DISCOVERY AND SIGNIFICANCE OF CONTINENTAL PILLOW BASALT IN CHAHAR RIGHT BACK BANNER, CENTRAL INNER MONGOLIA

doi:10.3969/j.issn.0253-4967.2022.05.001

Abstract

Abstract:

Marine pillow basalts are widely developed, while large-scale continental pillow basalts are especially rare in China. The continental pillow basalt newly discovered in Chahar Right Back Banner, Inner Mongolia, is mainly tholeiite and a part of the Hannuoba basalt in Pliocene. In the accumulation sequence, from the bottom to the top, there are grayish-white calcareous mudstone of deep lacustrine, pillow basalt, stomatal basalt, and massive basalt. The pillow basalt has the thickness of about 10~12m and is mainly composed of black pillow body and yellow quenched clastics. The pillow bodies are preserved well and rare in China with complete structure. In detail, most of them are cylindrical, long ellipsoidal, of different sizes, about 0.8~1.5m long, and the largest pillow is about 2m long. Most of the cross sections are nearly circular, with a diameter of about 0.6m, up to 1m. The pillow bodies have obvious concentric layered structure, which can be divided into crust, middle layer and core. The degree of crystallization gradually becomes better from outside to inside. The crust is glassy, the middle layer is mesocrypt structure, and the core has relatively good crystallization, which is of intergranular-intersertal structure. Radial and discontinuous concentric ring fractures often occur in the pillow bodies, of which radial fractures are the most developed. The number of fractures varies from 10 to 20, with a width of 3~5mm. Most of them are filled with calcium and silica. In terms of composition, the pillow body is mainly olivine tholeiite, with porphyritic texture, stomatal-almond and massive structures. Phenocrysts are mainly plagioclase, clinopyroxene and olivine. Plagioclase is in the shape of self-shaped and plated strip, with the size of 1~3mm, the length-width ratio of 3︰1 to 5︰1, and the content of polysynthetic twin is 10%~15%; Clinopyroxene is short columnar, with a size of 0.6~1mm and a content of 5%~8%; Olivine is granular, with the size of 1~2mm and the content of 3%~5%. The matrix is composed of glass-based interlaced structure and intergranular-intersertal structure. It is mainly composed of microcrystalline plagioclase, pyroxene and glassy, accounting for 70%~85%. The basalt has SiO₂ of 52.84% and(Na₂O+K₂O)of 5.46%, belonging to calc alkaline rock(Rittman index σ=3.0<3.3), with obvious fractionation of light and heavy rare earth elements(LREE/HREE=17.52, La_N/Yb_N=24)and weakly Eu negative anomaly(δEu=0.89), enriching large ion lithophile elements(Rb, Sr, Ba, etc.). The pillow bodies are mainly filled with calcareous cemented basaltic quenched clastics, including agglomerate, breccia, and tuff grades, mainly orange basaltic glassy quenched breccia. The determination of tuffaceous quenched clastics enriches the genetic types of volcanic ash. The cements are mainly calcareous and siliceous precipitated by hydrochemistry, a small amount of clay minerals and gypsum can be seen locally. The quenched breccia also contains some calcareous mudstone fragments. It shows that both marine and continental facies can form pillow basalt, and water is a necessary condition, but its formation is not related to water depth, and it is mainly controlled by the temperature and velocity of lava. When the temperature of underwater basaltic magma is between 1150℃ and 1000℃, pillow structure is easy to form, but it is difficult to form pillow lava below 1000℃, and relatively slow velocity is conducive to the formation of pillow body. Continental pillow basalts are usually distributed around craters, which belong to near-crater deposits. They are of definite significance of facies, which is of great practical significances for remodeling the morphology of continental volcanic edifice and studying the volcanic eruption process.

