大别山北部石榴辉石麻粒岩流体包裹体研究

大别山北部石榴辉石麻粒岩是一种基性麻粒岩,岩石中富含有大量CO_2、CH_4、H_2S、H_2O流体包裹体,及含子晶多相包裹体。首次在寄主矿物石榴石、透辉石发现有含固相的多相包裹体。经拉曼光谱及电镜分析,固相部分为石榴石,辉石、重晶石和铁的氧化物;气相成分为H_2O、CO、CO_2、H_2S、H_2、CH_4、C_2H_2等,均一温度分别为950℃、975℃。指示着石榴辉石麻粒岩在形成过程中,在还原气氛下曾经发生过局部深熔作用,产生在组成上近于石榴石、辉石的熔体。这种溶体被正在结晶的石榴石,透辉石所捕获。石榴石中早期的含石榴石子晶+CO_2多相包裹体其CO_2密度为0.65～0.626g/cm~3;二相的 CO_2包裹体,CO_2部分的均一温度26～28.2℃,为晚期捕获的低密度CO_2包裹体,密度为0.648～0.688g/cm~3。石英中三相H_2O-CO_2包裹体,Th=331～410℃,CO_2-水合物溶化温度7.3°～8.6℃,是一种低盐度包裹体,CO_2部分均一温度:25.7～28℃,CO_2密度0.65～0.698g/cm~3为早中期捕获的包裹体。整个岩石中未发现高密度CO_2流体包裹体。表明麻粒岩可以形成在低密度CO_2之中。H_2O-NaCl包体均一温度80～475℃,密度0.36～1.026g/cm~3,主要为晚期包裹体,少数高密度H_2O包裹体,为早期捕获的包裹体。通过流体包裹体等容线确立石榴辉石麻粒岩P-T轨迹为     

蔓箐沟一带石榴基性麻粒岩变质反应与矿物演化

蔓箐沟地区石榴基性麻粒岩发育多期变质反应结构。矿物组合演化可划分三个阶段：①峰期阶段（Ｍ１）,以包裹于石榴石中的Ｏｐｘ＋Ｃｐｘ±Ｈｂ＋Ｐｌ±Ｑｚ和由Ｇｔ＋Ｏｐｘ＋Ｃｐｘ±Ｈｂ＋Ｐｌ±Ｑｚ组成基质矿物组合为代表;②退变早期近等温减压阶段（Ｍ２）,形成蠕虫状后成合晶Ｏｐｘ＋Ｈｂ＋Ｐｌ±Ｍｔ;③退变晚期阶段（Ｍ３）,则形成细粒、黄绿色Ｈｂ＋中酸性Ｐｌ的较低温组合。并揭示该区石榴基性麻粒岩从中下部地壳的麻粒岩相变质,到快速抬升至中浅部地壳发生的近等温减压及晚期降温退变的复杂ｐＴ演化历史。     

胶东海阳所,葛家集基性麻粒岩P—5演化及成因意义

胶东地体中麻粒岩相岩石主要分布于米山断裂以西，而榴辉岩等高压岩石组合主林分布于该断裂以东，通过对米山断裂以西的海阳所，葛家集两地基性麻岩岩石学，矿物学和岩石热力学研究后得出：海阳所麻粒岩主要经历了３期变质作用，其Ｐ－Ｔ演化趋势为顺时针方向。     

承德北部高压基性麻粒岩的同位素年龄及其地质意义

最近在承德市北部地区发现了许多呈透镜状包体产于花岗片麻岩中的高压基性麻粒岩。运用全岩Ｓｍ －Ｎｄ、Ｒｂ－Ｓｒ、单颗粒锆石Ｕ－Ｐｂ 等多种同位素方法对这些高压麻粒岩进行了年代测定,得出了７个可供研究的年龄数据,即全岩Ｓｍ －Ｎｄ 等时线年龄２５５０±２１Ｍａ和３０６０±２．３Ｍａ,全岩Ｒｂ－Ｓｒ等时线年龄１５５０±３３Ｍａ 和１５６８Ｍａ,和单颗粒锆石Ｕ－Ｐｂ 同位素不一致线的上、下交点年龄分别为３４３２±５５６Ｍａ 和１８１７±１７Ｍａ, 颗粒锆石的谐和年龄１８３１±４ Ｍａ。在详细分析这些年代学数据可能的地质解释的基础上,认为该区的高压麻粒岩经历了复杂的地质演化过程,推测其原岩最早可能形成于新太古代早期至中太古代,并经受了太古宙末期花岗质岩浆侵入和变质作用改造。但其高压麻粒岩相变质很可能是古元古代末一次碰撞造山作用的产物, 最终进入上地壳可能在中元古代早期才完成, 与中元古代地壳的大规模拉张和燕辽裂陷槽的形成有关     

