Abstract
Hillslope viticulture has a long history in Mediterranean Europe, and still holds important cultural and economic value. Steep hillsides have widely been levelled by terraces, in order to control surface water flow and facilitate cultivation. However, under unsustainable management and growing rainfall aggressiveness, terraced vineyards have become one of the most erosion-prone agricultural landscapes. The Valcamonica valley in Lombardy (Italy) presents a typical example of an ancient wine production region where rural land abandonment has previously caused widespread degradation of the traditional terracing systems. Recently, a local revival of wine production led to restoration plans of the terraces and their drainage functioning, to safeguard productivity and hydrogeologic safety. In this study, an Unmanned Aerial Vehicle (UAV) survey was carried out to reconstruct an accurate and precise 3D terrain model of a Valcamonica vineyard through photogrammetry. The resulting high-resolution topographic data allowed insights of surface flow-induced soil erosion patterns based on the Relative Path Impact Index (RPII). Three diverse drainage networks were designed and digitally implemented, allowing scenario analysis of the costs and benefits in terms of potential erosion mitigation. The presented methodology could likely improve the time-efficiency and cost-effectiveness of similar restoration plans in degraded landscapes.
Highlights
Agricultural terraces are among the most evident anthropogenic signatures and dominant drivers of the geomorphology of our time [1,2]
Three critical zones (Figure 4, zones A–C) are highlighted for comparison of potential flow concentration and the effect of the different drainage network scenarios. The selection of these zones was based on the presence of critical patterns and field evidence of terrace damages
This study emphasises the potential of high-resolution topography data from low-cost Unmanned Aerial Vehicle (UAV) and image-based photogrammetry to digitally reconstruct terrace system morphology and facilitate the design of their drainage systems
Summary
Agricultural terraces are among the most evident anthropogenic signatures and dominant drivers of the geomorphology of our time [1,2]. Terrace degradation is worsening due to modern developments, such as the abandonment of rural areas and consequent lack of maintenance [4,5], increased pressure from machinery traffic [6], unsuitable terrace design and expansions [1] and changing rainfall patterns [7]. These factors contribute to hydrogeologic risks, such as soil erosion and nutrient loss or even terrace collapse, landslides and debris flows [8,9,10,11]. Most notable among these are the United Nations Educational, Scientific and Cultural Organization (UNESCO) World Heritage Sites or the Globally Important
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