Key words: pillow basalt, quenched breccia, continental facies, near-crater facies, Chahar Right Back Banner

摘要：

海相枕状玄武岩分布广泛, 而大规模陆相枕状玄武岩在国内罕见。内蒙古察右后旗陆相枕状玄武岩属上新世汉诺坝玄武岩。枕状玄武岩厚10~12m, 堆积序列自下而上为深湖相灰白色钙质泥岩、枕状玄武岩、气孔状玄武岩和块状玄武岩。枕状玄武岩由黑色枕状体和黄色淬碎角砾组成, 枕状体结构完整, 国内罕见。橄榄拉斑玄武岩枕状体, 呈斑状结构, 气孔、杏仁状及块状构造, 斑晶主要为斜长石、单斜辉石和橄榄石。基质为玻晶交织结构和间隐-间粒结构, 主要由微晶斜长石、辉石和玻璃质组成, 含量为70%~85%。枕体间的填充物主要为玄武质淬碎碎屑, 包括集块、角砾和凝灰级碎屑, 其中凝灰级淬碎碎屑的确定丰富了火山灰的成因类型。海相和陆相均可形成枕状玄武岩, 水是必要条件, 但其形成与水深关系不大, 主要受熔岩的温度和流速控制。水下玄武质熔浆在1150~1000℃时易形成枕状构造, 而低于1000℃则很难形成枕状熔岩, 相对缓慢的流速利于枕状体形成。陆相枕状玄武岩常分布于火山口周围, 属近火口相堆积物, 具有明确的指相意义, 这对恢复火山机构面貌及火山喷发过程具有重要的实际意义。

关键词: 枕状玄武岩, 淬碎角砾岩, 陆相, 近火口相, 察右后旗

CLC Number:

SHI Zhi-wei, BAI Zhi-da, DONG Guo-chen, WANG Xu. DISCOVERY AND SIGNIFICANCE OF CONTINENTAL PILLOW BASALT IN CHAHAR RIGHT BACK BANNER, CENTRAL INNER MONGOLIA[J]. SEISMOLOGY AND GEOLOGY, 2022, 44(5): 1087-1106.

史志伟, 白志达, 董国臣, 王旭. 内蒙古中部察哈尔右翼后旗陆相枕状玄武岩的发现及其意义[J]. 地震地质, 2022, 44(5): 1087-1106.

Figures/Tables 14

Fig. 1 Tectonic location in North China Craton(a)(after XU Wen-liang et al., 2009) and distribution of Cenozoic basalts in the study area(b)(modified from ZHANG Wen-hui et al., 2005).

Fig. 2 Photo about accumulation sequence and lateral accretion of Dawanzi continental pillow basalt.

Fig. 3 Transverse section of Dawanzi continental pillow basalt.

Fig. 4 Geological section about accumulation sequence of Dawanzi continental pillow basalt.

Fig. 5 Photo about accumulation sequence of Dawanzi continental pillow basalt.

Fig. 6 Field features of the continental pillow basalt.

Fig. 7 Microscopical characteristics of continental pillow basalt and field characteristics of quenched breccia.

Table1 Analytical data of major elements(wt%)and trace elements(ppm)of pillow basalt in the study area

样号	时代	岩石名称	SiO₂	Al₂O₃	TiO₂	Fe₂O₃	FeO	CaO	MgO	K₂O	Na₂O	MnO	P₂O₅	H₂O⁺	H₂O^-	LOI	总量
NB1	Nh	橄榄拉斑玄武岩	52.84	14.45	2.04	3.36	6.90	7.31	3.89	2.06	3.40	0.123	1.16	1.59	0.43	2.31	99.84
			La	Ce	Pr	Nd	Sm	Eu	Gd	Tb	Dy	Ho	Er	Tm	Yb	Lu	Y
			88	232	24.3	91	14.3	3.7	10.3	1.37	6.84	1.15	2.72	0.47	2.63	0.4	31
			Ba	Co	Cr	Hf	Nb	Ni	Rb	Sr	Ta	Th	U	Ⅴ	Zr	σ	ΣREE
			1609	25.9	48	8.24	33.6	23	82	891	1.69	6.4	1.19	170	498	3.0	479.18
			δEu	δCe	La_N/Yb_N	Zr/Hf	Nb/Ta
			0.89	1.21	24.00	60.44	19.88

Fig. 8 Plan(a)and section(b)of volcanic channel face(diabase)in west mountain of Baiyinchagan.

