape, knowledge structure, and evolution trends in the field of inductively coupled plasma atomic emission spectrometry (ICP-AES) were systematically analyzed in this study based on the CNKI database, using bibliometrics and knowledge mapping methods. The analysis, conducted with the aid of visualization tools, included statistics on the yearly distribution of articls, contributions of institutions, high frequency key words, and highly cited articls. The results showed that: (1) Temporally, research on ICP-AES grew rapidly after 1991 and reached its peak in 2013 (with 571 articles published annually); (2) Different institutions exhibited distinct innovation pathways; (3) Research topics focused on heavy metal detection, industrial material analysis, and biomedical applications, while technical bottlenecks were primarily concentrated on spectral interference and uncertainty control; (4) The highly cited articles from 2001 to 2014 were concentrated in a core group of journals, namely Metallurgical Analysis, Spectroscopy and Spectral Analysis, and Rock and Mineral Analysis(collectively accounting for 45.9%), highlighting its interdisciplinary nature. The study concluded that ICP-AES technology sustains its vitality through interdisciplinary integration, and future innovation should be driven by technological convergence (e.g., integration with artificial intelligence). This study provides an empirical reference for technical planning and interdisciplinary intersection in the field of analytical chemistry.
  • Application of F-test in limit value evaluation of standard deviation for analytical instrument
    SUN Xiaofei, ZHANG Xiuxin, YANG Jingwei, YANG Guowu
    Metallurgical Analysis. 2025, 45(10): 8-15. https://doi.org/10.13228/j.boyuan.issn1000-7571.012879
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    The limit value of the standard deviation of 10 repeated measurements is commonly used as a criterion for factory acceptance and precision inspection of analytical instruments. However, testing standards typically provide only the laboratory repeatability limit (r), which is the critical value for the difference between two independent measurement results of the analyte. The standard deviation of repeated measurements (instrument precision, Sn) and the repeatability limit (r) cannot be directly compared. This study establishes the relationship between the repeatability limit (r) and the instrumental measurement standard deviation (Sn) using the F-test, to determine whether the instrument precision meets the precision requirements of the testing standard. The results were compared with those from the χ2-distribution method and the range method. The results indicate that when the degree of freedom γ2=30, the F-test yields results consistent with those of the χ2-distribution method and the range method. Therefore, all three methods can be used as general approaches to evaluate whether the instrument precision complies with the requirements of a specific testing method. When γ2 ≤ 16, the upper limit of the standard deviation obtained by the F-test is significantly higher than that calculated by the other two methods. In such cases, the F-test should be applied for data evaluation, as the other methods may incorrectly classify some qualified data as unqualified. The testing method for hydrogen content in steel was used as an example to verify whether the precision of a hydrogen analyzer meets the requirements of the testing method.
  • Determination of gallium,rubidium and strontium in rare earth metals and their oxides by inductively coupled plasma tandem mass spectrometry
    LIU Danna, ZHANG Hao, FAN Xiaolong, BAO Xiangchun
    Metallurgical Analysis. 2025, 45(10): 16-22. https://doi.org/10.13228/j.boyuan.issn1000-7571.012807
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    The determination of Ga, Rb, and Sr in rare earth metals and their oxides by inductively coupled plasma mass spectrometry (ICP-MS) is severely affected by double-charge interferences from matrix elements such as La, Ce, Er, Yb, and Lu, compromising the accuracy of the results. This study established a method using inductively coupled plasma tandem mass spectrometry (ICP-MS/MS). Samples were digested with nitric acid and hydrogen peroxide, and diluted with 1% (V/V) nitric acid for analysis. Rh was employed as the internal standard to correct for matrix effects, and the tandem quadrupole (MS/MS) mode was used to eliminate double-charge interferences from the rare earth matrix. The mass-to-charge ratio (m/z) of the first mass filter (Q1) was set to transmit ions at m/z of 69, 85, and 88. Ammonia (NH3) was introduced into the collision/reaction cell. Under these conditions, the analyte ions (69Ga+, 85Rb+, 88Sr+) do not react with NH3, while the interfering double-charged ions (e.g., 138La++, 138Ce++, 170Er++, 170Yb++, 176Yb++, 176Lu++) undergo reaction with NH3, forming product ions with m/z different from the analytes. The second mass filter (Q2) was then set to m/z of 69, 85, and 88, allowing only the unaffected analyte ions to pass through to the detector, thus effectively eliminating the mass spectral interference. The NH3 flow rate was optimized, and the optimal value was found to be 1.80 mL/min. The calibration curves showed excellent linearity with correlation coefficients all greater than 0.999 9. The limits of detection (LODs) for Ga, Rb, and Sr ranged from 0.003 8 to 0.026 μg/g, and the limits of quantification (LOQs) were between 0.012 and 0.084 μg/g. This method was applied to determine Ga, Rb, and Sr in synthetic neodymium metal, synthetic samarium metal, CeO2, Er2O3, and Yb2O3 samples. The relative standard deviations (RSDs,n=11) ranged from 3.8% to 13.5%, and the spike recoveries were in the range of 88% to 114%.
