{"title":"镧系元素,稀土金属","authors":"W. Wells, Vickie L. Wells","doi":"10.1002/0471435139.TOX043","DOIUrl":null,"url":null,"abstract":"The lanthanides (or lanthanons) are a group of 15 elements of atomic numbers from 57 through 71 in which scandium (atomic number 21) and yttrium (atomic number 39) are sometimes included. The lanthanide series proper is that group of chemical elements that follow lanthanum in its group IIIB column position of the periodic table. Their distinguishing atomic feature is that they fill the 4f electronic subshell. Actually, only those elements with atomic numbers 58–71 are lanthanides. Most chemists also include lanthanum in the series because, although it does not fill the 4f subshell, its properties are very much like those of the lanthanides. The elements scandium and yttrium are also known as the “rare earths” because they were originally discovered together with the lanthanides in rare minerals and isolated as oxides, or “earths.” In comparison with many other elements, however, the rare earths are not really rare, except for promethium, which has only radioactive isotopes. Yttrium, lanthanum, cerium, and neodymium are all more abundant than lead in the earth's crust. All except promethium, which probably does not occur in nature, are more abundant than cadmium. The relative abundance and atomic numbers are tabulated and the more common lanthanide compounds are listed. \n \n \n \nScandium is a silvery white metallic chemical element, the first member of the first transition-metal series in the periodic table. The name is derived from Scandinavia, where the element was discovered in the minerals euxenite and gadolinite. In 1876, L. F. Nilson prepared about 2 g of high purity scandium oxide. It was subsequently established that scandium corresponds to the element “ekaboron,” predicted by Mendeleyev on the basis of a gap in the periodic table. Scandium occurs in small quantities in more than 800 minerals and causes the blue color of aquamarine beryl. \n \n \n \nYttrium is one of four chemical elements (the others are erbium, terbium, and ytterbium) named after Ytterby, a village in Sweden that is rich in unusual minerals and rare earths. Yttrium is a metal with a silvery luster and properties closely resembling those of rare earth metals. It is the first member of the second series of transition metals. Yttrium is found in several minerals and is produced primarily from the ore material xenotime. \n \n \n \nLanthanum is a white, malleable metal; it is the first member of the third series of transition metals, and the first of the rare earths. Lanthanum is found with other lanthanides in the ore minerals monazite, bastnaesite, and xenotime, and in other minerals. It was discovered in 1839 by the Swedish chemist Carl G. Mosander. Scientists have created many radioactive isotopes of lanthanum. \n \n \n \nThe physical and chemical properties of the lanthanides are given. The unique characteristic of the chemistry of the lanthanides is their similarity. \n \n \n \nThe elements occur together in nature in large part due to their chemical similarity. The exception is promethium, which is radioactive and probably occurs naturally only in trace amounts, if at all. The elements are extremely difficult to separate. Modern ion-exchange and repeated fractional crystallization techniques have been developed that result in the availability of pure (99.99%) materials. \n \n \n \nThe all lanthanides are silvery white, very reactive metals with high melting points. Solubility differences among ionic forms of the lanthanides seem to influence their metabolic fate in biological systems. In general, the toxicity of the lanthanides decreases as the atomic number increases, probably because of the greater solubility and ionic stability of the heavier lanthanide ions. \n \n \n \nRelatively little is known about the chemistry of scandium, even though it is not particularly rare. Its chemistry resembles that of aluminum in many ways. Yttrium is very similar to scandium. It is also an active metal. \n \n \n \nThe pulmonary toxicity of inhaled lanthanides has been the subject of debate. The relative contributions of radioactive versus stable elements in the development of lanthanide-associated progressive pulmonary interstitial fibrosis has been questioned. Although contamination of the dust of lanthanides with radioactive materials may accelerate and enhance the pathological response, depending on the form and dose of radioactivity encountered, there is little evidence to suggest that the level of radioactive