Fig. 9 Columnar joints(a)and cross section(b)of diabase porphyrite of volcanic vent facies in west mountain of Baiyinchagan.

Fig. 10 Formation of pillow basalt in the submarine environment(modified from Moore, 1975).

Table2 Formation conditions of pillow basalts in deep sea and lake

枕状玄武岩	深海	湖泊
水深	$2$ 000~ $3$ 000m	10~30m
水压	200~300atm	1~3atm
水温	3~5℃, 恒定	变化大, 0~30℃
数据来源	Jones, 1969	本文

Table2 Formation conditions of pillow basalts in deep sea and lake

枕状玄武岩	深海	湖泊
水深	$2$ 000~ $3$ 000m	10~30m
水压	200~300atm	1~3atm
水温	3~5℃, 恒定	变化大, 0~30℃
数据来源	Jones, 1969	本文

Table3 Stomatal contents of marine pillow basalts

位置或环境	气孔含量(水深)			数据来源
大洋中脊	10%~40%(<500m)	5%(1 000m)	1%~1.3%(3 000m)	朱佛宏, 1988
冰岛地区	40%(100m)	20%(300m)	<5% (470m)	Jones, 1968, 1969
雷克雅内斯海岭	40%(100m)	5%(1 000m)		朱佛宏, 1988

Fig. 11 Temperature phase diagram of the formation of pillow crust(modified from Moore, 1975).