内蒙古固阳朱拉沟基性麻粒岩T—P轨迹

本文通过对内蒙古朱拉沟基性麻粒岩的岩石学、矿物学及温度、压力等研究,建立了基性麻粒岩形成所经历的P-T轨迹,解释了基性麻粒岩形成的大地构造环境。     

冀西北麻粒岩相花岗质片麻岩中矿物的流体包裹体特征及其地质意义

本文报道了冀西北地区麻粒岩相片麻岩中矿物内流体包裹体的特征并讨论了其地质意义。根据包裹体的形态、赋存状态并结合包裹体ＣＯ２密度的演化,在麻粒岩相花岗质片麻岩的矿物中可识别出四种类型的流体包裹体：１）一相富ＣＯ２包裹体、２）气液两相富ＣＯ２包裹体、３）三相含液态ＣＯ２包裹体,４）含石盐子晶的多相包裹体。不同类型包裹体的特征和密度等表明,该区花岗质片麻岩经历了三个阶段的变质过程。第一阶段,在麻粒岩相变质作用峰期之后捕获了高密度的富ＣＯ２包裹体。在第二阶段形成了两相富ＣＯ２包裹体。第三阶段捕获了低密度的三相含液态ＣＯ２包裹体。这种很低密度的流体包裹体反映了晚期变形和退变质期间的温压条件     

大别山铙钹寨被麻粒岩相变质作用改造的变质超镁铁岩体：石榴辉石岩证据

对大别山铙钹寨超镁铁岩体中石榴辉石岩的研究表明，铙钹寨岩体经历了从尖晶石－富铝辉石相（750度，1．1GPa)，尖晶石－石榴石相（850度，1．5GPa)到麻粒岩相（800度，0．85GPa)的变质演化，该岩体与南大别超高压变质杂岩的演化过程存在很大差异，它基本上处于一较高温地热体制之下，属于南大别俯冲陆壳的上盘杂岩，铙钹寨岩体及其它超镁铁岩体的普遍麻粒岩化与区域麻粒岩相的相关性可能说明大别变质基底已被彻底改造，北大别（安徽省内）目前所展示的高级变质作用仅是印支期后麻粒岩相变质事件的反映。     

阴山陆块武川石榴基性麻粒岩P-T条件及其变质时代:来自相平衡模拟与锆石U-Pb定年的约束

武川高级片麻岩地体中石榴基性麻粒岩的变质用与同位素年代学研究对于揭示阴山陆块新太古代构造演化过程具有十分重要的研究意义。它们主要以不规则透镜体或变形岩墙/岩脉群的形式赋存于新太古代晚期英云闪长质片麻岩或变质表壳岩系之中,并切割近南-北向的区域性片麻理。岩相学观察、矿物相转变分析与矿物化学研究表明,武川石榴基性麻粒岩保留了十分典型的高压麻粒岩相矿物:石榴石+单斜辉石+斜长石+角闪石+石英+铁-钛氧化物。其中,粗粒石榴石边部常发育微弱的扩散环带,表现为从幔部至边部,镁铝榴石组分不断减少,相应地铁铝榴石组分不断增加,而钙铝榴石与锰铝榴石组分基本不变,指示晚期冷却降温作用对石榴石成分产生一定影响。斜长石具有细粒包体型与粗粒基质型两种不同的类型,它们具有十分相似化学成分,均为An=35~45的中长石。在NCFMASHTO(Na_2O-CaO-FeO-MgO-Al_2O_3-SiO_2-H_2O-TiO_2-Fe_2O_3)体系下,利用THERM OCA LC 3.33软件,对两件石榴基性麻粒岩样品进行了相平衡模拟,模拟的峰期矿物组合为:石榴石+单斜辉石+斜长石+角闪石+石英+铁-钛氧化物,与岩相学观察十分一致。采用石榴石中最小x(g)Fe~(2 +)/(Fe~(2 +)+Mg))与斜长石是中最小ca(pl)(Ca/(Ca+Na))等值线,将本区石榴基性麻粒岩峰期高压麻粒岩相的温压条件限定在P=1.31~1.40GPa,T=770~840℃的范围内。LA-ICP-MS锆石U-Pb定年结果表明,两件石榴基性麻粒岩麻粒岩中发育的变质锆石分别记录了2517±6Ma(BT58-1,MSWD=0.66,n=21)与2512±16Ma(LH66-1,MSWD=0.26,n=42)的加权平均年龄,与阴山陆块其它新太古代岩石记录的约2500Ma变质年龄一致,被解释为本区石榴基性麻粒岩遭受高压麻粒岩相变质时代。结合本区其它新的研究资料,本文认为武川石榴基性麻粒岩形成可能与区内新太古代晚期造山作用有关。     

