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Nutrient Dynamics and Retention in Land/Water Ecotones of Lowland, Temperate Lakes and Rivers PDF

361 Pages·1993·9.158 MB·English
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Nutrient Dynamics and Retention in Land/Water Ecotones of Lowland, Temperate Lakes and Rivers Developments in Hydrobiology 82 Series editor H. J. Dumont Nutrient Dynamics and Retention in Land/Water Ecotones of Lowland, Temperate Lakes and Rivers Edited by A. Hillbricht-llkowska & E. Pieczynska Reprinted from Hydrobiologia, vol. 251 (1993) Ii« SI Springer-Science+Business Media, B.V. Library of Congress Cataloging-in-Publication Data Nutrient dynamics and retention in land/water ecotones of lowland, temperate lakes, and rivers / edited by A. Hi 11bricht-11kowska and E. Pieczynska. p. cm. — (Developments in hydrobiology ; 82) "Reprinted from Hydrobio 1 ogia , vol. 251 " Includes bibliographical references. ISBN 978-94-010-4698-5 ISBN 978-94-011-1602-2 (eBook) DOI 10.1007/978-94-011-1602-2 1. Freshwater ecology—Congresses. 2. Eutrophication—Congresses. 3. Landscape ecology—Congresses. 4. Biogeochemica1 cycles- -Congresses. 5. Ecotones—Congresses. I. Hi 11bricht-11kowska, Anna. I I. Pieczynska, Ewa. III. Hydrobio1ogia. IV. Series. QH96.A1N87 1993 574.5'2632~dc20 92-46548 ISBN 978-94-010-4698-5 Printed on acid-free paper All Rights Reserved © 1993 Springer Science+Business Media Dordrecht Originally published by Kluwer Academic Publishers in 1993 Softcover reprint of the hardcover 1st edition 1993 No part of the material protected by this copyright notice may be reproduced or utilized in any form or by any means, electronic or mechanical, including photocopying, recording, or by any information storage and retrieval system, without written permission from the copyright owner. v Contents Foreword: Towards a better management of the margins of lakes and river by H. Decamps (UNESCO/MAB) .............................................. IX Preface by Anna Hillbricht-Ilkowska & Ewa Pieczynska XI Wetlands, lake littoral zones Seasonal nitrogen dynamics in reed beds (Phragmites australis. (Cav.)Trin. ex. Steudel) in relation to productivity by H. Kohl & J. G. Kohl ..................................................... . Growth and nutrient uptake by two species of Elodea in experimental conditions and their role in nutrient accumulation in a macrophyte-dominated lake by T. Ozimek, E. van Donk & R. D. Gulati ...................................... 13 Macrophyte-related shifts in the nitrogen and phosphorus contents of the different trophic levels in a biomanipulated shallow lake by E. van Donk, R. D. Gulati, A. Iedema & J. Meulemans . . . . . . . . . . . . . . . . . . . . . . . . . . 19 Functioning of land-water ecotones in relation to nutrient cycling by H. de Haan, H. T. S. Boschker, K. Buis & T. E. Cappenberg ..................... 27 Some considerations on the functioning of tropical riparian ecotones by F. W. B. Bugenyi . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .. 33 Nitrogen and phosphorus dynamics and retention in ecotones of Lake Titicaca, Bolivia/Peru c. by H. J. Carney, M. W. Binford, R. R. Marin & R. Goldman ..................... 39 Detritus and nutrient dynamics in the shore zone of lakes: a review by E. Pieczynska ............................................................. 49 Microbial decomposition of freshwater macrophytes in the littoral zones of lakes by M. Belova ................................................................ 59 Frost formation in the ecotonal zone and its role for release of nutrients by G. Renman ............................................................... 65 Effect of filtering activity of Dreissena polymorpha (Pall.) on the nutrient budget of the littoral of Lake Mikolajskie by A. Stanczykowska & K. Lewandowski ........................................ 73 The role of small mammals and birds in transport of matter through the shore zone of lakes by K. A. Dobrowolski, A. Kozakiewicz & B. Leznicka ............................. 81 Streams, rivers, riparian vegetation Transport and retention of matter in riparian ecotones by G. Bretschko & H. Moser. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .. 95 VI Nitrate transformation and water movement in a wetland area by W. Briisch & B. Nilsson .................................................... 103 Retention of nitrogen in small streams artificially polluted with nitrate by B. A. Faafeng & R. Roseth .................................................. 113 Retention of nitrogen and phosphorus in a Danish lowland river system: implications for the export from the watershed by L. M. Svendsen & B. Kronvang .............................................. 123 Flow and retention of particulate organic matter in riparian fluvial habitats under different climates by H. Chergui & E. Pattee ..................................................... 137 Importance of flood zones for nitrogen and phosphorus dynamics in the Danube Delta by S. Cristofor, A. Vadineanu & G. Ignat ........................................ 143 The Vistula river and its riparian zones by Z. Kajak . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .. 149 Hydrological problems of the Vistula river valley near Plock by E. Bajkiewicz-Grabowska ................................................... 159 Groundwater-swface water ecotones, air-water interface The role of water exchange between a stream channel and its hyporheic zone in nitrogen cycling at the terrestrial-aquatic interface by F. J. Triska, J. H. Duff & R. J. Avanzino ...................................... 167 Nutrient and flow vector dynamics and the hyporheic/groundwater interface and their effects on the interstitial fauna by D. D. Williams ............................................................ 