  • Frontiers in multi-domain applications and detection technology breakthroughs of strategic metal gallium
    CHEN Junbin, LI Jingyin, LIU Dong, HUANG Honghua WU Jingwu, MAI Baohua, FENG Junli
    Metallurgical Analysis. 2025, 45(10): 23-29. https://doi.org/10.13228/j.boyuan.issn1000-7571.012826
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    Gallium(Ga), as a critical strategic metal, has attracted increasing research attention due to its irreplaceable role in high-frequency semiconductors, optoelectronic devices, and new energy technologies. This paper provides a systematic review of Ga’s applications across four major domains: high-frequency semiconductor devices (e.g.,GaN HEMT power amplifiers and GaAs space solar cells), biomedical tracers (e.g.,67Ga-labeled diagnostic agents), self-healing electrode materials (e.g.,liquid metal batteries), and magnetic functional components (e.g.,gadolinium gallium garnet magneto-optical devices). Furthermore, a comprehensive evaluation is presented on Ga detection methodologies, covering wet chemical methods, spectroscopic analysis, inductively coupled plasma mass spectrometry (ICP-MS), electrochemical methods, and emerging detection technologies. The findings aim to offer technical support for export regulatory authorities and provide a basis for establishing standardized procedures in testing institutions. Finally, this article offers a forward-looking perspective on the future directions of Ga applications and the evolution of detection technologies, with the goal of providing valuable insights for further research in this field.
  • Solid waste attribute identification of an imported aluminum scrap sample
    ZHOU Junlong, TANG Zhikun, SHEN Dan, ZHAO Quan, LIN Chunmei CHEN Yihao, LI Quanzhong, XIAO Dahui
    Metallurgical Analysis. 2025, 45(10): 30-35. https://doi.org/10.13228/j.boyuan.issn1000-7571.012862
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    This study established a method for identifying the solid waste attributes of imported aluminum scrap claimed as “Recycled Casting Aluminum Alloy Raw Materials”. A combination of techniques was employed, including visual inspection, ultra-depth-of-field microscopy for microstructural morphology, inductively coupled plasma atomic emission spectroscopy (ICP-AES), X-ray fluorescence spectrometry (XRF), and X-ray diffraction (XRD) for compositional, phase, and characteristic element analysis (e.g., lithium, nickel, cobalt). Residual carbon content was measured using an infrared carbon-sulfur analyzer, and the suitability of the sample for direct use as high-quality recycled aluminum feedstock was evaluated via a high-frequency melting furnace. Results showed that the sample consisted of fine gray-white particles. Under microscopy, the aluminum scrap exhibited a wrinkled morphology with numerous black granular inclusions. After sieving through a 120-mesh sieve, XRF revealed a significant decrease in aluminum content in the fine fraction, along with synchronous increases in nickel, cobalt, manganese, and copper. ICP-AES further confirmed the abundance of copper, nickel, cobalt, manganese, and lithium in the sieved fraction. XRD and infrared carbon-sulfur analysis detected lithium nickel cobalt manganese oxide and a small amount of carbon in the sample. During high-frequency melting, the sample produced intense flashing and left substantial residue, with a metal recovery rate below 30% and failure to form liquid metal. These characteristics neither comply with the quality requirements for aluminum scrap stipulated in GB/T 38472-2023 of Recycled Casting Aluminum Alloy Raw Materials nor align with those of conventional machined aluminum scraps. The elemental composition and phase characteristics are consistent with the properties of recycled lithium battery cathode materials. Based on the analysis of the recycling process for aluminum foil current collectors from ternary lithium battery cathodes and in accordance with GB 34330-2017 of General Principles for Identification of Solid Waste Attributes, the sample is identified as solid waste derived from recycled aluminum scrap of ternary lithium battery cathode materials.
