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科学通报 2012

地幔转换带橄榄石高压相变实验研究

DOI: 10.1360/csb2012-57-7-542, PP. 542-549

吴耀,王雁宾,张艳飞,金振民,王超,周春银

Keywords: 地幔转换带,橄榄石,高压相变,上地幔结构,高温高压实验,中国东部

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Abstract:

橄榄石是上地幔的主要矿物之一,它的相变对于认识地幔不连续面的成因,整个地幔的物质组成和演化、地幔对流、俯冲板片深源地震等地球深部动力学问题具有重要意义.本研究使用中国地质大学地球深部研究实验室多面砧压机进行了2种成分的橄榄石(Fo100和Fo90)在压力为14.1~20GPa,温度为1400℃的相变实验研究.压力为14.8~15.6GPa时,Fo90和Fo100均转变为瓦兹利石(β);而在14.1GPa实验中,Fo90完全转变为瓦兹利石,Fo100则仍为橄榄石(α).瓦兹利石具有2种产状破碎的粒状结构(粒度大于100μm)和微晶集合体(微晶粒度小于10μm).瓦兹利石拉曼谱图中显示722~723和917~919cm-1特征峰.随着压力升高,实验产物中出现更多的呈微晶集合体结构产出的瓦兹利石,表明实验压力离橄榄石相变边界越远,瓦兹利石成核密度越大,导致体系Gibbs自由能下降,高压相矿物颗粒生长受到抑制.但由于瓦兹利石成核活化能很小,因此实验产物中均有大量呈微晶集合体产出的瓦兹利石.实验产物的显微结构特征对解释陨石中出现瓦兹利石的产状提供高温高压实验启示.压力为19.5和20GPa时实验产物为林伍德石(γ),其中压力为19.5GPa的实验中Fo100中瓦兹利石和林伍德石共存.实验产物林伍德石为自形粒状(颗粒度为10~20μm),三联点结构发育.798和840cm-1为林伍德石的拉曼特征峰.综合本次研究以及前人地震探测结果表明,中国东部上地幔复杂结构无法用单一的橄榄石体系相变来解释,其他矿物(如辉石-石榴石)的相变及其与橄榄石体系相变的相互影响可能导致了该地区上地幔具有复杂的结构.因此进一步开展复杂体系(如橄榄石+辉石体系)的高温高压相变实验研究,并在已有地球物理探测成果的基础上建立合理的地质-岩石学模型,对探讨中国东部地区上地幔复杂结构形成的物理机理,影响因素及其深部动力学机制具有重要意义.

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