185 Storage and dynamics of organic matter in different springs of small floodplain streams by M. Chafiq & J. Gibert ...................................................... 199 Transport of groundwater-borne phosphorus to Lake Bysjon, South Sweden by V. Vanek ................................................................. 211 Role of aquatic surface microlayer in the dynamics of nutrients and organic compounds in lakes, with implications for their ecotones by A. Sodergren .............................................................. 217 Patch/ecotone pattern in watershed, lake-river systems The shore vegetation in selected lakeland areas in northeastern Poland by S. Klosowski .............................................................. 227 Energy control of matter fluxes through land-water ecotones in an agricultural landscape by L. Ryszkowski & A. K<idziora ............................................... 239 Role of meadow strips for migration of dissolved organic compounds and heavy metals with groundwater by I. Zyczynska-Baloniak, B. Szpakowska, L. Ryszkowski & J. Pempkowiak .......... 249 The dynamics and retention of phosphorus in lentic and lotic patches of river-lake systems by A. Hillbricht-Ilkowska ...................................................... 257 Particulate phosphorus sedimentation at the river inflow to a lake by L. Kufel .................................................................. 269 Patterns of spatial distribution of phosphorus regeneration by zooplankton in a river-lake transitory zone by J. Ejsmont-Karabin, J. Kr6likowska & T. W<iglenska ............................ 275 VB Drainage history and land use pattern of a Swedish river system - their importance for under standing nitrogen and phosphorus load by A. Krug .................................................................. 285 Impact on lake development of changed agricultural watershed exploitation during the last three centuries by T. Klein .................................................................. 297 Ecotone recovery and management Nutrient retention of the Kis-Balaton Water Protection System by P. Pomogyi . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .. 309 A multi-pond system as a protective zone for the management of lakes in China by C. Yin, M. Zhao, W. Jin & Z. Lan ........................................... 321 Management of land/inland water ecotones: needs for regional approaches to achieve sustainable ecological systems by M. M. Holland ............................................................ 331 The application of the ecotone concept in defining nutrient management requirements for the upper Potomac River basin by N. A. Jaworski ............................................................ 341 Modelling the effects of alternative nutrient control policies - the example of Slapton Ley, Devon, UK by P. E. O'Sullivan ............................................................ 351 Hydrobiologia 251: ix-x, 1993. A. Hillbricht-Ilkowska & E. Pieczynska (eds), Nutrient Dynamics and Retention in Land/Water Ecotones of Lowland. Temperate Lakes and Rivers. IX Foreword Towards a better management of the margins of lakes and rivers The role of land/inland water ecotones in regulating landscape biogeochemistry has raised some important questions. It is now largely recognised that edges or transition zones of varying width between aquatic and terrestrial ecosystems have buffer capacities (Schlosser & Karr, 1981; Lowrance et al., 1984; Peterjohn & Correl, 1984; Jacobs & Gilliam, 1985; Pinay & Decamps, 1988). However, we need to known more precisely how far land/inland water ecotones are important in regulating landscape biogeochemistry, and what factors affect their ability to retain and process materials. For example, Pinay et al. (1992) have shown recently that nutrient and carbon retention along a river depends on the arrangement of erosional and depositional patches of riparian woodlands. This arrangement is controlled by hydrology and subject to large variations in time. This temporal variability must be included in hypotheses concerning ecotone biogeochemistry (Naiman et al., 1989). It is now two years since the beginning of the first field project of the Unesco collaborative research on "Role ofland/inland water ecotones in landscape management and restoration" (Naiman et al., 1989), and thus there is a need to redefine these hypotheses. Which of these hypotheses are the most valid and useful? These questions were addressed by the workshop "Wetland and riparian ecotones in landscape dynamics", September 1990, Oak Ridge, Tennessee, USA, and by the workshop "Phosphorus and nitrogen dynamics and retention in ecotones of lowland temperate lakes and rivers", May 1991, Mikolajki, Poland. This second workshop was more specifically concerned with biogeochemistry. Both workshops resulted in advances in methodology. After the Mikolajki workshop, it was clear that five linked approaches need to be developed in order to understand the biogeochemical processes that occur at lake and river margins. The first of these is the landscape approach which aims to understand the effect of pattern on process (Turner, 1989). Width, continuity of ecotones, physical characteristics such as slope, distribution of soil types may have different influences on fluxes across the land/inland water ecotones. The second approach is an experimental one: man-made modifications oflake and river margins may be used as the basis for experiments at the regional level. Thirdly, an interdisciplinary approach is necessary as a basis for the predictive modelling of complex processes which include hydrological, geomorphological and ecological elements. Fourthly, a comparative