碘量法测定铜冶炼烟尘中铜含量

研究了铜冶炼烟尘中铜含量的测定方法,试料用盐酸、氢氟酸、硝酸、高氯酸及硫酸分解,氢溴酸除去砷、锡、锑,硫酸除去硒的干扰。进一步对滴定条件和共存元素的干扰及消除进行了实验,最终确定了最佳条件。按照实验方法测定6个铜冶炼烟尘样品中铜含量,结果的相对标准偏差为0.22%～0.65%,精密度高,准确度好。样品加标回收率在98.9%～100%,适用于铜冶炼烟尘中铜含量为5.00%～65.00%的样品测定。     

碘量法测定铜冶炼烟尘中铜

试验研究了铜冶炼烟尘中铜含量的测定方法,试料用盐酸、氢氟酸、硝酸、高氯酸及硫酸分解,氢溴酸除去砷、锡、锑,硫酸除去硒的干扰。进一步对滴定条件和共存元素的干扰及消除进行了试验,最终确定了最佳条件。按照实验方法测定6个铜冶炼烟尘样品中铜量,结果的相对标准偏差为0.22%~0.65%,精密度高,准确度好。样品加标回收率在98.92%~100.38%之间, 适用于铜冶炼烟尘中铜含量为5.00 %～65.00 %的测定。     

碘量法测定铜冶炼烟尘中铜含量

研究了铜冶炼烟尘中铜含量的测定方法,试料用盐酸、氢氟酸、硝酸、高氯酸及硫酸分解,氢溴酸除去砷、锡、锑,硫酸除去硒的干扰。进一步对滴定条件和共存元素的干扰及消除进行了实验,最终确定了最佳条件。按照实验方法测定6个铜冶炼烟尘样品中铜含量,结果的相对标准偏差为0.22%～0.65%,精密度高,准确度好。样品加标回收率在98.9%～100%,适用于铜冶炼烟尘中铜含量为5.00%～65.00%的样品测定。     

电感耦合等离子体光谱法测定铜冶炼烟尘中锌

本实验介绍了电感耦合等离子体光谱法测定铜冶炼烟尘中锌含量的分析方法。针对样品碳,硅含量高的特点,有针对性的研究了样品的消解方法,确定采用盐酸、硝酸、氢氟酸、高氯酸对铜冶炼烟尘样品进行消解。同时进行了干扰试验,确定样品中高含量的铜,铅,砷等对样品测定结果没有影响。并对仪器的工作参数进行了优化。方法检出限为为0.011 mg/L,测定下限为0.019 mg/L,3个样品的相对标准偏差在0.54%~0.92%之间,加标回收率在96%~101.14%之间。该方法样品消解完全,流程短,操作简单,快速,测定准确度高,可以满足铜冶炼烟尘中锌含量的测定。     

碱熔酸浸试样–碘量法测定铜冶炼白烟尘中的铜

建立碱熔酸浸试样–碘量法测定铜冶炼白烟尘中铜的方法。采用氢氧化钾–硝酸钾混合溶剂熔融试样,用盐酸浸取,以溴消除砷、锑等元素的干扰,用碘量法测定铜的含量。对滴定条件及共存元素的干扰和消除进行了验证,从而确定了最佳测定条件。实验最佳条件:4 g氢氧化钾和0.5 g硝酸钾混合溶剂;马弗炉温度650 ℃;样品称样量0.300 0 g;硫代硫酸钠标准溶液浓度0.02 mol/L。采用该实验条件,铜冶炼白烟尘中的铜测定结果相对标准偏差在0.37%~0.83%之间(n=10),样品加标回收率为98.30%~101.40%。该方法分析时间短,测定结果准确可靠,具有良好的精密度,可用于铜冶炼白烟尘中铜的测定。     