contamination of occupationally encountered lanthanide dusts is sufficient to be included as a risk factor for pulmonary disease. \n \n \n \nNo standards have been recommended for any of the other lanthanides because either suitable data for setting a standard, such as inhalation studies, or studies on individual lanthanides are lacking. However, because of the accumulating evidence of induction of fibrosis with the lanthanides and their expanding use, the exposure should probably be limited to 1 mg/m3. \n \n \nKeywords: \n \nLanthanides; \nScandium; \nLanthanum; \nNeodymium; \nCerium; \nEuropium; \nGadolinium; \nTerbium; \nDysprosium; \nErbium; \nYtterbium; \nYttrium; \nOxides; \nChlorides; \nNitrates; \nLiver; \nKidneys; \nLungs; \nMonazite","PeriodicalId":19820,"journal":{"name":"Patty's Toxicology","volume":null,"pages":null},"PeriodicalIF":0.0000,"publicationDate":"2001-04-16","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"21","resultStr":"{\"title\":\"The Lanthanides, Rare Earth Metals\",\"authors\":\"W. Wells, Vickie L. Wells\",\"doi\":\"10.1002/0471435139.TOX043\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"The lanthanides (or lanthanons) are a group of 15 elements of atomic numbers from 57 through 71 in which scandium (atomic number 21) and yttrium (atomic number 39) are sometimes included. The lanthanide series proper is that group of chemical elements that follow lanthanum in its group IIIB column position of the periodic table. Their distinguishing atomic feature is that they fill the 4f electronic subshell. Actually, only those elements with atomic numbers 58–71 are lanthanides. Most chemists also include lanthanum in the series because, although it does not fill the 4f subshell, its properties are very much like those of the lanthanides. The elements scandium and yttrium are also known as the “rare earths” because they were originally discovered together with the lanthanides in rare minerals and isolated as oxides, or “earths.” In comparison with many other elements, however, the rare earths are not really rare, except for promethium, which has only radioactive isotopes. Yttrium, lanthanum, cerium, and neodymium are all more abundant than lead in the earth's crust. All except promethium, which probably does not occur in nature, are more abundant than cadmium. The relative abundance and atomic numbers are tabulated and the more common lanthanide compounds are listed. \\n \\n \\n \\nScandium is a silvery white metallic chemical element, the first member of the first transition-metal series in the periodic table. The name is derived from Scandinavia, where the element was discovered in the minerals euxenite and gadolinite. In 1876, L. F. Nilson prepared about 2 g of high purity scandium oxide. It was subsequently established that scandium corresponds to the element “ekaboron,” predicted by Mendeleyev on the basis of a gap in the periodic table. Scandium occurs in small quantities in more than 800 minerals and causes the blue color of aquamarine beryl. \\n \\n \\n \\nYttrium is one of four chemical elements (the others are erbium, terbium, and ytterbium) named after Ytterby, a village in Sweden that is rich in unusual minerals and rare earths. Yttrium is a metal with a silvery luster and properties closely resembling those of rare earth metals. It is the first member of the second series of transition metals. Yttrium is found in several minerals and is produced primarily from the ore material xenotime. \\n \\n \\n \\nLanthanum is a white, malleable metal; it is the first member of the third series of transition metals, and the first of the rare earths. Lanthanum is found with other lanthanides in the ore minerals monazite, bastnaesite, and xenotime, and in other minerals. It was discovered in 1839 by the Swedish chemist Carl G. Mosander. Scientists have created many radioactive isotopes of lanthanum. \\n \\n \\n \\nThe physical and chemical properties of the lanthanides are given. The unique characteristic of the chemistry of the lanthanides is their similarity. \\n \\n \\n \\nThe elements occur together in nature in large part due to their chemical similarity. The exception is promethium, which is radioactive and probably occurs naturally only in trace amounts, if at all. The elements are extremely difficult to separate. Modern ion-exchange and repeated fractional crystallization techniques have been developed that result in the availability of pure (99.99%) materials. \\n \\n \\n \\nThe all lanthanides are silvery white, very reactive metals with high melting points. Solubility differences