山东半岛潟湖湿地的发育过程及其环境退化研究——以朝阳港潟湖为例
|
摘要
潟湖是由沿岸沙嘴、沙坝或滨外坝等围拦海湾、河口或其它浅海水域而形成的半封闭或封闭性地貌体,是重要的海岸湿地类型之一。潟湖湿地具有极高的生态、资源、环境、科研、休闲旅游价值,是高生产力、高生物多样性的生态系统。和国外的大型滨外坝——潟湖湿地不同,我国的潟湖湿地一般面积较小,相对而言环境演变较迅速,因此潟湖湿地又是进行湿地形成演变和湿地退化研究的绝佳场所。
山东半岛濒临渤海和黄海,海岸线长而曲折,潟湖湿地资源丰富,共发育有潟湖湿地近60个。根据潟湖湿地的水文特征,将其划分为咸水潟湖、半咸水潟湖、淡水潟湖和干出潟湖四种类型。经计算,自虎头崖到岚山头的港湾海岸岸线全长2021.4km,潟湖岸线总长580.4km,占岸线长度的28.7%,远高于全球平均值。由于自然演变和人为盲目开发利用,目前潟湖湿地生态环境恶化趋势日益严重,湿地资源遭受到极大的破坏并濒于消亡。潟湖湿地退化所引发的一系列生态环境问题已经成为制约区域经济发展的一大障碍。研究潟湖湿地的发育过程,探讨环境退化原因,分析潟湖湿地退化下的生态环境效应,并提出可持续发展策略,对于保护和合理开发利用潟湖湿地资源具有重要意义。
朝阳港潟湖位于山东半岛东北角,是山东半岛诸多潟湖中所遭受到的人为干扰活动最强的潟湖湿地之一,潟湖近期演变比较剧烈,湿地退化较严重。本文以其为重点研究对象,以2002年现场调查为基础,结合历史资料,分析了朝阳港潟湖湿地的生态环境状况;对所取岩芯做了沉积物粒度分析、孢粉分析、微体古生物分析,同时结合测年数据,研究了朝阳港潟湖在垂向上所指示的沉积环境信息,探讨了朝阳港潟湖的形成和演变规律;根据景观生态学原理,研究了近几十年来朝阳港潟湖湿地的景观格局变化,并分析了人为作用在潟湖湿地景观变化中所起的作用;探讨了导致潟湖湿地退化的主要原因及其影响机制,综合评价了潟湖湿地的退化程度;分析了朝阳港潟湖湿地退化下的生态环境效应,提出了湿地退化的防治对策和可持续发展建议。
朝阳港渴湖湾口朝北,由一条狭窄的水道与外海相通,面积约1300hm2。朝阳
港渴湖水体较浅,平均水深在lm以内,渴湖中部是宽广平缓的潮滩,组成物质主
要是细砂,向潮滩边缘泥质成分渐多,在渴湖边缘发育有沼泽。四周陆地地貌为剥
蚀低丘和准平原。受水分、盐度和土壤特性的影响,湿地植被群落类型较少,渴湖
湿地生境较为简单,湿地自我调节功能和抗外力干扰能力十分弱,生态系统极不稳
定,显示出高脆弱性。
经数据统计,山东半岛的大多数渴湖是在6000一400Oa B.R间开始发育的。根据
钻孔资料揭示,在5000一4000a B.P.左右,朝阳港附近地区气候温暖、略湿,抱粉组
合以栋属一松属一篙属一水龙骨科一禾本科为主,并含有少量淡水介形虫,沉积环
境为半咸水渴湖沼泽环境;在4000一1 500 a B.P.年间,气候温暖,此时植被以栋属一
松属一篙属一黎科一禾本科一刺球藻为主,软体动物为菲律宾蛤仔、异白樱蛤、古
氏滩栖螺和多形滩栖螺,沉积环境为经常受海水淹没的潮间带环境;1500 aB,P.之后,
气温略为下降,植被以松属一栋属一篙属一黎科一水龙骨科为主,沉积环境为渴湖
沼泽相沉积环境,和前阶段相比海面相对稳定或略微下降。
朝阳港渴湖湿地的演变过程可以划分为四个阶段:(1)古海岸线形成阶段。(2)
水下沙坝发育阶段。(3)青矶岛连岛坝发育阶段。(4)现代渴湖湿地发育阶段。在
20世纪中期青矶岛基本与陆地相连。青矶岛连岛坝形成后,坝后渴湖被分割为朝阳
港渴湖和小海渴湖两个渴湖,朝阳港渴湖口门处次生沙嘴不断发育,渴湖口门进一
步封闭。
景观生态学是湿地研究的热点领域之一。在景观生态学研究中,景观格局与变
化过程是主要研究内容。根据朝阳港渴湖湿地的开发与利用状况,选取1954年、1971
年、1983年三期1:5万地形图和2002年现场调查资料,利用GIS技术对朝阳港渴
湖湿地的景观格局变化进行了分析。在朝阳港渴湖湿地中,自然景观主要为渴湖浅
滩、沼泽湿地和河口湿地;人工景观主要是养殖池、盐田和农用地。从1954年到
2002年,朝阳港渴湖的自然湿地逐渐被改造为人工湿地,人工湿地面积增加了532
腼2,湿地景观格局发生了很大的变化,景观多样性和均匀度增加,优势度下降。从
1954年到2002年,朝阳港渴湖总体斑块密度从0.0174个爪mZ增加到0.0346个小mZ;
廊道密度从0.6954m小mZ增加到22.0564m小mZ,景观破碎化程度呈递增趋势,显示
出人为干扰程度的不断增强态势。
当前山东半岛渴湖湿地正面临着面积萎缩和生态环境恶化等严重问题。在导致
渴湖湿地退化的诸多因素中,围垦、污染、城市建设、渴湖淤积、海岸侵蚀和海面
上升等是主要因素。这些环境因素对渴湖湿地的作用方式和影响程度是不同的,而
渴湖湿地在这些影响因素作用下的退化程度也不尽相同。根据综合评价指数法等方
法,对山东半岛的6个渴湖湿地的退化程度进行了定量评价。评价结果显示,朝阳
港渴湖是环境退化比较严重的渴湖湿地之一。导致渴湖湿地退化的最主要、最直接
的原因是人为因素,而自然因素对湿地的作用往往因人为因素的?
Lagoon is one of the most important types of coastal wetlands, which is separated from open sea by sand spits, sandbars or barriers. It is also an important type of ecosystem with great values in terms of natural resource, tourism, environment and scientific research. Because of their smaller area and shallower water, lagoonal wetlands along Chinese coast are more sensitive and fragile to external environment loads than those large barrier bar-lagoon wetlands (such as those in North America), and they are favorite places for studying wetland formation, evolution and degradation.
There are up to 60 lagoonal wetlands along Shandong Peninsula, they can be classificated into four types according to hydrologic characteristics: seawater lagoon, brackish lagoon, freshwater lagoon and drying lagoon. The total length of the lagoonal coastline in Shandong Peninsula is 580.4km, up to 28.7% of the coastline from Hutouya to Lanshantou. Lagoonal wetland possess very abundant resources and instinct ecosystems, which are under the threat of degradation by natural forces, such as global changes, and human's inappropriate development activities. The degradation and loss of lagoonal wetlands have resulted in eco-environment problem and become an obstacle to regional economic progress. The study on lagoonal wetland's formation, evolution, causes of wetland environmental degradation and their effect on eco-environment are very significant for lagoonal wetland resources protection.
Located at the northeastern Shandong Peninsula, Chaoyanggang lagoon is one of those suffering from human forcing, and seriously experiencing degradation and loss of wetlands along Shandong Peninsula coast. A multi-principle field investigation was conducted in 2002, the collected data and historical information were used to study the
ecological environment of Chaoyanggang lagoon. Comprehensive core sample analyses were carried out back to the laboratory, including grain size analysis with Mastersizer2000 Laser grain size analyzer, spore-pollen and microfossils analysis of 27 samples, 14C dating of 2 samples. This information was used to study the sedimentary environment, formation and evolution of the lagoon. With principles of Landscape Ecology, the landscape pattern changes in the latest several decades were studied, as well as the human's activities impact on landscape changes. The origin of this lagoonal wetland degradation was studied, and the level of the wetland degradation and loss was assessed. Based on the degradation and loss of the wetland, eco-environmental effects were analyzed and countermeasures were suggested for wetland protection and regional sustainable development.
Chaoyanggang, surrounded by low hills, is a closed shallow water lagoon, connected to the open sea only through a narrow inlet. It is about 1300 hm2 in area and an average water depth less than 1 .0m. The center of the lagoon is wide shallow tidal flat, comprised by fine sands, and mud component increase outward, and the edge is salt marsh, mainly dominated with phragmites. Limited by hydrology, salinity and soil character, the wetland habitat structure is very simple, and only few vegetation communities can be found. Self-adjusting capability of this lagoon is weak and the ecosystem is very instable, vulnerable to outer disturbances.