电感耦合等离子体原子发射光谱（ICP-AES）法测定铜冶炼烟尘中锌

建立了电感耦合等离子体原子发射光谱(ICP-AES)法测定铜冶炼烟尘中锌含量的分析方法。针对样品中碳、硅含量高的特点,有针对性地研究了样品的消解方法,确定采用盐酸、硝酸、氢氟酸、高氯酸对铜冶炼烟尘样品进行消解。同时进行了干扰实验,确定样品中高含量的铜、铅、砷等对样品测定结果没有影响。并对仪器的工作参数进行了优化。方法检出限为0.011mg/L,测定下限为0.019mg/L,3个样品的相对标准偏差在0.54%～0.92%,加标回收率在96.0%～101%。样品消解完全,流程短,操作简单,快速,测定准确度高,可以满足铜冶炼烟尘中锌含量的测定。     

火焰原子吸收光谱法测定铜冶炼烟尘中铋

本文研究了测定铜冶炼烟尘中铋含量0.050% ~5.00%的火焰原子吸收光谱法。对铜冶炼烟尘试样的溶解、测定体系中酸介质的影响和各干扰元素进行了试验研究。制定了铜冶炼烟尘中铋含量的原子吸收光谱法。方法标准偏差为0.0013 %~ 0.057 %,相对标准偏差为0.78 % ~1.44 %,样品加标回收率为98.95%~101.87%。本方法具有灵敏度高、结果准确、操作简便等特点,适合铜冶炼烟尘中铋含量0.050 % ~ 5.00 % 的测定。     

倾动式阳极炉冶炼废杂铜二噁英排放特征研究

再生铜行业是我国二噁英排放的重点行业之一,研究再生铜行业不同冶炼方式下二噁英的排放特征对我国再生铜行业二噁英的污染防治具有重要意义。本文以再生铜倾动式阳极炉为对象,研究了倾动式阳极炉冶炼废杂铜在除尘设施前后的二噁英排放特征,并提出了其二噁英的产生机理。     

粉末压片-X射线荧光光谱法测定铜冶炼炉前各种炉渣、冰铜中5种组分

应用X荧光光谱仪结合压片法制样快速测定铜冶炼中炉前的炉渣和冰铜中的铜、铁、二氧化硅、氧化钙及冰铜中各组分的分析。利用手工分析制备质控样品作为标准物质绘制工作曲线,解决了炉前样品没有标准样品的问题。对炉前分析样品基体不稳定带来的背景干扰,采用手工分析对照,不断调整工作曲线进行对照校正,通过质控管理能够满足生产指标控制的要求。分析结果表明,方法的相对标准偏差(RSD)为0.01%~0.28%,测定结果与通用的容量法分析结果对比,结果基本一致。     

红外吸收光谱法鉴定进口中亚铜矿和含铜物料

基于阿拉山口口岸重要地理位置,结合进口中亚铜矿和含铜物料情况,按照国别收集阿拉山口口岸进口铜矿和含铜物料样品。利用红外吸收光谱可根据未知物在红外吸收光谱中吸收峰的强度、位置和形状,确定该未知物分子中包含有哪些基团,从而推断该未知物结构的性质,通过优化实验条件,对铜矿和含铜物料进行定性鉴定技术的研究,并建立符合新疆口岸进口中亚国家铜矿产品谱图库,便于快速确定矿产国别及品质源头,防止低含量铜冶炼残渣易名高含量铜精矿进口,危害国家利益。     

碘量法测定废杂铜屑中的铜含量

采用硝酸-盐酸溶解样品,在硫酸体系下加入氢溴酸,使得氢溴酸与试样中的砷、锑、锡等元素反应生成易挥发的溴化物,从而消除其干扰,滴定前用氟化氢氨掩蔽铁,在pH=3.0～4.0的范围采用碘量法测定废杂铜屑中的铜含量。用于测定金属样废杂铜屑中铜的含量,测定结果的相对标准偏差(RSD,n=7)为0.20%～0.25%,加标回收率在98.8%～101%,方法简单准确,能够满足日常检测需求。     

