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1. Carbon dioxide (CO ₂ ) concentrations and emission in the newly constructed Belo Monte hydropower complex in the Xingu River, Amazonia

   https://doi.org/10.5194/bg-16-3527-2019  

   de Araújo, Kleiton R.; Sawakuchi, Henrique O.; Bertassoli Jr., Dailson J.; Sawakuchi, André O.; da Silva, Karina D.; Vieira, Thiago B.; Ward, Nicholas D.; Pereira, Tatiana S. (January 2019, Biogeosciences)

   Abstract. The Belo Monte hydropower complex located in the Xingu River is the largestrun-of-the-river (ROR) hydroelectric system in the world and has one of thehighest energy production capacities among dams. Its construction receivedsignificant media attention due to its potential social and environmentalimpacts. It is composed of two ROR reservoirs: the Xingu Reservoir (XR) inthe Xingu's main branch and the Intermediate Reservoir (IR), an artificialreservoir fed by waters diverted from the Xingu River with longer waterresidence time compared to XR. We aimed to evaluate spatiotemporalvariations in CO2 partial pressure (pCO2) and CO2 fluxes(FCO2) during the first 2 years after the Xingu River impoundmentunder the hypothesis that each reservoir has contrasting FCO2 andpCO2 as vegetation clearing reduces flooded area emissions. Time ofthe year had a significant influence on pCO2 with the highest averagevalues observed during the high-water season. Spatial heterogeneitythroughout the entire study area was observed for pCO2 during both low-and high-water seasons. FCO2, on the other hand, only showed significantspatial heterogeneity during the high-water period. FCO2 (0.90±0.47 and 1.08±0.62 µmol m2 d−1 for XR and IR,respectively) and pCO2 (1647±698 and 1676±323 µatm for XR and IR, respectively) measured during the high-water season wereon the same order of magnitude as previous observations in other Amazonianclearwater rivers unaffected by impoundment during the same season. Incontrast, during the low-water season FCO2 (0.69±0.28 and 7.32±4.07 µmol m2 d−1 for XR and IR, respectively) andpCO2 (839±646 and 1797±354 µatm for XR and IR,respectively) in IR were an order of magnitude higher than literatureFCO2 observations in clearwater rivers with naturally flowing waters.When CO2 emissions are compared between reservoirs, IR emissions were90 % higher than values from the XR during low-water season, reinforcingthe clear influence of reservoir characteristics on CO2 emissions.Based on our observations in the Belo Monte hydropower complex, CO2emissions from ROR reservoirs to the atmosphere are in the range of naturalAmazonian rivers. However, the associated reservoir (IR) may exceed naturalriver emission rates due to the preimpounding vegetation influence. Sincemany reservoirs are still planned to be constructed in the Amazon andthroughout the world, it is critical to evaluate the implications ofreservoir traits on FCO2 over their entire life cycle in order toimprove estimates of CO2 emissions per kilowatt for hydropower projectsplanned for tropical rivers. 

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2. Low Diffusive Methane Emissions From the Main Channel of a Large Amazonian Run-of-the-River Reservoir Attributed to High Methane Oxidation

   https://doi.org/10.3389/fenvs.2021.655455  

   Sawakuchi, Henrique O.; Bastviken, David; Enrich-Prast, Alex; Ward, Nicholas D.; Camargo, Plínio B.; Richey, Jeffrey E. (April 2021, Frontiers in Environmental Science)

   The global development of hydropower dams has rapidly expanded over the last several decades and has spread to historically non-impounded systems such as the Amazon River’s main low land tributaries in Brazil. Despite the recognized significance of reservoirs to the global methane (CH 4 ) emission, the processes controlling this emission remain poorly understood, especially in Tropical reservoirs. Here we evaluate CH 4 dynamics in the main channel and downstream of the Santo Antônio hydroelectric reservoir, a large tropical run-of-the-river (ROR) reservoir in Amazonia. This study is intended to give a snapshot of the CH 4 dynamics during the falling water season at the initial stage after the start of operations. Our results show substantial and higher CH 4 production in reservoirs’ littoral sediment than in the naturally flooded areas downstream of the dam. Despite the large production in the reservoir or naturally flooded areas, high CH 4 oxidation in the main channel keep the concentration and fluxes of CH 4 in the main channel low. Similar CH 4 concentrations in the reservoir and downstream close to the dam suggest negligible degassing at the dam, but stable isotopic evidence indicates the presence of a less oxidized pool of CH 4 after the dam. ROR reservoirs are designed to disturb the natural river flow dynamics less than traditional reservoirs. If enough mixing and oxygenation remain throughout the reservoir’s water column, naturally high CH 4 oxidation rates can also remain and limit the diffusive CH 4 emissions from the main channel. Nevertheless, it is important to highlight that our results focused on emissions in the deep and oxygenated main channel. High emissions, mainly through ebullition, may occur in the vast and shallow areas represented by bays and tributaries. However, detailed assessments are still required to understand the impacts of this reservoir on the annual emissions of CH 4 . 