Most lagoonal wetlands along Shandong Peninsula were formed since 6000-4000 aB.R. According to core information, at 5000~4000a B.P., this area was warm and humid, sporopollen assemblages were dominated by Quercus -Pinus- Artemisia-Polypodiaceae - Gramineae, freshwater Ostracoda was also found in the core, indicating a brackish lagoon-marsh coastal sedimentary environment. Between 4000 and 1500 aB.R, the sporopollen assemblages were dominated by Quercus - Pinus - Artemisia -Chenopodiaceae - Gramineae - Hystrichosphera, Hystrichosphera, Mullusca, such as Ruditapes philippinarum, Macoma incongrua, Batillaria cumingi and Batillaria
multiformis were found too, indicating a sedimentary environment submerged by tidal water frequently, and the clima
山东半岛濒临渤海和黄海,海岸线长而曲折,潟湖湿地资源丰富,共发育有潟湖湿地近60个。根据潟湖湿地的水文特征,将其划分为咸水潟湖、半咸水潟湖、淡水潟湖和干出潟湖四种类型。经计算,自虎头崖到岚山头的港湾海岸岸线全长2021.4km,潟湖岸线总长580.4km,占岸线长度的28.7%,远高于全球平均值。由于自然演变和人为盲目开发利用,目前潟湖湿地生态环境恶化趋势日益严重,湿地资源遭受到极大的破坏并濒于消亡。潟湖湿地退化所引发的一系列生态环境问题已经成为制约区域经济发展的一大障碍。研究潟湖湿地的发育过程,探讨环境退化原因,分析潟湖湿地退化下的生态环境效应,并提出可持续发展策略,对于保护和合理开发利用潟湖湿地资源具有重要意义。
朝阳港潟湖位于山东半岛东北角,是山东半岛诸多潟湖中所遭受到的人为干扰活动最强的潟湖湿地之一,潟湖近期演变比较剧烈,湿地退化较严重。本文以其为重点研究对象,以2002年现场调查为基础,结合历史资料,分析了朝阳港潟湖湿地的生态环境状况;对所取岩芯做了沉积物粒度分析、孢粉分析、微体古生物分析,同时结合测年数据,研究了朝阳港潟湖在垂向上所指示的沉积环境信息,探讨了朝阳港潟湖的形成和演变规律;根据景观生态学原理,研究了近几十年来朝阳港潟湖湿地的景观格局变化,并分析了人为作用在潟湖湿地景观变化中所起的作用;探讨了导致潟湖湿地退化的主要原因及其影响机制,综合评价了潟湖湿地的退化程度;分析了朝阳港潟湖湿地退化下的生态环境效应,提出了湿地退化的防治对策和可持续发展建议。
朝阳港渴湖湾口朝北,由一条狭窄的水道与外海相通,面积约1300hm2。朝阳
港渴湖水体较浅,平均水深在lm以内,渴湖中部是宽广平缓的潮滩,组成物质主
要是细砂,向潮滩边缘泥质成分渐多,在渴湖边缘发育有沼泽。四周陆地地貌为剥
蚀低丘和准平原。受水分、盐度和土壤特性的影响,湿地植被群落类型较少,渴湖
湿地生境较为简单,湿地自我调节功能和抗外力干扰能力十分弱,生态系统极不稳
定,显示出高脆弱性。
经数据统计,山东半岛的大多数渴湖是在6000一400Oa B.R间开始发育的。根据
钻孔资料揭示,在5000一4000a B.P.左右,朝阳港附近地区气候温暖、略湿,抱粉组
合以栋属一松属一篙属一水龙骨科一禾本科为主,并含有少量淡水介形虫,沉积环
境为半咸水渴湖沼泽环境;在4000一1 500 a B.P.年间,气候温暖,此时植被以栋属一
松属一篙属一黎科一禾本科一刺球藻为主,软体动物为菲律宾蛤仔、异白樱蛤、古
氏滩栖螺和多形滩栖螺,沉积环境为经常受海水淹没的潮间带环境;1500 aB,P.之后,
气温略为下降,植被以松属一栋属一篙属一黎科一水龙骨科为主,沉积环境为渴湖
沼泽相沉积环境,和前阶段相比海面相对稳定或略微下降。
朝阳港渴湖湿地的演变过程可以划分为四个阶段:(1)古海岸线形成阶段。(2)
水下沙坝发育阶段。(3)青矶岛连岛坝发育阶段。(4)现代渴湖湿地发育阶段。在
20世纪中期青矶岛基本与陆地相连。青矶岛连岛坝形成后,坝后渴湖被分割为朝阳
港渴湖和小海渴湖两个渴湖,朝阳港渴湖口门处次生沙嘴不断发育,渴湖口门进一
步封闭。
景观生态学是湿地研究的热点领域之一。在景观生态学研究中,景观格局与变
化过程是主要研究内容。根据朝阳港渴湖湿地的开发与利用状况,选取1954年、1971
年、1983年三期1:5万地形图和2002年现场调查资料,利用GIS技术对朝阳港渴
湖湿地的景观格局变化进行了分析。在朝阳港渴湖湿地中,自然景观主要为渴湖浅
滩、沼泽湿地和河口湿地;人工景观主要是养殖池、盐田和农用地。从1954年到
2002年,朝阳港渴湖的自然湿地逐渐被改造为人工湿地,人工湿地面积增加了532
腼2,湿地景观格局发生了很大的变化,景观多样性和均匀度增加,优势度下降。从
1954年到2002年,朝阳港渴湖总体斑块密度从0.0174个爪mZ增加到0.0346个小mZ;
廊道密度从0.6954m小mZ增加到22.0564m小mZ,景观破碎化程度呈递增趋势,显示
出人为干扰程度的不断增强态势。
当前山东半岛渴湖湿地正面临着面积萎缩和生态环境恶化等严重问题。在导致
渴湖湿地退化的诸多因素中,围垦、污染、城市建设、渴湖淤积、海岸侵蚀和海面
上升等是主要因素。这些环境因素对渴湖湿地的作用方式和影响程度是不同的,而
渴湖湿地在这些影响因素作用下的退化程度也不尽相同。根据综合评价指数法等方
法,对山东半岛的6个渴湖湿地的退化程度进行了定量评价。评价结果显示,朝阳
港渴湖是环境退化比较严重的渴湖湿地之一。导致渴湖湿地退化的最主要、最直接
的原因是人为因素,而自然因素对湿地的作用往往因人为因素的?
Lagoon is one of the most important types of coastal wetlands, which is separated from open sea by sand spits, sandbars or barriers. It is also an important type of ecosystem with great values in terms of natural resource, tourism, environment and scientific research. Because of their smaller area and shallower water, lagoonal wetlands along Chinese coast are more sensitive and fragile to external environment loads than those large barrier bar-lagoon wetlands (such as those in North America), and they are favorite places for studying wetland formation, evolution and degradation.
There are up to 60 lagoonal wetlands along Shandong Peninsula, they can be classificated into four types according to hydrologic characteristics: seawater lagoon, brackish lagoon, freshwater lagoon and drying lagoon. The total length of the lagoonal coastline in Shandong Peninsula is 580.4km, up to 28.7% of the coastline from Hutouya to Lanshantou. Lagoonal wetland possess very abundant resources and instinct ecosystems, which are under the threat of degradation by natural forces, such as global changes, and human's inappropriate development activities. The degradation and loss of lagoonal wetlands have resulted in eco-environment problem and become an obstacle to regional economic progress. The study on lagoonal wetland's formation, evolution, causes of wetland environmental degradation and their effect on eco-environment are very significant for lagoonal wetland resources protection.
Located at the northeastern Shandong Peninsula, Chaoyanggang lagoon is one of those suffering from human forcing, and seriously experiencing degradation and loss of wetlands along Shandong Peninsula coast. A multi-principle field investigation was conducted in 2002, the collected data and historical information were used to study the
ecological environment of Chaoyanggang lagoon. Comprehensive core sample analyses were carried out back to the laboratory, including grain size analysis with Mastersizer2000 Laser grain size analyzer, spore-pollen and microfossils analysis of 27 samples, 14C dating of 2 samples. This information was used to study the sedimentary environment, formation and evolution of the lagoon. With principles of Landscape Ecology, the landscape pattern changes in the latest several decades were studied, as well as the human's activities impact on landscape changes. The origin of this lagoonal wetland degradation was studied, and the level of the wetland degradation and loss was assessed. Based on the degradation and loss of the wetland, eco-environmental effects were analyzed and countermeasures were suggested for wetland protection and regional sustainable development.
Chaoyanggang, surrounded by low hills, is a closed shallow water lagoon, connected to the open sea only through a narrow inlet. It is about 1300 hm2 in area and an average water depth less than 1 .0m. The center of the lagoon is wide shallow tidal flat, comprised by fine sands, and mud component increase outward, and the edge is salt marsh, mainly dominated with phragmites. Limited by hydrology, salinity and soil character, the wetland habitat structure is very simple, and only few vegetation communities can be found. Self-adjusting capability of this lagoon is weak and the ecosystem is very instable, vulnerable to outer disturbances.
Most lagoonal wetlands along Shandong Peninsula were formed since 6000-4000 aB.R. According to core information, at 5000~4000a B.P., this area was warm and humid, sporopollen assemblages were dominated by Quercus -Pinus- Artemisia-Polypodiaceae - Gramineae, freshwater Ostracoda was also found in the core, indicating a brackish lagoon-marsh coastal sedimentary environment. Between 4000 and 1500 aB.R, the sporopollen assemblages were dominated by Quercus - Pinus - Artemisia -Chenopodiaceae - Gramineae - Hystrichosphera, Hystrichosphera, Mullusca, such as Ruditapes philippinarum, Macoma incongrua, Batillaria cumingi and Batillaria
multiformis were found too, indicating a sedimentary environment submerged by tidal water frequently, and the clima
引文
[1] Arrhennius O. Species and area. Journal o Ecology, 1921, 9: 95~99.
[2] Baker W L. A review of models of landscape change. Landscape Ecology, 1989,2:111~133.
[3] Barnes R. S. K.. Coastal lagoons. London: Cambridge University Press, 1980.
[4] Booth R K, Rich F Jetal. Evolution of a freshwater barrier-island marsh in coastal Georgia, USA, Wetlands, 1999, 19(3):570~577.
[5] Bruun P. Sea-level rise as a cause of shore erosion. J Waterway Div, 1962,88~177.
[6] Costanza R, d'Arge R, de Groot R, et al. The value of the world's ecosystem services and natural capital. Nature, 1997, 387: 253~260.
[7] Costanza R, Sklar F H, White M L, Day J W. A dynamic spatial simulation model of land loss and marsh succession in coastal Louisiana. In: Wetland Modeling(Edited by Mitsch W J, Straskraba M, Jorgensen S W. ) Elsebier, Amsterdam. 1988.