among ionic forms of the lanthanides seem to influence their metabolic fate in biological systems. In general, the toxicity of the lanthanides decreases as the atomic number increases, probably because of the greater solubility and ionic stability of the heavier lanthanide ions. \\n \\n \\n \\nRelatively little is known about the chemistry of scandium, even though it is not particularly rare. Its chemistry resembles that of aluminum in many ways. Yttrium is very similar to scandium. It is also an active metal. \\n \\n \\n \\nThe pulmonary toxicity of inhaled lanthanides has been the subject of debate. The relative contributions of radioactive versus stable elements in the development of lanthanide-associated progressive pulmonary interstitial fibrosis has been questioned. Although contamination of the dust of lanthanides with radioactive materials may accelerate and enhance the pathological response, depending on the form and dose of radioactivity encountered, there is little evidence to suggest that the level of radioactive contamination of occupationally encountered lanthanide dusts is sufficient to be included as a risk factor for pulmonary disease. \\n \\n \\n \\nNo standards have been recommended for any of the other lanthanides because either suitable data for setting a standard, such as inhalation studies, or studies on individual lanthanides are lacking. However, because of the accumulating evidence of induction of fibrosis with the lanthanides and their expanding use, the exposure should probably be limited to 1 mg/m3. \\n \\n \\nKeywords: \\n \\nLanthanides; \\nScandium; \\nLanthanum; \\nNeodymium; \\nCerium; \\nEuropium; \\nGadolinium; \\nTerbium; \\nDysprosium; \\nErbium; \\nYtterbium; \\nYttrium; \\nOxides; \\nChlorides; \\nNitrates; \\nLiver; \\nKidneys; \\nLungs; \\nMonazite\",\"PeriodicalId\":19820,\"journal\":{\"name\":\"Patty's Toxicology\",\"volume\":null,\"pages\":null},\"PeriodicalIF\":0.0000,\"publicationDate\":\"2001-04-16\",\"publicationTypes\":\"Journal Article\",\"fieldsOfStudy\":null,\"isOpenAccess\":false,\"openAccessPdf\":\"\",\"citationCount\":\"21\",\"resultStr\":null,\"platform\":\"Semanticscholar\",\"paperid\":null,\"PeriodicalName\":\"Patty's Toxicology\",\"FirstCategoryId\":\"1085\",\"ListUrlMain\":\"https://doi.org/10.1002/0471435139.TOX043\",\"RegionNum\":0,\"RegionCategory\":null,\"ArticlePicture\":[],\"TitleCN\":null,\"AbstractTextCN\":null,\"PMCID\":null,\"EPubDate\":\"\",\"PubModel\":\"\",\"JCR\":\"\",\"JCRName\":\"\",\"Score\":null,\"Total\":0}","platform":"Semanticscholar","paperid":null,"PeriodicalName":"Patty's Toxicology","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.1002/0471435139.TOX043","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}
引用次数: 21
摘要
镧系元素(或镧系元素)是一组原子序数从57到71的15种元素,其中有时包括钪(原子序数21)和钇(原子序数39)。镧系系是指在元素周期表的IIIB族列位中紧跟镧之后的一组化学元素。它们独特的原子特征是它们填满了4f电子亚层。实际上,只有那些原子序数为58-71的元素才是镧系元素。大多数化学家还把镧也包括在这个系列中,因为尽管它不填满4f亚壳层,但它的性质与镧系元素非常相似。元素钪和钇也被称为“稀土”,因为它们最初是与稀有矿物中的镧系元素一起被发现的,并作为氧化物或“地球”被分离出来。然而,与许多其他元素相比,稀土其实并不稀有,除了只有放射性同位素的钷。钇、镧、铈和钕在地壳中的含量都比铅丰富。除了自然界中可能不存在的钷以外,其他元素的含量都比镉高。将相对丰度和原子序数制成表格,并列出较常见的镧系化合物。钪是一种银白色的金属化学元素,是元素周期表中第一个过渡金属系列的第一个成员。这个名字来源于斯堪的纳维亚半岛,在那里,这种元素是在矿物永长石和钆长石中发现的。1876年,l·f·尼尔森制备了约2g的高纯氧化钪。随后确定钪对应于门捷列夫根据元素周期表中的一个间隙所预测的元素“ekaboron”。钪少量存在于800多种矿物中,使海蓝宝石呈现蓝色。钇是四种化学元素中的一种(其他三种是铒、铽和镱),它是以瑞典一个盛产稀有矿物和稀土的村庄Ytterby命名的。钇是一种具有银色光泽的金属,其性质与稀土金属非常相似。它是第二系列过渡金属的第一个成员。钇存在于几种矿物中,主要由矿物材料xenotime产生。镧是一种白色的、可延展的金属;它是过渡金属第三系的第一个成员,也是稀土的第一个成员。镧与其他镧系元素一起存在于矿石独居石、氟碳铈矿和钇铝钇石以及其他矿物中。1839年,瑞典化学家Carl G. Mosander发现了它。科学家们已经制造出许多镧的放射性同位素。给出了镧系元素的物理和化学性质。镧系元素化学的独特特征是它们的相似性。这些元素在自然界中一起出现,很大程度上是由于它们在化学上的相似性。唯一的例外是钷,它是放射性的,自然中可能只有微量存在,如果真的存在的话。这些元素极难分离。现代离子交换和重复分式结晶技术的发展,导致纯度(99.99%)材料的可用性。所有的镧系元素都是银白色的,熔点很高,非常活泼。镧系元素离子形式的溶解度差异似乎影响了它们在生物系统中的代谢命运。一般来说,镧系元素的毒性随着原子序数的增加而降低,这可能是因为较重的镧系元素离子具有更大的溶解度和离子稳定性。人们对钪的化学性质所知相对较少,尽管它并不特别罕见。它的化学性质在许多方面与铝相似。钇和钪很相似。它也是一种活性金属。吸入镧系元素的肺毒性一直是争论的主题。放射性元素与稳定元素在镧系相关的进行性肺间质纤维化发展中的相对贡献一直受到质疑。虽然镧系尘埃与放射性物质的污染可能会加速和加强病理反应,这取决于所遇到的放射性的形式和剂量,但几乎没有证据表明,职业上遇到的镧系尘埃的放射性污染水平足以作为肺部疾病的一个危险因素。没有建议任何其他镧系元素的标准,因为要么缺乏制定标准的适当数据,例如吸入研究,要么缺乏对单个镧系元素的研究。然而,由于越来越多的证据表明镧系元素可诱导纤维化及其使用范围的扩大,暴露量可能应限制在1 mg/m3。