南阿尔金巴什瓦克石榴橄榄岩的变质演化

南阿尔金巴什瓦克地区石榴橄榄岩在空间上呈透镜体状与高压基性麻粒岩和含石榴子石长英质片麻岩伴生.基于矿物共生组合关系和变质反应结构特征,并结合矿物化学详细分析以及温压条件的估算,我们将该区石榴橄榄岩的变质演化划分为3个阶段:峰期变质阶段(Ml)、峰后早期退变质阶段(M2)和晚期角闪岩相-绿片岩相退变质阶段(M3).M1阶段的矿物组合为石榴子石(Grt)+橄榄石(O1)+斜方辉石(Opx)+单斜辉石(Cpx),所估算的温压条件为:T=891～ 1054℃、P=17.2 ～24.7kbar; M2阶段以石榴子石周围出现斜方辉石(Opx)+单斜辉石(Cpx)+尖晶石(Spl)的次生边为特征,在P=10kbar时,估算的温度条件为:T=711 ～ 796℃;M3阶段以形成角闪石(Amp)+蛇纹石(Srp)+金云母(Phl)+绿泥石(Chl)+磁铁矿(Mag)±滑石(Tlc)为特征.石榴橄榄岩具有与相邻的长英质麻粒岩和基性麻粒岩类似的P-T演化历史.结合成因矿物学和初步的地球化学特征,我们认为石榴橄榄岩的原岩可能为侵位于大陆地壳的镁铁质-超镁铁质杂岩,并在早古生代与长英质地壳物质一起俯冲,经历高压(超高压?)/高温变质作用以及随后的变质和地球动力学演化.     

Metamorphic textures and P–T evolution of high-P granulites from the Lelukuau terrane, NE Grenville Province

High‐pressure (HP) granulites and eclogitized metagabbro are exposed along an orogen‐parallel high‐P belt that was developed at c. 1050–1020 Ma in the NE Grenville Province. Among these rocks, mafic granulites derived from a Labradorian anorthosite suite of the Lelukuau terrane contain garnet, Al‐Na diopside, and, depending on bulk composition, plagioclase and kyanite. Moreover, the distribution of phases is influenced by the original igneous texture. For instance, in high X_MgO leucocratic varieties, garnet porphyroblasts nucleated together with kyanite in An‐rich cores of plagioclase domains whereas in low X_MgO rocks garnet occurs together with clinopyroxene within formerly igneous ferromagnesian domains and kyanite is missing. In contrast, garnet pseudomorphs after igneous plagioclase in melanocratic varieties display evidence of earlier corona development. Metamorphic textures are consistent with a two stage evolution: (a) development of garnet and Al‐Na‐diopside (Cpx₁) under high‐P metamorphic conditions, concomitant with elimination of plagioclase in the mesocratic to melanocratic varieties; and (b) partial loss of Al‐Na from Cpx₁ resulting in production of new andesitic plagioclase, and growth of new clinopyroxene (Cpx₂) after garnet and quartz in leucocratic to mesocratic rocks consistent with decompression. Widespread equilibrium textures between garnet‐Pl₂‐Cpx₂ and/or reset Cpx₁ are consistent with development at the thermal peak. Estimated P–T conditions for the presumed thermal peak fall in the range 1500–1800 MPa and 800–900 °C and are comparable to those recorded by eclogitized gabbros from other parts of the high‐P belt of the NE Grenville province. Low jadeite content of clinopyroxene from the HP granulites is attributed to the low bulk Na₂O/(Na₂O + CaO) of these rocks relative to common basaltic compositions. Scarcity of apparent retrograde textural overprint in both the HP granulites and the eclogites suggests fast subsequent cooling, consistent with extrusion of the high‐P belt towards the foreland shortly after the metamorphic peak.     

