active source seismic imaging on near-surface granite body
TRANSCRIPT
Vol:.(1234567890)
Petroleum Science (2021) 18:742–757https://doi.org/10.1007/s12182-021-00569-8
1 3
ORIGINAL PAPER
Active source seismic imaging on near‑surface granite body: case study of siting a geological disposal repository for high‑level radioactive nuclear waste
Wen Li1,3 · Yi‑Ke Liu2 · Yong Chen1 · Bao‑Jin Liu3 · Shao‑Ying Feng3
Received: 17 November 2019 / Accepted: 12 March 2021 / Published online: 4 June 2021 © The Author(s) 2021
AbstractIn order to research whether it is suitable to set a geological disposal repository for high-level radioactive nuclear waste into one target granite body, two active source seismic profiles were arranged near a small town named Tamusu, Western China. The study area is with complex surface conditions, thus the seismic exploration encountered a variettraveltimey of technical difficulties such as crossing obstacles, de-noising harmful scattered waves, and building complex near-surface velocity mod-els. In order to address those problems, techniques including cross-obstacle seismic geometry design, angle-domain harmful scattered noise removal, and an acoustic wave equation-based inversion method jointly utilizing both the and waveform of first arrival waves were adopted. The final seismic images clearly exhibit the target rock’s unconformable contact boundary and its top interface beneath the sedimentary and weathered layers. On this basis, it could be confirmed that the target rock is not thin or has been transported by geological process from somewhere else, but a native and massive rock. There are a few small size fractures whose space distribution could be revealed by seismic images within the rock. The fractures should be kept away. Based on current research, it could be considered that active source seismic exploration is demanded during the sitting process of the geological disposal repository for nuclear waste. The seismic acquisition and processing techniques proposed in the present paper would offer a good reference value for similar researches in the future.
Keywords Geological disposal repository · Nuclear waste · Granite body · Active source seismic exploration · Near-surface velocity inversion
1 Introduction
High-level radioactive nuclear waste generally refers to the waste products containing high-level radioactive materi-als which are generated by the nuclear power industry and are inevitable by-products due to nuclear power plants. As they may seriously threaten the health of human and other
forms of life, countries across the globe have attached great importance to their safe disposal (Guo et al. 2001). The dis-posal technology normally includes marine disposal, island disposal, etc. At present, one widely adopted scheme for safe disposal of high-level radioactive nuclear waste is sup-posed to be deep geological disposal (Alberdi et al. 2000), which, in other words, means that the high-level radioactive nuclear waste is buried within a stable geological body at a depth of 500–1000 m to separate them from the biosphere permanently (Su et al. 2011). The engineered underground facility for burying the nuclear waste is called geological disposal repository. In various countries, different types of rocks would be selected for such repositories. China mainly focuses on the large granite masses (Wang et al. 2006).
For a comprehensive assessment of one target granite body, synthetical studies of the tectonics, hydrology, and geophysics are required. Active source seismic exploration is one of the most important technical approaches (Chen et al. 2017).
Edited by Jie Hao
* Yi-Ke Liu [email protected]
1 School of Earth Sciences and Engineering, Nanjing University, Nanjing 210008, China
2 Key Laboratory of Petroleum Resource Research, Institute of Geology and Geophysics, Chinese Academy of Sciences, Beijing 100029, China
3 Geophysical Exploration Center, China Earthquake Administration, Zhengzhou 450002, China
743Petroleum Science (2021) 18:742–757
1 3
On one pre-selected geological disposal repository located on the eastern edge of the Badanjilin Desert, our seismic exploration work was carried out. The objectives of the proposed exploration were to answer the following ques-tions: whether the rock is thin, where the rock’s boundaries are and their spatial distribution, if the faults interpreted by remote sensing technology (Fig. 1) exist.
The seismic exploration research focusing on one large high-velocity granitic pluton is uncommon. During the research, we found that the study area was with complex landforms which included three distinct types: semi-desert grasslands, areas of shifting dunes, and areas of outcrops (Fig. 2). In addition, the elevations along the seismic lines change dramatically (Fig. 3). Thus, in the course of seismic data acquisition and processing, we encountered difficulties (Chen et al. 2015) of crossing obstacles, removing harmful scattered waves, and building complex near-surface velocity models. To address those problems, targeted techniques such as cross-obstacle seismic geometry design, angle-domain vector resolution based scattered wave removal (Liu 2013; He et al. 2015), and an acoustic wave equation-based inver-sion method jointly utilizing both the travel time and wave-form of first arrival waves (Luo and Schuster 1991; Jiang and Zhang 2016; Yao et al. 2019), were adopted.
2 Seismic acquisition and the cross‑obstacle seismic geometry design
Based on the seismic exploration objectives, the main seis-mic working parameters were set as: 4 m trace interval, 24 m shot interval, 300 traces receiving (the receiver array length of one single-shot was 1.2 km), fold number ≥ 25, 1 ms sam-pling rate, and 3 s record length.