  • Distribution and segregation behavior of sulfides in 20Cr engineering machinery steel billet
    ZHOU Yan, ZHAO Zengwu, SONG Zhendong, LI Duoduo
    Metallurgical Analysis. 2025, 45(10): 36-44. https://doi.org/10.13228/j.boyuan.issn1000-7571.012802
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    This study investigates the segregation behavior of sulfides in 20Cr engineering machinery steel billets produced by a domestic steel plant. Using optical microscopy (OM), electron probe microanalysis (EPMA), and Thermo-Calc software, the distribution and segregation characteristics of sulfides were systematically analyzed. Elemental analysis revealed that the inclusions in the billet are predominantly MnS, with a small number of complex inclusions(composed of an Al2O3 core and an MnS shell)observed near the edge, consistent with thermodynamic calculations. The morphology of MnS transitions from isolated particles at the edge to chain-like and cluster-like formations toward the center. The highest area fraction and most non-uniform distribution of MnS were found in the center of the billet, followed by the 1/4 thickness position. A solute microsegregation model was established to simulate the precipitation process. In the first stage of MnS precipitation, the positive segregation rate of S significantly exceeded that of Mn, and the consumption rate of Mn remained lower than the enrichment rate of S. The diffusion of Mn was identified as the limiting factor for MnS precipitation, leading to the initial formation of fine MnS particles. In the second stage, consumption of S accelerated solidification, increasing the relative concentration of solute elements and promoting the expulsion of S into interdendritic regions, resulting in the clustered precipitation of MnS.
  • Research advances in analytical and detection technologies for mercury speciation
    NI Ziyue, FAN Zhen, YUE Yuanbo, LI Cheng, CHENG Dawei, LIU Mingbo
    Metallurgical Analysis. 2025, 45(10): 45-51. https://doi.org/10.13228/j.boyuan.issn1000-7571.012878
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    Given the significant differences in toxicity among various mercury species, the detection of total mercury and its individual species plays a crucial role in monitoring, source tracing, and environmental toxicological assessment of mercury pollution. This review summarizes recent advances in the separation, enrichment, and analytical methods for different mercury species. For mercury speciation separation, chromatographic techniques and sequential extraction methods are predominantly employed. Separation can also be achieved using specific materials that leverage differences in adsorption or desorption energies among mercury species. When mercury concentrations in separated or digested solutions are too low, liquid-liquid extraction or solid-phase extraction combined with elution can be applied to directly increase the concentration of target mercury species. Alternatively, taking advantage of mercury’s facile atomization, vapor generation devices can be used to reduce matrix interference and achieve indirect enrichment. In addition to providing an overview of these separation and enrichment strategies, this article compares and summarizes the characteristics and applicability of conventional instrumental methods, rapid analysis techniques, and non-instrumental methods for mercury detection.
  • Change and interpretation of the term “performance” in new and old version of national standard GB/T 27043
    ZHANG Huiliang, WANG Haiyan, XIANG Xinhua, HE Ping
    Metallurgical Analysis. 2025, 45(10): 52-58. https://doi.org/10.13228/j.boyuan.issn1000-7571.012881
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    ISO/IEC 17043:2023 Conformity assessment-General requirements for the competence of proficiency testing providers has been officially released. Due to the continuous development and evolution in the field of conformity assessment, the 2023 edition has involved in significant changes in English title and technical contents compared with the 2010 edition. In order to adapt to these changes and improve the scientificity of the standards, and also help readers further understand the connotation of international standards, in the process of the equivalent transformation of ISO/IEC 17043:2023 to China’s national recommended standards, the translators changed the translation of “performance” (which was widespread in the standard and related to result evaluation), literally from “competence evaluation” in GB/T 27043-2012 to “performance evaluation”. Meanwhile, the translation of “proficiency testing”, which had been widely accepted in China, was kept without change. The translation of “competence” was also unchanged, which was consistent with other national recommended standards for conformity assessment. This paper discriminated the connotation and differences of the above three English words, and introduced the background, reasons and guiding direction of the maintenance and change of translations, aiming to promote the correct understanding and application of the above concepts by proficiency testing providers and participants.