东昆仑大格勒一带基性二辉麻粒岩的变质演化及地质意义

基性麻粒岩作为高温变质作用产物, 其矿物组合能够较好地记录区域地壳热流的峰值范围, 是揭示造山带演化历史的重要窗口。本文报道了在东昆仑造山带东段大格勒地区金水口岩群副片麻岩中发现的基性二辉麻粒岩露头, 它们呈块状-片麻状构造, 斑状变晶-细粒变晶结构, 主要矿物为斜长石、斜方辉石、单斜辉石、黑云母和普通角闪石。斜方辉石与单斜辉石和高钙斜长石(An=74~81)的平衡结构以及斜方辉石中包裹残余普通角闪石和黑云母的结构表明这些岩石经历了较充分的麻粒岩相结晶作用。填隙状生长的普通角闪石和黑云母可能代表了冷却至固相线附近矿物-残余熔体发生反应的产物。根据二辉石温度计和相平衡模拟计算, 获得在0.4~0.7GPa压力条件下的麻粒岩相变质温度为840~910℃。详细的变斑晶斜长石和钛铁矿包体研究表明, 麻粒岩相变质之前可能存在一期低温高压变质作用, 形成的矿物组合为斜黝帘石+金红石+榍石+普通角闪石±阳起石+黑云母+石英, 相平衡模拟确定该阶段的温压条件为0.85~1.2GPa、500~640℃。斜黝帘石在减压阶段的早期转变为低钙斜长石(An=46-51), 同时角闪石转变为单斜辉石, 可能代表了低压角闪岩相阶段。通过LA-ICPMS锆石U-Pb测年以及锆石包体分析, 确定麻粒岩相变质年龄为411.4±2.9Ma(MSWD=1.05)。这些二辉麻粒岩是在金水口以外的东昆仑地区发现的首例晚古生代低压高温变基性岩, 其与围岩片麻岩构成一个麻粒岩地体。它们反映了泥盆纪早期东昆仑造山带的异常高温事件, 与后碰撞伸展阶段软流圈地幔上涌带来的区域高温热流有关。本研究对解析东昆仑造山带高级变质地体的精细结构以及古特提斯洋形成过程的深部动力学机制具有重要意义。

     

辽西建平杂岩高压麻粒岩相变质作用的P—T条件及其地质意义

辽西建平杂岩中广泛发育高压麻粒岩块体,其特征为在基性岩中出现石榴石+单斜辉石+斜长石+石英士角闪石,利用TWQ方法结合传统地质温压计估算其变质条件为T=785～820℃,P=L 05～L 17GPa.高压麻粒岩区的其他岩石如石榴石二辉麻粒岩等虽然不出现典型的高压麻粒岩矿物组合,但其变质条件相同.研究表明它们之间矿物组合的不同系由其全岩成分,尤其是SiO2含量不同所致.因此辽西高压麻粒岩相变质作用是区域性的.该区高压麻粒岩的特征与泛非造山带和西澳的高压麻粒岩相似,也符合高压麻粒岩的经典定义,但与在华北克拉通其他地区报道的"高压麻粒岩"有所不同.     

Challenges in constraining the P–T conditions of mafic granulites: An example from the northern Trans‐North China Orogen

