An insightful guide to the concepts and practices of modern landscape ecology
Elements of geography, conservation biology, soil science and other disciplines factor into landscape ecology's rich analyses of the ecological and environmental forces at play across different terrains. With its unique, organism-oriented approach to the subject,Applied Landscape Ecology considers the effects of ecological processes upon particular species and places its findings within the context of larger-scale concerns. Students, researchers, and practitioners alike will find this a rewarding and instructive read that offers practical and detailed information on the latest methods and technologies used in the field today.
This essential resource:
Takes an interdisciplinary approach to landscape ecologyExamines the subject within the contexts of specific organismsCovers cutting-edge technologies and methodsRepresents a collaboration between an international team of landscape ecology experts
Whether new to the practice or an established ecologist, anyone with an interest in this exciting and developing field should have a copy ofApplied Landscape Ecology at their disposal.
Francisco Castro Rego, Professor of Landscape Ecology, Centre for Applied Ecology "Prof. Baeta Neves", InBio and School of Agriculture, University of Lisbon, Lisbon, Portugal
Stephen C. Bunting, Emeritus Professor of Landscape and Rangeland Ecology, College of Natural Resources, University of Idaho, Moscow, ID, USA
Eva Kristina Strand, Professor of Landscape Ecology, College of Natural Resources, University of Idaho, Moscow, ID, USA
Paulo Godinho-Ferreira, Senior Researcher of Landscape Ecology, Centre for Applied Ecology "Prof. Baeta Neves", InBio and Institute for Agrarian and Veterinarian Research, Lisbon, Portugal
Foreword xi
Preface xiii
1 Concepts and Approaches in Landscape Ecology 1
1.1 The Historical Development of Landscape Ecology as a Science 1
1.2 Hierarchical Levels in Ecology 6
1.3 The Spatial Hierarchy of Land 7
1.4 Fundamental Concepts: Landscape Scale and Size, Pattern, Process, and Change 9
1.5 The Representation of the Landscape and its Elements 13
Key Points 20
Endnotes 20
2 Points as Landscape Elements 25
2.1 The Different Patterns 25
2.2 Distance Methods to Detect Pattern 29
2.3 Quadrat Analysis to Detect Pattern 31
2.4 Consideration of Scale in Nearest-Neighbor Analyses 35
2.5 Consideration of Scale in Quadrat Analyses 40
Key Points 44
Endnotes 44
3 Linear Elements and Networks 47
3.1 The Linear Features and Corridors in the Landscape 47
3.2 Curvilinearity and Fractal Analysis 50
3.3 Linear Density of Networks 57
3.4 Spatial Distribution of Linear Networks 60
3.5 Analysis of the Spatial Distribution of Linear Networks 62
3.6 A Study of Linear Features on the European Scale 65
3.7 The Topology of the Networks 66
3.8 Network Connectivity 68
3.9 Connectivity Indices Based on Topological Distances between Patches (Nodes) 72
Key Points 77
Endnotes 78
4 Patches and Their Interactions 81
4.1 The Importance of Patch Size for Species Diversity 81
4.2 The Importance of Patch Edge and Shape 86
4.3 The Measurement of Patch Size and Perimeter 88
4.4 Quantifying Patch Shape 90
4.5 An Example for the Use of PerimeterArea Relationships 92
4.6 Patch Interior and Edge 94
4.7 Interaction between Patches and the Theory of Island Biogeography 99
4.8 Interaction between Patches and Populations: The Concept of Metapopulation 102
4.9 Estimating the Interaction between Patches by the Distance and Size of Neighbors 104
4.10 An Example of the Use of the Gravity Model 108
Key Points 111
Endnotes 111
5 The Vertical Dimension of Landscapes 115
5.1 The Importance of Elevation Illustrated for Birds in the Macaronesian Islands 115
5.2 Montane Islands 120
5.3 The Vertical Dimension in Aquatic Systems 122
5.4 The Vertical Structure of Vegetation and Species Diversity 122
Key Points 126
Endnotes 126
6 Movements through Landscapes 129
6.1 Percolation Theory 129
6.2 Contagion Analysis and Percolation 133
6.3 Resistance Surfaces 137
6.4 Example of Percolation Movements through Landscapes 140
Key Points 142
Endnotes 143
7 Landscape Composition, Diversity, and Habitat Selection 145
7.1 Measurements of Diversity 145
7.2 Species Diversity of Habitats and Landscapes 150
7.3 The Habitat Use Diversity of a Species 155
7.4 The Relationship between the Species Diversity of a Landscape and the Habitat Use Diversity of the Species 157
7.5 Habitat Selection 161
7.6 Landscape Composition and Diversity 169
Key Points 170
Endnotes 171
8 Landscape Pattern: Composition and Configuration 173
8.1 Composition and Configuration Represent Different Aspects of Landscapes 173
8.2 Configuration Assessed by Patch Numbers, Sizes, Perimeters, and Shapes 175
8.3 Edge Contrast 178
8.4 Configuration Assessed by Types of Cell Adjacencies 181
8.5 Combination of Landscape Pattern Indices 186
8.6 Example of Uses of Pattern and Configuration Metrics to Compare Landscapes 189
Key Points 191
Endnotes 191
9 Landscape Dynamics 193
9.1 The Dynamic Nature of Landscapes: Disturbances and Equilibrium 193
9.2 The Two-State Landscapes 195
9.3 Rotating Landscapes 198
9.4 Indices for the Dynamics and Randomness of Landscape Changes 202
9.5 Measuring the Complexity of Landscape Change 204
9.6 Simulating Changes in Landscape Composition 206
9.7 Conditional Landscape Changes 211
Key Points 216
Endnotes 217
10 From Landscape Ecology to Landscape Management 219
10.1 Natural Processes and Landscape Management 219
10.2 Transition Matrices as the Mathematical Framework 223
10.3 Management of Landscape Composition and the Transition Matrix Model 226
10.4 The Use of Transition Matrices to Incorporate Changes in Disturbance Regimes and/or Management Activities 228
10.5 Combining Spatial and Temporal Analysis in Transition Models 238
Key Points 252
Endnotes 252
Appendix A Description of Notation Used in Formulae and Metrics 255
Index 263