In the course of seismic acquisition, seismic spread must overcome certain obstacles. As shown in Fig. 2d, one large rock outcrop emerges from the ground (stake 4748–5084 m of the TMS2 seismic line). If its negative influences were ignored, it would engender the lack of seis-mic data, and there would be a gap existing between stake 4750–5100 m in the final reflection imaging profile. Given this realization, we presented a patent for invention (Li et al. ZL201710342906.5) whose function aims at mitigating the harmful effect of obstacles on the seismic line via rede-signing the routine seismic geometry. As shown in Fig. 4a, new shot and receiver positions were set (Fig. 4a). One of the rules for setting those new positions was to assure the real fold numbers on each Common Mid-Point (red points) always above the mean level (blue points) in the most eco-nomical way. As shown in Fig. 4b, there was no gap in the
Mafic DikesInterpreted Faults
Seismic LinesGeological Work Area
Legend
TMS2TMS1
102°30′00″E 103°00′00″E 103°30′00″E
40°3
0′00
″N41
°00′
00″N
Fig. 1 Graph of remote sensing interpretation of the seismic work area
744 Petroleum Science (2021) 18:742–757
1 3
relevant position, thus the negative influence of the obstacle was effectively weakened. It was due to this technique, the geological task of continuously tracking the rock’s top inter-face could be realized.
3 Removing complex near‑surface scattered waves via an angle‑domain vector resolution de‑noising method
When active source seismic exploration work is carried out in a complex near-surface area, the acquired seismic records normally contain many harmful scattered waves. The Tamusu research area is also a case in point. The scattered waves are usually mixed with the effective signal (Fig. 5a), and by our research, they could not be reasonably filtered out via the tra-ditional filtering methods of the time and frequency domain or wavelet domain (Li et al. 2016).
To de-noise the harmful complex near-surface scattered waves, an angle-domain vector resolution de-noising method was adopted. This method could make use of the difference
of emergence angles between reflected waves and scattered waves to de-noise. In addition, it could be used in pre-stack processing.
After applying the abovementioned method on common-shot-gathers, the useful reflected waves and the harmful scat-tered waves were separated satisfactorily (Fig. 5b, c). Conse-quently, the quality of the seismic imaging profile, especially the left and top portion of the profile, was improved signifi-cantly (Fig. 6).
4 Building complex near‑surface velocity models utilizing both the travel time and waveform of first arrival waves
According to previous experience, the accuracy of near-surface velocity would influence the total quality of seismic profiles (Xia 2014), especially in a study area with complex surface conditions.
Thus, an acoustic wave equation-based high-resolution near-surface velocity inversion method, which could jointly
Fig. 2 Pictures of landforms along the seismic lines
745Petroleum Science (2021) 18:742–757
1 3
utilize both the travel time and waveform of first arrival waves, was adopted in the present research. The fundamen-tal theory of this method was proposed by Luo and Schuster in 1991. Its basic procedure includes: firstly, get simulated data (Yao et al. 2016) by solving acoustic wave equation and work out a kind of pseudo-residual data via a link func-tion which relates the simulated data and the observed data; secondly, we are supposed to minimize the pseudo-residual data with the classical full-waveform inversion engine (Yao and Wu 2017; Li et al. 2020; Liu et al. 2020).
The abovementioned method has been applied to cross-hole seismic data effectively. In the present research, we adopt it to process ground-observation seismic data on the complex near-surface area. The detailed algorithm is elaborated as follows:
1. Calculate the simulated seismic data via solving the acoustic wave equation;
2. Calculate the pseudo-residual data of first arrival waves via the following equations,
and
(1)dpres(
xr, t;xs)
= −2
E
�dcal(
xr, t;xs)
�t�
(
xr;xs)
where Δ�(
xr;xs)
is the time difference of the first arrival waves of observed data and simulated data. dcal
(
xr, t;xs)
represents the calculated simulated data. dobs
(
xr, t + Δ�;xs)
represents the observed data, which have been corrected by Δ� . dpres
(
xr, t;xs)
represents the pseudo-residual data. E is the energy term related to the time derivative of dcal
(
xr, t;xs)
and dobs(
xr, t + Δ�;xs)
;3. Backward-propagate the pseudo-residual data to calcu-
late the pseudo-residual wavefield, meanwhile recon-struct the source wavefield;
4. Calculate the correction gradient direction g(�) of the velocity model via Eq. (3), and calculate the update direction via a kind of conjugate gradient method (e.g., Conjugate Descent scheme, Fletcher–Reeves scheme, Hestenes–Stiefel scheme, etc.);
where ps(
�, t;xs)
is the reconstructed forward-propagat-ing source wavefield. pr
(
�, t;xs)
is the backward-prop-agating pseudo residual wavefield. v(�) represents the current velocity model;
(2)E = ∫�d
obs
(
xr, t + Δ�;xs)
�t
�dcal
(
xr, t;xs)
�tdt
(3)g(�) = −1
v3(�)
∑
s∈S∫
T
0
�ps(
�, t;xs)
�t
�pr(
�, t;xs)
�tdt
Distance, m
14000 1000 2000 3000 4000 5000 6000 7000 8000 9000 10000
1420
1440
1460
1480
1500
Elev
atio
n, m
TMS1 elevations
Distance, m
1280
1300
1320
1340
1360
1380
1400
1420
Elev
atio
n, m
TMS2 elevations
0 1000 2000 3000 4000 5000 6000 7000 8000 9000 10000 11000 12000 13000 14000 15000 16000
(a)
(b)
Fig. 3 Elevations along the TMS1 (a) and TMS2 (b) lines
746 Petroleum Science (2021) 18:742–757
1 3
5. Take the sum of the square of the pseudo-residual data of all the shots as the objective function, which is math-ematically expressed as,
and calculate the iteration step length via a three-point parabola method.