进口铜精矿属性鉴别过程中的思考

随着我国铜精矿进口量的日益增加及物料性质趋于复杂,有必要采用科学高效的方法对矿产品开展属性鉴别,来规避矿产品进口贸易中潜在的风险。本次对某疑似“掺杂明铜”的进口铜精矿开展物性鉴定,采用矿物自动分析仪（BPMA）、光学显微镜、X-射线衍射仪等综合手段查明了产品中的物质组成和结构特征,并从矿床成因、冶金机理、选矿工艺等多角度对该铜精矿的产出来源和生产工艺进行了深入研究和探讨,论证产品中未掺杂有冶金组分,最终确定其为天然铜精矿。从而协助了海关部门对该货源顺利通关,也保障了贸易双方的权益,实现境外战略资源的有效利用。     

Synthesis and thermal characterization of copper and calcium mixed phosphates

A series of compounds with composition of Ca_1–xCu_xHPO₄, where x varied from 0.05 to 0.5 were synthesized by precipitation method. The compounds were characterized by elemental analysis, X-ray diffraction, infrared spectroscopy, scanning electron microscopy, and thermogravimetry. The chemical stabilities of solids were investigated at several pH. Elemental analysis of copper, calcium and phosphorus are in agreement with the proposed composition. The formation of lamellar phosphates was evidenced. The stability of the set of compounds was better for samples with high copper content.     

固体进样直接测定法测定铜精矿中汞

建立了固体进样直接测定法测定铜精矿中汞含量的方法。铜精矿样品在测汞仪的分解炉中经300℃干燥和750℃高温热分解后,汞被催化分解为汞原子,于850℃齐化成金汞齐。汞蒸气被氧气流带入单波长光学吸收池,在波长253.7 nm处测量汞的吸光度,采用标准曲线法计算汞量。方法的线性范围分别为0~1.00,0~100μg/mL,线性相关系数为0.9999,检出限分别为0.10,0.04 ng/g。5个汞含量不同的铜精矿样品测定结果的相对标准偏差为2.14%~4.35%(n=11),样品加标回收率为92.00%~104.02%。采用该方法分别对2个铜精矿样品和铜精矿国际标准物质进行测定,测定结果与标准分析方法测定值和标准物质标示值基本一致。该方法简便、快速、准确,可以作为标准方法推广使用。     

Ultraviolet spectrophotometric determination of copper in copper ores by flow-injection analysis

A flow-injection analysis (FIA) method for the ultraviolet spectrophotometric determination of copper in copper ores is described. The ore samples are dissolved in concentrated perchloric acid, the excess acid is neutralized with ammonia solution, and the resulting solution is used for the determination of copper. The UV-FIA system is based on the reaction of copper (II) ions with pyrophosphate and subsequent measurement of the absorbance of the dipyrophosphatocuprate (II) complex at 240 nm. The main factors which control the formation of this complex and the FIA variables influencing the system are discussed. The calibration graph is linear from 2-50 ppm copper. At a sampling rate of about 70 samples h(-1) with 50 mul sample injections, precision was about 1% relative standard deviation. Results obtained compare well with those obtained by atomic absorption spectrometry.     

Microwave plasma torch mass spectrometry for the direct detection of copper and molybdenum ions in aqueous liquids

Microwave plasma torch (MPT) is a simple and low power‐consumption ambient ion source. And the MPT Mass spectra of many metal elements usually exhibit some novel features different from their inductively coupled plasma (ICP) mass spectra, which may be helpful for metal element analysis. Here, we presented the results about the MPT mass spectra of copper and molybdenum elements by a linear ion trap mass spectrometer (LTQ). The generated copper or molybdenum contained ions in plasma were characterized further in collision‐induced dissociated (CID) experiments. These researches built a novel, direct and sensitive method for the direct analysis of trace levels of copper and molybdenum in aqueous liquids. Quantitative results showed that the limit of detection (LOD) by using MS² procedure was estimated to be 0.265 µg/l (ppb) for copper and 0.497 µg/l for molybdenum. The linear dynamics ranges cover at least 2 orders of magnitude and the analysis of a single aqueous sample can be completed in 5–6 min with a reasonable semi‐quantitative sense. Two practical aqueous samples, milk and urine, were also analyzed qualitatively with reasonable recovery rates and RSD. These experimental data demonstrated that the MPT MS is able to turn into a promising and hopeful tool in field analysis of copper and molybdenum ions in water and some aqueous media, and can be applied in many fields, such as environmental controlling, hydrogeology, and water quality inspection. Moreover, MPT MS could also be used as the supplement of ICP‐MS for the rapid and in‐situ analysis of metal ions. Copyright © 2016 John Wiley & Sons, Ltd.     

