Landslide Data in Riviere Frorse Basin Triggered by Haiti Earthquake on 12 January 2010
Lv, T. T.1* Liu, C.2 Zhao, J. L.3 Dai, L. J.4 Wang, J. N.1 Gu, X. F.1
1. Institute of Geographic Sciences and Natural Resources Research, Chinese Academy of Sciences, Beijing 100101, China;
2. Institute of Remote Sensing and Digital Earth, Chinese Academy of Sciences, Beijing 100101, China;
3. Henan University, Kaifeng 475004, China;
4. Texas State University, San Marcos 78666, USA
Abstract: As secondary effects, a series of landslides were triggered by the earthquake that occurred in Haiti on January 12, 2010. From the epicenter to Port au Prince, triggered landslides mainly distributed in upper reaches of Riviere Momance, the Riviere Frorse basin, the north slope of Morne Saint-Laurent and so on. Among these regions, the amount of landslides in Riviere Frorse basin was the most. It was also the primary region to influence the densely populated areas in the downstream area of the Riviere Frorse due to potential debris flow. By using the Word View-2 of pre-earthquake, GeoEye-1 of post-earthquake, as well as the Google Earth images, the Landslide data in Riviere Frorse Basin triggered by Haiti earthquake on 12 January 2010 (HaitiEQ_LS_2010data for short) was developed .The data was archived in .shp data format with the compressed data size of 650 KB.
Keywords: Haiti; Earthquake; 2010; Riviere Frorse Basin; Landslide
1 Introduction
The Republic of Haiti locates in the Caribbean island of Hispaniola. On January 12, 2010, it was reported that a magnitude 7 earthquake struck the country at 21:53:10 (UTC). The centroid of this earthquake was 18.457°N, 72.533°W[1]. Because it was very near to Port au Prince which is a densely populated area, thousands of persons were dead or injured. On January 18, the National Aeronautics and Space Administration (NASA) distributed a potential landslide map based on the EO-1 images. From January 18 to January 19, post-earthquake images of Haiti were published by American GeoEye company and American Digital Global company. Almost during the same time the images of Haiti regions were updated by Google Earth. On January 19, the Institute of Geographic Sciences and Natural Resources Research (IGSNRR), Chinese Academy of Sciences (CAS), the World Resources Research, College of Resources Science & Technology, Beijing Normal University and the Institute of Remote sensing and Digital Earth (RADI), CAS interpreted the distribution locations and types of landslide in the key places in Haiti based on the above images.
Riviere Frorse Basin locates between the epicenter of this earthquake and Port au Prince, which is one of the densest region of triggered landslides. Figure 1 shows the geographic location map of Riviere Frorse Basin.
Figure 1 Geographic location map of Riviere Frorse Basin
2 Metadata of Dataset
The descriptions of the HaitiEQ_LS_2010data[2] are recorded. These information include the dataset full name, dataset short name, authors, geographical region of the dataset content, year of the dataset, number of the dataset tiles, dataset spatial and temporal resolution, dataset format and size, data publisher, and data sharing policy (Table 1).
3 Methods
Visual interpretation of remote sensing images has become an important method to identify landslides. In this paper landslides were identified from Word View-2 images of pre-
earthquake and GeoEye-1 images of post-earthquake images. Table 2 shows the technical specification of used remote sensing data.
The basic procedure of the dataset development is shown in Figure 2. After analyzing the remote sensing images of study area, relatively lighter tone of the slide area than the
adjoining stable area, vegetation differences, detached large blocks of rocks have been used as indicators for landslide interpretation[4–5].The results were cross-checked between
different work groups.
