南海典型珊瑚礁生态系统健康评价方法研究

doi:10.11978/2020070

Abstract

Abstract:

In this paper, we discuss the principle of ecosystem complexity, and propose a method for evaluating the health of typical coral reef ecosystems in the South China Sea-"Organization and System Function Evaluation." The evaluation framework of this method includes four modules: the structure and function of coral reef ecosystems, the relationship between coral reef ecosystems and other marine ecosystems, the relationship with human social ecosystems, and the development constraints of coral reef ecosystems. The evaluation index system is divided into six levels, including target level, criterion level, factor level, and element level, totaling 67 indicators. We systematically put forward the process of coral reef ecosystem health evaluation, which improves the standardization and timeliness of coral reef health evaluation. The organizing power and system function evaluation method was used to evaluate the health of the coral reef ecosystem of the Paracel Islands from 2011 to 2018. The results show that the health index has fallen by 2.3%-2.4% annually since 2011. Except for a slight rebound in 2012 and 2015, the health index has shown a downward trend in the rest of the years. The overall evaluation is that the coral reef ecosystem of the Paracel Islands is sub-healthy. This result is consistent with the results of field investigations and questionnaire surveys on residents' lives around the Qilianyu Islands. We find that the development of fisheries in 2006-2008, the flooding of starfish in 2012, and the construction of islands and reefs in 2014-2015 had great impacts on the coral reef ecosystem. The fishery output dropped by 50%-80% in 10 years, which is also consistent with the evaluation results. It verifies the science and feasibility of the evaluation method from another angle.

Key words: South China Sea, coral reef, ecosystem, health assessment

CLC Number:

P735.12

WU Yingying, LEI Xinming, HUANG Hui, ZHANG Yuyang, DING Dewen. Study on the health assessment method of typical coral reef ecosystem in the South China Sea[J].Journal of Tropical Oceanography, 2021, 40(4): 84-97.

Figures/Tables 7

Tab. 1

Tab. 2

Tab. 3

Coral reef ecosystem health evaluation system"

目标层	次目标层	准则层	次准则层	因素层	一级要素层	二级要素层	三级要素层	四级要素层
生态系统健康指数	1. 生态系统内平衡水平	1.1生态系统结构均衡性: 共生关系	1.1.1 物种间共生关系和功能	1.1.1.1 组织黏性	食物链完整度	消费者存量: 杂食性植食性鱼类、底栖动物	种类	鱼类种类
							种类	底栖种类
							密度	鱼类密度
							密度	底栖动物密度
							丰富度	鱼类丰富度
								浮游植物细胞丰度
								浮游动物丰度
							生物量	鱼类平均体长
								底栖动物生物量
								浮游动物生物量
						生产者存量: 藻类
					天敌海星密度
				1.1.1.2 关键物种生物量	造礁珊瑚种类	活珊瑚物种数
					造礁珊瑚种类	造礁石珊瑚物种数
					珊瑚覆盖率	活珊瑚平均覆盖率
						软珊瑚平均覆盖率
						石珊瑚平均覆盖率
			1.1.2 种群组成动态平衡水平	1.1.2.1 物种多样性指数	鱼类多样性(个体数I)
					底栖动物物种多样性指数
					浮游植物物种多样性指数
					浮游动物物种多样性指数
				1.1.2.2 物种均匀度指数	鱼类均匀度(Evennes) (个体数I)
					底栖动物均匀度指数
					浮游植物均匀度指数
					浮游动物均匀度指数
		1.2 生态系统功能: 互惠关系	1.2.1 物质能量循环-鱼类密度与石珊瑚覆盖率比值
目标层	次目标层	准则层	次准则层	因素层	一级要素层	二级要素层	三级要素层	四级要素层
			1.2.2 系统弹性, 繁衍和恢复力	1.2.2.1 病害类型、发病率
				1.2.2.2 幼体补充量
				1.2.2.3 死亡率
	2. 生态系统间平衡水平	2.1 地理环境-栖息地破坏水平	2.1.1 人为开发	2.1.1.1 森林覆盖率
			2.1.1 人为开发	2.1.1.2 自然保护区面积占比
			2.1.2 自然灾害(飓风、降水、干旱、高温、严寒)	2.1.2.1 自然灾害强度	海浪年均波高
				2.1.2.1 自然灾害强度	相对年平均潮位
				2.1.2.2 自然灾害频率	灾害性巨浪天数(有效波高大于4m的海浪)
				2.1.2.2 自然灾害频率	沿岸最大增水大于40cm的风暴潮次数
		2.2 水环境变化	2.2.1 生产力相关水文条件	2.2.1.1 海水pH
				2.2.1.2 海表温度-温室效应
				2.2.1.3 海水透明度
				2.2.1.4 悬浮物
			2.2.2 水质条件	2.2.2.1 重金属
				2.2.2.2 富营养		站点盐度
						站点溶解氧(DO)
						站点氨氮
						站点叶绿素
				2.2.2.3 站点海水油类含量		站点海水油类含量
		2.3 人类社会环境发展水平	2.3.1 人类生活环境	2.3.1.1 污水排放量	渔业废水	渔业养殖污染-海水养殖产量
					农业化肥污水量	农田水利有效灌溉面积
					农业化肥污水量	周边农业化肥用量
					全省废水排放量	农业化肥污水量
					工业污染-南海区油气平台废水	工业污染-南海区油气平台废水
					固体垃圾倾倒入海	海洋倾倒量
					固体垃圾倾倒入海	工业固体废物
				2.3.1.2 污水水质	河流入海口水质	南渡江-河流入海污染物COD
目标层	次目标层	准则层	次准则层	因素层	一级要素层	二级要素层	三级要素层	四级要素层
						南渡江-磷酸盐入海
						南渡江-氨氮入海
						南渡江石油河流入海
						南渡江重金属河流入海
					省内陆源入海排污口水质	溶解氧
						化学需氧量(COD)
						氨氮
						活性磷酸盐
						重金属
			2.3.2 人口素质	2.3.2.1 全省常驻人口密度
				2.3.2.2 教育水平-文盲率
				2.3.2.3 农村居民人均可支配收入
			2.3.3 环保水平	2.3.3.1 城镇污水处理率
				2.3.3.2 农村生活污水处理率
				2.3.3.3 工业固体综合利用率
				2.3.3.4 生活垃圾无害化处理率
			2.3.4 经济发展	2.3.4.1 渔业捕捞发展	海水捕捞产品占海水产品比重
				2.3.4.1 渔业捕捞发展	海水捕捞产值占海水产品产值比重
				2.3.4.2 海水养殖业发展	海水养殖产品占海水产品比重
				2.3.4.2 海水养殖业发展	海水养殖产值占海水产品产值比重
				2.3.4.3 货物吞吐量
				2.3.4.4 旅游业发展	旅游过夜人数
				2.3.4.4 旅游业发展	旅游总收入
				2.3.4.5 工业制造业发展	机制纸及纸板(外购原纸加工除外)
					原油加工量
					商品混凝土
					粗钢

