Figure 1.2 Cause of hydromorphic degradation in the UK.
Source: www.riverhabitatsurvey.org/wp-content/uploads/2012/07/RHS.pdf
It is interesting to review the figures above against the Water Framework Directive measure of river health currently being used across Europe. Entwistle et al. (2019a) used floodplain land‐use data for 2017 broken down according to current water body status generating 2975 auditable units. Water bodies presently at Good status were selected (n = 375), arable and horticulture covers in excess of 50% of the floodplain area on around 15% of Good status water bodies, this increases to around 50% for area under improved grassland and when the two are considered together between 70 and 75% of Good Status water bodies are covered by at least 50% farmland. Around half of these water bodies are utilised over 90% by farming.
1.4 River and Floodplain Recovery
The preceding section summarises several studies relating to river and floodplain degradation; however, it remains difficult for the reader to understand exactly what has happened to watercourses and valley bottoms in England. Rivers seen in the landscape today are often regarded as “natural” systems with little regard to the actual levels of degradation they have suffered. This is perfectly understandable as we have grown up with heavily modified and managed systems, and we have few natural analogues left against which we can judge the degree of alteration. “Stability” is seen as desirable with neatness and uniformity favoured above natural functionality. Fortunately, this attitude is changing as the economics of river and floodplain management has resulted in reduced river training and a consequent increase in the influence of natural fluvial processes. Many systems are showing small but significant signs of recovery towards a better functioning system aligned with current catchment controls. Recovery has not always been back to a previous river state before human intervention as conditions in the catchment have changed significantly enough to cause a state change in our rivers, but their diversity is improving.
The situation above is best illustrated through examples. Figure 1.3 illustrates a typical lowland watercourse; here historic engineering and current management has led to the development of a monotonous single‐thread watercourse devoid of in‐channel morphological units and showing no signs of any lateral movement due to revetment works and a subdued flood regime. Floodplain areas, although often extensive, display no functional morphological units with intensive land use severing hydrological and hydraulic connections, modifying, or destroying floodplain features and altering vegetative assemblages. Upland rivers have suffered similarly (Figure 1.4). Natural flow paths have been altered to maximise valley bottom land use. Lateral activity has been suppressed through revetment and tree planting, in‐channel morphological development has been suppressed by repeat dredging and floodplain functionality has been disrupted due to a combination of bed lowering, embanking, and incision in response to human modification.
Figure 1.3 Typical heavily modified lowland system with artificial flood protection embankments, channel straightening and dredging, and removal of in‐channel and riparian vegetation. The Yorkshire Derwent at Yedingham.
Figure 1.4 Typical heavily modified upland system, straightened, walled, and dredged. The Upper Whit Beck at Low Lorton.
Examples of naturally functioning fluvial systems are few and far between, existing only as small fragments developing because of a lack of system management. Nevertheless, these reaches offer valuable insights into how our rivers and floodplains would function when unconstrained, acting as exemplars against which we should be judging our present systems. On lowland rivers, the propensity appears to be one of the development of a low‐gradient stable multiple channel river network well connected to intervening areas of floodplain (Figure 1.5). The recovery of such areas appears strongly influenced by vegetation which acts as the precursor to sediment deposition and consolidation and creates high levels of local morphologic, hydrologic, and hydraulic diversity. Development of such systems remains highly restricted, but their form and functionality, even at a local scale, offers clear indications of how many lowland systems should look and behave.
Upland systems appear to be naturalising most strongly through in‐channel feature re‐development leading to enhanced local bank erosion and lateral reworking of floodplain sediment, which on many rivers has created a well‐connected narrow inset floodplain (Figure 1.6). On more energetic systems, the loss of constraints on channel movement has seen the development of strong active meandering systems (Figure 1.7), or wandering channel networks (Figure 1.8), both of which offer considerably higher morphologic, hydrologic, and hydraulic diversity over their previously managed state.
1.5 Purpose of This Book
This book aims to highlight the true form and function of watercourses and valley bottom areas using examples from the British Isles on which the authors have worked, either individually or together, over the last three decades. The intention is to encourage the reader to view fluvial systems, and their potential for management and restoration in a new light using examples of functional river types. The book will act as a guide to recognising these river types, and Chapter 2 serves to illustrate and widen understanding of their classification into different functional types based on character and complexity. In Chapter 3, we illustrate the morphological unit makeup of, and drivers and processes behind, each river type through a comprehensive photographic guide, and review the current research understanding of their form and function through a focussed review of published studies. Whilst we include examples of the science from outside the British Isles, these studies all focus on temperate rivers, and all examples of functional river types used are from the United Kingdom. Of great value to the river scientist is the ability to infer fluvial processes and probable directions of fluvial change from the current morphology of the system, and in Chapter 4, we provide a guide to “reading” rivers, describing key watercourse indicators that help in this task. Finally in Chapter 5, we provide some thoughts regarding sensitive and appropriate management for British rivers going forward.