  • Cause analysis of surface damage on the inner ring of a gearbox bearing
    MA Ruidong, WANG Gangjun, LI Qinglin, YE Zhi, XIE Jinpeng LI Zhen, ZHAO Xiao, LIU Chang
    Metallurgical Analysis. 2025, 45(10): 59-65. https://doi.org/10.13228/j.boyuan.issn1000-7571.012915
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    Common bearing failures in gearboxes are typically caused by issues such as fatigue, wear, defects, and indentations. However, the mechanism of rolling contact fatigue (RCF) failure remains a subject of debate. This study investigates the failure mode of RCF in a wind turbine gearbox bearing, where failure occurred due to spalling of the inner ring. Quantitative analyses of chemical composition and hardness were performed, alongside macroscopic and microscopic morphological examinations of the damaged area. The results indicate that the RCF failure is attributed to the synergistic effect of high load and the presence of white etching areas (WEAs, comprising nano-ferrite). Microcrack initiation was observed at the interface between subsurface non-metallic inclusions (MnS) and the matrix. Additionally, WEAs, resulting from carbon migration, were found distributed on both sides of these inclusions. The small size and deformable nature of the MnS inclusions (less than 20 μm) contribute only limitedly to local stress concentration. Therefore, the primary cause of premature bearing failure is the combined action of high load and the brittle white etching areas, which accelerates the initiation and propagation of surface damage.
  • Determination of copper,lead,zinc and arsenic in copper smelting dust by energy dispersive X-ray fluorescence spectrometry
    ZHONG Kangxiang, CHEN Zhuhai, LUO Ronggen, LAI Qiuxiang, LIU Chunhua
    Metallurgical Analysis. 2025, 45(10): 66-72. https://doi.org/10.13228/j.boyuan.issn1000-7571.012808
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    Copper smelting dust mainly consists of Cu, Pb, Zn, and As. The contents of these elements are key indicators for evaluating smelting process efficiency, environmental impact control, resource recovery value, and the selection of subsequent treatment processes. In this study, a pressed powder pellet method was employed for sample preparation. The samples were ground to a particle size of 74 μm, mixed with soluble starch as a diluent at a 1∶1 mass ratio, and then pressed with boric acid as a binder for backing and encasement. Smooth and flat pellets were formed under a pressure of 20 t for 20 s. Calibration curves were established using nine production samples of copper smelting dust with varying concentration gradients of each element, with reference values determined according to YS/T 1512.10-2022. Matrix corrections for Cu, Pb, and Zn were performed using the empirical coefficient method, while the ratio method was applied for As. This approach enabled rapid determination of Cu, Pb, Zn, and As in copper smelting dust by energy dispersive X-ray fluorescence spectrometry (ED-XRF). The linear correlation coefficients of the calibration curves for all elements were no less than 0.996 6, and the limits of detection ranged from 0.001 8% to 0.021%. The relative standard deviations (RSD,n=7) for the determination of Cu, Pb, and Zn in production samples were between 0.15% and 2.8%. The proposed method was further compared with YS/T 1512.10-2022, and the results for Cu, Pb, Zn, and As were in good agreement.
  • Determination of free carbon in tungsten carbide powder by high-frequency combustion infrared absorption method with porous crucible collection
    YU Hang, LI Jiahua, ZHOU Yuanjing
    Metallurgical Analysis. 2025, 45(10): 73-77. https://doi.org/10.13228/j.boyuan.issn1000-7571.012877
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    Tungsten carbide powder is a key raw material in hard alloy production, and its free carbon (Cf) content is a critical quality control indicator. Addressing the limitations of the current national standard method (GB/T 5124.2-2008 gravimetric method), which is cumbersome and time-consuming, this study proposes a novel approach using a porous crucible collection system coupled with high-frequency combustion infrared absorption for determining free carbon. By regulating micropores in the crucible with alumina suspension to prevent particle penetration, the method allows direct drying and measurement of the separated sample, thereby eliminating transfer-related errors. It reduces processing time by approximately 4 hours per sample compared to the national standard, with even greater efficiency gains in batch analysis. The optimized procedure uses 0.50 g of sample along with a flux mixture of 0.5 g of pure iron, 1.6 g of tungsten, and 0.05 g of tin. The limit of detection (LOD) and limit of quantification (LOQ) of the method were 0.000 93% and 0.003 1%, respectively. The relative standard deviations (RSD,n=7) for free carbon determination in four tungsten carbide powder samples ranged from 0.51% to 3.8%. Validation using certified reference material GSB 04-3138-2014 showed that the measured values agreed with the certified values. Comparative evaluation with the national standard GB/T 5124.2-2008 demonstrated that the proposed method achieves significantly lower RSD.
