GRAVITY VARIATION CHARACTERISTICS IN YUNNAN AND ITS SURROUNDING AREAS FROM 2010 TO 2020

doi:10.3969/j.issn.0253-4967.2021.04.015

Abstract

Abstract:

Based on the absolute gravity observation data of 10 gravity datum stations of the Crustal Movement Observation Network of China(CMONOC)in Yunnan and adjacent areas during 2010-2020, the gravity datum and its dynamic variation of each gravity datum station are obtained. The gravity variation trend of 9 stations at three different time scales and time periods shows that the gravity variation increased first and then decreased, and the turning point occurred around 2014, while Kunming Station is just the opposite. The Ludian M_S6.5, Yingjiang M_S6.1 and Jinggu M_S6.6 events occurred successively in 2014 when the gravity change increased to the turning point. Thereafter, the gravity change trend decreased until the occurrence of the Yangbi M_S6.4 earthquake in 2021. The results show that the variation of the gravity field in Yunnan and adjacent area is large and fast, and the transition period of increasing to decreasing is short and the variation trend is consistent. The gravity field change mechanism may be dominated by that the Qinghai-Tibetan plateau moves to the northeast caused by the push of Indian Plate, then is blocked by the Sichuan Basin, and the crustal material under the Qinghai-Tibetan plateau moves forward to Yunnan and its adjacent regions. The repeated observations of the absolute gravity survey network covering the whole country provide abundant and reliable data for obtaining the time-variable gravity field which is related to the crustal movement. Many scholars have done a lot of research on the results of the absolute gravity dynamic changes in the Chinese mainland, but the region is mainly focused on the Qinghai-Tibetan plateau, while the results of the absolute gravity dynamic change in other regions are still rarely revealed.

(1)The absolute gravity observation data of 10 gravity datum stations in Yunnan and Panzhihua from 2010 to 2020 show that except Kunming observation station, the gravity change trend increased first and then decreased, and the turning point occurred around 2014. Kunming station is the only station in the cave among the 10 observation stations, and its gravity change may be affected by the water content of the mountain. Five gravity observation campaigns at each observation station were carried out in different months of different years. Due to the lack of hydrological data at each observation station, the seasonal gravity change was not considered. Therefore, eliminating its influence is one of the important jobs in our future study.

(2)Earthquakes of M_S6.1, M_S6.5 and Ms6.6 occurred on May 31, August 3 and October 7, 2014 in Yingjiang, Ludian and Jinggu, Yunnan Province, respectively. The epicentral distances of all the gravity datum stations to the three events are more than 100km, so the coseismic gravity changes caused by events can be ignored.

(3)The Ludian M_S6.5, Yingjiang M_S6.1 and Jinggu M_S6.6 earthquakes occurred successively during the turning point period, and the gravity changes show a decreasing trend until the occurrence of the Yangbi M_S6.4 event in 2021. The mechanism of gravity field change of Yunnan and the adjacent areas may be as follows: The Qinghai-Tibetan plateau is pushed to the northeast by the Indian plate, then blocked by the Sichuan Basin, and the crustal material under the Qinghai-Tibetan plateau moves forward to Yunnan and its adjacent regions.

(4)Yunnan and the adjacent areas are characterized by complex tectonic environment and rapid seismic energy accumulation and release, which puts forward new demands for absolute gravity measurement mode, adding absolute gravity measurement stations and shortening observation period, so as to enhance the ability of more absolute gravity measurement to serve for monitoring the seismic activity and regional geological tectonic activity in Chinese mainland.

Key words: gravity datum, CMONOC, absolute gravity measurements, gravity change rate

摘要：

文中利用国家重大科学工程 “大陆构造环境监测网络” 2010-2020年云南境内及周边区域10个基准站的绝对重力观测资料, 初步获得了各基准站的重力基准及其动态变化。其中, 9个测站的3个不同时间尺度和时段的重力变化趋势结果显示重力变化先增后减, 转折发生于2014年前后, 在重力变化增大至转折点时, 先后发生了2014年鲁甸M_S6.5、盈江M_S6.1和景谷M_S6.6地震, 随后至2021年漾濞M_S6.4地震发生之前重力一直呈减小趋势, 昆明站的情况则正好相反。文中研究表明, 云南及邻近区域内重力场变化幅度大、速度快、升降转换周期短, 且变化趋势一致。其重力场变化机制可能是由青藏高原受印度板块推挤向NE运移, 后受四川盆地阻挡, 青藏高原下的地壳物质转向SE的云南及邻近区域的运动所主导。

关键词: 重力基准, 陆态网络, 绝对重力测量, 重力变化速率

CLC Number:

P315.726

ZHANG Xin-lin, WANG Jian, HU Min-zhang, WANG Jia-pei, LI Zhong-ya, ZHANG Yi. GRAVITY VARIATION CHARACTERISTICS IN YUNNAN AND ITS SURROUNDING AREAS FROM 2010 TO 2020[J]. SEISMOLOGY AND EGOLOGY, 2021, 43(4): 972-983.

