利用H-κ-c方法研究腾冲火山区的地壳厚度与泊松比

doi:10.3969/j.issn.0253-4967.2024.05.004

摘要/Abstract

摘要：

文中从腾冲火山及周边地区分布的23个数字地震台站记录的远震波形数据中提取了4 286条P波接收函数, 采用具有谐波校正的H-κ-c方法获取了腾冲火山区的地壳厚度和平均泊松比分布情况。结果表明: 腾冲块体的快波极化方向由北部的NW-SE向转变为南部的NE-SW向, 延迟时间为0.06~0.80s, 平均延迟为0.40s, 与整个腾冲块体围绕EHS顺时针旋转一致。腾冲断裂、盈江断裂、陇川断裂的交会部位具有倾斜的莫霍面和较强的方位各向异性。腾冲火山区的地壳厚度范围为32~39km, 泊松比范围为0.235~0.326。存在3个莫霍面隆起中心, 分别位于固东—曲石—马站—腾冲、清水—新华、镇安—龙新—象达, 泊松比较高(σ>0.3)的区域也位于这3个位置, 推测是岩浆囊所在的区域。3个岩浆囊的水平规模分别为35km×20km、 20km×20km、 25km×25km, 且受到深大断裂的控制。大多数地震都分布在莫霍面隆起中心周围的地壳中, 而在隆起中心的地壳中几乎没有地震发生, 这可能是由于岩浆上涌使地壳温度升高, 导致岩石脆性降低, 不容易积累较大的应变。

关键词: 腾冲火山, 地壳各向异性, 地壳厚度, 泊松比, 岩浆囊

Abstract:

Tengchong volcanoes are not extinct but a group of dormant volcanoes with magma underground. The Tengchong volcanic area is a unique geological condition integrating magma activity, earthquakes, and hot springs. Crustal thickness and Poisson’s ratio are two important parameters that characterize crustal structure and material composition and are crucial for accurately detecting the location and scale of magma chambers in the Tengchong volcanic area. However, previous studies on obtaining crustal thickness and Poisson’s ratio in the Tengchong volcanic area only used nine volcanic network stations, which had insufficient resolution and could not effectively constrain the position of magma chambers. The traditional H-κ method is adopted to an isotropic crust with a flat Moho. The crust maybe anisotropic and the Moho is dipping. In the presence of a complex crustal structure with azimuthal anisotropy or dipping Moho, the H-κ results may be biased. So, we extracted 4 268 P receiver functions from teleseismic wave data recorded at 23 digital seismic stations. A H-κ-c method with harmonic corrections is used to obtain crustal thickness and Poisson’s ratio in the Tengchong volcano area. Before the harmonic corrections to the P receiver functions, we perform the incident moveout corrections and back azimuthal binning of 5°. The H-κ-c method can correct the influence of crustal anisotropy and dipping interfaces on receiver functions by harmonic transformation, can acquire more stable and reliable crustal thickness and wave velocity ratios, and can obtain information on the inclination of the Moho and crustal azimuthal anisotropy. Based on previous research, we discussed the crustal deformation mechanism of the Tengchong block and revealed the corresponding relationship between crustal structure, heat flow, earthquakes, and magmatism.

Results show the fast-wave polarization directions with a dominant NW-SE orientation in the north and change to a dominant NE-SW orientation in the south, and delay times varying between 0.06 and 0.80s, with a mean of 0.40s. It is consistent with the Tengchong block undergoing clockwise rotation around the EHS. There is an inclined Moho surface and strong azimuthal anisotropy in the intersection of the Tengchong Fault, Yingjiang Fault, and Longchuan Fault. The strong azimuthal anisotropy in the Tengchong block maybe related to the strong influence of the upwelling of the deep thermal material from the upper mantle. The fast wave polarization direction parallel to the Longling-Ruili fault indicates that the observed anisotropy may be related to the fracture of the fault. The crustal thickness ranges from 32 to 39km, and the Poisson’s ratio ranges from 0.235 to 0.326. There exist three Moho-uplifting centers, one in Gudong-Qvshi-Mazhan-Tengchong, the other in Qingshui-Xinhua, another in Zhen’an-Longxin-Xiangda. The very high Poisson’s ratio(σ>0.3) is consistently located within these three locations. We speculated that the Moho-uplifting and higher Poisson’s ratio at the three sites denote the existence of three magma chambers. The horizontal scale of the three magma chambers is respectively 20km×35km, 20km×20km, 25km×25km, and separately controlled by the Tengchong Fault and Longchuanjiang Fault, Tengchong Fault and Longchuan Fault, Nujiang Fault and Longling-Ruili Fault. The locations of the magma chambers are different from that obtained by the same receiver function method, which the different seismic stations and stacking methods may cause. The locations of the magma chambers are not exactly the same as those of the geothermal anomaly areas and the mantle-derived volatile release anomaly areas measured by the surface hot springs. The reason for this difference may be the ground temperature and the mantle-derived volatile component, which are the measurement results of the surface hot spring. The Poisson’s ratio value we calculated is the average value of the entire crust. Under the four Holocene volcanic craters of HeikongShan, Dayingshan, Laoguipo, and Ma’anshan, there is an interconnected magma chamber, the most vigorous volcanic activity since the Holocene. There are almost no earthquakes occurring in the crust at the center of the Moho uplift; most earthquakes are distributed in the crust around the Moho-uplifting centers. This may be because the hot magma heated the crust, resulted in the rocks in the crust being plastic, and it is difficult to accumulate large strains. Our results have important reference value and guiding significance for earthquake and volcanic activity monitoring, earthquake prevention and disaster reduction in the Tengchong volcanic area.

