1980—2020年大湾区海岸线变迁及影响因素分析

doi:10.11978/2021116

Abstract

Abstract:

Coastline dynamic change is a common reflection of global change and human activities. Based on seven Landsat remote sensing images and Google Earth high-resolution images of the Guangdong-Hong Kong-Macao Greater Bay Area, Tokyo Bay and San Francisco Bay from 1980 to 2020, this paper used threshold segmentation combined with water index method and Sobel operator method to extract the coastline of each analysis period. In addition, this study also analyzed the changes of coastline in terms of length, spatial morphology, structure and utilization degree, and analyzed qualitatively and quantitatively the influencing factors with the help of geographic detectors. The results show that: (1) from 1980 to 2020, the intensity of annual average length change in the Tokyo Bay is the largest, which is 0.37%, and the coastline tends to be straight; (2) in the past 40 years, the depth of coastlines in all analyzed bay areas has remained stable, and the structures tend to be complex and the morphology tends to be dispersed. Among them, the difference of fractal dimension of coastlines in the Guangdong-Hong Kong-Macao Greater Bay Area is the smallest and the morphology is the most dispersed; (3) during the past 40 years, the natural coastline of each bay area decreased, while the length of port wharf coastline and other artificial coastline increased significantly, and the biological coastline of the Guangdong-Hong Kong-Macao Greater Bay Area fluctuated, and the coastline utilization index increased the most. The results show that temperature, wave height, tide, area and port throughput are the main factors that affect the coastline change, the interaction of any two factors is greater than the single factor.

Key words: bay area, coastline, coastline type, index of coastline length change, utilization index

CLC Number:

P737.1

SU Qianxin, LI Jing, LI Zhiqiang, WANG Aijun, LI Gaocong. Analyzing the coastline changes and its influencing factors in the Greater Bay Area from 1980 to 2020[J].Journal of Tropical Oceanography, 2022, 41(4): 116-125.