6. Update the model and go to the next iteration.
As shown in Fig. 3, the ground surface of the Tamusu area is rugged. To address the issue of an irregular free-surface, we adopt an algorithm called the acoustic-elastic boundary approach (Xu et al. 2007) which deals with the model’s top free-surface by modifying the den-sity and lame constants on special positions. As shown in Fig. 7, the red and blue triangles separately indicate the positions on which �x and �z should be modified ( �x = 0.5�, �z = 0.5� ) in a staggered-grid finite-difference model. The black points indicate where � should be set 0 ( � = 0).
(4)C =∑
s∈S∫
T
0
d2pres
(
xr, t;xs)
dt
In addition to the above, there were some details required manual intervention when real data were processed. The total processing procedure of the seismic data of Tamusu is described below.
4.1 Pick up the travel time of first arrival waves
In the total inversion process, travel time of first arrival waves of the observed data needs to be picked up once. But because real data normally includes a mass of noises and abnormal values, this process needs human intervention to ensure the results’ quality. The travel time of first arrival waves of the TMS1 and TMS2 seismic lines are shown in Fig. 8a, b.
4.2 Waveform data preparation
The frequency band of the raw data of Tamusu is about 16–80 Hz, which is slightly higher for the waveform inver-sion research. Hence, the filtering work should be done to extract the low-frequency components of the observed data.
200 800 1400 2000 2600 3200 3800 4400 5000 5600 6200 6800 7400 8000 8600 9200 98000
0.20
0.40
0.60
TWT,
s
N
187
189
191
193
195
197199201203205
207209211213215
217219221223225227229231233
235
237
239
241
243245
247
249
251
253
255
257
259261
263
265
188
190
192
194
196
198200202204206
208210212214
216
218220222224226228230232234
236
238
240
242
244
246
248
250
252
254
256258
260
262
264
266
1864416444044644488451245364560458446084632465646804704472847524776480048244848487248964920494449684992501650405064508851125136516051845208523252565280530453285352537654005424544854725496552055445568559256165640566456885712573657605784580858325856588059045928595259766000
4392
(a)
(b)
Fig. 4 The redesigned cross-obstacle seismic geometry (a) and the final profile (b) utilizing the new geometry
747Petroleum Science (2021) 18:742–757
1 3
According to the research, we finally chose a band-pass filter with the parameters of (4.8–24.48 Hz). To avoid the disturbance that came from background noises and late-arrival waves, we only left the first arrival wave. The
typical data processing results of seismic data of TMS1 (FFID = 101) and TMS2 (FFID = 201) are shown in Fig. 9.
(c)0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
1.0
Tim
e, s
1 21 41 61 81 101 121 141 161 181 201 221 241 261 281
Traces
(b)0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
1.0
Tim
e, s
1 21 41 61 81 101 121 141 161 181 201 221 241 261 281
Traces
(a)0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
1.0
Tim
e, s
1 21 41 61 81 101 121 141 161 181 201 221 241 261 281
Traces
Fig. 5 Results of removing scattered noises: original common-shot gather (a), de-noised common-shot gather (b), and the separated noises (c)
748 Petroleum Science (2021) 18:742–757
1 3
4.3 Initial models’ building
To carry out the joint inversion of travel time and wave-form of first arrival waves, initial velocity models were built via an MSFM (multi-stencil fast marching) based ray-tracing inversion algorithm (Lu et al. 2013). The initial models built for the TMS1 and TMS2 seismic lines are displayed in Fig. 10a, b.
4.4 Velocity model updating process
Started with the initial models mentioned above, the inversion calculation of the TMS1 line stopped after 68
iterations, and the calculation of the TMS2 line stopped after 71 iterations. The updated velocity models obtained in the first, middle, and last iterations are displayed sepa-rately in Fig. 11.
4.5 Analysis of the pseudo‑residual of first arrival waves
To check the inversion processing, parts of pseudo-resid-ual data and the corresponding observed data and simu-lated data are displayed in Fig. 12. It could be found that the value of initial velocity models built via the ray-tracing inversion algorithm tended to be small, because in the first iteration, the arrival-time of the simulated data (blue line) felled behind that of the real data (red line). As iteration
(a)0
0.25
0.50
0.75
TWT,
s
800 2000 3200 4400 5600 6800 8000 9200 10400 11600 12800 14000
Distance, m
(b)0
0.25
0.50
0.75
TWT,
s
800 2000 3200 4400 5600 6800 8000 9200 10400 11600 12800 14000
Distance, m
Fig. 6 The top portion of the reflection imaging profiles obtained from the original common-shot gathers (a) and the de-noised common-shot gathers (b)
x on horizontal freesurface
Normal grid position
Normal grid position on freesurface
z on vertical freesurface��
X-Grids
Z-G
rids
25
27
29
31
33
35
37
39
41
43
45620 625 630 635 640 645 650 655 660 665 670
6000
5000
4000
3000
2000
1000
0
Fig. 7 Model parameter modification scheme for irregular free-surface of acoustic-elastic boundary approach
749Petroleum Science (2021) 18:742–757
1 3
Station locations, m
0
0.1
0.2
0.3
0.4
0.5Travel time of first arrival waves of TMS2
Travel time of first arrival waves of TMS1
Tim
e, s
0 2000 4000 6000 8000 10000 12000 14000 16000
(b)
Station locations, m
0
0.1
0.2
0.3
0.4
0.5
Tim
e, s
0 2000 4000 6000 8000 10000 12000 14000 16000
(a)
Fig. 8 Manually picked travel time of the first arrival waves of the TMS1 (a) and TMS2 (b) lines
First arrival TMS1, ffid101
60 120 180 240 60 120 180 240 60 120 180 240 60 120 180 24060 120 180 24060 120 180 240
Traces
Filtered data TMS1, ffid101
Traces
Original data TMS1, ffid101
Traces
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
Tim
e, s
-2 20 -1 10 -1 10×1011
-2 20 -1 10 -1 10×1011
(a)First arrival TMS2, ffid201
Traces
Filtered data TMS2, ffid201
Traces
Original data TMS2, ffid201
Traces
(b)
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
Tim
e, s
Fig. 9 Examples of filtering and extracting first arrival waves: single shot of TMS1 (a), single shot of TMS2 (b). Left: raw data; middle: filted data; right: first arrival waves; cyan line: travel time picked by manual
750 Petroleum Science (2021) 18:742–757
1 3
went on, the difference between the red line and the blue line decreased gradually.