References 52

[1]	白志达, 王剑民, 许桂玲, 等. 2008. 内蒙古察哈尔右翼后旗乌兰哈达第四纪火山群[J]. 岩石学报, 24(11): 2585-2594.
	BAI Zhi-da, WANG Jian-min, XU Gui-ling, et al. 2008. Quaternary volcano cluster of Wulanhada, Right-back-banner, Chahaer, Inner Mongolia[J]. Acta Petrologica Sinica, 24(11): 2585-2594. (in Chinese)
[2]	池际尚. 1988. 中国东部新生代玄武岩及上地幔研究[M]. 武汉: 中国地质大学出版社:1-285.
	CHI Ji-shang. 1988. Cenozoic Basalts and Upper Mantle from Eastern China[M]. China University of Geosciences Press, Wuhan: 1-285. (in Chinese)
[3]	冯家麟, 谢漫泽, 张红, 等. 1982. 汉诺坝玄武岩及其深源包体[J]. 河北地质学院学报, Z1: 45-63.
	FENG Jia-lin, XIE Man-ze, ZHANG Hong, et al. 1982. Hannuoba basalts and their deep-seated enclaves[J]. Journal of Hebei College of Geology, Z1: 45-63. (in Chinese)
[4]	冯家麟, 谢漫泽, 郑海飞. 1986. 汉诺坝玄武岩稀土元素地球化学特征及成因意义[J]. 河北地质学院学报, 9(3-4): 217-232.
	FENG Jia-lin, XIE Man-ze, ZHENG Hai-fei. 1986. Geochemical characteristics of rare earth elements in Hannorpa basalts[J]. Journal of Hebei College of Geology, 9(3-4): 217-232. (in Chinese)
[5]	郝艳丽, 黄启帅, 张晓冉, 等. 2013. 峨眉山大火成岩省底部枕状玄武岩的地质地球化学特征及成因探讨[J]. 地质科学, 48(2): 557-568.
	HAO Yan-li, HUANG Qi-shuai, ZHANG Xiao-ran, et al. 2013. The Shangcang pillow lavas from the bottom of the Emeishan Large Igneous Province, southwestern China: Petrogenesis and tectonic implications[J]. Chinese Journal of Geology, 48(2): 557-568. (in Chinese)
[6]	李福田, 段国政. 1982. 黑龙江五大连池陆相枕状熔岩的特征及其形成机制[J]. 长春地质学院学报, (3): 95-98.
	LI Fu-tian, DUAN Guo-zheng. 1982. The character and the formation of the Wudalianchi continental pillow lava[J]. Journal of Changchun University of Earth Science, (3): 95-98. (in Chinese)
[7]	李双庆. 1997. 内蒙古中部早古生代地体的拼合与增置[J]. 内蒙古地质, (1): 18-23.
	LI Shuang-qing. 1997. Early Palaeozoic era of terrane pieced together and accreted in middle of Inner Mongolia[J]. Geology of Inner Mongolia, (1): 18-23. (in Chinese)
[8]	刘光亚, 谭绩文, 孙德佩. 1978. 汉诺坝玄武岩的时代归属[J]. 河北地质学院学报, (2): 32-46.
	LIU Guang-ya, TAN Ji-wen, SUN De-pei. 1978. The age of Hannuoba basalt[J]. Journal of Hebei Institute of Geology, (2): 32-46. (in Chinese)
[9]	刘磊. 2007. 内蒙古乌兰哈达第四纪火山地质与新构造特征[D]. 北京: 中国地质大学:5-8.
	LIU Lei. 2007. Research on volcanic geology and new tectonics in Wulanhada region, Inner Mongolia[D]. China University of Geosciences, Beijing: 5-8. (in Chinese)
[10]	刘延畅, 白志达, 宋卡迪, 等. 2016. 内蒙古乌兰哈达晚第四纪玄武岩岩石学特征[J]. 地震地质, 38(1): 182-196. doi: 10.3969/j.issn.0253-4967.2016.01.014. DOI
	LIU Yan-chang, BAI Zhi-da, SONG Ka-di, et al. 2016. Petrological properties of late Quaternary basalts from Wulanhada, Inner Mongolia, China[J]. Seismology and Geology, 38(1): 182-196. (in Chinese)
[11]	卢进才, 魏仙样, 曹萱铎, 等. 2002. 内蒙古商都地区CO₂气藏地质条件研究[J]. 西北地质, 35(4): 122-134.
	LU Jin-cai, WEI Xian-yang, CAO Xuan-duo, et al. 2002. Research on CO₂ gas pool-geological conditions in Shangdu area, Inner Mongolia[J]. Northwestern Geology, 35(4): 122-134. (in Chinese)
[12]	内蒙古地质研究队. 1978. 内蒙古地质概论[M]. 呼和浩特: 内蒙古自治区革命委员会地质局科技情报室:1-50.