  • Determination of lithium oxide in lithium ores by flame photometry
    LIN Yingling, CHEN Zhuhai, LONG Xiujia, CAO Yu ZOU Xiaofen, ZHANG Houqiang
    Metallurgical Analysis. 2025, 45(10): 78-82. https://doi.org/10.13228/j.boyuan.issn1000-7571.012902
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    Lithium ore serves as one of the primary sources of lithium metal, making the rapid and accurate determination of its lithium oxide content crucial for efficient resource development and comprehensive utilization. This study established a flame photometry method for determining lithium oxide in lithium ores. Samples were digested using a mixture of 10 mL hydrofluoric acid and 2 mL sulfuric acid (1+1), with a 0.5%-1% (V/V) sulfuric acid solution selected as the measurement medium. Results indicated that common easily ionizable elements (potassium, sodium, calcium, magnesium, rubidium, cesium, and strontium) caused no interference in the lithium determination. A excellent linear relationship was observed between the mass concentration of lithium oxide in the range of 0.50 to 30.00 μg/mL and the emission intensity, with a correlation coefficient (r) of 0.999. The method achieved a limit of detection of 0.001% for lithium oxide. The proposed method was applied to determine lithium oxide in CRMs lithium ore (GBW07152, GBW07153), CRM spodumene (GBW07734), a actual lithium ore sample, and a simulated high-lithium sample (with a lithium oxide mass fraction of 10%). The relative standard deviations (RSD, n=11) of the results ranged from 0.60% to 2.5%. Comparative analysis of one lithium ore sample and two certified reference materials (GBW07152 and GBW07153) using both this method and the national standard method (GB/T 17413.1-2010) yielded consistent results. Furthermore, the measured values for the reference materials agreed well with their certified values. This method is simple, cost-effective, and provides a reliable solution for the quantitative analysis of lithium oxide in remote mining areas and beneficiation/metallurgical laboratories.
  • Determination of Se(Ⅳ) and Se(Ⅵ) in soil available selenium by hydride generation-atomic fluorescence spectrometry
    SONG Juanjuan, ZHANG Mo, YU Congling, ZOU Jiajie, QIN Chong, SUN Lianwei
    Metallurgical Analysis. 2025, 45(10): 83-87. https://doi.org/10.13228/j.boyuan.issn1000-7571.012791
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    Accurate determination of the speciation distribution of Se(Ⅳ) and Se(Ⅵ) in soil available selenium is crucial for studying the migration and transformation processes of selenium in the soil-plant system. The challenge lies in completely digesting the available selenium while preserving the original valence states. In this study, the available selenium extract was obtained following NY/T 3420-2019. After digestion with a nitric-perchloric acid system (ensuring valence stability of Se(Ⅳ) and Se(Ⅵ) during the perchloric acid fuming stage), the digest was treated as follows: (1) dissolved with 50% HCl(V/V) under heating to reduce Se(Ⅵ) to Se(Ⅳ), and total available selenium was determined by hydride generation-atomic fluorescence spectrometry (HG-AFS); (2) dissolved with 10%(V/V) HCl at room temperature to maintain the valence of Se(Ⅵ), and the content of Se(Ⅳ) was determined by HG-AFS; (3) the content of Se(Ⅵ) was calculated by subtracting Se(Ⅳ) from total available selenium. A method for determining Se(Ⅳ) and Se(Ⅵ) in soil available selenium by HG-AFS was thus established. Key parameters of the method were as follows: hydrochloric acid carrier concentration of 5%(V/V), potassium borohydride solution mass concentration of 13.0 g/L; interference was negligible when the concentration of coexisting elements did not exceed 500 times that of selenium. Method validation showed good linearity for Se(Ⅳ) in the range of 2.00-12.00 μg/L, with a linear correlation coefficient (r) of 0.999 7. The limits of detection for available selenium and Se(Ⅳ) were 0.001 2 mg/kg and 0.001 6 mg/kg, respectively. The method was applied to determine total available selenium, Se(Ⅳ), and Se(Ⅵ) in soil certified reference materials GBW(E)070333, GBW(E)070334, and GBW(E)070339. The relative standard deviations (RSD,n=6) of the results ranged from 1.9% to 15%. The relative error (RE) between measured and certified values of available selenium was 0.59%-5.3%. The spike recoveries of Se(Ⅳ) and Se(Ⅵ) ranged from 91% to 108%, meeting the requirements of DZ/T 0289-2015 Specification for Regional Eco-geochemical Assessment.
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