{"title":"保加利亚东南部东罗多贝古近系火山区酸性火山流纹岩-珍珠岩过渡带","authors":"Y. Yanev","doi":"10.52215/rev.bgs.2022.83.1.51","DOIUrl":null,"url":null,"abstract":"In the siliceous volcanoes, the transition between rhyolites and perlite is carried out through a zone with the following morphology: i) rhyolite balls (spheruloids with spherulitic or felsitic texture) among the perlites; ii) alternation of subparallel perlite and rhyolite bands with felsitic texture; iii) a combination of the above two morphologies – rhyolite bands with spheruloids adhering to them; iv) alternation of finger-like wedge-shaped perlite and rhyolite wedges. The rhyolite spheruloids have Na composition (they are composed of tridymite and Na-K feldspar), while the perlites including them, as well as all rhyolites in the Eastern Rhodopes, are potassic. This chemistry, as well as many morphological features, show their immiscibility origin, which has been recently proven also experimentally (Kotel’nikov et al., 2016, 2019). Complex spheruloids are also observed, which consist of two types of spheruloids with different distribu¬tion of alkalis in them: small, in which Na>K and large spheruloids, which include small ones and in which potassium predominates. It is assumed that they are a product of a two-step immiscibility – in the first step large drops and matrix are formed, and in the second the large drops decompose into small drops (enriched with Na) and a new matrix (enriched with potassium), which is the building element of the large drops. The drops crystallize as spherulites, while the matrix solidifies as perlite. The spheruloids are products of nucleation and growth mechanism, i.e. they are formed in the fields between the binodal and spinodal curves. The other type of transition – the alternation of perlite and rhyolite bands is assumed to be formed by the spinodal decomposition, i.e. in the field limited by the spinodal curves.","PeriodicalId":40733,"journal":{"name":"Spisanie Na B Lgarskoto Geologichesko Druzhestov-Review of the Bulgarian Geological Society","volume":" ","pages":""},"PeriodicalIF":0.2000,"publicationDate":"2022-06-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Rhyolite-perlite transition zone in the acid volcanoes of the Eastern Rhodopes Paleogene volcanic area (SE Bulgaria)\",\"authors\":\"Y. 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Complex spheruloids are also observed, which consist of two types of spheruloids with different distribu¬tion of alkalis in them: small, in which Na>K and large spheruloids, which include small ones and in which potassium predominates. It is assumed that they are a product of a two-step immiscibility – in the first step large drops and matrix are formed, and in the second the large drops decompose into small drops (enriched with Na) and a new matrix (enriched with potassium), which is the building element of the large drops. The drops crystallize as spherulites, while the matrix solidifies as perlite. The spheruloids are products of nucleation and growth mechanism, i.e. they are formed in the fields between the binodal and spinodal curves. 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引用次数: 0
摘要
在硅质火山中,流纹岩和珍珠岩之间的过渡是通过一个具有以下形态的带进行的:1)在珍珠岩之间的流纹岩球(具有球粒或长晶石质地的球体);Ii)近平行的珍珠岩和流纹岩带交替存在,具有长绒质结构;Iii)上述两种形态的结合——流纹岩带上附着球状体;指状楔状珍珠岩与流纹岩楔的交替。流纹岩球粒由钾钾长石和钾钾长石组成,含钠球粒的珍珠岩以及东罗杜贝所有流纹岩均为钾质。这种化学性质以及许多形态特征显示了它们的非混溶性起源,这一点最近也得到了实验证明(Kotel 'nikov et al., 2016, 2019)。还观察到复杂的球体,它由两种类型的球体组成,其中碱的分布不同:小球体,其中Na bbbbk和大球体,其中包括小球体,其中钾占主导地位。假设它们是两步不混溶的产物——第一步形成大液滴和基质,第二步大液滴分解成小液滴(富含Na)和新基质(富含钾),这是大液滴的构建元素。液滴结晶为球晶,而基体凝固为珍珠岩。椭球体是在双节曲线和单节曲线之间的场中形成的,是形核和生长机制的产物。另一种类型的过渡-珍珠岩和流纹岩带的交替被认为是由旋多分解形成的,即在受旋多曲线限制的场中形成的。
Rhyolite-perlite transition zone in the acid volcanoes of the Eastern Rhodopes Paleogene volcanic area (SE Bulgaria)
In the siliceous volcanoes, the transition between rhyolites and perlite is carried out through a zone with the following morphology: i) rhyolite balls (spheruloids with spherulitic or felsitic texture) among the perlites; ii) alternation of subparallel perlite and rhyolite bands with felsitic texture; iii) a combination of the above two morphologies – rhyolite bands with spheruloids adhering to them; iv) alternation of finger-like wedge-shaped perlite and rhyolite wedges. The rhyolite spheruloids have Na composition (they are composed of tridymite and Na-K feldspar), while the perlites including them, as well as all rhyolites in the Eastern Rhodopes, are potassic. This chemistry, as well as many morphological features, show their immiscibility origin, which has been recently proven also experimentally (Kotel’nikov et al., 2016, 2019). Complex spheruloids are also observed, which consist of two types of spheruloids with different distribu¬tion of alkalis in them: small, in which Na>K and large spheruloids, which include small ones and in which potassium predominates. It is assumed that they are a product of a two-step immiscibility – in the first step large drops and matrix are formed, and in the second the large drops decompose into small drops (enriched with Na) and a new matrix (enriched with potassium), which is the building element of the large drops. The drops crystallize as spherulites, while the matrix solidifies as perlite. The spheruloids are products of nucleation and growth mechanism, i.e. they are formed in the fields between the binodal and spinodal curves. The other type of transition – the alternation of perlite and rhyolite bands is assumed to be formed by the spinodal decomposition, i.e. in the field limited by the spinodal curves.