Some mafic granulites in the Sanggan area of the northern Trans‐North China Orogen (TNCO) have a relatively simple mineralogy with low energy grain shapes that are compatible with an assumption of equilibrium, but the rock‐forming minerals show variations in composition that create challenges for thermobarometry. The mafic granulites, which occur as apparently disrupted dyke‐like bodies in tonalite–trondhjemite–granodiorite gneisses, are divided into two types based on petrography and chemical composition. Type 1 mafic granulites are fine‐ to medium‐grained with an equilibrated texture and an assemblage of plagioclase+clinopyroxene+garnet+magnetite+ilmenite and sometimes minor hornblende±orthopyroxene. Type 2 mafic granulites are coarse‐grained and hornblende bearing with a peak assemblage of garnet+clinopyroxene+plagioclase+hornblende and variably developed coronae and symplectites of plagioclase+hornblende+orthopyroxene partially replacing porphyroblastic garnet±clinopyroxene. SIMS U–Pb dating of metamorphic zircon from two type 1 mafic granulites yields metamorphic ages of c. 1.84 and 1.83 Ga, consistent with published ages of the type 2 mafic granulites. Based on phase equilibrium modelling, we use the common overlap of P–T fields defined by the mineral assemblage limits, and the mole proportion and composition isopleths of different minerals in each sample to quantify the metamorphic conditions. For type 1 granulites, overlap of the mineral proportion and composition fields for each of three samples yields similar P–T conditions of 710–880°C at 0.57–0.79 GPa, 820–850°C at 0.59–0.63 GPa and 800–860°C at 0.59–0.68 GPa. For the type 2 granulites, overlaying the peak assemblage fields for three samples yields common P–T conditions of 870–890°C at 1.1–1.2 GPa. For the retrograde assemblage, overlap of the mineral proportion and composition fields for each sample yields similar P–T conditions of 820–840°C at 0.85–0.88 GPa, 860–880°C at 0.83–0.86 GPa and 880–930°C at 0.89–0.95 GPa. The P–T conditions appear distinct between the two types of mafic granulite, with the mineralogically simple type 1 mafic granulites recording the lowest pressures. However, there are significant uncertainties associated with these results. For the granulites, there are uncertainties related to the determination of modes and composition of the equilibration volume, particularly estimation of O and H₂O contents, and in the phase equilibrium modelling there are uncertainties that propagate through the calculation of mole proportions and mineral compositions. The compound uncertainties on pressure and temperature for high‐T granulites are large and the results of our study show that it may be unwise to rely on P–T conditions determined from the simple intersection of calculated mineral composition isopleths alone. Since the samples in this study are from a limited area—a few hundred square metres—we infer that they record a single P–T path involving both decompression and cooling. However, there is no evidence of the high‐P granulite facies event at 1.93–1.90 Ga that is recorded elsewhere in the TNCO, which suggests that the precursor basic dykes were emplaced late during the assembly of the North China Craton.     

东南极格罗夫山镁铁质麻粒岩的变质作用

东南极内陆－格罗夫山存在一套经历了麻粒岩相变质作用的镁铁质麻粒岩和斜长角闪岩。变质反应结构显示该区多为单一的区域性麻粒岩相变质作用。但是，对含石榴石的镁铁质麻粒岩的详细工作则显示了包括3个阶段的近等温降压（ITD）的顺时针PT演化轨迹，M1：0．93GPa＞800℃：M2:0.65GPa,733-850℃;M3:0.46-0.61GPa，并有着与拉斯曼丘陵相似的演化历史。根据矿物组合和成分、变质反应结构及温压计算结果，格罗夫山镁铁质麻粒岩可能为高压麻粒岩。     