The green line represents the waveform matching results which were obtained through the calculation of waveform cross-correlation. In the first iteration, they were not continu-ous and regular enough. This phenomenon could be attrib-uted to the waveform of first arrival waves of the observed data and the simulated data had large differences. As the iter-ation continued, the continuity and regularity of the green line were improved. What’s more, it could also be observed that the amplitude of the pseudo-residuals became smaller until hardly could be seen. All of these indicate the model’s updating was in the right direction for reducing the travel time and waveform residuals.
4.6 Analysis of the evolution of the objective function
As mentioned above, we have taken the sum of the square of pseudo-residual data of all the shots as the objective func-tion. Figure 13 shows the evolution of the objective function, in which we could see the value decreases with the itera-tion number increasing. The reason why the curve heightens at some points is due to the fact that we have set the top and bottom limitations for the velocity model, when some value excesses the limits, the value would be clipped and the model would be smoothed again to remove the sharp interfaces.
Based on the features shown in Figs. 12 and 13, the final updated models of TMS1 and TMS2 could be deemed reli-able. The obtained near-surface velocity models could be used as important references for the seismic interpretation. Meanwhile, the subsequent seismic processing steps, such as
tomographic static correction, migration, etc., could benefit from the models as well.
5 Seismic interpretation
For seismic interpretation in the present research, it is important to take distinctions into consideration between the high-velocity rock seismic exploration and those carried out on sedimentary environments (Yuan et al. 2017). Few studies of seismic imaging profiles on granite body have been published in China. But generally speaking, because the velocity of granite would normally exceed the values of its surrounding rocks, the seismic events from rock bounda-ries, e.g., the side or top boundary, would be characterized by strong amplitude and good continuation. However, the seismic events within the rock are normally disordered and with low-frequency, intermittent, worm-like forms. The unconformable contact relationships may be observed on the flanks of the granite rock or between the rock with its overlying strata.
According to regional geological research (Wang et al. 1998; Liu and Zhang 2014), the study area could be divided into two geologic zones: a Late Paleozoic plutonic zone in the northwest and a Mesozoic–Cenozoic basin in the southeast (Fig. 14). The Late Paleozoic plutonic zone consists primarily of Late Paleozoic plutonic rocks. And there are a few residues of Early Paleozoic plutonic rocks and Precambrian metamorphic crystalline basement, as well as some Indo-Chinese plutonic rocks. The deposits of the Mesozoic–Cenozoic basin are composed primarily of Jurassic–Cretaceous sandy conglomerate. In the study area, the granite rock mass is always NEE extension and there are almost no fold structures. The major structural
5000
4500
4000
3500
3000
2500
5000
4500
4000
3500
3000
2500
14801000 2000 3000 4000 5000 6000 7000 8000 9000 10000
1430
1380
1330
1280
1420
1370
1270
1170
1320
1220
1120
1070
MZ
= 11
0, d
z = 2
mM
Z =
183,
dz =
2 m
MX = 5104, dx = 2 m
2000 4000 6000 8000
Initial velocity model of TMS2
Initial velocity model of TMS1
(a)
(b) 10000 12000 14000 16000
MX = 8501, dx = 2 m
Fig. 10 Initial velocity models for the TMS1 (a) and TMS2 (b) lines
751Petroleum Science (2021) 18:742–757
1 3
features of the study area consist of faults with different strikes and ductile shear zones (Fig. 14).
5.1 TMS1 seismic line
Figure 15 shows the interpretation results of the TMS1 seis-mic line, based on the near-surface velocity profile (Fig. 15a) and the reflection profile (Fig. 15b).