	Inner Mongolia Geological Research Team. 1978. Introduction to Inner Mongolia Geology[M]. Science and Technology Information Office, Geological Bureau, Revolutionary Committee of Inner Mongolia Autonomous Region, Hohhot: 1-50. (in Chinese)
[13]	内蒙古自治区地质矿产局. 1991. 内蒙古自治区区域地质志[M]. 北京: 地质出版社:573-627.
	Bureau of Geology and Mineral Resources of Inner Mongolia Autonomous Region. 1991. Regional Geological Records of Inner Mongolia Autonomous Region[M]. Geological Publishing House, Beijing: 573-627. (in Chinese)
[14]	邱家骧, 李昌年, 马昌前. 1986. 汉诺坝玄武岩板块构造环境及岩浆成因机理的分析[J]. 岩石学报, 2(3): 1-12.
	QIU Jia-xiang, LI Chang-nian, MA Chang-qian. 1986. The analysis of plate tectonic setting and magma-genetic mechanism of basaltic from Hannuoba[J]. Acta Petrologica Sinica, 2(3): 1-12. (in Chinese)
[15]	全国地层委员会. 1963. 全国地层会议学术报告汇编: 中国的新生界[M]. 北京: 科学出版社:31-32.
	National Stratigraphic Committee. 1963. Compilation of Academic Reports of the National Stratigraphic Conference: Cenozoic in China[M]. Science Press, Beijing: 31-32. (in Chinese)
[16]	孙明道, 徐义刚, 陈汉林. 2018. 中国东北饶河杂岩中的侏罗纪玄武质凝灰岩及枕状玄武岩: 对古太平洋水下火山活动的启示[J]. 中国科学(D辑), 48(8): 1016-1032.
	SUN Ming-dao, XU Yi-gang, CHEN Han-lin. 2018. Subaqueous volcanism in the Paleo-Pacific Ocean based on Jurassic basaltic tuff and pillow basalt in the Raohe Complex, NE China[J]. Science in China (Ser D), 48(8): 1016-1032.
[17]	王慧芬, 戴橦谟, 范嗣昆, 等. 1985. 张家口汉诺坝玄武岩K-Ar年龄计时[J]. 地球化学, (3): 206-215.
	WANG Hui-fen, DAI Tong-mo, FAN Si-kun, et al. 1985. K-Ar dating of Hannuoba basalts at Zhangjiakou[J]. Geochimica, (3): 206-215. (in Chinese)
[18]	夏国礼. 1993. 冀北地区陆相玄武质淬碎碎屑岩的特征及成因[J]. 中国区域地质, (3): 223-228.
	XIA Guo-li. 1993. Features and genesis of terrestrial basaltic vitroclastic rocks in northern Hebei[J]. Regional Geology of China, (3): 223-228. (in Chinese)
[19]	徐力峰, 夏斌, 李建峰, 等. 2010. 藏北湖区拉弄蛇绿岩枕状玄武岩地球化学特征及其成因[J]. 大地构造与成矿学, 34(1): 105-113.
	XU Li-feng, XIA Bin, LI Jian-feng, et al. 2010. Geochemical characteristics and genesis of pillow basalts from the Lanong ophiolite in Tibet, China[J]. Geotectonica et Metallogenia, 34(1): 105-113. (in Chinese)
[20]	许文良, 杨德彬, 裴福萍, 等. 2009. 太行山南段符山高镁闪长岩的成因: 拆沉陆壳物质熔融的熔体与地幔橄榄岩反应的结果[J]. 岩石学报, 25(8): 1947-1961.
	XU Wen-liang, YANG De-bin, PEI Fu-ping, et al. 2009. Petrogenesis of Fushan high-Mg^# diorites from the southern Taihang Mts. in the central North China Craton: Resulting from interaction of peridotite-melt derived from partial melting of delaminated lower continental crust[J]. Acta Petrologica Sinica, 25(8): 1947-1961. (in Chinese)
[21]	杨芳林, 王五力, 张宏, 等. 2005. 辽西义县组中淬碎熔岩的发现及其意义[J]. 地质与资源, 14(4): 241-244.
	YANG Fang-lin, WANG Wu-li, ZHANG Hong, et al. 2005. Discovery and significance of the quench fragment lava in Yixian formation in western Liaoning Province[J]. Geology and Resources, 14(4): 241-244. (in Chinese)
[22]	袁万明, 冯家麟. 1993. 河北汉诺坝玄武岩中深源包体和巨晶分布的动力学机理[J]. 岩石矿物学杂志, 12(1): 12-19.
	YUAN Wan-ming, FENG Jia-lin. 1993. Dynamic mechanism of the distribution of deep-seated xenoliths and megacrysts in Hannuoba basalts of Hebei Province[J]. Acta Petrologica Et Mineralogica, 12(1): 12-19. (in Chinese)