[8] Cowell P. G., Thorn B. G.. Morphodynamics of coastal evolution. Carter R W G, Woodroffe C D. Coastal evolution: Later Quaternary shoreline morphodynamics. Cambridge Press,1994,33~86.
[9] Cromwell, J. E. Barrier coastal distribution: A world-wide survey. In "Barrier Island", 1975, 407~408.
[10] Daily, G. C. Natures Services: Societal Dependence on Natural Ecosystems. Washington D C: Island Press, 1997.
[11] David A. Pinder and Michael E. Witherick. PORT INDUSTRIALIZATION, urbanization and Wetland Loss. WETLANDS: A THREANED LANDSCAPE Edited by Michael Williams, 2000.
[12] DAVIS, R. A., 1994. Barriers of the Florida Gulf Peninsula. In: R. A. DAVIS(ed. ), Geology of Holocene Barrier Island Systems. Springer-Verlag, New York, 167~206.
[13] Datys Jr, J. Rybczyk, F. Scarton, A. Rismondo, D. Are and G. Cecconi. Soil Accretionary Dynamics, Sea-Level Rise and the Survival of Wetlands in Venice Lagoon: A Field and Modelling Approach. Estuarine, Coastal and Shelf Science 1999(49): 607~628.
[14] Edward B. et al. Economic valuation of wetlands. Ramsar Convention Bureau, 1997.
[15] Fairbanks R. G. A 17000-year glacio-eustatic sea level record: influence of glacial melting rate on the Younger Dryas event and deep-ocean circulation, Nature, 1989,342, 637~642.
[16] Fitzgerald, D., and Van Heteren, S. Classification of Paraglacial Barrier Systems: Coastal ew England, USA. Sedimentology, 1999,46:1083~1108.
[17] Forman R T T. Landscape mosaics. The ecology of landscape and regions, Cambridge University Press, 1995,85~101.
[18] Franzer L. G. Can earth afford to lose the wetlands in the battle against the increasing greenhouse effect? International Peat Society, Proceedings of 9th International Peat Congress, Uppsala, 1992:1~18.
[19] Gerhard Masselink and Guithermelessa. Barrier stratigraphy on the Macrotidal central Queesland costaline. Journal of coastal research, 1995,11(2):25~30.
[20] Gorman M L. Island Ecology. London: Chapman & Hall, 1979.
[21] H. Suzanne Bolton,T. Magoon. Coastal Wetlands. New York: American Society of Civil Engineers, 1991.
[22] Hopkinson C S,Wetzel R L,Day J W. Simulation models of coastal wetland and estuarine systems:
relization of goals. In:Wetland Modelling(Edited by Mitsch W J, Straskraba M, Jorgensen S W. ) Elsebier, Amsterdam. 1988.
[23] Hulme, M., Mitchell, J,. Ingram, W., et al. Climate change scenarios for global impact studies. Global Environmental Change9, 1999, S3~S19.
[24] IPCC, Coastal Zone Management Subgroup. Global climate change and the rising challenge of the Sea, IPCC. Tech. Report, 1992, P7.
[25] Johmon,J. W. Scale effect in hydraulic models involving wave motion. Trans. AM. Geophys. Union: 1949(30):517~525.
[26] John G. Ehrenfeld. Evaluating wetlands within an urban context. Ecological Engineering, 2000(15):253~265.
[27] John R. Wetland assessment and survey manual. Wetland International,1996.
[28] Kjerfve,B. and Magill,K. E.. Geographic and hydrodynamic characteristic of shallow coastal lagoons. Marine Geology, 1989,88:189~199.
[29] Kolasa J, Pickett S T A, ed. Ecological Heterogeneity. New York: Springer-Verlag, 1991.
[30] Komar A D著,邱建立译.海滩过程与沉积作用.海洋出版社,1985.
[31] Leatherman S P. Barrier island evolution in response to sea rise-discussion[J], Jour Sed Pet, 1983, 53: 1026~1031.
[32] Leonteev O K. Tapes and formation of lagoons in present coastal zones. Marine Geology, USSR Acedemic press, 1960.
[33] Lippman T C and Holman R A. The spatial and temporal variability of sand bar morphology. Journal Geophysical Resarch, 1990. 95:11575~11590.
[34] Maltby E. and Immirzi C. P. The global status of peatlands and their role in Carbon cycling. Published by Friends of the Earth Trust Limited. 1992.
[35] Matthew L. Stutz and Orrin H. Pilkey. Global Distribution and Morphology of Deltaic Barrier Island Systems. Journal of Coastal research. 2002, 36:694~707.
[36] McAuliffe J R. Landscape evolution, soil formation, and ecological patterns and processes in Sonoran Desert bajadas. Ecological Monographs, 1994, 64:111~148.
[37] Mitsch. W. J. and Gosselink J. G.. Wetlands. New York: Van Nostrand Reinhold Compnay 1986.
[38] Mitsch. W. J. and Gosselink J. G. Wetlands. New York: John Wiley & Sons, Inc. 2000.
[39] Naveh Z. Some remarks on recent developments in landscape ecology as a transdiseiplinary ecological and geographical science. Landscape Ecology, 1991,5: 65~73.
[40] Nicholls M M and Boon J D. Sediment transport processes in coastal lagoons. In: Kjerfve B. (editor), Coastal Lagoon prcesses. Elsevier, Amsterdam, 1994. 157~219.
[41] O'Brien, M. P.. Equillibrium flow areas of tidal inlents on sandy coasts. Proceedings of Tenth Coference on Coastal Engineerings,1966: 676~706.
[42] Paine R T, Levin S A. Intertidal landscapes: disturbance and the dynamics of pattern, Ecological Monographs, 1981, 51: 145~178.
[43] Pickeet S T A, Wu J, Cadenasso M L. Patch dynamics and the ecology of disturbed ground. In: Walker L R, ed. Ecosystems of Disturbed ground, Amsterdam: Elsevier. 1999: 707~722.
[44] Pickett S T A, Cadenasso M L. Landscape ecology: spatial heterogeneity in ecological systems. Science, 1995, 269:331~334.
[45] Plag, H. P., Late Quaternary relative sea level changes and the role of glaciation upon continental shelves, Terra Nova. 1996,8,213~222.
[46] Preston F W. Time and space and the variation of species. Ecolgy, 1960, 41: 785~790.
[47] RIGGS, S. L., CLEARY, W. J., and SNYDER, S. W.. Influence of inherited geologic framework on barriershoreface morphology and dynamics. Marine Geology, 1995, 126: 213~234.
[48] Riitters K H, O'Neill R V, Hunsaker C T, et al. A factor analysis of landscape pattern and structure metrics. Landscape Ecology, 1995,10: 23~39.
[49] Robert J. NICHOLLS, Frank M. J. Hoozemans, Marcel Marchand. Increasing flood risk and wetland losses due to global sea-level rise: regional and global analyses. Global Environmental Change, 1999(9): S69~S87.
[50] Ronanov,B.G.各种生态条件下人类对土壤演化地影响,土壤学进展,1991,19(2):32~36.
[51] Rossi R E, Mulla D J, Journel A G, et al. Geostatistical tools for modeling and interpreting ecological spatial dependence. Ecological Monographs, 1992, 62:277~314.
[52] Roy P. S. and Thom B. G. and Wright L. D., Holoence sequence sequence on an embayed high-energy coast: an evolutionary model. Sedimentary Geology, 1980,18:28~41.
[53] Sallenger A H and Holman R A. Storm-induced response of a nearshore-bar system. Marine Geology, 1985, 64: 237~257.
[54] Scott, Theodore. Sand movement by wave. U. S. Army Corp of Engineer, Beach Erosion Board tech. Memo. 1954(48).
[55] Speer P E and Aubry D G. A study of nonlinear tidal propagation in shallow inlet/extuarine system: Part□. Theory, Estuarine, Coastal and Shelf Science, 1985, 207~224.
[56] Stutz, M. L. and Pilkey, O. H. A review of global barrier island distribution. Journal of Coastal Research, 2001, 34: 15~22.
[57] Turner M G. Landscape ecology: The effect of pattern on process. Annual Review of Ecology and Sysematics, 1989, 20:171~197
[58] Warrick R A, Leprovost C et al. Change in sea level. Climate Change 1995. The Science of Climate Change. Cambridge: Cambridge University Press, 1996, 359~406.
[59] YUE T X, Haber W, Grossmann W D, et al. Discussion on models for species diversity and suggestion on comprehensive model. ECOMOD, 1998, September: 1~15.
[60] YUE T X, Haber W, Grossmann W D, et al. Towards the satisfying model for biological diversity. EKOLOGIA, 1998,17(3): 129~141.
[61] 蔡爱智.论芝罘连岛沙坝的形成.海洋与湖沼,1978,9(1):1~13.
[62] 蔡程英.水产养殖与海岸带综合管理.海洋开发与管理,1999,16(2):21~24.
[63] 蔡月娥,蔡爱智.山东半岛海岸潟湖的沉积环境.海洋与湖沼,1984,15(5):468~477.
[64] 陈刚,李从先.荣成海岸类型与海岸侵蚀的研究.同济大学学报,1991,19(3):295~305.
[65] 陈梦熊.海平面上升与沿海地区有关的环境地质问题.中国科学院地学部“海平面上升对我国沿海地区经济发展影响与对策”论文集,1993.
[66] 陈伟,李经武,张起信.大天鹅的越冬栖息地——荣成天鹅湖调查初报.海洋湖沼通报,1991(2):57~61.
[67] 陈宜瑜主编.中国湿地研究.长春:吉林科技出版社,1995.
[68] 陈振楼.渤黄海近15000年沉积物地球化学记录与环境变化.华东师范大学博士后研究工作报告,1996.
[69] 陈仲新,张新时.中国生态系统的价值.科学通报,2000,45(1):17~22.
