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\n <\/picture>But Castro believes the current problem is caused by climate change, which has drastically affected the rainfall in Brazil. \u201cIn eight of the last 10 years, rainfall has been below the historical average. As a result, the water levels of hydroelectric plant reservoirs have decreased, leading to greater use of thermoelectric plants,” he says. An aggravating factor, he says, is the government’s lack of environmental policy. “Priority is not given to preserving the Amazon rainforest, which has a dual environmental function: in addition to recycling CO2<\/sub> [carbon dioxide], it also generates a huge amount of moisture, which is transformed into \u2018flying rivers\u2019 that carrying rain to the Southeast.\u201d<\/p>\n Ildo Lu\u00eds Sauer head of the Center for Energy Analysis, Planning, and Development (CPLEN) at the Institute of Energy and the Environment (IEE) of the University of S\u00e3o Paulo (USP), says that the crisis the electricity sector is currently experiencing was foreseeable and argues that in addition to circumstantial problems\u2014such as a lack of rain\u2014the sector has suffered for many years from structural deficiencies, dating back to reforms in the 1990s by the Fernando Henrique Cardoso administration (1995\u20132002), which began privatizing electricity companies, and in the following years by the governments of Luiz In\u00e1cio Lula da Silva (2003\u20132010) and Dilma Rousseff (2011\u20132016), when legislative changes were made.<\/p>\n \u201cThe instability we are seeing in the electricity sector has lasted for over two and a half decades. The big mistake behind the current electricity crisis in Brazil is in how the sector was planned and how it is being run. In efforts to expand the system and ensure its safety, we have been using the wrong types of plants in recent years, from a technical and economic standpoint. I’m talking about thermoelectric plants powered by fossil fuels, such as coal, oil, and natural gas. The right choice would have been to use more wind and solar power plants,\u201d says Sauer, who was gas and energy director at Petrobras between 2003 and 2007 and has written several articles on the energy sector, the most recent on the potential of solar and wind energy in the country, which was coauthored by Nilton Amado and Erick Pelegia, also from the IEE.<\/p>\n Fabio Colombini<\/span><\/a> Tr\u00eas Irm\u00e3os Hydroelectric Power Plant, located in the Tiet\u00ea River basin in Pereira Barreto, S\u00e3o Paulo StateFabio Colombini<\/span><\/p><\/div>\n According to Sauer’s calculations, Brazil spent approximately R$110 billion on fossil fuels for thermal power plants between 2008 and the last electricity crisis in 2015. \u201cWith this money, we could have built wind power plants with a capacity of 30 gigawatts [the current national wind energy capacity is 20 GW]. The issue is that Brazil made bad choices and gave contracts to unsuitable plants. Thus, the crisis reappears in periods of weak economic activity, like now.\u201d He also argues that the approach to planning and offering energy contracts should take into account hydrological changes. “The problem is not nature, but the organization and management of the national electricity system.”<\/p>\n There are around 3,200 thermoelectric power stations in Brazil, with a total capacity of 44 GW. Sixty-six percent of them run on fossil fuels\u2014the remaining 34% use biomass or nuclear power. \u201cThermal plants are a highly flexible source because you can bring them into operation very quickly. They function well as a backup,\u201d says Maur\u00edcio Uriona Maldonado, from the Department of Production and Systems Engineering at the Federal University of Santa Catarina (UFSC). The total capacity of thermal sources has grown substantially since the energy crisis in 2001, when it was 10.4 GW, just 25% of the current value.<\/p>\n The problem is that these plants burn fossil fuels, mainly coal and oil, releasing greenhouse gases into the atmosphere, which contribute to global warming. Costs are also high: around R$1,600 per megawatt-hour (MWh) compared to less than R$200 for hydroelectric plants. To cover this expense, the government has had to raise electricity prices, instituting a special \u201cwater shortage\u201d tariff. Expected to remain in effect until April 2022, it adds an extra R$14.20 for every 100 kilowatt-hours (kWh) consumed, 50% more than the previously most expensive tariff.<\/p>\n Andr\u00e9 Lu\u00eds da Silva Leite, an expert in regulation and competition in the electricity sector from the Department of Administrative Sciences at UFSC, says another mistake made by the authorities was their failure to oversee the so-called physical guarantee of hydroelectric plants, which represents their maximum generation capacity in the face of certain risks. The risk in this case is the reduced volume of the rivers where the plants are located.<\/p>\n \u201cWhen the physical guarantee isn\u2019t up-to-date, the energy provided by water sources is lower than expected,\u201d he explains. According to Leite, hydroelectric plants nationwide generate an average of approximately 70% of their physical guarantee. \u201cWhile the 2001 blackout was caused by a poorly formed market with incomplete regulations that was unable to attract the investment needed to increase capacity, the 2021 crisis is a result of bad management of the entire system,\u201d he stresses.<\/p>\n In an article published in the journal New Economy <\/em>in July 2001, Jo\u00e3o Lizardo de Ara\u00fajo, from UFRJ’s Institute of Economics, analyzed the reforms that began in the previous decade and warned of the energy crisis to come. \u201cA lack of financial resources led to delays and suspensions of energy generation and transmission expansion projects. Consumption, on the other hand, increased as the economy grew and continued to increase even when the economy stagnated, as more and more people gained access to electricity,\u201d pointed out the researcher.