Key words: Tengchong volcano, crustal azimuthal anisotropy, crustal thickness, Poisson’s ratio, magma chambers

张天继, 李秋凤, 李凤英, 钟玉盛, 段洪杰. 利用H-κ-c方法研究腾冲火山区的地壳厚度与泊松比[J]. 地震地质, 2024, 46(5): 1048-1065.

ZHANG Tian-ji, LI Qiu-feng, LI Feng-ying, ZHONG Yu-sheng, DUAN Hong-jie. THE STUDY OF CRUSTAL THICKNESS AND POISSON'S RATIO IN TENGCHONG VOLCANO AREA BY H-к-c METHOD[J]. SEISMOLOGY AND GEOLOGY, 2024, 46(5): 1048-1065.

图/表 7

图 1 地震台站、地质构造背景及远震分布情况 a 地震台站及火山口分布; b 地质构造背景; c 远震震中分布情况, 黑色三角形代表腾冲火山区。 F1怒江断裂;F2龙川江断裂; F3腾冲断裂; F4盈江断裂; F5陇川断裂; F6龙陵-瑞丽断裂

Fig. 1 Tectonic structure, distribution of seismic stations and teleseismic events.

图 2 XHT台站谐波校正前(a)、后(b)接收函数随反方位角的分布

Fig. 2 Receiver functions with azimuth recorded by station XHT before(a) and after(b) harmonic corrections.

图 3 XHT台站H-κ-c叠加示例 a—c XHT台站Ps、 M1、 M2震相到时的谐波拟合情况。在每个能量图中绘制了99%的等值线以表示经验不确定性,白色十字表示最优解。d、 e 谐波校正前、后的H-κ叠加结果和误差范围

Fig. 3 H-κ-c results on example station XHT.

表1 各台站下方的地壳厚度、波速比和泊松比值

Table 1 Crustal thickness, VP/VS ratios and Poisson’s ratios beneath stations

序号	台站代码	东经/(°)	北纬/(°)	H/km	波速比κ	泊松比σ	接收函数个数	方法
1	CZS	98.67	24.90	37.4±2.8	1.70±0.07	0.235	242	H-k-c
2	LYH	98.43	24.96	38.0±2.3	1.74±0.07	0.253	182	H-k-c
3	MAS	98.59	24.42	34.6±2.4	1.78±0.06	0.269	283	H-k-c
4	MGT	98.57	25.46	38.5±2.2	1.80±0.06	0.277	229	H-k-c
5	MIZ	98.42	25.13	36.5±2.1	1.86±0.07	0.297	248	H-k-c
6	MZT	98.49	25.21	34.1±3.3	1.93±0.12	0.317	273	H-k-c
7	QKT	98.33	25.22	36.5±2.4	1.80±0.07	0.277	248	H-k-c
8	RHT	98.44	24.95	37.6±2.3	1.72±0.06	0.245	256	H-k-c
9	RST	98.39	24.91	37.6±2.6	1.73±0.07	0.249	275	H-k-c
10	SBT	98.54	24.95	36.0±2.1	1.84±0.07	0.290	259	H-k-c
11	TCG	98.52	25.03	33.0±2.3	1.97±0.09	0.326	268	H-k-c
12	XHT	98.48	24.75	36.4±2.2	1.71±0.06	0.240	273	H-k-c
13	53061	98.54	25.51	38.6±1.7	1.77±0.05	0.266	131	H-k-c
14	MLL01	98.88	24.54	32.0±3.2	1.95±0.15	0.322	142	H-k-c
15	MLY02	98.87	25.40	36.4±2.9	1.85±0.12	0.294	166	H-k-c
16	NLH01	98.48	24.84	32.5±2.2	1.92±0.09	0.314	177	H-k-c
17	DTT	98.46	25.45	38.0±3.3	1.88±0.11	0.303	61	H-k
18	53066	98.84	25.20	39.0±4.1	1.73±0.16	0.249	71	H-k
19	53067	98.86	25.45	38.6±2.9	1.81±0.10	0.280	152	H-k
20	53068	98.84	24.69	35.1±4.4	1.85±0.13	0.294	89	H-k
21	53069	99.03	24.56	35.5±2.2	1.74±0.07	0.253	88	H-k
22	53080	98.22	24.66	34.5±1.7	1.87±0.08	0.300	108	H-k
23	53081	98.03	24.50	35.4±2.7	1.75±0.10	0.258	65	H-k

图 4 谐波校正前、后16个台站的H(a)和κ(b)误差(标准差)分布图

Fig. 4 Histograms of the standard deviation of H (a) and κ (b) at 16 seismic stations before and after the harmonic corrections.

图 5 各台站下方的地壳厚度(a)、泊松比值(b)及地壳方位各向异性(c)分布情况断层名称见图 1

Fig. 5 Crustal thickness(a), Poisson’s(b)and azimuthal anisotropy of the crust(c)beneath each seismic station.

图 6 腾冲火山区的地壳厚度(a)与泊松比值(b)总体分布情况断层名称参见图 1, 红色圆圈是2008年以来MS≥1.0的地震震中

Fig. 6 Overall distribution of crustal thickness (a) and Poisson’s ratio (b) in the Tengchong volcanic area.

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