After analyzing characteristics of different landslides, two categories were divided: new added
Table 1 Summary of the HaitiEQ_LS_2010data metadata
|
Items
|
Description
|
|
Dataset full name
|
Haiti Earthquake (2010) Landslides Dataset in Riviere_Frorse Basin
|
|
Dataset short name
|
HaitiEQ_LS_2010data
|
|
Authors
|
Lv, T. T. R-8978-2016, Institute of Remote sensing and Digital Earth, Chinese Academy of Sciences, lvtt@radi.ac.cn
Liu, C. L-3684-2016, Institute of Geographic Sciences and Natural Resources Research, Chinese Academy of Sciences, lchuang@radi.ac.cn
Zhao, J. L. A-4856-2017, Henan University, China, aling0123@163.com
Dai, L. J. A-4836-2017, Texas State University, USA, 40081944@qq.com
Wang, J. N. E-2431-2017, Institute of Remote sensing and Digital Earth, Chinese Academy of Sciences, jwang@radi.ac.cn
Gu, X. F. L-7328-2016, Institute of Remote sensing and Digital Earth, Chinese Academy of Sciences, guxf@radi.ac.cn
|
|
Geographical region
|
18.4°N-18.5°N, 72.32°W-72.48°W
|
|
Time
|
2010
|
|
Data format
|
.shp, .zip
|
|
Data size
|
650 KB in compressed file
|
|
Data files
|
The dataset consists of two data files. They are:
1.HTI_Landslide_Point.zip,this is the ARC/GIS .shp compressed file of the landslide points triggered by 2010 earthquake in Riviere Frorse Basin
2.HTI_Landslide_Polygon.zip,this is the ARC/GIS .shp compressed file of the landslide polygons triggered by 2010 earthquake in Riviere Frorse Basin
|
|
Foundation(s)
|
Chinese Academy of Sciences (CXIOG-D04-03)
|
|
Data publisher
|
Global Change Research Data Publishing & Repository, http://www.geodoi.ac.cn
|
|
Address
|
No. 11A, Datun Road, Chaoyang District, Beijing 100101, China
|
|
Data sharing policy
|
Data from the Global Change Research Data Publishing & Repository includes metadata, datasets (data products), and publications (in this case, in the Journal of Global Change Data & Discovery). Data sharing policy includes: (1) Data are openly available and can be free downloaded via the Internet; (2) End users are encouraged to use Data subject to citation; (3) Users, who are by definition also value-added service providers, are welcome to redistribute Data subject to written permission from the GCdataPR Editorial Office and the issuance of a Data redistribution license; and (4) If Data are used to compile new datasets, the ‘ten per cent principal’ should be followed such that Data records utilized should not surpass 10% of the new dataset contents, while sources should be clearly noted in suitable places in the new dataset[3]
|
and old landslides. Those landslides were further divided into four types as listed in table 3, namely new landslides, extended landslides based on the old landslides, not obviously changed old landslides and recovered landslides.
Table 2 Technical specification of used remote sensing data
|
Satellite
|
Country
|
Compny
|
Sensor
|
Spatial
resolution
|
Revisit cycle
|
Acquisition time
|
Website
|
|
GeoEye-1
|
USA
|
GeoEye, Inc. Nasdaq
|
Panchromatic
Multispectral
|
0.41 m(Nadir)
1.65 m(Nadir)
|
3days
|
January 13, 2010
January 16, 2010
|
http://www.google.com/relief/haitiearthquake/geoeye.html
|
|
World View-2
|
USA
|
DigitalGlobe
|
Panchromatic
Multispectral
|
0.61 m(Nadir)
2.44 m(Nadir)
|
1-6 days
|
December 13, 2009
|
http://dgl.us.neolane.net/res/dgl/survey/CES_H.jsp
|
Table 3 Definition and corresponding description of landslide types
|
Code
|
Before event image
|
After event image
|
Vector landslides
|
Type
|
|
A
|
|
|
|
New landslides
|
|
B
|
|
|
|
Extended landslides based on the old landslides
|
|
C
|
|
|
|
Not obviously changed old landslides
|
|
N
|
|
|
|
Not completely Recovered landslides
|
|
Figure 2 Procedure of the dataset development
Figure 3 Spatial distribution of landslides
in Riviere Frorse Basin
|
4 Dataset Compositions
Figure 3 shows the spatial distribution of landslides in Riviere Frorse Basin. Figure 3 shows the spatial distribution map of landslides of four types in Riviere Frorse River Basin. A total of 165 landslides were interpreted. There were 98 new landslides, 35 landslides expanded on the original basis, 24 landslides which were changed not significantly after the earthquake and 8 not completely recovered landslides. Table 4, table 5, table 6 and table7 are statistics of the location and area of different types of landslide. From these tables we can see that the area of new landslides (type A) is 54,132 m2 which account for 59.6% of the area of total landslides. The area of 35 landslides (type B) expanded from the 163,819 m2 to 40,315 m2.The area of not obviously changed old landslides (type C) after earthquake is about 186,962 m2 and the area of the recovered landslides (type C) is about 5,618 m2.