张新林, 汪健, 胡敏章, 王嘉沛, 李忠亚, 张毅. 2010-2020年云南及周缘绝对重力变化特征[J]. 地震地质, 2021, 43(4): 972-983.

Figures/Tables 5

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点名	东经 /(°)	北纬 /(°)	观测日期	重力值 /10^-8m·s^-2	标准偏差 /10^-8m·s^-2	观测仪器	重力变化率 (第1~2期) /10^-8m·s^-2·a^-1	重力变化率 (第2~5期) /10^-8m·s^-2·a^-1	重力变化率 (全5期) /10^-8m·s^-2·a^-1
攀枝花	101.74	26.50	2011-07-06	124.20	1.21	FG5-232	0.12	-4.16±1.52	-2.99±0.93
			2014-11-26	124.61	1.60	FG5-232
			2015-08-21	111.13	1.7	FG5-232
			2017-12-05	111.27	0.85	FG5X-255
			2019-09-26	98.90	0.8	FG5X-255
昆明	102.75	25.14	2010-12-02	70.20	1.18	FG5-232	-0.24	1.06±0.85	0.63±0.46
			2014-08-20	69.31	1.60	FG5-232
			2015-08-01	70.12	1.20	FG5-232
			2018-05-11	78.01	0.62	FG5X-255
			2019-10-31	72.71	2.74	FG5X-255
东川	103.18	26.10	2011-06-09	64.32	1.17	FG5-232	2.95	-1.49±0.52	0.27±0.84
			2014-11-23	74.50	1.10	FG5-232
			2015-08-19	73.81	1.70	FG5-232
			2017-12-02	73.13	0.92	FG5X-255
			2019-11-03	66.31	2.44	FG5X-255
蒙自	103.40	23.35	2011-06-12	67.82	1.77	FG5-232	8.16	-3.24±1.80	1.36±2.02
			2014-11-17	95.84	2.00	FG5-232
			2016-10-15	97.93	3.20	FG5-232
			2018-05-16	80.00	1.94	FG5X-255
			2019-10-27	83.50	2.68	FG5X-255
思茅	101.05	22.74	2011-06-14	50.53	1.33	FG5-232	6.47	-0.68±1.76	0.87±1.39
			2014-11-14	72.62	1.70	FG5-232
			2015-08-03	62.72	2.10	FG5-232
			2018-05-19	66.74	0.99	FG5X-255
			2019-10-24	58.43	2.55	FG5X-255
勐海	100.45	21.95	2011-06-17	60.34	1.19	FG5-232	1.91	-3.32±0.83	-1.72±0.93
			2014-11-12	66.82	1.70	FG5-232
			2015-08-05	64.36	3.30	FG5-232
			2018-05-21	49.51	1.49	FG5X-255
			2020-08-11	49.07	0.19	FG5X-255
耿马	99.40	23.53	2011-06-26	46.32	1.25	FG5-232	5.31	-4.15±0.26	-0.85±1.48
			2014-11-10	64.24	1.20	FG5-232
			2016-10-12	57.63	1.40	FG5-232
			2018-05-23	51.28	1.10	FG5X-255
			2020-08-12	39.96	1.36	FG5X-255
瑞丽	97.84	24.0	2011-06-29	78.10	2.38	FG5-232	5.20	-2.93±1.89	-0.83±1.49
			2014-11-08	94.91	3.60	FG5-232
			2015-08-11	86.93	2.90	FG5-232
			2018-05-27	70.16	1.84	FG5X-255
			2020-08-15	79.15	0.21	FG5X-255
下关	100.25	25.61	2010-12-06	69.10	1.40	FG5-232	1.96	-1.15±1.31	-0.20±0.67
			2014-11-05	76.83	1.50	FG5-232
			2016-10-03	65.62	0.90	FG5-232
			2018-05-31	68.85	0.62	FG5X-255
			2019-10-11	69.95	1.18	FG5X-259
丽江	100.03	26.70	2014-08-23	77.87	1.30	FG5-232		-1.95±0.87
			2015-08-16	69.90	1.00	FG5-232
			2018-07-04	71.68	0.87	FG5-232
			2020-08-11	62.34	0.83	FG5X-259