500045004000350030002500
14801000 2000 3000 4000 5000 6000 7000 8000 9000 10000
1430
1380
1330
1280
Elev
atio
n, m
Distance, m
Updated model (iters: 001)
(a)
500045004000350030002500
14801000 2000 3000 4000 5000 6000 7000 8000 9000 10000
1430
1380
1330
1280
Elev
atio
n, m
Distance, m
Updated model (iters: 036)
500045004000350030002500
14801000 2000 3000 4000 5000 6000 7000 8000 9000 10000
1430
1380
1330
1280
Elev
atio
n, m
Distance, m
Updated model (iters: 068)
500045004000350030002500
2000 4000 6000 8000 10000 12000 14000 16000142013701320
12201270
1170
10701120El
evat
ion,
m
Distance, m
Updated model (iters: 001)
500045004000350030002500
2000 4000 6000 8000 10000 12000 14000 16000142013701320
12201270
1170
10701120El
evat
ion,
m
Distance, m
Updated model (iters: 036)
500045004000350030002500
2000 4000 6000 8000 10000 12000 14000 16000142013701320
12201270
1170
10701120El
evat
ion,
m
Distance, m
Updated model (iters: 071)
(b)
Fig. 11 Velocity model updating processes of the TMS1 (a) and TMS2 (b) lines
752 Petroleum Science (2021) 18:742–757
1 3
(b)
Tim
e, s
(a)
TMS2, pres201(iters: 001)
Traces
TMS2, dcal201(iters: 001)
Traces
TMS2, dobs201(input data)
Traces
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
Tim
e, s
TMS1, pres101(iters: 001)
Traces
×10-6
TMS1, dcal101(iters: 001)
Traces
TMS1, dobs101(input data)
60 120 180 240 60 120 180 240 60 120 180 240 60 120 180 240 60 120 180 240 60 120 180 240
Traces
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
Tim
e, s
-1 0 1 -1 0 1 -1 0 1×10-6
-1 0 1 -1 0 1 -1 0 1
TMS2, pres201(iters: 036)
Traces
TMS2, dcal201(iters: 036)
Traces
TMS2, dobs201(input data)
Traces
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
Tim
e, s
TMS1, pres101(iters: 036)
Traces
TMS1, dcal101(iters: 036)
Traces
TMS1, dobs101(input data)
Traces
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
Tim
e, s
60 120 180 240 60 120 180 240 60 120 180 240 60 120 180 240 60 120 180 240 60 120 180 240
×10-6
-1 0 1 -1 0 1 -1 0 1×10-6
-1 0 1 -1 0 1 -1 0 1
TMS2, pres201(iters: 071)
Traces
TMS2, dcal201(iters: 071)
Traces
TMS2, dobs201(input data)
Traces
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
Tim
e, s
TMS1, pres101(iters: 068)
Traces
TMS1, dcal101(iters: 068)
Traces
TMS1, dobs101(input data)
Traces
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
60 120 180 240 60 120 180 240 60 120 180 240 60 120 180 240 60 120 180 240 60 120 180 240
×10-6
-1 0 1 -1 0 1 -1 0 1×10-6
-1 0 1 -1 0 1 -1 0 1
Fig. 12 Example analysis of the pseudo-residual of first arrival waves of the TMS1 (a) and TMS2 (b) lines left: observed data; middle: simu-lated data; right: pseudo-residual data; red line: first break of observed data; green line: first break of simulated data; cyan line: waveform march-ing result
753Petroleum Science (2021) 18:742–757
1 3
On the top of Fig. 15b, there is a high-energy reflection wave group composed of two seismic events with good lateral continuation. In Fig. 15a, at the depth of 40–50 m below ground surface, the velocity value increases rapidly
from 2000 m/s to about 4200 m/s. As can be seen, the upper boundary of the high-velocity part in Fig. 15a is consistent with the lateral variation of the strong seismic events on the top of Fig. 15b. Comprehensively speaking, it could be spec-ulated that the high-energy reflections on the top of Fig. 15b derive from the top interface of the granite rock. Above the granite, there exist sedimentary and weathered strata, which
0 20 40 60 80 0 20 40 60 80
Iterations
0
2
4
6
Obj
ectiv
e fu
nctio
n
×10-4
Sum of pres2 of TMS1 Sum of pres2 of TMS2
Iterations
0
2
4
6
8
Obj
ectiv
e fu
nctio
n
×10-3
(b)(a)
Fig. 13 Evolution curves of the objective function of the TMS1 (a) and TMS2 (b) lines
Qp3pl
K1b K1b
Qhpal Qp3plK1b
Qp3pl
K1b
Qhpal
103°00′ 103°04′ 103°08′ 103°12′ 103°16′ 103°20′
40°38′
40°42′
40°46′
40°50′
0 km
16.856 km
0 km
10.196 km
Qp3pl
T��
T��
T��
T��
T��
T��
T��
C1��
C1��
T1��
P3���P3��
P3��
P3��
P3�ο
P3���
P3�ο
Qhpal
P3�οP3�ο
Pt3bpg
Pt3bpg
Qp3pl
Qp3pl
K1b
Zhgn
T��
T��
P3��
J1-2j
P2�ο
T��
T��
T��
T��
P3���
Qhpl+eolP3���
P3���
Pt3bpg
P2��� P2���
Pt3sch
Pt3sch
Pt3phg
C1��
P2�
P2�
J1-2jK1b
Qhpal
Qp3pl
P3�ο
P2�ο
T��P2�
T��
Qhpal
P3��
P3��
T��
T1��
P3�ο
P3�οP3�ο
T��
P3��� P3�ο
T��
C1��Pt3bpg
C1��
P3�
P3�
P3�
P3��
Qp3pl
J1-2j
J1-2j
K1bQhpal
P3�
P3�J1-2j
P3��
TMS1
TMS2
HuobenghurenHao Nuoergong
Chaker Taolegai
Huhetaolegai Huduge
Yihe Erbeng
Haizi Adergen
Delewulan
Chagantaolegai
Yihetukemu Haoyaoer Aobao
Huhe Wenduoer
Hanggale Har ZhaoenjiBaga Erbeng
Pideritu
Kouergen Huduge
Chagansai
New Huduge
Hadan Nuoergong
ArgashunZhagaitu
Huhe Nuoergong
Harzhagai
Yihe Hairhan
Baga Hairhan
Figure legend
Geological drill Ductile shear zone
Seismic line Geological boundary
Ductile-Brittle deformation zone
Interpreted fault
Meso-Cenozoic Basin
Target Granite outcropping Zone
Fig. 14 Regional geological map of the seismic work area
754 Petroleum Science (2021) 18:742–757
1 3
shows low-speed. Below the top interface of the rock, the reflection events are weak and irregular (Fig. 15b), which could represent that the wave impedance differences within the rock are small.