Tab. 3

Fig. 1

Fig. 2

Fig. 3

Fig. 4

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级别	赋分范围	健康状况
1	80~100	理想状况
2	60~80	健康
3	35~60	亚健康
4	0~35	不健康

评价模块	类别	小类	指标
模块一: 珊瑚礁生态系统结构及功能	1.1系统共生	1.1.1物种间共生关系和功能	组织粘性	食物链完整度	消费者存量
					生产者存量
					分解者存量
				天敌密度
			珊瑚关键种存量	覆盖率及病害
		1.1.2种群组成动态平衡水平	物种多样性、均匀度
	1.2系统互惠	食物网物质能量循环
	1.3系统弹性	珊瑚繁殖恢复力及遗传抗逆性
模块二: 珊瑚礁生态系统与其他海洋生态系统间关系	2.1陆地	2.1.1栖息地	城市建设与野生林地保护
		2.1.2空间外力	自然灾害频率和强度
		2.1.3地理分布	纬度及深度
	2.2水域	2.2.1季节性洋流
		2.2.2初级生产力相关水文条件
		2.2.3水质富营养化
模块三: 珊瑚礁生态系统与人类社会生态系统间关系	3.1人类社会系统压力	3.1.1人口	生存资源及就业需求
	3.1人类社会系统压力	3.1.2环境	治污排污、垃圾填埋
	3.2人类社会系统弹性	3.2.1城市建设	沿海城市生态建设水平与远景规划
		3.2.2经济	渔业、运输业、制造业、旅游业发展
		3.2.3政治	维护领土领海, 国家权力博弈
模块四: 珊瑚礁生态系统发展制约因素	4.1空间因素	4.1.1人文因素	陆源污染物
			人口增长
			经济及制造业发展
			国家政策及国际形势
			生态功能型城市建设与规划
			海洋经济发展
		4.1.2水域因素	洋流及板块运动
			温室效应
			富营养化及石油泄漏
		4.1.3气候因素	自然灾害
	4.2时间因素	引发生态系统健康状况整体变化的时间点, 即缓慢侵蚀性因素

Study on the health assessment method of typical coral reef ecosystem in the South China Sea

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