[23]	张立东, 郭胜哲, 张长捷, 等. 2002. 辽宁西部义县组湖相枕状熔岩的发现及其意义[J]. 地球学报, 23(6): 491-494.
	ZHANG Li-dong, GUO Sheng-zhe, ZHANG Chang-jie, et al. 2002. The discovery of pillow lavas in Yixian formation, western Liaoning, and its significance[J]. Acta Geoscientia Sinica, 23(6): 491-494. (in Chinese)
[24]	张楠. 2008. 内蒙乌兰哈达第四纪火山地质及资源保护与开发[D]. 北京: 中国地质大学:6-8.
	ZHANG Nan. 2008. Quaternary volcanic geology and resource protection and development in Wulanhada area, Inner Mongolia[D]. China University of Geosciences, Beijing: 6-8. (in Chinese)
[25]	张文慧, 韩宝福. 2006. 内蒙古集宁新生代玄武岩的K-Ar年代学和地球化学及其深部动力学意义[J]. 岩石学报, 22(6): 1597-1607.
	ZHANG Wen-hui, HAN Bao-fu. 2006. K-Ar chronology and geochemistry of Jining Cenozoic basalts, Inner Mongolia, and geodynamic implications[J]. Acta Petrologica Sinica, 22(6): 1597-1607. (in Chinese)
[26]	张文慧, 韩宝福, 杜蔚, 等. 2005. 内蒙古集宁新生代玄武岩的地幔源区特征: 元素及Sr-Nd-Pb同位素地球化学证据[J]. 岩石学报, 21(6): 1569-1582.
	ZHANG Wen-hui, HAN Bao-fu, DU Wei, et al. 2005. Characteristics of mantle source for Jining Cenozoic basalts from southern Inner Mongolia: Evidence from element and Sr-Nd-Pb isotopic geochemistry[J]. Acta Petrologica Sinica, 21(6): 1569-1582. (in Chinese)
[27]	钟建华, 倪良田, 邵珠福, 等. 2018. 新疆乌鲁木齐东部早二叠世枕状玄武岩火山岩系的发现及大地构造意义[J]. 地质学报, 92(4): 638-664.
	ZHONG Jian-hua, NI Liang-tian, SHAO Zhu-fu, et al. 2018. The discovery of early Permian pillow basalts in eastern Urumqi, Xinjiang, and its tectonic significance[J]. Acta Geologica Sinica, 92(4): 638-664. (in Chinese)
[28]	朱佛宏. 1988. 玄武岩的气孔率: 弧后盆地火山作用的标志[J]. 海洋地质译丛, (6): 28-32.
	ZHU Fo-hong. 1988. Porosity of basalt: A sign of volcanism in back arc basin[J]. Translation of Marine Geology, (6):28-32. (in Chinese)
[29]	Anderson R N, Noltimier H C. 1973. A model for the horst and graben structure of mid ocean ridge crests based upon spreading velocity and basalt delivery to the oceanic crust[J]. Geophysical Journal of the Royal Astronomical Society, 34(2): 137-147.
[30]	Aumento F. 1969. The Mid-Atlantic Ridge near 45°N, V: Fission track and ferro-manganese chronology[J]. Canadian Journal of Earth Sciences, 6(6): 1431-1440. DOI URL
[31]	Aumento F. 1971. Vesicularity of Mid-Oceanic pillow lavas[J]. Canadian Journal of Earth Sciences, 8(10): 1315-1319. DOI URL
[32]	Ballard R D, Bryan W B, Heirtzler J R, et al. 1975. Manned submersible observations in the famous area: Mid-Atlantic Ridge[J]. Science, 190(4210): 103-108. DOI URL
[33]	Brown J, Colling A, Park D, et al. 1989. The Ocean Basins: Their Structure and Evolution[M]. Pergamon Press, New York: 68-95.
[34]	Carlisle D. 1963. Pillow breccias and their aquagene tuffs, Quadra Island, British Columbia[J]. The Journal of Geology, 71(1): 48-71. DOI URL
[35]	Carracedo S M, Sarrionandia F, Juteau T, et al. 2012. Structure and organization of submarine basaltic flows: Sheet flow transformation into pillow lavas in shallow submarine environments[J]. International Journal of Earth Sciences, 101(8): 2201-2214.