[70] 崔保山,刘兴土.湿地恢复研究综述.地球科学进展,1999,14(4):358~64.
[71] 崔保山,杨志峰.湿地生态系统模型研究进展.地球科学进展,2001,16(3):352~358.
[72] 崔金瑞,夏东兴.山东半岛海岸地貌与波浪、潮汐特征的关系.黄渤海海洋,1992,10(3):21~25.
[73] 党志超.实施沿岸水产养殖业环境管理势在必行.海洋开发与管理,1994,1:35~37.
[74] 樊正球,陈鹭真,李振基.人为干扰对生物多样性的影响.中国生态农业学报,2001,9(2):31~34.
[75] 范强东.胶东半岛鸟类资源的研究.山东林业科技,2001(5):31~33.
[76] 冯浩鉴.海平面上升对我国沿海地区经济发展和生态环境的影响及其对策.中国东部沿海地区海平面与陆地垂直运动.北京:海洋出版社,1999,83~105.
[77] 傅伯杰.景观多样性分析及制图研究.生态学报,1995,15(4):345~350.
[78] 高善明,李元芳.辽宁海岸沙砾堤—潟湖体系沉积特征与全新世海面变化.地理学报,1992,47(2):129~137.
[79] 高尚德,吴以平,魏建功等.中国对虾养成过程中虾池水质和底质的变化.海洋环境科学,1993,12(3~4):7~14.
[80] 高抒.论海岸带受损环境恢复与改善之对策:以山东半岛月湖为例.世纪科技研究与发展—21世纪青年学者论坛,1998,20(4):123~126.
[81] 耿秀山,王永吉,傅命佐.晚冰期以来山东半岛沿岸的海面变动.黄渤海海洋,1987,5(4):38~46.
[82] 攻关专题研究报告之一.半封闭海湾淤积灾害预测关键技术研究——以胶州湾为例.2000.
[83] 谷东起,赵晓涛,夏东兴.中国海岸湿地退化压力因素的综合分析.海洋学报,2003,25(1):78~85.
[84] 国家海洋局.2000年中国海平面公报,2001:41~45.
[85] 国家海洋局第一海洋研究所.山东入海河流概况,1986.
[86] 国家海洋局第一海洋研究所.山东省海湾概查报告,1986.
[87] 国家林业局,等.中国湿地保护行动计划.北京:中国林业出版社,2000.1~48.
[88] 韩德亮.中更新世末期以来黄渤海陆架区衍生沉积体的研究.中国科学院博士学位论文,1999.
[89] 韩有松,孟广兰等.华北沿海中全新世高温期与高海面.中国全新世大暖期气候与环境[M],施雅风主编.海洋出版社,1992.121~130.
[90] 何池.湿地生态系统服务功能与效益评价.生态系统服务功能研究.北京:气象出版社,2002.67~87.
[91] 何念鹏,周道玮,孙刚,吴泠.人为干扰强度对村级景观结构的影响.农村生态环境,2001,17(2):9-12,21.
[92] 何为,李春初,雷亚平.沙坝—潟湖海岸动力地貌学研究进展.台湾海峡,2001,20(4):565~572.
[93] 洪华生,丁原红,洪丽玉,等.我国海岸带生态环境问题及其调控对策.环境污染治理技术与设备,2003,4(1):89~94.
[94] 华泽爱,贾泓.中国沿海湿地开发利用、管理与保护.海洋通报,1996,15(1):78~83.
[95] 胡兆量,陈宗兴,张育乐.地理环境概述.北京:科学出版社.1998.
[96] 黄立人,马青,韩月萍.中国沿海验潮水准点的垂直运动订正.海洋通报,1993,12(6):87~90.
[97] 黄思铭,欧晓昆,杨树华,等.可持续发展的评判.北京:高等教育出版社,2001.
[98] 黄锡畴,马学慧.我国沼泽研究的回顾与展望.地理科学,1988,8(1):1~10.
[99] 季子修,蒋白巽等.海平面上升对长江三角洲及附近地区潮滩和湿地的影响.海洋与湖沼,1994,25(6):582~590.
[100] 季子修,蒋自巽等.海平面上升对长江三角洲及江苏滨海平原海岸侵蚀的可能影响.地理学报,1993,48(6):516~526.
[101] 姜梅.试论山东省荣成市海岸带的可持续利用.国家海洋局第一海洋研究所硕士论文,2000.
[102] 姜启源 编.数学模型.北京:高等教育出版社,1993.
[103] 焦念志 等著.海湾生态过程与持续发展.北京:科学出版社,2001.
[104] 郎惠卿主编.中国湿地研究和保护.上海:华东师大出版社,1998.
[105] 雷亚平.国外砂质海滩沙坝地貌动力学研究进展.海洋通报,1997,16(3):81~87.
[106] 黎广钊,陈荣华,梁文等.北海外沙潟湖全新世微体古生物群特征及其古地理意义.东海海洋,1999,17(4):29~37.
[107] 李春初,雷亚平.全球变化与我国海岸研究问题.地球科学进展,1999,14(2):189~192.
[108] 李春初,罗宪林,张镇元,等.粤西水东沙坝潟湖海岸体系的形成演化.科学通报,1985,31(20):1579~1582.
[109] 李春初,应秩甫,杨干然,等.粤西水东湾潮汐通道—落潮流三角洲的动力地貌过程.海洋工程,1990,8(2):78~88.
[110] 李春初.滨面转移与我国沉积性海岸地貌的几个问题.海洋通报,1987,6(1):69~73.
[111] 李从先,陈刚,王平.我国沿岸晚第四纪沙坝—潟湖体系的沉积模式.沉积学报,1991,9(4):12~19.
[112] 李从先,陈刚.山东荣成桃园沙坝—潟湖地区的垂直层序和沉积环境.海洋通报,1984,3(4):38~44.
[113] 李丛先,蔡进功,陈刚.沙坝—潟湖沉积体系地层分类及其应用.同济大学学报,1990,21(1):80~90.
[114] 李丛先,王平.我国沿岸全新世沙坝—潟湖体系的地层和分布.海洋通报,1993,12(1):80~85.
[115] 李道高,郭永盛,姜爱霞.山东半岛南、北岸全新世海侵及古地理环境差异的初步探讨.海洋学报,1996,18(4):63~71.
[116] 李道高.山东半岛滨海平原全新统研究.海洋学报,1995,17(6):90~96.
[117] 李凤业,高抒,贾建军等.黄、渤海泥质沉积区现代沉积速率.海洋与湖沼,2002,33(4):364~369.
[118] 李哈滨,Franklin J F.景观生态学——生态学领域里的新概念构架.生态学进展,1988,6(3):149~155.
[119] 李哈滨,伍业纲.,景观生态学的数量研究方法.李建国主编,当代生态学博论.北京:中国科学技术出版社,1992:209~233.
[120] 李汉鼎,王升忠,冷雪天,等.渤海湾沿岸泥炭沼泽形成机制与时空分布.海洋地质与第四纪地质.1995,15(2):11~16.
[121] 李培英等.中国东部海岸带黄土成因及冰期渤海沙漠化之探讨.中国海陆第四纪对比研究,北京:科学出版社,1991.
[122] 李平日.华南沿海全新世沙坝及其改造利用.地理学报,1990,45(4):467~474.
[123] 李荣钧 著.模糊多决策理论与应用.北京:科学出版社,2002.
[124] 李善为,夏东兴.山东海岸地貌发育特征.海洋湖沼通报,1981(3):39~44.
[125] 李秀亭.山东半岛沿岸海域的潮汐特征.海岸工程,1989(4):30~36.
[126] 李元芝,邹丽俭,曲延光编辑.威海市湿地资源调查技术报告,1997.
[127] 林业部野生动物与森林植物保护司主编.中国湿地保护研讨会论文集.北京:中国林业出版社,1996.
[128] 刘红玉,吕宪国,刘振乾,等.辽河三角洲湿地资源与区域持续发展.地理科学,2000,20(6):545~551.
[129] 刘红玉,吕宪国,刘振乾.环渤海三角洲湿地资源研究.自然资源学报,2001,16(2):101~106.
[130] 刘兴土.中国沼泽综合分类系统的探讨.地理科学,1997,17(增刊):389~408.
[131] 刘振乾,刘红玉,吕宪国.三江平原湿地生态系统脆弱性研究.应用生态学报,2001,12(2):241~244.
[132] 刘振夏,李培英,李铁刚,等.冲绳海槽5万年以来的古气候事件.科学通报,2000,45(16):1776~1781.
[133] 陆键键.中国滨海湿地的分类.环境导报,1996(1):1~2.
[134] 陆铁松,等.粤东竭石潟湖口外近岸泥沙运移及海岸地貌演变.海洋学报,1988,10(3):318~326.
[135] 鹿守本.海洋资源与可持续发展.北京:中国科学技术出版社,1999.
[136] 鹿守本.中国沿海湿地开发利用、管理与保护.林业部野生动物与森林植物保护司主编.中国湿地保护研讨会文集.北京:中国林业出版社,1996.41~45.
[137] 马俊红,赵济.山东半岛小海潟湖沉积地球化学特征与环境演变.北京师范大学学报(自然科学版),1992,28(1):402~408.
[138] 倪健.山东半岛海岸带砂生植物.科技简讯,1995:4~5.
[139] 欧阳志云,王如松,赵景柱.生态系统服务功能及其经济价值评价.应用生态学报,1999,10(5):635~640.
[140] 彭应登 编.区域开发环境影响评价.北京:中国环境科学出版社,1999.
[141] 齐钟严,马绣同,王祯瑞,等著.黄渤海的软体动物.北京:农业出版社,1989.
[142] 秦蕴珊,赵一阳,陈丽蓉,赵松龄.东海地质.北京,科学出版社,1987.
[143] 曲绵旭,王文海,丰鉴章等编.龙口湾自然环境.北京:海洋出版社,1995.
