Abstract
Present and prospective climate change will likely affect the hydrological cycle in sensitive areas, such as the Alps, thus impacting water-based activities. A most representative example is hydropower production, i.e., exploitation of water to produce energy. In the Italian Alps hydropower is strictly dependent upon water from snow and ice melt, and both are decreasing in response to global warming. Here, we study the effects of potential climate change scenarios at 2100 upon hydropower production from the Chavonne plant, in Valle d’Aosta region of Italy, a run-of-the-river (ROR) plant taking water from two high altitude glacierized catchments of Val di Cogne, and Valsavarenche. We use Poli-Hydro, a state-of-the-art hydrological model to mimic the hydrological budget of the area, including ice and snow melt share. Projections of the hydrological budget were built until 2100 by means of selected climate change scenarios, under proper downscaling. We used runs of three General Circulation Models (GCMs), EC-Earth, CCSM4, and ECHAM6.0 under three Representative Concentration Pathways RCP 2.6, RCP 4.5, and RCP 8.5 from AR5 of IPCC, and of their updated version under four Shared Socio-Economic Pathways SSP1 2.6, SSP2 4.5, SSP3 7.0, and SSP5 8.5 from AR6. We then assessed hydropower production changes against a recent control run CR period (2005–2015). Mean annual flow is estimated at 14.33 m3 s−1 during CR, with ice melt contribution ca. 2%, and snow melt contribution ca. 44%. Ice cover in 2005 was estimated as 19.2 km2, reaching in 2015, 9.93 km2. Mean hydropower production was estimated at 153.72 GWh during the CR. Temperature would largely increase throughout the century (+0.93 °C on average at the half century, +2.45 °C at the end of the century). The ice covered area would be largely depleted (ca. −86%, −94% respectively), with reduced contribution of ice melt (0.23%, <0.1%, respectively) and snow melt (ca. 37%, 33%, respectively). Precipitation would show uncertain patterns, and hence incoming discharge at the plant would erratically vary (−29% to +24% half century, −27% to +59% end of century). Hydropower production displays a large dependence upon monthly discharge patterns, with mostly positive variations (+2.90% on average at half century, +6.95% on average at end of century), with its change driven by exceedance of plant’s capacity.
Highlights
Ongoing climate change is modifying the hydrological cycle, and water availability thereby. ice caps, glaciers, and seasonal snow will suffer most in this sense
In the section “Data and methods”, we discuss the area of interest, and the plant, we report the data used here for the model setup, and we describe the main traits of the model
We used Poli-Hydro, a semi-distributed model, fully accounting for changes in cryospheric process under climate change, including glaciers’ flow/melting, and snow cover accumulation/depletion, so gathering scenarios that were largely significant from the hydrological point of view; (ii) We originally provided climate, and hydrological scenarios in this part of Italy, using the latest, most recently released climate scenarios of the AR6 of the IPCC, unexploited hitherto as far as we know; (iii) We studied for the first time to our knowledge, present and future hydro-power productivity in the Val d’Aosta valley, and in the Gran Paradiso National Park area, an area of tremendous ecological value, and displaying a very large hydropower potential, to be properly exploited henceforward
Summary
Ongoing climate change is modifying the hydrological cycle, and water availability thereby. Hydropower plants in mountain areas largely depend upon ice/snow melt. The Alps of Italy are paradigmatic of the effects of climate change on the cryosphere [2,3,4,5]. Modified seasonal snow-cover dynamics may provide impact upon hydropower production within the Alps. We assessed the effects of potential climate change scenarios upon the energy production of the Chavonne plant, which collects water from the Val di Cogne and the Valsavarenche, in the Valle d’Aosta region of Italy, and in the Gran Paradiso National Park area, an area of tremendous ecological value, and displaying very large hydropower potential. In the section “Literature review” we provide some scientific background from recent studies tackling hydropower assessment in the Italian Alps under prospective climate change.
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