Data from: Continent-side paleo-rift structure in the western East Sea (Sea of Japan) and linkage between Moho uplift and mountain range formation
Data files
Oct 27, 2025 version files 6.65 GB
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data.zip
114.02 MB
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event_waveform.tar.xz
6.53 GB
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README.md
5.12 KB
Abstract
The continental-side paleo-rift structure in the east-central Korean Peninsula is investigated using joint inversion of receiver functions and surface-wave dispersions based on dense seismic networks. The joint inversion analysis provides precise constraints on crustal thickness and Vp/Vs ratios, and high-resolution 3-D shear-wave velocity model. The model reveals distinct lateral and vertical variations associated with tectonic evolution during continental rifting. Inland regions exhibit typical continental crustal thickness (~33 km) and moderate Vp/Vs ratios (1.60-1.75). On the other hand, coastal regions present shallower Moho depths (~24 km), high Vp/Vs ratios (1.8-1.9), and laterally deformed crustal structures to reflect continental-to-oceanic transition. Low-velocity anomalies at shallow depths (≤ 3km) and strong velocity contrasts in the middle and lower crust correlate with sedimentary basins and major faults, indicating tectonic boundaries that influence regional seismicity. Coastal high-velocity anomalies at depth (~30 km) suggest localized mantle uplift related to rifting. Moho uplift near the coast, together with the asymmetric uplift of the Taebaek Mountain Range, indicates depth-dependent lithospheric stretching and isostatic rebound during rifting. These observations are consistent with geological evidence of East Sea (Sea of Japan) opening, highlighting the offshore rift center and its influence on onshore crustal structure. The results provide new constraints on rift-related processes, including lithospheric thinning, mantle upwelling, and asymmetric rift-flank uplift, demonstrating the role of paleo-rift structures in controlling present-day seismicity.
This dataset is concerned with the paper "Continent-side paleo-rift structure in the western East Sea (Sea of Japan) and linkage between Moho uplift and mountain range formation" submitted to Journal of Geophysical Research: Solid Earth by Jeongin Lee, Tae-Kyung Hong, Junhyung Lee, Seongjun Park and Byeongwoo Kim in 2025.
The earthquake waveforms, receiver functions, group velocity dispersion and shear-wave velocity models analyzed in the article are provided.
Also We provide data files to produce three figures in the paper: Figures 10, 11, and 12.
The dataset includes .dat and .sac files.
The .txt files are in ASCII format and can be opened with common text editors (e.g., vi, WordPad).
The .sac files are in sac format and can be processed using seismic data processing tools such as SAC.
If access to SAC software is limited, the Python library ObsPy can be used to read and process .sac files.
Please see the detailed information for the files below.
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1. station.txt
This file includes information of seismic stations analyzed in this study.
The file is given in the ASCII format with four columns: network, station, latitude (N, deg), and longitude (E, deg).
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2. event.txt
This file includes source information of global earthquakes analyzed in this study.
The file is given in the ASCII format with seven columns: event ID, date (yyyy-mm-dd), time (HH:MM:SS), latitude (N, deg), longitude (E, deg), depth (km), and moment magnitude.
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3. event_waveform.tar.xz
This tar file includes the data files for earthquake waveforms used for receiver function analysis.
All files are seperated by event directory that is named by ev_[event ID].
The waveforms are given in miniseed files that are named by [station][channel][commponent].sac
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4. receiver_funnction.zip
This zip file includes the data files for receiver functions analyzed in the study.
The folders are named by following format:
[station][channel]
The data files are named by following format:
R.[station][channel][commponent][year][julian day][hour][min].[Gaussian bandwidth constants]
All data files are given in the sac format.
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5. fig4_group_velocity_dispersion.txt
This file includes the data of Rayleigh and Love wave group velocity dispersion analyzed in this study.
The data files are named by following format:
The file is given in the ASCII format with three columns: wave type (Love, Rayleigh), period (sec), and group wave velocity (km/s).
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6. fig7_moho_vpvs.txt
This file includes the date of crustal thickness and Vp/Vs ratio analyzed in this study.
The data files are named by following format:
The file is given in the ASCII format with five columns: station, latitude (N, deg), longitude (E, deg), crustal thickness (km) and Vp/Vs ratio.
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7. fig10
This folder includes the data files to produce Figure 10 in the paper.
All data files are given in the ASCII format.
The data files are named by following format:
fig10[subfigure label (a-l)].dat
The data is given in three columns: latitude (N, deg), longitude (E, deg), and shear-wave velocity (km/s).
Note: Subfigure labels (a through l) represent the shear-wave velocity (Vs) model at specific depths:
a:0.5 km
b:2.5 km
c:6.5 km
d:10.5 km
e:12.5 km
f:14.5 km
g:20.5 km
h:24.5 km
i:28.5 km
j:30.5 km
k:33.5 km
l:37.5 km
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8. fig11
This folder includes the data files to produce Figure 11 in the paper.
All data files are given in the ASCII format.
The data files are named by following format:
fig11[subfigure label (b-i)].dat
The data is given in three columns
(fig11 b-h): distance (km), depth (km), and shear-wave velocity (km/s)
(fig11 i): distance (km), depth (km), and differential shear-wave velocity (km/s).
Note: The subfigure labels (b through i) represent cross-sectional profiles cut along different locations. Specifically:
b through h: Profiles A through G
i: One of the profiles showing differential shear-wave velocity
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9. fig12
This folder includes the data files to produce Figure 12 in the paper.
All data files are given in the ASCII format.
The data files are named by following format:
fig12[subfigure label (a-l)].dat
The data is given in three columns: latitude (N, deg), longitude (E, deg), and differential shear-wave velocity (km/s).
Note: Subfigure labels (a through l) represent the differential shear-wave velocity (Vs) model at specific depths:
a:0.5 km
b:2.5 km
c:6.5 km
d:10.5 km
e:12.5 km
f:14.5 km
g:20.5 km
h:24.5 km
i:28.5 km
j:30.5 km
k:33.5 km
l:37.5 km