Application of a new nanoporous sorbent for extraction and pre-concentration of lead and copper ions

The authors describe a method for the trace determination of copper (II) and lead (II) in water and fish samples using solid-phase extraction via siliceous mesocellular foam functionalised by dithizone. Siliceous mesocellular was functionalised with dithizone, and the resulting sorbent was characterised by scanning electron microscopy, surface area analysis, thermogravimetric/differential thermal analysis and FTIR. Following solid-phase extraction of target ions by the sorbent, copper and lead ions were quantified by flame atomic absorption spectrometry. Factors affecting the sorption and desorption of target ions by the sorbent were evaluated and optimised. The calibration plot is linear in the 1 – 500 μg L^?1 copper (II) and 3–700 μg L^?1 lead (II) concentration range. The relative recovery efficiency in real sample analysis is in the range from 96 to 102%, and precision varies between 1.7 and 2.8%. It is should be noted that the limits of detection for the copper and lead analysis were 0.8 and 1.6 μg L^?1, respectively. Also, the adsorption capacities for copper and lead ions were 120 and 160 mg g^?1, respectively. The obtained pre-concentration factor for the lead and copper ions by the proposed solid-phase extraction was 75. The method was successfully applied to the determination of low levels of copper (II) and lead (II) in tap, Caspian sea, Persian gulf and lake water and also their detection in fish samples.     

A pre-concentration procedure employing a new imprinted polymer for the determination of copper in water

This work describes the development by response surface methodology (RSM) of a procedure for copper determination by inductively coupled plasma optical emission spectrometry (ICP OES) in water samples after extraction by copper imprinted polymer. Results of the two-level full factorial design (2⁴) based on an analysis of variance demonstrated that only the solution pH; amount of polymer and adsorption time were statistically significant. Optimal conditions for the extraction of copper samples were obtained by using Box-Behnken design. Solution pH; amount of polymer and adsorption time were regarded as factors in the optimisation study. The working conditions were 4.6, 0.03?g and 3.5?h, for solution pH, amount of polymer; and adsorption time, respectively. Under the optimised experimental conditions, the detection limit of the proposed method followed by ICP OES was found to be 0.8?µg?L^?1. The relative standard deviation (RSD) was found to less than 0.81%. The pre-concentration factor was 22.5. The accuracy of the optimised procedure was evaluated by analysis of certified reference material. The method was applied to the determination of copper in water samples.     

Novel synthesis of copper oxide on fabric samples by cathodic cage plasma deposition

The fabrics with copper or copper oxide deposition are of considerable interest because of exceptional antibacterial properties, which are useable in medical, textiles, and hygiene applications. Unfortunately, the conventional techniques take long processing time, complex equipment, and combination of several processing steps (nanoparticles synthesis and their deposition on fabrics). In this novel study, cathodic cage plasma deposition assisted with copper cathodic cage is used for the synthesis of the copper oxide on polyester and polyamide fabrics. For the enhancement of synthesis efficiency, the effect of cathodic cage lid thickness is also investigated. The samples are assessed by using scanning electron microscopy, elemental dispersive spectroscopy, and X‐ray photoelectron spectroscopy. It is found that using cathodic cage plasma deposition, fabrics can be successfully synthesized by the copper oxide with comparatively small treatment time, cost‐effectively, and environmentally friendly. Interestingly, cathodic cage plasma treatment is already proved to be working effectively on industrial scale; thus, it is predicted to be of noteworthy importance for fabrics processing on large‐scale garments manufacturing and hospitals.