Figure 4 Spatial distribution map of landslides of four types in Riviere Frorse River Basin
Table 4 Spatial distribution and area statistics of new added landslides
|
Code
|
Longitude
|
Latitude
|
Area(m2)
|
Code
|
Longitude
|
Latitude
|
Area (m2)
|
|
A-1
|
‒72.410,023
|
18.517,005
|
1,227
|
A-85
|
‒72.414,524
|
18.511,089
|
1,462
|
|
A-2
|
‒72.409,911
|
18.516,559
|
459
|
A-87
|
‒72.414,700
|
18.502,667
|
2,302
|
|
A-3
|
‒72.411,403
|
18.515,828
|
384
|
A-88
|
‒72.416,270
|
18.499,076
|
256
|
|
A-9
|
‒72.410,848
|
18.502,558
|
94
|
A-89
|
‒72.417,292
|
18.510,066
|
71
|
|
A-12
|
‒72.413,726
|
18.500,876
|
894
|
A-90
|
‒72.418,292
|
18.508,785
|
152
|
|
A-13
|
‒72.412,961
|
18.500,460
|
61
|
A-91
|
‒72.418,510
|
18.508,511
|
426
|
|
A-14
|
‒72.413,147
|
18.500,278
|
74
|
A-92
|
‒72.418,864
|
18.507,587
|
117
|
|
A-15
|
‒72.414,106
|
18.500,331
|
21
|
A-93
|
‒72.419,413
|
18.507,676
|
113
|
|
A-17
|
‒72.414,525
|
18.500,234
|
82
|
A-94
|
‒72.418,287
|
18.510,309
|
191
|
|
A-18
|
‒72.414,898
|
18.499,817
|
70
|
A-95
|
‒72.417,960
|
18.510,391
|
42
|
|
A-19
|
‒72.411,442
|
18.500,714
|
239
|
A-96
|
‒72.399,644
|
18.496,660
|
5,601
|
|
A-20
|
‒72.410,864
|
18.500,128
|
419
|
A-97
|
‒72.411,566
|
18.511,410
|
83
|
|
A-21
|
‒72.410,406
|
18.500,055
|
539
|
A-98
|
‒72.413,005
|
18.511,654
|
61
|
|
A-22
|
‒72.410,050
|
18.500,153
|
289
|
A-99
|
‒72.413,289
|
18.511,703
|
104
|
|
A-23
|
‒72.411,364
|
18.499,670
|
1,505
|
A-100
|
‒72.413,797
|
18.511,520
|
43
|
|
A-24
|
‒72.411,915
|
18.499,461
|
479
|
A-103
|
‒72.415,171
|
18.511,227
|
55
|
|
A-26
|
‒72.414,733
|
18.496,194
|
209
|
A-104
|
‒72.415,425
|
18.510,932
|
47
|
|
A-27
|
‒72.414,811
|
18.495,840
|
71
|
A-105
|
‒72.425,117
|
18.505,668
|
210
|
(To be continued on the next page)
(Continued)
|
Code
|
Longitude
|
Latitude
|
Area(m2)
|
Code
|
Longitude
|
Latitude
|
Area(m2)
|
|
A-28
|
‒72.413,499
|
18.494,566
|
1,820
|
A-106
|
‒72.424,035
|
18.505,656
|
88
|
|
A-29
|
‒72.414,576
|
18.491,550
|
93
|
A-107
|
‒72.424,693
|
18.505,803
|
60
|
|
A-30
|
‒72.415,183
|
18.489,767
|
28
|
A-108
|
‒72.425,966
|
18.505,561
|
69
|
|
A-31
|
‒72.415,326
|
18.489,536
|
64
|
A-111
|
‒72.419,899
|
18.517,228
|
272
|
|
A-32
|
‒72.411,163
|
18.487,830
|
128
|
A-112
|
‒72.424,073
|
18.515,308
|
3,579
|
|
A-33
|
‒72.408,867
|
18.488,362
|
332
|
A-113
|
‒72.423,267
|
18.51,568
|
1,339
|
|
A-34
|
‒72.408,381
|
