TY  - JOUR
A1  - Encinas Fernández, Jorge
A1  - Hofmann, Hilmar
A1  - Peeters, Frank
T1  - Diurnal Pumped‐Storage Operation Minimizes Methane Ebullition Fluxes From Hydropower Reservoirs
Y1  - 2020-12-04
VL  - 56
IS  - 12
JF  - Water Resources Research
DO  - 10.1029/2020WR027221
DO  - 10.23689/fidgeo-4095
N2  - Hydropower is considered green energy and promoted to reduce greenhouse warming. However, hydropower is typically generated using reservoirs and reservoirs are known to emit substantial amounts of the greenhouse gas methane (CH4) to the atmosphere. In many reservoirs ebullition is the dominant pathway of CH4 emission. We show that continuous diurnal pumped‐storage operation, which combines water pumping into the reservoir typically during the night and water drawdown during high demand of electricity, is beneficial for reducing CH4 ebullition associated with hydropower generation. This conclusion is based on ebullition fluxes and water levels measured over 3 months in Schwarzenbach reservoir located in Germany. The reservoir was managed using three modes of operation: (1) diurnal pumping and turbination, (2) no pumping and no turbination, and (3) diurnal turbination. Cross‐correlation analysis indicates that ebullition fluxes predominantly occur during diurnal water level decrease associated with turbination. Consistently, average ebullition fluxes of CH4 were negligible during Mode (2) and substantial during Modes (1) and (3). During Mode (3) the average CH4 ebullition flux was ~197 mg m−2day−1, ~12 times larger than during Mode (1) (16 mg m−2day−1). Our data indicate that overall CH4 ebullition is about 3 times larger during 51 days of operation consisting of 38 days of no turbination followed by 13 days of diurnal turbination than during 51 days of continuous diurnal pumped‐storage operation. This suggests that continuous diurnal pumped‐storage operation leads to reduced CH4 ebullition from reservoirs and is therefore advantageous compared to modes of operations involving long‐term, large‐amplitude turbination cycles.
N2  - Key Points: Draw down associated with turbination during pumped‐storage operation triggers ebullition in reservoirs Continuous pumped‐storage operation results in smaller ebullition than intensive pumping after long‐term storage Appropriate management strategies can contribute to a reduction of greenhouse gas emissions from reservoirs
UR  - http://resolver.sub.uni-goettingen.de/purl?gldocs-11858/8435
ER  -