| 1. | Subaerial River Bank Processes and Interaction with other Bank Erosion Mechanisms on the River Arrow, Warwickshire, UK | 2205 | |
| 2. | The Importance of Physical Habitat Assessment for Evaluating River Health | 1610 | |
| 3. | Insights into River Bank Erosion Processes Derived from Analysis of Negative Erosion-pin Recordings: Observations from Three Recent UK Studies. | 1503 | |
| 4. | Reallocation of Compensation Releases to Restore River Flows and Improve Instream Habitat Availability in the Upper Derwent Catchment, Derbyshire, UK | 1446 | |
| 5. | Assessing the Viability of Complex Electrical Impedance Tomography (EIT) with a Spatially Distributed Sensor Array for Imaging of River Bed Morphology: a Proof of Concept (Study) | 1389 | 486 |
| 6. | The Effect of Flow Regulation on Channel Geomorphic Unit (CGU) Composition in the Soča River, Slovenia. | 1178 | 237 |
| 7. | The Effect of Flow Regulation on the Spatial Distribution and Dynamics of Channel Geomorphic Units (CGU’s) in the Soča River, Slovenia. | 927 | 211 |
| 8. | Identifying the Influence of Channel Morphology on Physical Habitat Availability for Native Fish: Application to the Two-spined Blackfish (Gadopsis bispinosus) in the Cotter River, Australia. | 921 | |
| 9. | The Rivers of Worcestershire: a Baseline Geomorphological Survey | 865 | 581 |
| 10. | River Habitat Mapping: are Surface Flow Type Habitats Biologically Distinct? | 610 | 583 |
| 11. | Quantifying Submerged Fluvial Topography Using Hyperspatial Resolution UAS Imagery and Structure From Motion Photogrammetry. | 547 | 551 |
| 12. | Quantifying Fluvial Topography Using UAS Imagery and SfM-Photogrammetry. | 543 | 122 |
| 13. | Monitoring Stream and Watershed Restoration, edited by Philip Roni (Book Review) | 464 | 347 |
| 14. | An Evaluation of the Spatial Configuration and Temporal Dynamics of Hydraulic River Habitats | 462 | 91 |
| 15. | The Routledge Handbook of Wetlands | 441 | |
| 16. | A Framework for Evaluating the Spatial Configuration and Temporal Dynamics of Hydraulic Patches | 432 | |
| 17. | Evaluation and Application of Environmental Flows in Running Waters in Slovenia | 408 | |
| 18. | Book Review: Groundwater in the Environment: an Introduction, by Paul L. Younger, 2007. Blackwell: London, 390 pages. ISBN 1-4051-2143-2 | 398 | |
| 19. | Environmental Flows: Habitat Modeling | 380 | |
| 20. | Mesohabitat Use by Bullhead (Cottus gobio) | 379 | |
| 21. | The Development of Hydraulic and Geomorphic Complexity in Recently Formed Streams in Glacier Bay National Park, Alaska | 373 | |
| 22. | Ecohydraulics: An Integrated Approach | 369 | |
| 23. | Rapid Assessment of Physical Habitat Sensitivity to Abstraction (RAPHSA) | 367 | |
| 24. | Incorporating Hydrodynamics into Ecohydraulics: The Role of Turbulence in the Swimming Performance and Habitat Selection of Stream-Dwellling Fish | 348 | |
| 25. | Defining Spatial and Temporal Hydromorphological Sampling Strategies for the Leigh Brook River Site | 344 | |
| 26. | Hydrodynamic Variability in the Physical Biotopes of a Trout Stream | 338 | 48 |
| 27. | The Effect of Flow Regulation on the Distribution and Dynamics of Channel Geomorphic Units (CGUs) and Implications for Marble Trout (Salmo marmoratus) Spawning Habitat in the Soča River, Slovenia. | 336 | |
| 28. | The Accuracy and Reliability of Traditional Surface Flow Type Mapping: Is It Time for A New Method of Characterising Physical River Habitat? | 335 | 94 |
| 29. | Spatio-temporal Dynamics of Edge Habitat in Natural and Altered Spring Snowmelt Recession Flow Regimes, Sierra Nevada, California. | 326 | 108 |
| 30. | Field-based monitoring of instream leaky barrier backwater and storage during storm events | 314 | 100 |
| 31. | Quantifying Fluvial Substrate Size using Hyperspatial Resolution UAS Imagery and SfM-photogrammetry | 312 | 6 |
| 32. | Interactions Between instream wood and Hydrogeomorphic Development within Recently Deglaciated Streams in Glacier Bay National Park, Alaska | 300 | |
| 33. | Are Surface Flow Type Mesohabitats Biologically Distinct? | 293 | 69 |
| 34. | Monitoring river channel dynamics by Unmanned Aerial Systems | 285 | 1 |
| 35. | Position Choice and Swimming Costs of Juvenile
Atlantic Salmon Salmo Salar in Turbulent Flow | 278 | 173 |
| 36. | Drones and Digital Photogrammetry: From Classifications to Continuums for Monitoring River Habitat and Hydromorphology | 276 | 127 |
| 37. | Advancing river monitoring using image-based techniques: Challenges and opportunities | 269 | 159 |
| 38. | High Resolution Remote Sensing of Water Surface Patterns | 269 | 61 |
| 39. | Achieving the Aquatic Ecosystem Perspective: Integrating Interdisciplinary Approaches Describe Instream Ecohydraulic Processes | 269 | |
| 40. | Ecohydraulics: An Introduction | 267 | |
| 41. | Mesohabitat Use by Brown Trout (Salmo trutta) in a Small Groundwater-dominated Stream | 267 | |
| 42. | Research Needs, Challenges and the Future of Ecohydraulics Research | 264 | |
| 43. | New Developments in Legislation to Enforce Ecologically Acceptable Flows in Slovenia | 258 | |
| 44. | High Resolution Remote Sensing from a UAV for Quantifying Fluvial Topography | 257 | 143 |
| 45. | Testing the Relationship Between Surface Flow Types and Benthic Macroinvertebrates | 255 | |
| 46. | The Development of Geomorphological Complexity and its Influence on Fish Habitat | 253 | 75 |
| 47. | Determining the Sensitivity of Rivers to Abstraction. RAPHSA- a Tool for Environmental Managers | 224 | 76 |
| 48. | The hyporheic zone as an invertebrate refuge during a fine sediment disturbance event | 216 | 105 |
| 49. | A Community-Level, Mesoscale Analysis of Fish Assemblage Structure in Shoreline Habitats of a Large River Using Multivariate Regression Trees. | 212 | |
| 50. | Instream wood functions as an ecosystem engineer in river ecosystem development following recent deglaciation in Glacier Bay National Park, Alaska | 193 | |
| 51. | Increasing LSPIV performances by exploiting the seeding distribution index at different spatial scales | 174 | 109 |
| 52. | Do legacy effects of deposited fine sediment influence the ecological response of drifting invertebrates to a fine sediment pulse? | 127 | 90 |
| 53. | Introduction | 120 | |
| 54. | Mapping stress in submerged aquatic vegetation using multispectral imagery and structure from motion photogrammetry | 97 | |
| 55. | Assessing on-farm impacts of the deep bed farming system on soil and water conservation, and maize yields among smallholder farmers in Malawi | 52 | 22 |
| 56. | Wetlands, Geographical Information Systems (GIS) and Spatial Modelling | 41 | |