点名	东经 /(°)	北纬 /(°)	观测日期	重力值 /10^-8m·s^-2	标准偏差 /10^-8m·s^-2	观测仪器	重力变化率 (第1~2期) /10^-8m·s^-2·a^-1	重力变化率 (第2~5期) /10^-8m·s^-2·a^-1	重力变化率 (全5期) /10^-8m·s^-2·a^-1
攀枝花	101.74	26.50	2011-07-06	124.20	1.21	FG5-232	0.12	-4.16±1.52	-2.99±0.93
			2014-11-26	124.61	1.60	FG5-232
			2015-08-21	111.13	1.7	FG5-232
			2017-12-05	111.27	0.85	FG5X-255
			2019-09-26	98.90	0.8	FG5X-255
昆明	102.75	25.14	2010-12-02	70.20	1.18	FG5-232	-0.24	1.06±0.85	0.63±0.46
			2014-08-20	69.31	1.60	FG5-232
			2015-08-01	70.12	1.20	FG5-232
			2018-05-11	78.01	0.62	FG5X-255
			2019-10-31	72.71	2.74	FG5X-255
东川	103.18	26.10	2011-06-09	64.32	1.17	FG5-232	2.95	-1.49±0.52	0.27±0.84
			2014-11-23	74.50	1.10	FG5-232
			2015-08-19	73.81	1.70	FG5-232
			2017-12-02	73.13	0.92	FG5X-255
			2019-11-03	66.31	2.44	FG5X-255
蒙自	103.40	23.35	2011-06-12	67.82	1.77	FG5-232	8.16	-3.24±1.80	1.36±2.02
			2014-11-17	95.84	2.00	FG5-232
			2016-10-15	97.93	3.20	FG5-232
			2018-05-16	80.00	1.94	FG5X-255
			2019-10-27	83.50	2.68	FG5X-255
思茅	101.05	22.74	2011-06-14	50.53	1.33	FG5-232	6.47	-0.68±1.76	0.87±1.39
			2014-11-14	72.62	1.70	FG5-232
			2015-08-03	62.72	2.10	FG5-232
			2018-05-19	66.74	0.99	FG5X-255
			2019-10-24	58.43	2.55	FG5X-255
勐海	100.45	21.95	2011-06-17	60.34	1.19	FG5-232	1.91	-3.32±0.83	-1.72±0.93
			2014-11-12	66.82	1.70	FG5-232
			2015-08-05	64.36	3.30	FG5-232
			2018-05-21	49.51	1.49	FG5X-255
			2020-08-11	49.07	0.19	FG5X-255
耿马	99.40	23.53	2011-06-26	46.32	1.25	FG5-232	5.31	-4.15±0.26	-0.85±1.48
			2014-11-10	64.24	1.20	FG5-232
			2016-10-12	57.63	1.40	FG5-232
			2018-05-23	51.28	1.10	FG5X-255
			2020-08-12	39.96	1.36	FG5X-255
瑞丽	97.84	24.0	2011-06-29	78.10	2.38	FG5-232	5.20	-2.93±1.89	-0.83±1.49
			2014-11-08	94.91	3.60	FG5-232
			2015-08-11	86.93	2.90	FG5-232
			2018-05-27	70.16	1.84	FG5X-255
			2020-08-15	79.15	0.21	FG5X-255
下关	100.25	25.61	2010-12-06	69.10	1.40	FG5-232	1.96	-1.15±1.31	-0.20±0.67
			2014-11-05	76.83	1.50	FG5-232
			2016-10-03	65.62	0.90	FG5-232
			2018-05-31	68.85	0.62	FG5X-255
			2019-10-11	69.95	1.18	FG5X-259
丽江	100.03	26.70	2014-08-23	77.87	1.30	FG5-232		-1.95±0.87
			2015-08-16	69.90	1.00	FG5-232
			2018-07-04	71.68	0.87	FG5-232
			2020-08-11	62.34	0.83	FG5X-259

观测仪器	时间	观测值/10^-8m·s^-2	时间	观测值/10^-8m·s^-2	时间	观测值/10^-8m·s^-2
FG5-232	2018-03-15	979 350 962.72	2019-03-29	979 350 966.11
FG5X-255	2018-03-20	979 350 960.32	2019-03-21	979 350 963.52	2020-12-24	979 350 971.34
FG5X-259			2019-03-19	979 350 962.18	2020-12-20	979 350 972.71

观测仪器	时间	观测值/10^-8m·s^-2	时间	观测值/10^-8m·s^-2	时间	观测值/10^-8m·s^-2
FG5-232	2018-03-15	979 350 962.72	2019-03-29	979 350 966.11
FG5X-255	2018-03-20	979 350 960.32	2019-03-21	979 350 963.52	2020-12-24	979 350 971.34
FG5X-259			2019-03-19	979 350 962.18	2020-12-20	979 350 972.71