18.488,465
|
261
|
A-114
|
‒72.422,789
|
18.51,591
|
358
|
|
A-35
|
‒72.407,310
|
18.487,899
|
412
|
A-115
|
‒72.425,038
|
18.514,647
|
150
|
|
A-36
|
‒72.407,650
|
18.487,549
|
36
|
A-116
|
‒72.390,341
|
18.484,392
|
509
|
|
A-38
|
‒72.406,816
|
18.486,959
|
223
|
A-120
|
‒72.362,893
|
18.485,649
|
3,981
|
|
A-39
|
‒72.405,553
|
18.483,970
|
426
|
A-121
|
‒72.362,535
|
18.484,869
|
2,083
|
|
A-40
|
‒72.405,431
|
18.482,665
|
96
|
A-129
|
‒72.363,419
|
18.473,738
|
215
|
|
A-41
|
‒72.405,217
|
18.482,574
|
632
|
A-131
|
‒72.369,663
|
18.468,884
|
2,210
|
|
A-42
|
‒72.405,237
|
18.482,239
|
195
|
A-134
|
‒72.344,852
|
18.495,708
|
601
|
|
A-45
|
‒72.404,720
|
18.482,578
|
203
|
A-135
|
‒72.345,413
|
18.495,726
|
488
|
|
A-46
|
‒72.402,901
|
18.482,051
|
120
|
A-136
|
‒72.343,778
|
18.495,654
|
808
|
|
A-47
|
‒72.403,029
|
18.481,368
|
28
|
A-138
|
‒72.335,524
|
18.473,274
|
1,346
|
|
A-48
|
‒72.403,038
|
18.481,019
|
82
|
A-148
|
‒72.413,437
|
18.504,888
|
98
|
|
A-49
|
‒72.392,923
|
18.482,494
|
26
|
A-151
|
‒72.376,395
|
18.477,268
|
1,216
|
|
A-52
|
‒72.381,927
|
18.484,673
|
169
|
A-152
|
‒72.375,885
|
18.477,568
|
403
|
|
A-56
|
‒72.365,625
|
18.490,172
|
1,671
|
A-153
|
‒72.376,545
|
18.479,031
|
163
|
|
A-66
|
‒72.308,770
|
18.468511
|
959
|
A-154
|
‒72.376,855
|
18.478,965
|
118
|
|
A-68
|
‒72.296,273
|
18.465,,213
|
63
|
A-155
|
‒72.412,875
|
18.504,097
|
359
|
|
A-71
|
‒72.295,276
|
18.463,979
|
848
|
A-156
|
‒72.412,059
|
18.502,420
|
1,093
|
|
A-72
|
‒72.294,840
|
18.463,523
|
513
|
A-163
|
‒72.328,117
|
18.478,238
|
781
|
|
A-75
|
‒72.292,914
|
18.462,871
|
657
|
A-112
|
‒72.328,635
|
18.478,328
|
669
|
|
A-77
|
‒72.292,023
|
18.461,747
|
108
|
A-164
|
‒72.326,217
|
18.477,004
|
262
|
|
A-78
|
‒72.291,989
|
18.461,484
|
188
|
A-171
|
‒72.292,781
|
18.464,173
|
40
|
|
A-81
|
‒72.294,250
|
18.463,956
|
34
|
A-172
|
‒72.292,382
|
18.461,997
|
1,497
|
|
A-82
|
‒72.293,820
|
18.464,076
|
76
|
A-173
|
‒72.292,405
|
18.461,719
|
170
|
|
A-83
|
‒72.293,723
|
18.464,032
|
92
|
A-174
|
‒72.292,185
|
18.461,316
|
71
|
|
Total
|
54,132 m2
|
Table 5 Spatial distribution and area statistics of extended landslides
|
Code
|
Longitude
|
Latitude
|
Area pre-earthquake (m2)
|
Area post-earthquake (m2)
|
Changed
area (m2)
|
|
B-4
|
‒72.411,870
|
18.509,008
|
29,716
|
33,158
|
3,442
|
|
B-5
|
‒72.411,839
|
18.505,923
|
1,252
|
1,321
|
69
|
|
B-6