Based on the regional geology findings (Fig. 14), there was one fault (named Yihe Erbeng fault) across the middle part of the TMS1 seismic line. It could be observed that the strong reflection wave group on the top of Fig. 15b obvi-ously disconnects beneath the stack 4599 m. In Fig. 15a, the high-speed portion nearly emerged from the ground at the corresponding position. With all the above evidence consid-ered, a southward-dipping reverse fault (labeled FP1) was interpreted.
Beyond that, the other three fault points (labeled FP2–FP4) could be interpreted in TMS1 profiles. There is a low-speed anomaly beneath the stack 6100–7100 m in Fig. 15a. Comparing this phenomenon with the reflection imaging profile (Fig. 15b), we could speculate that a north-ward-dipping fault (labeled FP2) and a southward-dipping fault (labeled FP3) exist. FP2 extended downward to FP3, and the FP2, FP3 faults commonly controlled the Quater-nary sedimentary sequence between them. In addition to this, there was a velocity reversal between FP2 and FP3 in Fig. 15a. Meanwhile, there are phenomena of distortions
or interruptions of reflection events at the corresponding position in Fig. 15b. These phenomena could indicate the presence of a small fracture labeled as FP4.
Based on the position of the faults, FP3 is speculated to control the southeastern boundary of the Haizi Adergen ductile shear zone (Fig. 14), and FP2 is speculated to con-trol the southern boundary of the shallow graben which is filled with Quaternary. The FP3 fault has been revealed as a normal fault in its upper part and a reverse fault in its lower part, which is considered to be related to multistage tectonization under a stress environment that had changed.
A few arcuate reflection events such as R1 and R2 are recognized in Fig. 15b, the phenomenon of which is con-sidered to be related to the nonuniform property inside the rock.
5.2 TMS2 seismic line
Figure 16 shows the interpretation results of TMS2 seismic line, based on the near-surface velocity profile (Fig. 16a) and the reflection profile (Fig. 16b).
What is interpreted at first is the southern unconform-ity (labeled AU3) of the target granite. We could see there is a clear color edge below the stack 4240 m in Fig. 16a.
Distance, m
Velo
city
, m/s
12801330138014301480
Elev
atio
n, m
250030003500400045005000
100 700 1300 1900 2500 3100 3700 4300 4900 5500 6100 6700 7300 7900 8500 9100 9700
Distance, m
(a)
(b)
NS T�� P3��� P3�οPt3bpgT�� Qhpl+eol P3�ο
0.20
0.40
0.80
0.60
1.00
0
TWT,
s
100 700 1300 1900 2500 3100 3700 4300 4900 5500 6100 6700 7300 7900 8500 9100 9700
R1 R2
NS T�� P3��� P3�οPt3bpgT�� Qhpl+eol P3�ο
Fig. 15 Seismic interpretation of the TMS1 line: near-surface velocity profile (a); reflection profile (b)
755Petroleum Science (2021) 18:742–757
1 3
Besides, there is a group of strong, steep reflection events in Fig. 16b. On south of AU3, the reflections are numerous. What’s more, the neighboring reflections generally exhibit parallel or subparallel, all of which reveal that the reflection events on the south side of AU3 derive from a sedimentary environment. But on the north of AU3, the number of reflec-tions decreases obviously, meanwhile most of them seem disordered and weak. With the regional geological findings considered, AU3 is interpreted as the southern boundary of the target granite, the south of which is the Mesozoic–Ceno-zoic basin.
Furthermore, it could be inferred that two unconformities (labeled AU1 and AU2) and two faults (labeled FP5 and FP6) exist within the Mesozoic–Cenozoic basin. As shown in Fig. 16b, the neighboring reflections are usually paral-lel in local regions. However, on both sides of AU1 and AU2, clear crossing angles between the overlying and the nether reflection events are demonstrated. This phenomenon is a typical characteristic of the angular unconformity on reflection imaging profiles. In addition, Fig. 16a exhibits rapid changes of velocity at the corresponding locations of AU1 and AU2. Based on the research of regional tectonics, AU3 reflects the unconformable contact between the lower-middle Jurassic Jijigou Formation (J1–2j) and the middle Per-mian quartz diorite (P2δο). AU2 represents the unconformity between the nether lower-middle Jurassic Jijigou Formation (J1–2j) and the overlying lower Cretaceous Bayingebi Forma-tion (K1b). AU1 represents the unconformity between the nether strata (K1b) and the overlying widespread proluvial
series of Pleistocene (Qp3pl). As the old strata (K1b) crops
out the ground, AU1 is discontinuous.On the north side of AU3, there is a group of high-energy
reflections with good lateral continuation on the top por-tion of Fig. 16b. It could be speculated that the reflections derive from the top of the granite. The fluctuation changes of this reflection group are in perfect accordance with the color edge of the high-speed portion in Fig. 16a. Meanwhile, there is good correspondence between the continuations of the top reflection with the changes of outcrops’ lithology as shown in Fig. 14.