Figures/Tables 11

Tab. 1

Tab. 2

Fig. 1

Tab. 3

Fig. 2

Tab. 4

Tab. 5

Fig. 3

Fig. 4

Tab. 6

Tab. 7

References 21

[1]	陈金月, 2017. 基于GIS和RS的近40年珠江三角洲海岸线变迁及驱动因素研究[D]. 成都: 四川师范大学: 64-67.
	CHEN JINYUE, 2017. Changes and driving factors of coastline in the Pearl River Delta in recent 40 years based on GIS and RS[D]. Chengdu: Sichuan Normal University: 64-67. (in Chinese with English abstract)
[2]	刘旭拢, 邓孺孺, 许剑辉, 等, 2017. 近40年来珠江河口区海岸线时空变化特征及驱动力分析[J]. 地球信息科学学报, 19(10): 1336-1345. doi: 10.3724/SP.J.1047.2017.01336
	LIU XULONG, DENG RURU, XU JIANHUI, et al, 2017. Spatiotemporal evolution characteristics of coastlines and driving force analysis of the Pearl River Estuary in the past 40 years[J]. Journal of Geo-Information Science, 19(10): 1336-1345. (in Chinese with English abstract) doi: 10.3724/SP.J.1047.2017.01336
[3]	王劲峰, 徐成东, 2017. 地理探测器: 原理与展望[J]. 地理学报, 72(1): 116-134. doi: 10.11821/dlxb201701010
	WANG JINFENG, XU CHENGDONG, 2017. Geodetector: principle and prospective[J]. Acta Geographica Sinica, 72(1): 116-134. (in Chinese with English abstract) doi: 10.11821/dlxb201701010
[4]	肖锐, 2017. 近三十五年中国海岸线变化及其驱动力因素分析[D]. 上海: 华东师范大学: 22
	XIAO RUI, 2017. Analysis of change and driving force of the coastline of mainland in the nearly 35 years[D]. Shanghai: East China Normal University: 22 (in Chinese with English abstract)
[5]	邢婧, 孟丹, 白沁灵, 等, 2021. 近30年来我国河口海岸线变迁及驱动因素分析[J]. 首都师范大学学报(自然科学版), 42(5): 58-65.
	XING JING, MENG DAN, BAI QINLING, et al, 2021. Analysis of coastline changes of Chinese estuaries and its driving factors in the past 30 years[J]. Journal of Capital Normal University (Natural Science Edition), 42(5): 58-65. (in Chinese with English abstract)
[6]	赵玉灵, 2018. 粤港澳大湾区自然资源遥感调查与保护建议[J]. 国土资源遥感, 30(4): 139-147.
	ZHAO YULING, 2018. Remote sensing survey and proposal for protection of the natural resources in Guangdong-Hong Kong-Macao Greater Bay Area[J]. Remote Sensing for Land & Resources, 30(4): 139-147. (in Chinese with English abstract)
[7]	赵永玉, 阿里木江·卡斯木, 高鹏文, 等, 2021. 基于地理探测器的乌鲁木齐市城区扩展及影响因素分析[J]. 干旱区地理, 44(6): 1729-1739.
	ZHAO YONGYU, ALIMUJIA NG·KASIMU, GAO PENGWEN, et al, 2021. Quantitative analysis of urban expansion and response factors in Urumqi city based on random forest algorithm and geographical detector[J]. Arid Land Geography, 44(6): 1729-1739. (in Chinese with English abstract)
[8]	中华人民共和国国家质量监督检验检疫总局, 2004. GB/T 18190-2000海洋学术语海洋地质学[S]. 北京: 中国标准出版社.
	General Administration of Quality Supervision, Inspection and Quarantine of the People's Republic of China, 2004. GB/T 18190-2000 Oceanological terminology-Marine geology[S]. Beijing: Standards Press of China (in Chinese with English abstract)
[9]	ALESHEIKH A A, GHORBANALI A, NOURI N, 2007. Coastline change detection using remote sensing[J]. International Journal of Environmental Science & Technology, 4(1): 61-66.
[10]	BIDORN B, SOK K, BIDORN K, et al, 2021. An analysis of the factors responsible for the shoreline retreat of the Chao Phraya Delta (Thailand)[J]. Science of the Total Environment, 769: 145253. doi: 10.1016/j.scitotenv.2021.145253
[11]	BOAK E H, TURNER I L, 2005. Shoreline definition and detection: a review[J]. Journal of Coastal Research, 21(4): 688-703.
[12]	CAI FENG, SU XIANZE, LIU JIANHUI, et al, 2009. Coastal erosion in China under the condition of global climate change and measures for its prevention[J]. Progress in Natural Science, 19(4): 415-426. doi: 10.1016/j.pnsc.2008.05.034
[13]	CONOMOS T J, SMITH R E, GARTNER J W, 1985. Environmental setting of San Francisco Bay[J]. Hydrobiologia, 129(1): 1-12. doi: 10.1007/BF00048684
[14]	DALLAS K L, BARNARD P L, 2011. Anthropogenic influences on shoreline and nearshore evolution in the San Francisco Bay coastal system[J]. Estuarine, Coastal and Shelf Science, 92(1): 195-204. doi: 10.1016/j.ecss.2010.12.031
[15]	DING XIAOSONG, SHAN XIUJUAN, CHEN YUNLONG, et al, 2019. Dynamics of shoreline and land reclamation from 1985 to 2015 in the Bohai Sea, China[J]. Journal of Geographical Sciences, 29(12): 2031-2046. doi: 10.1007/s11442-019-1703-1
[16]	SU QIANXIN, LI ZHIQIANG, 2021a. Coastline types and their spatiotemporal variations in Guangdong, Hong Kong and Macao Bay Area (1979-2020)[J/DB/OL]. Digital Journal of Global Change Data Repository, https://doi.org/10.3974/geodb.2021.04.07.V1.
[17]	SU QIANXIN, LI ZHIQIANG, 2021b. Coastline types and their spatiotemporal variations in Tokyo Bay (1980-2020)[J/DB/OL]. Digital Journal of Global Change Data Repository, https://doi.org/10.3974/geodb.2021.04.08.V1.
[18]	SU QIANXIN, LI ZHIQIANG, 2021c. Coastline types and their spatiotemporal variations in San Francisco Bay (1980-2020)[J/DB/OL]. Digital Journal of Global Change Data Repository, https://doi.org/10.3974/geodb.2021.04.09.V1.
[19]	SU QIANXIN, LI ZHIQIANG, 2021d. Coastline datasets of the Guangdong-Hong Kong-Macao Bay Area, Tokyo Bay, and San Francisco Bay (1980-2020)[J]. Journal of Global Change Data & Discovery, 5(2): 148-155.
[20]	WU XUELING, LIU CHAOXIAN, WU GUOFENG, 2018. Spatial-temporal analysis and stability investigation of coastline changes: A case study in Shenzhen, China[J]. IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing, 11(1): 45-56. doi: 10.1109/JSTARS.2017.2755444
[21]	ZHANG YUXIN, HOU XIYONG, 2020. Characteristics of coastline changes on Southeast Asia Islands from 2000 to 2015[J]. Remote Sensing, 12(3): 519. doi: 10.3390/rs12030519

湾区	粤港澳大湾区	东京湾	旧金山湾
经度范围	111°21'—115°24'E	138°24'—140°30'E	121°24'—123°5'W
纬度范围	21°34'—24°23'N	34°30'—36°12'N	36°30'—38°30'N
所属国家	中国	日本	美国
地域组成	珠江三角洲9个城市(广州、深圳、珠海、佛山、中山、东莞、惠州、江门、肇庆)、香港和澳门	东京都、埼玉县、神奈川县和千叶县	分为旧金山、北湾、东湾、南湾和半岛5大区域, 旧金山、马林等9个县
潮汐特征	最大潮差<3m	最大潮差<2m	最大潮差<3m
水文特征	大河河口区域, 有西江、北江和东江流入, 总径流量大, 海水动力较弱	鹤见川、江户川等河流汇入, 袋状结构海湾, 水深浪小	平均水深6m, 位于混合型、潮汐振荡泻湖型河口汇合处, 环流强烈