|
‒72.412,271
|
18.505,496
|
1,229
|
1,601
|
372
|
|
B-7
|
‒72.412,581
|
18.504,923
|
1,844
|
2,446
|
602
|
|
B-8
|
‒72.411,330
|
18.503,267
|
5,897
|
6,777
|
880
|
(To be continued on the next page)
(Continued)
|
Code
|
Longitude
|
Latitude
|
Area pre-earthquake (m2)
|
Area post-earthquake (m2)
|
Changed
area (m2)
|
|
B-11
|
‒72.413,063
|
18.501,734
|
3,288
|
3,846
|
558
|
|
B-16
|
‒72.414,192
|
18.500,304
|
32
|
29
|
‒4
|
|
B-25
|
‒72.412,801
|
18.498,849
|
7,029
|
13,184
|
6,155
|
|
B-37
|
‒72.407,522
|
18.487,241
|
61
|
401
|
340
|
|
B-43
|
‒72.404,595
|
18.481,929
|
248
|
210
|
‒38
|
|
B-50
|
‒72.387,408
|
18.484,879
|
9,260
|
11,584
|
2,323
|
|
B-51
|
‒72.384,476
|
18.484,730
|
899
|
1,518
|
618
|
|
B-55
|
‒72.366,027
|
18.490,210
|
1,190
|
1,778
|
588
|
|
B-59
|
‒72.338,008
|
18.485,133
|
1,939
|
3,748
|
1,808
|
|
B-60
|
‒72.336,677
|
18.484,604
|
20,223
|
30,957
|
10,734
|
|
B-62
|
‒72.337,896
|
18.478,077
|
1,728
|
1,945
|
217
|
|
B-86
|
‒72.412,421
|
18.511,778
|
291
|
410
|
119
|
|
B-101
|
‒72.414,969
|
18.511,205
|
399
|
320
|
‒79
|
|
B-102
|
‒72.414,301
|
18.511,263
|
85
|
86
|
2
|
|
B-117
|
‒72.400,669
|
18.482,798
|
450
|
637
|
186
|
|
B-118
|
‒72.360,785
|
18.483,721
|
13,052
|
13,656
|
604
|
|
B-119
|
‒72.361,793
|
18.485,346
|
3,865
|
5,707
|
1,841
|
|
B-122
|
‒72.362,305
|
18.480,712
|
21,882
|
22,525
|
643
|
|
B-123
|
‒72.361,465
|
18.479,159
|
8,656
|
10,623
|
1,967
|
|
B-124
|
‒72.359,610
|
18.479,021
|
10,872
|
11,743
|
872
|
|
B-125
|
‒72.362,750
|
18.475,673
|
634
|
1,680
|
1,046
|
|
B-137
|
‒72.341,020
|
18.496,429
|
6,517
|
7,171
|
654
|
|
B-159
|
‒72.358,730
|
18.490,508
|
464
|
476
|
11
|
|
B-160
|
‒72.359,841
|
18.490,348
|
214
|
527
|
314
|
|
B-161
|
‒72.337,603
|
18.478,393
|
538
|
524
|
‒14
|
|
B-165
|
‒72.323,940
|
18.475,698
|
838
|
1,004
|
166
|
|
B-166
|
‒72.318,504
|
18.473,757
|
75
|
829
|
755
|
|
B-176
|
‒72.419,742
|
18.522,877
|
5,662
|
6,154
|
492
|
|
B-177
|
‒72.418,623
|
18.522,813
|
3,208
|
4,528
|
1,320
|
|
B-178
|
‒72.417,332
|
18.523,535
|
282
|
1,035
|
752
|
|
Total
|
163,819
|
204,134
|
40,315
|
| |
|
|
|
|
|
|
5 Discussion and Conclusion