approach is necessary for a better understanding of the processes involved not only between sites of lowland temperate lakes and rivers, but also between temperate and tropical sites. Fifthly, a long term approach is still the only way to follow the consequences of environmental changes that are taking place everywhere as a result of human activities. A combination of these approaches will allow a better management of the margins of lakes and rivers in order to control the quality of our continental waters. References Jacobs, T. C. & J. W. Gilliam, 1985. Riparian losses of nitrate from agricultural drainage waters. J. environ. Qual. 14: 472-478. Naiman, R. J., H. Decamps & F. Fournier, 1989. Role ofiand/inland water ecotones in landscape management and restoration. Proposals for collaborative research. MAE Digest 4: 1-93. x Lowrance, R. R., R. L. Todd & L. E. Asmussen, 1984. Nutrient cycling in an agricultural watershed: Streamflow and artificial drainage. J. environ. Qual. 13: 27-32. Peterjohn, W. T. & D. L. Correl, 1984. Nutrient dynamics in an agricultural watershed: observations on the role of a riparian forest. Ecology 65: 1466-1475. Pinay, G. & H. Decamps, 1988. The role of riparian woods in regulating nitrogen fluxes between the alluvial aquifer and surface water: a conceptual model. Regulated Rivers 2: 507-516. Pinay, G., A. Fabre, Ph. Vervier & F. Gazelle, 1992. Control ofC, N, P distribution in soils of riparian forests. Landscape Ecology (in press). Schlosser, I. J. & I. R. Karr, 1981. Water quality in agricultural watersheds: impact of riparian vegetation during baseflow. Wat. Res. Bull. 17: 233-240. Turner, M. G., 1989. Landscape ecology: the effect of pattern on process. Annual Review of Ecology and Systematics 20: 171-197. HENRI DECAMPS (UNESCO/MAB) Hydrobiologia 251: xi-xiv, 1993. A. Hillbricht-Ilkowska & E. Pieczynska (eds), Nutrient Dynamics and Retention in Land/Water Ecotones of Lowland, Temperate Lakes and Rivers. Xl Preface Ecotones or boundary zones between land and inland waters (such as lakes, streams and rivers) are the principal routes for transport of organic matter and nutrients across landscapes via physical and biological vectors. The ecotone is the place of cumulation and transformation of in situ production as well as of allochthonous material from adjacent aquatic and terrestrial systems (Di Castri et al., 1988; Naiman et al., 1989; Naiman & Decamps, 1990). The ecotone functions as an important barrier or filter for principal nutrients like phosphorus and nitrogen, responsible for eutrophication and degradation of surface waters. Intensive forest cutting, agriculture, pollution and bank regulation, urbanization and hydrotechnical constructions seriously endanger ecotone systems, and damage their protective function. It is vital to develop a scientific understanding of the behaviour of phosphorus and nitrogen in these transitional, boundary habitats. Such an understanding is important for rational protection, management and restoration of ecotones connected with lakes and rivers. These problems are centered mostly on temperate regions, and were the main objective of the workshop on "Phosphorus and nitrogen dynamics and retention in ecotones oflowland temperate lakes and rivers" (20-26 May, 1991) sponsored by UNESCO/MAB (Man and the Biosphere Programme) and IHP (International Hydrological Programme) and by the Polish Committee for MAB. The workshop was organized by the Institute of Ecology, Polish Academy of Sciences, and hosted by its Hydrobiological Station at Lake Mikolajskie (Masurian Lakeland, Poland). The importance of nutrient cycling and retention was discussed from the point of view of ecotone functioning, management and reconstruction in order to sustain its protective role for water bodies. Various types of land/water transitory zones were discussed: wetlands, lake littoral systems, riparian zones of rivers, streams and brooks, the contact zones between groundwater and surface waters of lakes and rivers, air-water interfaces as well as patch/ecotone structures in watersheds. Some 70 participants from 22 countries attended the workshop, and 54 oral and poster contributions (including longer papers on general topics) were presented. Most of them are included in this volume and are arranged in five sections. The section Wetlands, lake littoral zones is concerned with the role of physical and biological variables in nutrient dynamics and retention. Macrophytes are the most important structural and functional biotic element in the shore zone of lakes. Species composition and biomass distribution of plants, seasonality of nutrient uptake, storage and release, all are very important for the functions of ecotones. Detritus origin and processing (including microbial decomposition) and exchange of nutrients between water and sediments are discussed in relation to matter cycling. Physical factors (water level fluctuations), land use pattern of surrounding terrestrial patches as well as biomanipulation (introduction of piscivorous fish) change internal heterogeneity of ecotone habitats and cause shifts in community structure. Animals (birds and mammals) can effectively transfer nutrients across ecotones. Littoral invertebrates, which occur in massive numbers, can be important in nutrient storage. Specificity of tropical wetlands as compared with temperate ones is also demonstrated and discussed. The importance of physical factors and biological processes for nutrient and organic matter cycling and retention in riverine ecotones is discussed in the section Streams, rivers, riparian vegetation. Narrow shore zones of small brooks and streams as well as wide floodplains of larger rivers are discussed.

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