内容	数据集描述
研究区		粤港澳大湾区、东京湾区、旧金山湾区
时间		1980年、1990年、2000年、2005年、2010年、2015年、2020年
数据来源		Landsat、Google Earth影像, 云覆盖量小于5%, 成像时间集中于10月至翌年3月
数据分辨率		<10m
岸线提取方法		修复归一化水体指数(Modified Normalized Difference Water Index, MNDWI)、灰度阈值法、数学形态法和Sobel算子法。对提取的岸线, 利用Google Earth进行目视解译修正
岸线类型		基岩岸线、淤泥质岸线、砂砾质岸线、生物岸线、农田养殖岸线、港口码头岸线和其他人工岸线

年份	粤港澳大湾区			东京湾			旧金山湾
年份	L/km	K_i/%	E	L/km	K_i/%	E	L/km	K_i/%	E
1980	2090.36	0.03	0.22	507.22	0.06	1.75	658.43	0.23	0.94
1990	2096.76	0.03	0.22	510.07	0.06	1.75	673.45	0.23	0.94
1990	2096.76	0.08	0.21	510.07	0.49	0.15	673.45	0.13	1.32
2000	2113.49	0.08	0.21	534.82	0.49	0.15	682.33	0.13	1.32
2000	2113.49	0.36	0.06	534.82	0.24	1.40	682.33	-0.06	0.47
2005	2151.49	0.36	0.06	541.13	0.24	1.40	680.38	-0.06	0.47
2005	2151.49	0.32	0.08	541.13	0.84	0.54	680.38	0.25	0.39
2010	2185.41	0.32	0.08	563.99	0.84	0.54	688.76	0.25	0.39
2010	2185.41	0.35	0.21	563.99	0.84	0.75	688.76	0.12	2.99
2015	2223.51	0.35	0.21	587.75	0.84	0.75	692.84	0.12	2.99
2015	2223.51	0.18	0.38	587.75	-0.24	9.94	692.84	-0.11	3.75
2020	2243.17	0.18	0.38	580.68	-0.24	9.94	689.11	-0.11	3.75
平均	3.83	0.22	0.20	1.84	0.37	2.42	0.77	0.09	1.64

年份	粤港澳大湾区			东京湾			旧金山湾
年份	D	R²	c	D	R²	c	D	R²	c
1980	1.0904	0.9997	0.1549	1.1257	0.9989	0.3422	1.1005	0.9999	0.3228
1990	1.0912	0.9997	0.1545	1.1245	0.9990	0.3403	1.1042	0.9999	0.3156
2000	1.0940	0.9997	0.1535	1.1295	0.9991	0.3248	1.1058	1	0.3115
2005	1.0982	0.9997	0.1517	1.1302	0.9991	0.3211	1.1038	1	0.3121
2010	1.1010	0.9997	0.1509	1.1379	0.9989	0.3082	1.1057	1	0.3085
2015	1.1061	0.9997	0.1486	1.1404	0.9990	0.2959	1.1052	1	0.3067
2020	1.0911	0.9969	0.1475	1.1327	0.9983	0.2995	1.1045	1	0.3083

因变量	自变量	代码	分级
自然岸线长度	平均气温	X₁	3
	潮差	X₂	3
	波高	X₃	3
	年径流量	X₄	3
	年输沙量	X₅	3
岸线利用程度指数	面积	X₆	3
	GDP	X₇	5
	人口	X₈	5
	港口吞吐量	X₉	3
	第三产业比重	X₁₀	4

Analyzing the coastline changes and its influencing factors in the Greater Bay Area from 1980 to 2020

RichHTML

PDF (PC)

Like

Knowledge

Abstract

Cite this article

share this article

Figures/Tables 11

References 21

Related Articles 2

Metrics

Comments

Recommended 0

[1]	WU Tongren, LIU Pei, YU Jitao, WEN Tingting. Comparative study on different tide level correction methods in remote sensing extraction of coastline under balanced profile model^* [J]. Journal of Tropical Oceanography, 2023, 42(6): 52-62.
[2]	SONG Xingyu, LIN Yajun, ZHANG Liangkui, XIANG Chenhui, HUANG Yadong, ZHENG Chuanyang. Distribution characteristics and influencing factors of meso- and micro-zooplankton communities in the offshore waters of the Guangdong-Hong Kong-Macao Greater Bay Area^* [J]. Journal of Tropical Oceanography, 2023, 42(3): 136-148.

自然因素						社会经济因素
	X₁	X₂	X₃	X₄	X₅		X₆	X₇	X₈	X₉	X₁₀
X₁	0.9942					X₆	0.9828
X₂	0.9945	0.9942				X₇	0.9985	0.4716
X₃	0.9945	0.9945	0.9942			X₈	0.9969	0.9986	0.5517
X₄	0.9954	0.9954	0.9954	0.5276		X₉	0.9920	0.9823	0.9969	0.8102
X₅	0.9975	0.9975	0.9975	0.7807	0.3870	X₁₀	0.9963	0.6370	0.9985	0.8679	0.2096
p	0	0	0	0.0091	0.0407	p	0	0.2230	0.0371	0	0.7153