[144] 任美锷.海平面研究的最近进展.南京大学学报(自然科学),2000,36(3):269~279.
[145] 荣成县潮间带生物资源调查队.潮间带生物资源综合调查报告.1983.
[146] 荣成县水产局区划组.荣成县渔业资源调查与渔业区划报告.1985.
[147] 山东省地质矿产局.山东省地质志.北京:地质出版社,1988.
[148] 山东省科学技术委员会.山东省海岸带和海涂资源综合调查报告.北京:中国科学技术出版社,1990.
[149] 山东省荣成市地方史志编纂委员会编.荣成市志,1999.
[150] 施雅风.我国海岸带灾害的加剧发展及其防御方略.自然灾害学报,1994,3(2):3~15.
[151] 史同广,景才瑞.鲁东南沿海全新世古地理环境演变.华中师范大学学报(自然科学版),1994,28(1):118~122.
[152] 孙广友.沼泽湿地的形成演化.国土与自然资源研究,1998(4):33~35.
[153] 孙广友.中国湿地科学进展与展望.地球科学进展,2000,15(6):666~672.
[154] 孙松龄,梁国思,鞠传龙等.威海市湿地资源浅析.山东林业科技,2000(4):17~18.
[155] 孙廷智,李波.渤海西部近海全新世孢粉组合及古气候、古植被的演变.海洋通报,1992,11(1):32~40.
[156] 同济大学海洋地质系微古组.南黄海西北部底质中有孔虫、介形虫分布规律及其地质意义.上海:同济大学科技情报组编印,1978.
[157] 汪品先,卞云华,李保华,等.西太平洋边缘的“新仙女木”时间.中国科学,D辑,1996,26(5):452~460.
[158] 汪品先,章纪军,赵泉鸿等.东海底质中的有孔虫与介形虫.北京:海洋出版社,1988,1~307.
[159] 王宝灿,黄仰松编著.海岸动力地貌.上海:华东师范大学出版社,1989.
[160] 王开发,王永吉等著.黄海沉积孢粉藻类组合.北京:海洋出版社,1987.
[161] 王庆.全新世以来山东半岛东北部沿海地区相对海面变化的地貌响应.北京大学博士学位论文,1997.
[162] 王庆,夏东兴.山东半岛北岸与南岸现代岸线差异及其影响因素.海洋地质与第四纪地质,1999(1):109~115.
[163] 王文海,吴桑云.中国海岸侵蚀灾害.中国海岸侵蚀研究,国家海洋局第一海洋研究所.1996:9~17.
[164] 王文海,吴桑云.山东省的海岸侵蚀灾害.海岸工程,1996,15(1):12~17.
[165] 王宪礼,布仁仓,肖笃宁.辽河三角洲的景观破碎化分析,应用生态学报,1996,7(3):299~304.
[166] 王宪礼,肖笃宁,布仁仓,等.辽河三角洲湿地的景观格局分析.生态学报,1997,17(3):317~323.
[167] 王绪峨,尹惠蓉,马建新等.山东半岛近海浮游植物调查.齐鲁渔业,1992(1):26~30.
[168] 王永红.山东荣成成山卫潟湖链的形成及其可持续发展.青岛海洋大学硕士学位论文,1999.
[169] 王永吉,李善为.青岛胶州湾地区20000年以来的古植被与古气候.植物学报,1983,25(4):386~391.
[170] 王玉秀,常艳君.沿海虾池开发与环境建设协调发展的研究.中国水产,1999(9):42~43.
[171] 威海市林业局.威海市湿地资源调查技术报告,1997.
[172] 威海市农业局.威海市海岸带农业综合开发规划,1988.
[173] 温志良.海水养殖对环境的影响.环境科学动态,2000(1):29~32.
[174] 邬建国.景观生态学——格局、过程、尺度与等级.北京:高等教育出版社,2000.
[175] 吴桑云.屺姆岛连岛坝沙坝发育初探.黄渤海海洋,1986,4(1):62~66.
[176] 武志杰.人类生产活动对土壤生态系统地影响.生态学杂志,1993,12(4):47~51.
[177] 夏东兴,刘振夏.中国海湾的成因类型.海洋与湖沼,1990,12(2):185~191.
[178] 夏东兴,刘振夏等.渤海湾西岸海平面上升威胁的防治对策.自然灾害学报,1993,2(1):48~52.
[179] 夏东兴.全新世高海面何在.海洋学报,1981,3(4):601~609.
[180] 夏东兴,王文海,武桂秋,崔金瑞,李福林.中国海岸侵蚀述要.地理学报,1993,48(5):468~475.
[181] 肖笃宁,胡远满,李秀珍等著.环渤海三角洲湿地的景观生态学研究.北京:科学出版社,2001.
[182] 肖笃宁.景观空间结构的指标体系和研究方法.景观生态学理论方法及应用.北京:中国林业出版社,1991,92~98
[183] 肖笃宁等.环渤海三角洲湿地的景观生态学研究.北京:科学出版社,2001.
[184] 徐德成,倪玉乐,毕可阳.山东半岛砂质海岸的特点和生态环境.防护林科技,1998(1):11~13,30.
[185] 徐德成.胶东海岸的砂生植被.生态学杂志,1991,10(4):58~61.
[186] 徐家声.渤海湾黄骅沿海贝壳堤与海面变化.海洋学报,1994,16(1):68~77.
[187] 徐家声.山东半岛北部全新世后期沙坝—潟湖发育和岸线演变形式.黄渤海海洋,1989,7(4):25~31.
[188] 徐家声.我国北部沿海的湿地及其保护.湿地保护与合理利用——中国湿地保护研讨会文集.北京:中国林业出版社,1996:172~177.
集.北京:中国林业出版社,1996:172~177.
[189] 徐君义.海水养殖业可持续发展若干问题的探讨.海洋开发与管理,1999,16(2):18~20.
[190] 闫理钦,姜广源,韩云池等.山东湿地类型生物多样性及其保护.山东林业科技,1998(1):27~30.
[191] 杨华庭.中国沿岸海平面上升与海岸灾害.第四纪研究,1999(5):456~465.
[192] 杨永兴.国际湿地科学研究的主要特点、进展与展望.地理科学进展,2002,21(2):111~120.
[193] 杨永兴.国际湿地科学研究进展和中国湿地科学研究优先领域与展望.地球科学进展,2002,17(4):508~514.
[194] 于红军,韩德亮,初风友.晚更新世末期北方陆架区沙漠—黄土堆积群的初步研究.地质力学学报,1997(4).
[195] 于新建,史瑞芳,李经武等.大天鹅在山东荣成越冬习性观察.山东林业科技,1997(1):5~7.
[196] 岳天祥.生物多样性模型研究.自然资源学报,1999,14(4):377~380.
[197] 翟美华.烟台市养虾废水排放及控制.海洋环境科学,1996,15(4):58~61.
[198] 詹滨秋.可持续发展是海水养殖兴衰的关键.海洋科学,1999,2:66~67.
[199] 张海启,朱而勤.褚岛连岛沙坝的形成与演变.青岛海洋大学学报,1993,(3):81~90.
[200] 张理华,周秉根,万荣荣.生态交界带特征与动态变化机理分析.地域研究与开发,2003,22(1):59~61.
[201] 张明祥,严承高.中国湿地效益研究.林业资源管理,1999(3):43~47.
[202] 张淑华,刘德辅.海洋资源开发中的环境问题及对策.山东环境,1998(1):12~13.
[203] 赵德三主编,山东沿海区域环境与灾害.北京:科学出版社,1991.
[204] 赵平等.恢复生态学—退化生态系统生物多样性恢复的有效途径.生态学杂志,2000,19(1):53~58.
[205] 赵松龄,杨光复,苍树溪等.关于渤海西岸海相地层与海岸线问题.海洋与湖沼,1978,9(1):15~25.
[206] 赵松龄,于红军,刘敬圃.晚更新世末期陆架沙漠化环境演化模式的探讨.中国科学(D)1996,26(2):142~146.
[207] 赵松龄.陆架沙漠化.北京:海洋出版社,1996.
[208] 赵松龄.晚更新世末期中国陆架沙漠化及其衍生沉积的研究.海洋与湖沼,1991,22(3):285~293.
[209] 中国海湾志编纂委员会.中国海湾志第三分册.北京:海洋出版社,1991.
[210] 中国科学院地学部.海平面上升对中国三角洲地区的影响及对策.北京:科学出版社,1994.
[211] 竺可桢.中国近五千年来气候变浅的初步研究.中国科学,1973,(2):168~188.
[212] 庄振业.沙坝潟湖沉积体系.朱而勤编著.近代海洋地质学.青岛:青岛海洋大学出版社,1991.199~233.
[213] 庄振业.潟湖沉积环境—山东半岛为例.青岛海洋大学学报,1993,23(1):52~60.
[214] 庄振业,李从先.山东半岛滨岸沙坝沉积特征.海洋学报,1989,11(4):470~480.
[215] 庄振业,林振宏,刘志杰,祁兴芬.海平面变化及其海岸响应.海洋地质动态,2003,9(7):1~12.
[216] 庄振业,鞠连军,冯秀丽等.山东莱州三山岛—刁龙嘴地区沙坝漏湖沉积和演化.海洋地质与第四纪地质,1994,4(4):43~52.
[217] 庄振业,印萍,吴建政,等.鲁南沙质海岸的侵蚀量及其影响因素.海洋地质与第四纪地质,2000,20(3):15~21.
[2] Baker W L. A review of models of landscape change. Landscape Ecology, 1989,2:111~133.
[3] Barnes R. S. K.. Coastal lagoons. London: Cambridge University Press, 1980.
[4] Booth R K, Rich F Jetal. Evolution of a freshwater barrier-island marsh in coastal Georgia, USA, Wetlands, 1999, 19(3):570~577.
[5] Bruun P. Sea-level rise as a cause of shore erosion. J Waterway Div, 1962,88~177.