[36]	Cas R A F, Wright J V. 1988. Volcanic Successions Modern and Ancient: A Geological Approach to Processes, Products and Successions[M]. Chapman & Hall, London: 73-75.
[37]	de Moraes L C, Seer H J. 2018. Pillow lavas and fluvio-lacustrine deposits in the northeast of Paraná Continental Magmatic Province, Brazil[J]. Journal of Volcanology and Geothermal Research, 355: 78-86. DOI URL
[38]	Famelli N, Lima E F, Carmo I O. 2021. Lithostratigraphy of the Serra Geral Formation in the northern portion of the Paraná-Etendeka Igneous Province: A tool for tracking Early Cretaceous paleoenvironmental changes[J]. Journal of Volcanology and Geothermal Research, 410: 107152. DOI URL
[39]	Greenberger R N, Mustard J F, Cloutis E A, et al. 2015. Hydrothermal alteration and diagenesis of terrestrial lacustrine pillow basalts: Coordination of hyperspectral imaging with laboratory measurements[J]. Geochimica et Cosmochimica Acta, 171: 174-200. DOI URL
[40]	Hargreaves R, Ayres L D. 1979. Morphology of Archean metabasalt flows, Utik Lake, Manitoba[J]. Canadian Journal of Earth Sciences, 16(7): 1452-1466. DOI URL
[41]	Hickson C J, Vigouroux N. 2015. Volcanism and glacial interaction in the Wells Gray-Clearwater volcanic field, east-central British Columbia[J]. The Geological Society of America, 38(1): 169-191.
[42]	Johnston W E Q. 1969. Pillow lava and pahoehoe: A discussion[J]. Journal of Petrology, 77: 730-732.
[43]	Jones J G. 1968. Pillow lava and pahoehoe[J]. The Journal of Geology, 76(4): 485-488. DOI URL
[44]	Jones J G. 1969. Pillow lavas as depth indicator[J]. American Journal of Science, 267: 181-195. DOI URL
[45]	Kawachi Y, Pringle I J. 1988. Multiple-rind structure in pillow lava as an indicator of shallow water[J]. Bulletin of Volcanology, 50(3): 161-168. DOI URL
[46]	Moore J G. 1975. Mechanism of formation of pillow lava, produced as fluid lava cools underwater, is the most abundant volcanic rock on earth, but only recently have divers observed it forming[J]. American Scientist, 63(3): 269-277.
[47]	Moore J G, Fiske R S. 1969. Volcanic substructure inferred from dredge samples and ocean-bottom photographs, Hawaii[J]. Geological Society of America Bulletin, 80(7): 1191-1202. DOI URL
[48]	Moore J G, Schilling J G. 1973. Vesicles, water, and sulfur in Reykjanes Ridge basalts[J]. Contributions to Mineralogy & Petrology, 41: 105-118.
[49]	Salters V J M, Stracke A. 2004. Composition of the depleted mantle[J]. Geochemistry, Geophysics, Geosystems, 5(5): 1-27.
[50]	Snyder G L, Fraser G D. 1963. Pillowed Lavas: Intrusive Layered Lava Pods and Pillowed Lavas, Unalaska Island, Alaska, and A Review of Selected Recent Literature[M]. United States Government Printing Office, Washington: 454-455.
[51]	Wilkinson J F G. 1985. Undepleted mantle composition beneath Hawaii[J]. Earth and Planetary Science Letters, 75(2-3): 129-138.
[52]	Yamagishi H. 1985. Growth of pillow lobes: Evidence from pillow lavas of Hokkaido, Japan and North Island, New Zealand[J]. Geology, 13(7): 499-502. DOI URL