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3. Forecasting the Evolution of Hydropower Generation

   https://doi.org/10.1145/3394486.3403337  

   Zhou, Fan; Li, Liang; Zhang, Kunpeng; Trajcevski, Goce; Yao, Fuming; Huang, Ying; Zhong, Ting; Wang, Jiahao; Liu, Qiao (July 2020, The 26th {ACM} {SIGKDD} Conference on Knowledge Discovery and Data Mining, CA, August 2020)

   null (Ed.)

   Hydropower is the largest renewable energy source for electricity generation in the world, with numerous benefits in terms of: environment protection (near-zero air pollution and climate impact), cost-effectiveness (long-term use, without significant impacts of market fluctuation), and reliability (quickly respond to surge in demand). However, the effectiveness of hydropower plants is affected by multiple factors such as reservoir capacity, rainfall, temperature and fluctuating electricity demand, and particularly their complicated relationships, which make the prediction/recommendation of station operational output a difficult challenge. In this paper, we present DeepHydro, a novel stochastic method for modeling multivariate time series (e.g., water inflow/outflow and temperature) and forecasting power generation of hydropower stations. DeepHydro captures temporal dependencies in co-evolving time series with a new conditioned latent recurrent neural networks, which not only considers the hidden states of observations but also preserves the uncertainty of latent variables. We introduce a generative network parameterized on a continuous normalizing flow to approximate the complex posterior distribution of multivariate time series data, and further use neural ordinary differential equations to estimate the continuous-time dynamics of the latent variables constituting the observable data. This allows our model to deal with the discrete observations in the context of continuous dynamic systems, while being robust to the noise. We conduct extensive experiments on real-world datasets from a large power generation company consisting of cascade hydropower stations. The experimental results demonstrate that the proposed method can effectively predict the power production and significantly outperform the possible candidate baseline approaches. 

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4. Sustainable hydropower in the 21st century

   https://doi.org/10.1073/pnas.1809426115  

   Moran, Emilio F.; Lopez, Maria Claudia; Moore, Nathan; Müller, Norbert; Hyndman, David W. (November 2018, Proceedings of the National Academy of Sciences)

   Hydropower has been the leading source of renewable energy across the world, accounting for up to 71% of this supply as of 2016. This capacity was built up in North America and Europe between 1920 and 1970 when thousands of dams were built. Big dams stopped being built in developed nations, because the best sites for dams were already developed and environmental and social concerns made the costs unacceptable. Nowadays, more dams are being removed in North America and Europe than are being built. The hydropower industry moved to building dams in the developing world and since the 1970s, began to build even larger hydropower dams along the Mekong River Basin, the Amazon River Basin, and the Congo River Basin. The same problems are being repeated: disrupting river ecology, deforestation, losing aquatic and terrestrial biodiversity, releasing substantial greenhouse gases, displacing thousands of people, and altering people’s livelihoods plus affecting the food systems, water quality, and agriculture near them. This paper studies the proliferation of large dams in developing countries and the importance of incorporating climate change into considerations of whether to build a dam along with some of the governance and compensation challenges. We also examine the overestimation of benefits and underestimation of costs along with changes that are needed to address the legitimate social and environmental concerns of people living in areas where dams are planned. Finally, we propose innovative solutions that can move hydropower toward sustainable practices together with solar, wind, and other renewable sources. 

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5. Intercomparison of Burned Area Products and Its Implication for Carbon Emission Estimations in the Amazon

   https://doi.org/10.3390/rs12233864  

   Pessôa, Ana Carolina; Anderson, Liana O.; Carvalho, Nathália S.; Campanharo, Wesley A.; Junior, Celso H.; Rosan, Thais M.; Reis, João B.; Pereira, Francisca R.; Assis, Mauro; Jacon, Aline D.; et al (December 2020, Remote Sensing)

   Carbon (C) emissions from forest fires in the Amazon during extreme droughts may correspond to more than half of the global emissions resulting from land cover changes. Despite their relevant contribution, forest fire-related C emissions are not directly accounted for within national-level inventories or carbon budgets. A fundamental condition for quantifying these emissions is to have a reliable estimation of the extent and location of land cover types affected by fires. Here, we evaluated the relative performance of four burned area products (TREES, MCD64A1 c6, GABAM, and Fire_cci v5.0), contrasting their estimates of total burned area, and their influence on the fire-related C emissions in the Amazon biome for the year 2015. In addition, we distinguished the burned areas occurring in forests from non-forest areas. The four products presented great divergence in the total burned area and, consequently, total related C emissions. Globally, the TREES product detected the largest amount of burned area (35,559 km2), and consequently it presented the largest estimate of committed carbon emission (45 Tg), followed by MCD64A1, with only 3% less burned area detected, GABAM (28,193 km2) and Fire_cci (14,924 km2). The use of Fire_cci may result in an underestimation of 29.54 ± 3.36 Tg of C emissions in relation to the TREES product. The same pattern was found for non-forest areas. Considering only forest burned areas, GABAM was the product that detected the largest area (8994 km2), followed by TREES (7985 km2), MCD64A1 (7181 km2) and Fire_cci (1745 km2). Regionally, Fire_cci detected 98% less burned area in Acre state in southwest Amazonia than TREES, and approximately 160 times less burned area in forests than GABAM. Thus, we show that global products used interchangeably on a regional scale could significantly underestimate the impacts caused by fire and, consequently, their related carbon emissions. 

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