[6] Costanza R, d'Arge R, de Groot R, et al. The value of the world's ecosystem services and natural capital. Nature, 1997, 387: 253~260.
[7] Costanza R, Sklar F H, White M L, Day J W. A dynamic spatial simulation model of land loss and marsh succession in coastal Louisiana. In: Wetland Modeling(Edited by Mitsch W J, Straskraba M, Jorgensen S W. ) Elsebier, Amsterdam. 1988.
[8] Cowell P. G., Thorn B. G.. Morphodynamics of coastal evolution. Carter R W G, Woodroffe C D. Coastal evolution: Later Quaternary shoreline morphodynamics. Cambridge Press,1994,33~86.
[9] Cromwell, J. E. Barrier coastal distribution: A world-wide survey. In "Barrier Island", 1975, 407~408.
[10] Daily, G. C. Natures Services: Societal Dependence on Natural Ecosystems. Washington D C: Island Press, 1997.
[11] David A. Pinder and Michael E. Witherick. PORT INDUSTRIALIZATION, urbanization and Wetland Loss. WETLANDS: A THREANED LANDSCAPE Edited by Michael Williams, 2000.
[12] DAVIS, R. A., 1994. Barriers of the Florida Gulf Peninsula. In: R. A. DAVIS(ed. ), Geology of Holocene Barrier Island Systems. Springer-Verlag, New York, 167~206.
[13] Datys Jr, J. Rybczyk, F. Scarton, A. Rismondo, D. Are and G. Cecconi. Soil Accretionary Dynamics, Sea-Level Rise and the Survival of Wetlands in Venice Lagoon: A Field and Modelling Approach. Estuarine, Coastal and Shelf Science 1999(49): 607~628.
[14] Edward B. et al. Economic valuation of wetlands. Ramsar Convention Bureau, 1997.
[15] Fairbanks R. G. A 17000-year glacio-eustatic sea level record: influence of glacial melting rate on the Younger Dryas event and deep-ocean circulation, Nature, 1989,342, 637~642.
[16] Fitzgerald, D., and Van Heteren, S. Classification of Paraglacial Barrier Systems: Coastal ew England, USA. Sedimentology, 1999,46:1083~1108.
[17] Forman R T T. Landscape mosaics. The ecology of landscape and regions, Cambridge University Press, 1995,85~101.
[18] Franzer L. G. Can earth afford to lose the wetlands in the battle against the increasing greenhouse effect? International Peat Society, Proceedings of 9th International Peat Congress, Uppsala, 1992:1~18.
[19] Gerhard Masselink and Guithermelessa. Barrier stratigraphy on the Macrotidal central Queesland costaline. Journal of coastal research, 1995,11(2):25~30.
[20] Gorman M L. Island Ecology. London: Chapman & Hall, 1979.
[21] H. Suzanne Bolton,T. Magoon. Coastal Wetlands. New York: American Society of Civil Engineers, 1991.
[22] Hopkinson C S,Wetzel R L,Day J W. Simulation models of coastal wetland and estuarine systems:
relization of goals. In:Wetland Modelling(Edited by Mitsch W J, Straskraba M, Jorgensen S W. ) Elsebier, Amsterdam. 1988.
[23] Hulme, M., Mitchell, J,. Ingram, W., et al. Climate change scenarios for global impact studies. Global Environmental Change9, 1999, S3~S19.
[24] IPCC, Coastal Zone Management Subgroup. Global climate change and the rising challenge of the Sea, IPCC. Tech. Report, 1992, P7.
[25] Johmon,J. W. Scale effect in hydraulic models involving wave motion. Trans. AM. Geophys. Union: 1949(30):517~525.
[26] John G. Ehrenfeld. Evaluating wetlands within an urban context. Ecological Engineering, 2000(15):253~265.
[27] John R. Wetland assessment and survey manual. Wetland International,1996.
[28] Kjerfve,B. and Magill,K. E.. Geographic and hydrodynamic characteristic of shallow coastal lagoons. Marine Geology, 1989,88:189~199.
[29] Kolasa J, Pickett S T A, ed. Ecological Heterogeneity. New York: Springer-Verlag, 1991.
[30] Komar A D著,邱建立译.海滩过程与沉积作用.海洋出版社,1985.
[31] Leatherman S P. Barrier island evolution in response to sea rise-discussion[J], Jour Sed Pet, 1983, 53: 1026~1031.
[32] Leonteev O K. Tapes and formation of lagoons in present coastal zones. Marine Geology, USSR Acedemic press, 1960.
[33] Lippman T C and Holman R A. The spatial and temporal variability of sand bar morphology. Journal Geophysical Resarch, 1990. 95:11575~11590.
[34] Maltby E. and Immirzi C. P. The global status of peatlands and their role in Carbon cycling. Published by Friends of the Earth Trust Limited. 1992.
[35] Matthew L. Stutz and Orrin H. Pilkey. Global Distribution and Morphology of Deltaic Barrier Island Systems. Journal of Coastal research. 2002, 36:694~707.
[36] McAuliffe J R. Landscape evolution, soil formation, and ecological patterns and processes in Sonoran Desert bajadas. Ecological Monographs, 1994, 64:111~148.
[37] Mitsch. W. J. and Gosselink J. G.. Wetlands. New York: Van Nostrand Reinhold Compnay 1986.
[38] Mitsch. W. J. and Gosselink J. G. Wetlands. New York: John Wiley & Sons, Inc. 2000.
[39] Naveh Z. Some remarks on recent developments in landscape ecology as a transdiseiplinary ecological and geographical science. Landscape Ecology, 1991,5: 65~73.
[40] Nicholls M M and Boon J D. Sediment transport processes in coastal lagoons. In: Kjerfve B. (editor), Coastal Lagoon prcesses. Elsevier, Amsterdam, 1994. 157~219.
[41] O'Brien, M. P.. Equillibrium flow areas of tidal inlents on sandy coasts. Proceedings of Tenth Coference on Coastal Engineerings,1966: 676~706.
[42] Paine R T, Levin S A. Intertidal landscapes: disturbance and the dynamics of pattern, Ecological Monographs, 1981, 51: 145~178.
[43] Pickeet S T A, Wu J, Cadenasso M L. Patch dynamics and the ecology of disturbed ground. In: Walker L R, ed. Ecosystems of Disturbed ground, Amsterdam: Elsevier. 1999: 707~722.
[44] Pickett S T A, Cadenasso M L. Landscape ecology: spatial heterogeneity in ecological systems. Science, 1995, 269:331~334.
[45] Plag, H. P., Late Quaternary relative sea level changes and the role of glaciation upon continental shelves, Terra Nova. 1996,8,213~222.
[46] Preston F W. Time and space and the variation of species. Ecolgy, 1960, 41: 785~790.
[47] RIGGS, S. L., CLEARY, W. J., and SNYDER, S. W.. Influence of inherited geologic framework on barriershoreface morphology and dynamics. Marine Geology, 1995, 126: 213~234.
[48] Riitters K H, O'Neill R V, Hunsaker C T, et al. A factor analysis of landscape pattern and structure metrics. Landscape Ecology, 1995,10: 23~39.
[49] Robert J. NICHOLLS, Frank M. J. Hoozemans, Marcel Marchand. Increasing flood risk and wetland losses due to global sea-level rise: regional and global analyses. Global Environmental Change, 1999(9): S69~S87.
[50] Ronanov,B.G.各种生态条件下人类对土壤演化地影响,土壤学进展,1991,19(2):32~36.
[51] Rossi R E, Mulla D J, Journel A G, et al. Geostatistical tools for modeling and interpreting ecological spatial dependence. Ecological Monographs, 1992, 62:277~314.
[52] Roy P. S. and Thom B. G. and Wright L. D., Holoence sequence sequence on an embayed high-energy coast: an evolutionary model. Sedimentary Geology, 1980,18:28~41.
[53] Sallenger A H and Holman R A. Storm-induced response of a nearshore-bar system. Marine Geology, 1985, 64: 237~257.
[54] Scott, Theodore. Sand movement by wave. U. S. Army Corp of Engineer, Beach Erosion Board tech. Memo. 1954(48).
[55] Speer P E and Aubry D G. A study of nonlinear tidal propagation in shallow inlet/extuarine system: Part□. Theory, Estuarine, Coastal and Shelf Science, 1985, 207~224.
[56] Stutz, M. L. and Pilkey, O. H. A review of global barrier island distribution. Journal of Coastal Research, 2001, 34: 15~22.
[57] Turner M G. Landscape ecology: The effect of pattern on process. Annual Review of Ecology and Sysematics, 1989, 20:171~197
[58] Warrick R A, Leprovost C et al. Change in sea level. Climate Change 1995. The Science of Climate Change. Cambridge: Cambridge University Press, 1996, 359~406.
[59] YUE T X, Haber W, Grossmann W D, et al. Discussion on models for species diversity and suggestion on comprehensive model. ECOMOD, 1998, September: 1~15.
[60] YUE T X, Haber W, Grossmann W D, et al. Towards the satisfying model for biological diversity. EKOLOGIA, 1998,17(3): 129~141.
[61] 蔡爱智.论芝罘连岛沙坝的形成.海洋与湖沼,1978,9(1):1~13.
[62] 蔡程英.水产养殖与海岸带综合管理.海洋开发与管理,1999,16(2):21~24.
[63] 蔡月娥,蔡爱智.山东半岛海岸潟湖的沉积环境.海洋与湖沼,1984,15(5):468~477.
[64] 陈刚,李从先.荣成海岸类型与海岸侵蚀的研究.同济大学学报,1991,19(3):295~305.
[65] 陈梦熊.海平面上升与沿海地区有关的环境地质问题.中国科学院地学部“海平面上升对我国沿海地区经济发展影响与对策”论文集,1993.