By using remote sensing images with high spatial resolution before and after the earthquake in the Riviere Frorse basin, four types of landslides were identified. There were 98 new landslides (the area is 54,132 m2), 35 landslides was expanded on the original basis (the original area was 163,819 m2 and added area was 40,315 m2). In addition, there were still 24 landslides which were changed not significantly after the earthquake and 8 not recovered old landslides by vegetation. The landslides above mainly distributed above 25 degree slope. The ARC/GIS datasets of landslides and related analysis report were submit to UN-SPIDER and UNPAN by the GAID e-SDDC team (Scientific Data Sharing in Developing Countries Community Activities, Global Alliance for Information and Development, UNDESA) on February 2, 2012 and we received good feedback from them.
|
Code
|
Longitude
|
Latitude
|
Area (m2)
|
|
N-44
|
‒72.404,253
|
18.482,336
|
440
|
|
N-53
|
‒72.383,776
|
18.483,057
|
707
|
|
N-54
|
‒72.383,440
|
18.482,848
|
1,013
|
|
N-126
|
‒72.362,449
|
18.476,512
|
350
|
|
N-168
|
‒72.306,310
|
18.468,512
|
491
|
|
N-169
|
‒72.306,530
|
18.468,694
|
791
|
|
N-170
|
‒72.307,095
|
18.468,773
|
1,677
|
|
N-175
|
‒72.363,948
|
18.472,975
|
149
|
|
Total
|
|
|
5,618
|
Table 7 Spatial distribution and area statistics of recovered landslides
Author Contributions
Liu, C. , Wang, J. N. and Gu X. F. were responsible for the overall project design. Lv, T. T., Zhao, J. L. and DAI, L. J. finished the both data processing and landslides extraction. Lv, T. T. wrote this paper. Liu, C. reviewed both the dataset and the data paper, Liu, C. submitted the data and paper to UN-SPIDER and UNPAN.
References
[1] USGS Magnitude 7.0―Haiti Region [OL]. http://earthquake.usgs.gov/earthquakes/recenteqsww/Quakes/ us2010rja6.php.
[2] Lv, T. T., Liu, C., Zhao, J. L., et al. Haiti Earthquake (2010) Landslides Dataset in Riviere_Frorse Basin [DB/OL]. Global Change Research Data Publishing & Repository, 2014. DOI: 10.3974/geodb. 2014.02.10.V1.
[3] GCdataPR Editorial Office. GCdataPR Data Sharing Policy [OL]. DOI:10.3974/dp.policy.2014.05 (Updated 2017).
[4] Temesgen, B., Mohammed, M. U. Natural hazard assessment using GIS and remote sensing methods, with particular reference to the landslides in the Wondogenet Area Ethiopia [J]. Physics and Chemistry of the Earth, 2001, 26(9): 665-675.
[5] Zhao, J. L., Liu, C., Lv, T. T., et al. Identification of landslide spatial distribution and their types along the Riviere Frorse Drainage Basin triggered by the earthquake in Haiti on 12 January 2010 [J]. Disaster Advances, 2012, 5(1): 5-13.