There are some groups of arcuate reflection events (labeled R1–R3), which could be recognized in Fig. 16b. This phenomenon may be related to the nonuniform property within the rock mass.
Near the north end of the TMS2, based on Fig. 16a and b, three faults (labeled as FP7–FP9) are interpreted.
There is a distinct low-speed zone in Fig. 16a. As well as a distinct dislocation phenomenon of reflections exists beneath the stack 16,440 m in Fig. 16b. Meanwhile, the dis-tortions and interruptions phenomena of reflections could be observed. All of these phenomena reveal that one south-ward-dipping fault (FP8) exists beneath the TMS2 seismic line.
According to the reflection wave features and the veloc-ity reversal phenomenon next to FP8, we could infer that two small northward-dipping faults (labeled FP7 and FP9) exist, and they merge downward with FP8. As shown in the regional tectonic map (Fig. 14), the north of the TMS2
0
0.20
0.40
0.60
1.00
0.80
1.20
TWT,
s
R2R1
R3
200 800 1400 2000 2600 3200 3800 4400 5000 5600 6200 6800 7400 8000 8600 9200 9800 10400 11000 11600 12200 12800 13400 14000 14600 15200 15800 16400
Distance, m
AU1AU2
AU3FP5
FP6FP8
FP7 FP9
Velo
city
, m/s
250030003500400045005000
10701120117012201270132013701420
Elev
atio
n, m
200 800 1400 2000 2600 3200 3800 4400 5000 5600 6200 6800 7400 8000 8600 9200 9800 10400 11000 11600 12200 12800 13400 14000 14600 15200 15800 16400
Distance, m
NS P2�ο P3��Qp3pl T�� P3��J1-2jK1b T�� Qp3
pl P3��Qhpal
NS P2�ο P3��Qp3pl T�� P3��J1-2jK1b T�� Qp3
pl P3��Qhpal(a)
(b)
Fig. 16 Seismic interpretation of the TMS2 line: near-surface velocity profile (a); reflection profile (b)
756 Petroleum Science (2021) 18:742–757
1 3
seismic line crosses the southwest corner of the Cretaceous Yihetukemu basin which is covered by Quaternary. Thus, FP7 and FP8 faults just correspond to the two boundaries of the southwest corner of the basin.
The reason why FP8 shows normal property in its upper part and demonstrates reverse property in its lower part is considered to be related to multistage tectonization under different stress environments.
6 Conclusions
The present research adopts seismic exploration technology, which has a long history for serving the petroleum industry, to address the issue of siting a geological disposal repository for high-level radioactive nuclear waste in the nuclear indus-try. The techniques presented in the paper, e.g., cross-obsta-cle seismic geometry design, angle-domain near-surface scattered wave removal, and acoustic wave equation-based inversion method jointly utilizing both the and waveform of first arrival waves, have reference value for seismic explora-tion on complex near-surface areas in Western or Southern China. Based on the practice of seismic exploration on tar-get granite rock mass, the following conclusions could be developed:travel time
1. To address the problems include crossing obstacles seis-mic acquisition, harmful scattered wave removal, and complex near-surface area velocity inversion, several targeted techniques were adopted. It could be considered that the experience derived from the present research is beneficial and worthy of reference for future stud-ies. Some geotectonic phenomena, such as rock’s top interface and side boundaries, as well as local fractures within the rock, were revealed by the velocity and reflec-tion imaging profiles separately. The features on differ-ent kinds of profiles had good coincidence.
2. The AU3 on the TMS2 seismic line is a significant boundary between the target granite body and the Meso-zoic–Cenozoic basin. Combined with previous geologi-cal research, it could be inferred that AU3 separates the lower–middle Jurassic Jijigou Group (J1–2j) on its south side from the middle Permian quartz diorite (P2δο) on its north side.
3. In accordance with the “Safety guide for siting of geolog-ical disposal repository for nuclear waste (HAD401/06)” (China National Nuclear Safety Administration 2013), section 3.2.2, “The host rock must be adequately deep and extensive. The fractures that can offer a migration pathway for radioactive nuclide should be kept away in the site selection.” The results of the active source seismic exploration at Tamusu area indicate that: ① the
target rock is not thin or has been transported by geo-logical process from somewhere else, but a native and massive rock; ② a few small-scale local fractures whose space distribution and characteristics were revealed by the seismic profiles exist, and then keeping away from these fractures is needed to be taken into account.
Acknowledgements This research was supported by the National Key R&D Program of China (No. 2018YFC1503200), the Nuclear Waste Geological Disposal Project ([2013]727), the National Natural Sci-ence Foundation of China (Grant Nos. 41790463 and 41730425), the Spark Program of Earthquake Sciences of CEA (XH18063Y), and the Special Fund of GEC of CEA (YFGEC2017003, SFGEC2014006). We sincerely thank the two anonymous reviewers of this article, for their earnest and patience, and have suggested the explicit, detailed, constructive revisions for our manuscripts.