[66] 陈伟,李经武,张起信.大天鹅的越冬栖息地——荣成天鹅湖调查初报.海洋湖沼通报,1991(2):57~61.
[67] 陈宜瑜主编.中国湿地研究.长春:吉林科技出版社,1995.
[68] 陈振楼.渤黄海近15000年沉积物地球化学记录与环境变化.华东师范大学博士后研究工作报告,1996.
[69] 陈仲新,张新时.中国生态系统的价值.科学通报,2000,45(1):17~22.
[70] 崔保山,刘兴土.湿地恢复研究综述.地球科学进展,1999,14(4):358~64.
[71] 崔保山,杨志峰.湿地生态系统模型研究进展.地球科学进展,2001,16(3):352~358.
[72] 崔金瑞,夏东兴.山东半岛海岸地貌与波浪、潮汐特征的关系.黄渤海海洋,1992,10(3):21~25.
[73] 党志超.实施沿岸水产养殖业环境管理势在必行.海洋开发与管理,1994,1:35~37.
[74] 樊正球,陈鹭真,李振基.人为干扰对生物多样性的影响.中国生态农业学报,2001,9(2):31~34.
[75] 范强东.胶东半岛鸟类资源的研究.山东林业科技,2001(5):31~33.
[76] 冯浩鉴.海平面上升对我国沿海地区经济发展和生态环境的影响及其对策.中国东部沿海地区海平面与陆地垂直运动.北京:海洋出版社,1999,83~105.
[77] 傅伯杰.景观多样性分析及制图研究.生态学报,1995,15(4):345~350.
[78] 高善明,李元芳.辽宁海岸沙砾堤—潟湖体系沉积特征与全新世海面变化.地理学报,1992,47(2):129~137.
[79] 高尚德,吴以平,魏建功等.中国对虾养成过程中虾池水质和底质的变化.海洋环境科学,1993,12(3~4):7~14.
[80] 高抒.论海岸带受损环境恢复与改善之对策:以山东半岛月湖为例.世纪科技研究与发展—21世纪青年学者论坛,1998,20(4):123~126.
[81] 耿秀山,王永吉,傅命佐.晚冰期以来山东半岛沿岸的海面变动.黄渤海海洋,1987,5(4):38~46.
[82] 攻关专题研究报告之一.半封闭海湾淤积灾害预测关键技术研究——以胶州湾为例.2000.
[83] 谷东起,赵晓涛,夏东兴.中国海岸湿地退化压力因素的综合分析.海洋学报,2003,25(1):78~85.
[84] 国家海洋局.2000年中国海平面公报,2001:41~45.
[85] 国家海洋局第一海洋研究所.山东入海河流概况,1986.
[86] 国家海洋局第一海洋研究所.山东省海湾概查报告,1986.
[87] 国家林业局,等.中国湿地保护行动计划.北京:中国林业出版社,2000.1~48.
[88] 韩德亮.中更新世末期以来黄渤海陆架区衍生沉积体的研究.中国科学院博士学位论文,1999.
[89] 韩有松,孟广兰等.华北沿海中全新世高温期与高海面.中国全新世大暖期气候与环境[M],施雅风主编.海洋出版社,1992.121~130.
[90] 何池.湿地生态系统服务功能与效益评价.生态系统服务功能研究.北京:气象出版社,2002.67~87.
[91] 何念鹏,周道玮,孙刚,吴泠.人为干扰强度对村级景观结构的影响.农村生态环境,2001,17(2):9-12,21.
[92] 何为,李春初,雷亚平.沙坝—潟湖海岸动力地貌学研究进展.台湾海峡,2001,20(4):565~572.
[93] 洪华生,丁原红,洪丽玉,等.我国海岸带生态环境问题及其调控对策.环境污染治理技术与设备,2003,4(1):89~94.
[94] 华泽爱,贾泓.中国沿海湿地开发利用、管理与保护.海洋通报,1996,15(1):78~83.
[95] 胡兆量,陈宗兴,张育乐.地理环境概述.北京:科学出版社.1998.
[96] 黄立人,马青,韩月萍.中国沿海验潮水准点的垂直运动订正.海洋通报,1993,12(6):87~90.
[97] 黄思铭,欧晓昆,杨树华,等.可持续发展的评判.北京:高等教育出版社,2001.
[98] 黄锡畴,马学慧.我国沼泽研究的回顾与展望.地理科学,1988,8(1):1~10.
[99] 季子修,蒋白巽等.海平面上升对长江三角洲及附近地区潮滩和湿地的影响.海洋与湖沼,1994,25(6):582~590.
[100] 季子修,蒋自巽等.海平面上升对长江三角洲及江苏滨海平原海岸侵蚀的可能影响.地理学报,1993,48(6):516~526.
[101] 姜梅.试论山东省荣成市海岸带的可持续利用.国家海洋局第一海洋研究所硕士论文,2000.
[102] 姜启源 编.数学模型.北京:高等教育出版社,1993.
[103] 焦念志 等著.海湾生态过程与持续发展.北京:科学出版社,2001.
[104] 郎惠卿主编.中国湿地研究和保护.上海:华东师大出版社,1998.
[105] 雷亚平.国外砂质海滩沙坝地貌动力学研究进展.海洋通报,1997,16(3):81~87.
[106] 黎广钊,陈荣华,梁文等.北海外沙潟湖全新世微体古生物群特征及其古地理意义.东海海洋,1999,17(4):29~37.
[107] 李春初,雷亚平.全球变化与我国海岸研究问题.地球科学进展,1999,14(2):189~192.
[108] 李春初,罗宪林,张镇元,等.粤西水东沙坝潟湖海岸体系的形成演化.科学通报,1985,31(20):1579~1582.
[109] 李春初,应秩甫,杨干然,等.粤西水东湾潮汐通道—落潮流三角洲的动力地貌过程.海洋工程,1990,8(2):78~88.
[110] 李春初.滨面转移与我国沉积性海岸地貌的几个问题.海洋通报,1987,6(1):69~73.
[111] 李从先,陈刚,王平.我国沿岸晚第四纪沙坝—潟湖体系的沉积模式.沉积学报,1991,9(4):12~19.
[112] 李从先,陈刚.山东荣成桃园沙坝—潟湖地区的垂直层序和沉积环境.海洋通报,1984,3(4):38~44.
[113] 李丛先,蔡进功,陈刚.沙坝—潟湖沉积体系地层分类及其应用.同济大学学报,1990,21(1):80~90.
[114] 李丛先,王平.我国沿岸全新世沙坝—潟湖体系的地层和分布.海洋通报,1993,12(1):80~85.
[115] 李道高,郭永盛,姜爱霞.山东半岛南、北岸全新世海侵及古地理环境差异的初步探讨.海洋学报,1996,18(4):63~71.
[116] 李道高.山东半岛滨海平原全新统研究.海洋学报,1995,17(6):90~96.
[117] 李凤业,高抒,贾建军等.黄、渤海泥质沉积区现代沉积速率.海洋与湖沼,2002,33(4):364~369.
[118] 李哈滨,Franklin J F.景观生态学——生态学领域里的新概念构架.生态学进展,1988,6(3):149~155.
[119] 李哈滨,伍业纲.,景观生态学的数量研究方法.李建国主编,当代生态学博论.北京:中国科学技术出版社,1992:209~233.
[120] 李汉鼎,王升忠,冷雪天,等.渤海湾沿岸泥炭沼泽形成机制与时空分布.海洋地质与第四纪地质.1995,15(2):11~16.
[121] 李培英等.中国东部海岸带黄土成因及冰期渤海沙漠化之探讨.中国海陆第四纪对比研究,北京:科学出版社,1991.
[122] 李平日.华南沿海全新世沙坝及其改造利用.地理学报,1990,45(4):467~474.
[123] 李荣钧 著.模糊多决策理论与应用.北京:科学出版社,2002.
[124] 李善为,夏东兴.山东海岸地貌发育特征.海洋湖沼通报,1981(3):39~44.
[125] 李秀亭.山东半岛沿岸海域的潮汐特征.海岸工程,1989(4):30~36.
[126] 李元芝,邹丽俭,曲延光编辑.威海市湿地资源调查技术报告,1997.
[127] 林业部野生动物与森林植物保护司主编.中国湿地保护研讨会论文集.北京:中国林业出版社,1996.
[128] 刘红玉,吕宪国,刘振乾,等.辽河三角洲湿地资源与区域持续发展.地理科学,2000,20(6):545~551.
[129] 刘红玉,吕宪国,刘振乾.环渤海三角洲湿地资源研究.自然资源学报,2001,16(2):101~106.
[130] 刘兴土.中国沼泽综合分类系统的探讨.地理科学,1997,17(增刊):389~408.
[131] 刘振乾,刘红玉,吕宪国.三江平原湿地生态系统脆弱性研究.应用生态学报,2001,12(2):241~244.
[132] 刘振夏,李培英,李铁刚,等.冲绳海槽5万年以来的古气候事件.科学通报,2000,45(16):1776~1781.
[133] 陆键键.中国滨海湿地的分类.环境导报,1996(1):1~2.
[134] 陆铁松,等.粤东竭石潟湖口外近岸泥沙运移及海岸地貌演变.海洋学报,1988,10(3):318~326.
[135] 鹿守本.海洋资源与可持续发展.北京:中国科学技术出版社,1999.
[136] 鹿守本.中国沿海湿地开发利用、管理与保护.林业部野生动物与森林植物保护司主编.中国湿地保护研讨会文集.北京:中国林业出版社,1996.41~45.
[137] 马俊红,赵济.山东半岛小海潟湖沉积地球化学特征与环境演变.北京师范大学学报(自然科学版),1992,28(1):402~408.
[138] 倪健.山东半岛海岸带砂生植物.科技简讯,1995:4~5.
[139] 欧阳志云,王如松,赵景柱.生态系统服务功能及其经济价值评价.应用生态学报,1999,10(5):635~640.