The lanthanides (or lanthanons) are a group of 15 elements of atomic numbers from 57 through 71 in which scandium (atomic number 21) and yttrium (atomic number 39) are sometimes included. The lanthanide series proper is that group of chemical elements that follow lanthanum in its group IIIB column position of the periodic table. Their distinguishing atomic feature is that they fill the 4f electronic subshell. Actually, only those elements with atomic numbers 58–71 are lanthanides. Most chemists also include lanthanum in the series because, although it does not fill the 4f subshell, its properties are very much like those of the lanthanides. The elements scandium and yttrium are also known as the “rare earths” because they were originally discovered together with the lanthanides in rare minerals and isolated as oxides, or “earths.” In comparison with many other elements, however, the rare earths are not really rare, except for promethium, which has only radioactive isotopes. Yttrium, lanthanum, cerium, and neodymium are all more abundant than lead in the earth's crust. All except promethium, which probably does not occur in nature, are more abundant than cadmium. The relative abundance and atomic numbers are tabulated and the more common lanthanide compounds are listed.
Scandium is a silvery white metallic chemical element, the first member of the first transition-metal series in the periodic table. The name is derived from Scandinavia, where the element was discovered in the minerals euxenite and gadolinite. In 1876, L. F. Nilson prepared about 2 g of high purity scandium oxide. It was subsequently established that scandium corresponds to the element “ekaboron,” predicted by Mendeleyev on the basis of a gap in the periodic table. Scandium occurs in small quantities in more than 800 minerals and causes the blue color of aquamarine beryl.
Yttrium is one of four chemical elements (the others are erbium, terbium, and ytterbium) named after Ytterby, a village in Sweden that is rich in unusual minerals and rare earths. Yttrium is a metal with a silvery luster and properties closely resembling those of rare earth metals. It is the first member of the second series of transition metals. Yttrium is found in several minerals and is produced primarily from the ore material xenotime.
Lanthanum is a white, malleable metal; it is the first member of the third series of transition metals, and the first of the rare earths. Lanthanum is found with other lanthanides in the ore minerals monazite, bastnaesite, and xenotime, and in other minerals. It was discovered in 1839 by the Swedish chemist Carl G. Mosander. Scientists have created many radioactive isotopes of lanthanum.
The physical and chemical properties of the lanthanides are given. The unique characteristic of the chemistry of the lanthanides is their similarity.
The elements occur together in nature in large part due to their chemical similarity. The exception is promethium, which is radioactive and probably occurs naturally only in trace amounts, if at all. The elements are extremely difficult to separate. Modern ion-exchange and repeated fractional crystallization techniques have been developed that result in the availability of pure (99.99%) materials.
The all lanthanides are silvery white, very reactive metals with high melting points. Solubility differences among ionic forms of the lanthanides seem to influence their metabolic fate in biological systems. In general, the toxicity of the lanthanides decreases as the atomic number increases, probably because of the greater solubility and ionic stability of the heavier lanthanide ions.
Relatively little is known about the chemistry of scandium, even though it is not particularly rare. Its chemistry resembles that of aluminum in many ways. Yttrium is very similar to scandium. It is also an active metal.
The pulmonary toxicity of inhaled lanthanides has been the subject of debate. The relative contributions of radioactive versus stable elements in the development of lanthanide-associated progressive pulmonary interstitial fibrosis has been questioned. Although contamination of the dust of lanthanides with radioactive materials may accelerate and enhance the pathological response, depending on the form and dose of radioactivity encountered, there is little evidence to suggest that the level of radioactive contamination of occupationally encountered lanthanide dusts is sufficient to be included as a risk factor for pulmonary disease.
No standards have been recommended for any of the other lanthanides because either suitable data for setting a standard, such as inhalation studies, or studies on individual lanthanides are lacking. However, because of the accumulating evidence of induction of fibrosis with the lanthanides and their expanding use, the exposure should probably be limited to 1 mg/m3.
Keywords:
Lanthanides;
Scandium;
Lanthanum;
Neodymium;
Cerium;
Europium;
Gadolinium;
Terbium;
Dysprosium;
Erbium;
Ytterbium;
Yttrium;
Oxides;
Chlorides;
Nitrates;
Liver;
Kidneys;
Lungs;
Monazite