Open Access This article is licensed under a Creative Commons Attri-bution 4.0 International License, which permits use, sharing, adapta-tion, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article’s Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article’s Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http:// creat iveco mmons. org/ licen ses/ by/4. 0/.
References
Alberdi J, Barcala JM, Campos R, et al. Full-scale engineered barriers experiment for a deep geological repository for high-level radioac-tive waste in crystalline host rock (FEBEX project). Luxembourg: EUR; 2000.
Chen MC, Liu ZD, Lv QT, et al. Key techniques and method for deep seismic data acquisition in hard-rock environment. Chin J Geo-phys. 2015;58(12):4544–58. https:// doi. org/ 10. 6038/ cjg20 151217.
Chen Y, Wang BS, Yao HJ. Seismic airgun exploration of continental crust structures. Sci China Earth Sci. 2017;60:1739–51. https:// doi. org/ 10. 1007/ s11430- 016- 9096-6.
China National Nuclear Safety Administration. Safety guide for sit-ing of geological disposal repository for radioactive waste (HAD401/06). 2013. Accessed 1 Aug 2020.
Guo YH, Wang J, Jin YX. The general situation of geological disposal repository siting in the world and research progress in China. Earth Sci Front. 2001;8(2):327–32.
He YJ, Li W, Liu BJ, et al. An improved vector resolution noise removal approach. Oil Geophys Prospect. 2015;50(2):243–53.
Jiang WB, Zhang J. First-arrival travel time tomography with modified total-variation regularization. Geophys Prospect. 2016;65(5):1138–54. https:// doi. org/ 10. 1111/ 1365- 2478. 12477.
Li W, Chen Y, Wang FY, et al. Feasibility study of developing one new type of seismic source via carbon dioxide phase transition. Chin J Geophys. 2020;63(7):2605–16. https:// doi. org/ 10. 6038/ cjg20 20N03 35.
757Petroleum Science (2021) 18:742–757
1 3
Li W, Ji JF, Li Q, et al. Method for cross-obstacle 2D urban seis-mic geometry optimally designing. China Patent. 2019; ZL201710342906.5.
Li W, Liu YK, Liu BJ. Downhole microseismic signal recognition and extraction based on sparse distribution features. Chin J Geophys. 2016;59(10):3869–82. https:// doi. org/ 10. 6038/ cjg20 161030.
Liu YK. Noise reduction by vector median filtering. Geophysics. 2013;78(3):V79-87. https:// doi. org/ 10. 1190/ geo20 12- 0232.1.
Liu YK, He B, Zheng YC. Controlled-order multiple waveform inver-sion. Geophysics. 2020;85(3):R243-250. https:// doi. org/ 10. 1190/ GEO20 19- 0658.1.
Liu ZB, Zhang WJ. Geochemical characteristics and LA-ICP-MS zircon U–Pb dating of the middle permian quartz diorite in hanggale, alax right banner, inner mongolia. Acta Geol Sin. 2014;88(2):198–207.
Lu HY, Liu YK, Chang X. MSFM-based travel-times calculation in complex near-surface model. Chin J Geophys. 2013;56(9):3100–8.
Luo Y, Schuster GT. Wave-equation travel time inversion. Geophysics. 1991;56(5):645–53. https:// doi. org/ 10. 1190/1. 14430 81.
Su R, Cheng QF, Wang J, et al. Discussion on technical ideas of site selection of geological disposal repository for high-level radioac-tive waste in China. World Nucl Geosci. 2011;28(1):45–51.
Wang J, Chen WM, Su R, et al. Geological disposal of high-level radio-active waste and its key scientific issues. Chin J Rock Mech Eng. 2006;25(4):801–12. https:// doi. org/ 10. 1300/ J064v 28n01_ 10.
Wang TY, Gao JP, Wang JR, et al. Magmatism of collisional and post-orogenic period in Northern Alaxa Region in Inner Mongolia. Acta Geol Sin. 1998;72(2):126–37.
Xia JH. Estimation of near-surface shear-wave velocities and quality factors using multichannel analysis of surface-wave methods. J Appl Geophys. 2014;103:140–51. https:// doi. org/ 10. 1016/j. jappg eo. 2014. 01. 016.
Xu YX, Xia JH, Miller RD. Numerical investigation of implementation of air-earth boundary by acoustic-elastic boundary approach. Geo-physics. 2007;72(5):M147–53. https:// doi. org/ 10. 1190/1. 27538 31.
Yao G, Silva NVD, Kazei V, et al. Extraction of the tomography mode with nonstationary smoothing for full-waveform inversion. Geo-physics. 2019;84(4):R527–37. https:// doi. org/ 10. 1190/ geo20 18- 0586.1.
Yao G, Wu D, Debens HA. Adaptive finite difference for seismic wave-field modelling in acoustic media. Sci Rep. 2016;6(1):30302. https:// doi. org/ 10. 1038/ srep3 0302.
Yao G, Wu D. Reflection full waveform inversion. Sci China Earth Sci. 2017;60(10):1783–94. https:// doi. org/ 10. 1007/ s11430- 016- 9091-9.
Yuan YS, Jin ZJ, Zhou Y, et al. Burial depth interval of the shale brittle-ductile transition zone and its implications in shale gas exploration and production. Petrol Sci. 2017;14(4):637–47. https:// doi. org/ 10. 1007/ s12182- 017- 0189-7.