柴北缘鱼卡河榴辉岩的变质演化——石榴石成分环带及矿物反应结构的证据

柴北缘鱼卡河榴辉岩的典型矿物组合为石榴石-绿辉石-多硅白云母-金红石。其中粗粒石榴石变斑晶普遍保存进变质生长环带,从核部到边部石榴石的化学成分、包体矿物的种类和粒度皆呈现出规律的分带性。岩相学和矿物化学研究进一步表明,该榴辉岩经历了前榴辉岩相、榴辉岩相及后榴辉岩相三个主要变质演化阶段。前榴辉岩相以石榴石核部成分及核部包体矿物组合石榴石(GrtⅠ) 角闪石(AmpⅠ) 斜长石(PⅡ) 石英(Qtz)为特征,P-T 估算结果为450～500℃和0.6～0.7GPa。榴辉岩相变质阶段又可细分为早期、峰期榴辉岩和退变角闪榴辉岩三个亚相。早期榴辉岩亚相以石榴石幔部成分和幔部包体矿物组合石榴石(GrtⅡA) 绿辉石(OmpⅡA) 多硅白云母(PheⅡA)±黝帘石(Zoi) 金红石(Ru)为代表,估算的温压条件为580～640℃和2.4～2.5GPa;峰期榴辉岩相以石榴石的边部(GrtⅡB)及基质中绿辉石(OmpⅡB)和多硅白云母(PheⅡB)的核部为代表,矿物组合为 GrtⅡB OmpⅡB PheⅡB Ru,估算的 P-T 条件为620～680℃和3.0～3.4GPa;退变角闪榴辉岩相以共生的石榴石的最边部(GrtⅡC)、基质绿辉石(OmpⅡC)和多硅白云母(PheⅡC)的边部及镁红闪石(AmpⅡ)组合为代表,矿物组合为 GrtⅡC OmpⅡC AmpⅡ PheⅡC,估算的 P-T 条件为700～720℃和2.3～2.4GPa。后榴辉岩阶段主要为麻粒岩-高角闪岩相,以绿辉石分解形成透辉石 钠长石冠状体以及进一步分解形成韭闪石 斜长石,铁红闪石分解形成浅闪石 斜长石为代表,P-T 估算结果为550～600℃和0.6～1GPa。温压估算结果表明,鱼卡河榴辉岩经历了升温升压—升温降压—降温降压的一个顺时针 P-T 演化轨迹,它记录了从俯冲-超高压变质-抬升的连续的演化过程。峰期变质条件为630～680℃和3.0～3.4GPa,已达超高压变质范畴。榴辉岩中进变质矿物组合和生长环带的保存说明榴辉岩的形成经历了相对快速的俯冲和折返的动力学过程。     

On the formation of granulites

The tectonic settings for the formation and evolution of regional granulite terranes and the lowermost continental crust can be deduced from pressure–temperature–time (P–T–time) paths and constrained by petrological and geophysical considerations. P–T conditions deduced for regional granulites require transient, average geothermal gradients of greater than 35°C km^?1, implying minimum heat flow in excess of 100 mWm^?2. Such high heat flow is probably caused by magmatic heating. Tectonic settings wherein such conditions are found include convergent plate margins, continental rifts, hot spots and at the margins of large, deep-seated batholiths. However, particular P–T–time paths do not allow specific tectonic settings to be distinguished at this time. Under different conditions, both clockwise, CW (P_max attained before T_max), and anticlockwise, ACW (P_max attained slightly after T_max), paths are possible in the same tectonic setting. Both CW and ACW end-member paths can yield nearly isobaric cooling, IBC, paths. Such cooling paths are clearly not an artefact of thermobarometry, but can be constrained by solid–solid and devolatilization equilibria and geophysical modelling. In terms of understanding the evolution of the deep crust, a potentially significant group of regional granulite terranes are those that show evidence for ACW-IBC paths. Such paths are the likely result of: (i) episodic igneous activity resulting in intrusions within all levels of the crust, (ii) thickening of the crust by magmatic underplating, (iii) slow uplift as a result of the formation of a deep, garnet-rich crustal root and (iv) excavation resulting from a later tectonic event unrelated to that resulting in the formation of the granulites. The later event might be triggered by the delamination of the garnet-rich, lowermost crust.     

浙西南松阳地区石榴辉石岩变质作用演化与地质意义

浙西南松阳地区的八都群中分布有一套基性变质岩:石榴辉石岩与石榴角闪岩,其变质作用演化特点目前尚不明确。根据岩相学和矿物微区化学系统研究,发现石榴角闪岩是由石榴辉石岩退变而来,而非由榴辉岩退变而来,并经历了三个变质演化阶段,分别为峰期高压麻粒岩相阶段(M1),其矿物组合为石榴石+次透辉石±钛铁矿±石英;峰后近等温减压中压麻粒岩相退变质阶段(M2),以出现典型的减压反应结构和斜方辉石+斜长石(An_(90-92))为标志;角闪岩相退变质阶段(M3),以角闪石+斜长石(An_(33-53))+钛铁矿±次透辉石±石英等退变矿物组合为特征。相平衡模拟与传统地质温压计结合限定M1期温压条件为P=11. 6～12. 5kbar,T=780～840℃,M2期温压条件为P=7. 4～8. 2kbar,T=800～880℃,M3期温压条件为P=6. 6～7. 5kbar,T=500～560℃,三个变质阶段的温压条件具有典型的顺时针近等温减压型ITD型特征,这种演化轨迹通常代表加厚下地壳快速折返地表的动力学过程,因此,该项研究对华夏地块构造作用演化的动力学过程具有重要意义。