[140] 彭应登 编.区域开发环境影响评价.北京:中国环境科学出版社,1999.
[141] 齐钟严,马绣同,王祯瑞,等著.黄渤海的软体动物.北京:农业出版社,1989.
[142] 秦蕴珊,赵一阳,陈丽蓉,赵松龄.东海地质.北京,科学出版社,1987.
[143] 曲绵旭,王文海,丰鉴章等编.龙口湾自然环境.北京:海洋出版社,1995.
[144] 任美锷.海平面研究的最近进展.南京大学学报(自然科学),2000,36(3):269~279.
[145] 荣成县潮间带生物资源调查队.潮间带生物资源综合调查报告.1983.
[146] 荣成县水产局区划组.荣成县渔业资源调查与渔业区划报告.1985.
[147] 山东省地质矿产局.山东省地质志.北京:地质出版社,1988.
[148] 山东省科学技术委员会.山东省海岸带和海涂资源综合调查报告.北京:中国科学技术出版社,1990.
[149] 山东省荣成市地方史志编纂委员会编.荣成市志,1999.
[150] 施雅风.我国海岸带灾害的加剧发展及其防御方略.自然灾害学报,1994,3(2):3~15.
[151] 史同广,景才瑞.鲁东南沿海全新世古地理环境演变.华中师范大学学报(自然科学版),1994,28(1):118~122.
[152] 孙广友.沼泽湿地的形成演化.国土与自然资源研究,1998(4):33~35.
[153] 孙广友.中国湿地科学进展与展望.地球科学进展,2000,15(6):666~672.
[154] 孙松龄,梁国思,鞠传龙等.威海市湿地资源浅析.山东林业科技,2000(4):17~18.
[155] 孙廷智,李波.渤海西部近海全新世孢粉组合及古气候、古植被的演变.海洋通报,1992,11(1):32~40.
[156] 同济大学海洋地质系微古组.南黄海西北部底质中有孔虫、介形虫分布规律及其地质意义.上海:同济大学科技情报组编印,1978.
[157] 汪品先,卞云华,李保华,等.西太平洋边缘的“新仙女木”时间.中国科学,D辑,1996,26(5):452~460.
[158] 汪品先,章纪军,赵泉鸿等.东海底质中的有孔虫与介形虫.北京:海洋出版社,1988,1~307.
[159] 王宝灿,黄仰松编著.海岸动力地貌.上海:华东师范大学出版社,1989.
[160] 王开发,王永吉等著.黄海沉积孢粉藻类组合.北京:海洋出版社,1987.
[161] 王庆.全新世以来山东半岛东北部沿海地区相对海面变化的地貌响应.北京大学博士学位论文,1997.
[162] 王庆,夏东兴.山东半岛北岸与南岸现代岸线差异及其影响因素.海洋地质与第四纪地质,1999(1):109~115.
[163] 王文海,吴桑云.中国海岸侵蚀灾害.中国海岸侵蚀研究,国家海洋局第一海洋研究所.1996:9~17.
[164] 王文海,吴桑云.山东省的海岸侵蚀灾害.海岸工程,1996,15(1):12~17.
[165] 王宪礼,布仁仓,肖笃宁.辽河三角洲的景观破碎化分析,应用生态学报,1996,7(3):299~304.
[166] 王宪礼,肖笃宁,布仁仓,等.辽河三角洲湿地的景观格局分析.生态学报,1997,17(3):317~323.
[167] 王绪峨,尹惠蓉,马建新等.山东半岛近海浮游植物调查.齐鲁渔业,1992(1):26~30.
[168] 王永红.山东荣成成山卫潟湖链的形成及其可持续发展.青岛海洋大学硕士学位论文,1999.
[169] 王永吉,李善为.青岛胶州湾地区20000年以来的古植被与古气候.植物学报,1983,25(4):386~391.
[170] 王玉秀,常艳君.沿海虾池开发与环境建设协调发展的研究.中国水产,1999(9):42~43.
[171] 威海市林业局.威海市湿地资源调查技术报告,1997.
[172] 威海市农业局.威海市海岸带农业综合开发规划,1988.
[173] 温志良.海水养殖对环境的影响.环境科学动态,2000(1):29~32.
[174] 邬建国.景观生态学——格局、过程、尺度与等级.北京:高等教育出版社,2000.
[175] 吴桑云.屺姆岛连岛坝沙坝发育初探.黄渤海海洋,1986,4(1):62~66.
[176] 武志杰.人类生产活动对土壤生态系统地影响.生态学杂志,1993,12(4):47~51.
[177] 夏东兴,刘振夏.中国海湾的成因类型.海洋与湖沼,1990,12(2):185~191.
[178] 夏东兴,刘振夏等.渤海湾西岸海平面上升威胁的防治对策.自然灾害学报,1993,2(1):48~52.
[179] 夏东兴.全新世高海面何在.海洋学报,1981,3(4):601~609.
[180] 夏东兴,王文海,武桂秋,崔金瑞,李福林.中国海岸侵蚀述要.地理学报,1993,48(5):468~475.
[181] 肖笃宁,胡远满,李秀珍等著.环渤海三角洲湿地的景观生态学研究.北京:科学出版社,2001.
[182] 肖笃宁.景观空间结构的指标体系和研究方法.景观生态学理论方法及应用.北京:中国林业出版社,1991,92~98
[183] 肖笃宁等.环渤海三角洲湿地的景观生态学研究.北京:科学出版社,2001.
[184] 徐德成,倪玉乐,毕可阳.山东半岛砂质海岸的特点和生态环境.防护林科技,1998(1):11~13,30.
[185] 徐德成.胶东海岸的砂生植被.生态学杂志,1991,10(4):58~61.
[186] 徐家声.渤海湾黄骅沿海贝壳堤与海面变化.海洋学报,1994,16(1):68~77.
[187] 徐家声.山东半岛北部全新世后期沙坝—潟湖发育和岸线演变形式.黄渤海海洋,1989,7(4):25~31.
[188] 徐家声.我国北部沿海的湿地及其保护.湿地保护与合理利用——中国湿地保护研讨会文集.北京:中国林业出版社,1996:172~177.
集.北京:中国林业出版社,1996:172~177.
[189] 徐君义.海水养殖业可持续发展若干问题的探讨.海洋开发与管理,1999,16(2):18~20.
[190] 闫理钦,姜广源,韩云池等.山东湿地类型生物多样性及其保护.山东林业科技,1998(1):27~30.
[191] 杨华庭.中国沿岸海平面上升与海岸灾害.第四纪研究,1999(5):456~465.
[192] 杨永兴.国际湿地科学研究的主要特点、进展与展望.地理科学进展,2002,21(2):111~120.
[193] 杨永兴.国际湿地科学研究进展和中国湿地科学研究优先领域与展望.地球科学进展,2002,17(4):508~514.
[194] 于红军,韩德亮,初风友.晚更新世末期北方陆架区沙漠—黄土堆积群的初步研究.地质力学学报,1997(4).
[195] 于新建,史瑞芳,李经武等.大天鹅在山东荣成越冬习性观察.山东林业科技,1997(1):5~7.
[196] 岳天祥.生物多样性模型研究.自然资源学报,1999,14(4):377~380.
[197] 翟美华.烟台市养虾废水排放及控制.海洋环境科学,1996,15(4):58~61.
[198] 詹滨秋.可持续发展是海水养殖兴衰的关键.海洋科学,1999,2:66~67.
[199] 张海启,朱而勤.褚岛连岛沙坝的形成与演变.青岛海洋大学学报,1993,(3):81~90.
[200] 张理华,周秉根,万荣荣.生态交界带特征与动态变化机理分析.地域研究与开发,2003,22(1):59~61.
[201] 张明祥,严承高.中国湿地效益研究.林业资源管理,1999(3):43~47.
[202] 张淑华,刘德辅.海洋资源开发中的环境问题及对策.山东环境,1998(1):12~13.
[203] 赵德三主编,山东沿海区域环境与灾害.北京:科学出版社,1991.
[204] 赵平等.恢复生态学—退化生态系统生物多样性恢复的有效途径.生态学杂志,2000,19(1):53~58.
[205] 赵松龄,杨光复,苍树溪等.关于渤海西岸海相地层与海岸线问题.海洋与湖沼,1978,9(1):15~25.
[206] 赵松龄,于红军,刘敬圃.晚更新世末期陆架沙漠化环境演化模式的探讨.中国科学(D)1996,26(2):142~146.
[207] 赵松龄.陆架沙漠化.北京:海洋出版社,1996.
[208] 赵松龄.晚更新世末期中国陆架沙漠化及其衍生沉积的研究.海洋与湖沼,1991,22(3):285~293.
[209] 中国海湾志编纂委员会.中国海湾志第三分册.北京:海洋出版社,1991.
[210] 中国科学院地学部.海平面上升对中国三角洲地区的影响及对策.北京:科学出版社,1994.
[211] 竺可桢.中国近五千年来气候变浅的初步研究.中国科学,1973,(2):168~188.
[212] 庄振业.沙坝潟湖沉积体系.朱而勤编著.近代海洋地质学.青岛:青岛海洋大学出版社,1991.199~233.
[213] 庄振业.潟湖沉积环境—山东半岛为例.青岛海洋大学学报,1993,23(1):52~60.
[214] 庄振业,李从先.山东半岛滨岸沙坝沉积特征.海洋学报,1989,11(4):470~480.
[215] 庄振业,林振宏,刘志杰,祁兴芬.海平面变化及其海岸响应.海洋地质动态,2003,9(7):1~12.
[216] 庄振业,鞠连军,冯秀丽等.山东莱州三山岛—刁龙嘴地区沙坝漏湖沉积和演化.海洋地质与第四纪地质,1994,4(4):43~52.
[217] 庄振业,印萍,吴建政,等.鲁南沙质海岸的侵蚀量及其影响因素.海洋地质与第四纪地质,2000,20(3):15~21.