<\/p>\n Daniel Ramalho \/ AFP via Getty Images<\/span><\/a> Angra 3: nuclear power plant, which has been under construction for decades, is projected to offer 1.4 GW of powerDaniel Ramalho \/ AFP via Getty Images<\/span><\/p><\/div>\n In a 2003 study on the energy crisis of the same period, Jos\u00e9 Goldemberg and Luiz Tadeu Siqueira Prado from USP\u2019s Polytechnic School also examined the reforms. \u201cThe government was not able to implement an adequate regulatory environment nor a reliable free market in the MAE [Wholesale Electricity Market], but it was able to paralyze the management activities of Eletrobr\u00e1s, leaving the system without a head,\u201d they wrote. The authors conclude that this led to the vast majority of electricity companies running up huge debts and requiring public money not to go bankrupt.<\/p>\n To overcome the crisis, the general understanding is that diversification of the national power generation mix needs to be accelerated, prioritizing renewable sources (see article on page 36<\/em>). \u201cEmerging energy sources, especially solar and wind, are on the rise and everything indicates that they will dominate the energy sector in the future,\u201d says Ana Fl\u00e1via Nogueira, a chemist from the Institute of Chemistry at the University of Campinas (UNICAMP) and director of the Center for Innovation in New Energies (CINE), an Engineering Research Center (CPE) formed by FAPESP and Shell that unites researchers from UNICAMP, USP, and the Institute for Energy and Nuclear Research (IPEN). “In this regard, Brazil is in a comfortable position, since it has an abundance of sun and wind, especially in the northeast.”<\/p>\n One problem with these sources, however, is that they are intermittent\u2014the amount of energy generated on a given day varies, with wind farms depending on the occurrence of wind and solar plants on the presence of solar radiation. This variance can affect the energy distribution and transmission network. According to Nogueira, the problem can be solved by installing stationary batteries at solar and wind farms to store the energy they produce, allowing them to supply electricity to the SIN at a steadier pace.<\/p>\n One of CINE’s lines of research is the development of efficient storage systems for wind and solar power stations. Researchers are striving to reduce the cost and increase the storage capacity of these batteries. \u201cLarge systems are increasingly being used to store the additional energy generated by solar or wind farms, but they are expensive,\u201d highlights Ricardo R\u00fcther, a metallurgical and materials engineer and head of the Photovoltaic Laboratory at UFSC.<\/p>\n According to the 2030 10-Year Energy Expansion Plan (PDE) written by the Brazilian Energy Research Company (EPE), which provides services to the MME, the share of renewable sources in the Brazilian power generation mix was 84.8% last year, slightly higher than in 2019 (see <\/em>Pesquisa FAPESP issue n\u00ba 297<\/em><\/a>). Among renewable energies, hydropower was top, followed by wind, biomass, and then solar. Fossil sources accounted for about 13% and nuclear energy for just over 1% (see infographic<\/em>). A country\u2019s power generation mix is the range of sources used to generate electricity and is part of the energy mix, which also includes other sources, such as fuels for cars, buses, and trucks (gasoline, diesel, ethanol, etc.) and for cooking food (firewood).<\/p>\n<\/div>![\"\"](\"https:\/\/revistapesquisa.fapesp.br\/wp-content\/uploads\/2022\/01\/030-039_capa-energia_310-2-1140.jpg\")
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\n– The power of renewables<\/a>
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Above average rainfall in October and November\u2014the beginning of the rainy season\u2014brought some relief but did not completely resolve the problem. “Projections for the end of November [after this issue goes to print] estimate that reservoir volumes in the South and Southeast\/Midwest subsystems will reach 53.4% and 21.3% of capacity, respectively,”\u00a0 Luiz Carlos Ciocchi, general director of Brazil\u2019s National Electricity System Operator (ONS), responsible for operating, overseeing, and managing electricity generation in the country, told Pesquisa FAPESP<\/em>.<\/p>\n The MME estimates that dams in the Southeast\/Midwest will reach 38% capacity in April 2022 if this year\u2019s rainfall matches the volume of the 2020\/2021 rainy season\u2014if reservoir levels fail to surpass around 30% by then, the authorities will be on alert. “We are paying close attention and will continue to monitor the indicators so that we can adopt any measures needed to meet the demands of the SIN [National Interconnected System].” The SIN is the country’s electricity production and transmission network.<\/p>\n According to Christiano Vieira, electricity secretary at the MME, measures were implemented in October 2020 to ensure enough electricity is generated and supplied this year and next. \u201cThermoelectric production was maximized during the 2021 dry period [May to October] to preserve water levels in the system\u2019s main reservoirs.\u201d<\/p>\n Researchers and electricity sector experts interviewed by Pesquisa<\/em> FAPESP<\/em> both recognize the challenges faced by the sector, which is highly dependent on water sources, but their opinions differ on the root causes. \u201cThe 2001 crisis taught us some very important lessons. That year, 90% of our power generation mix was hydroelectric plants, today it is around 62%, and within ten years it will be 58%,\u201d says economist Nivalde de Castro, general coordinator of the Electricity Sector Studies Group (GESEL) at the Federal University of Rio de Janeiro (UFRJ).<\/p>\n![](\"\/wp-content\/uploads\/2022\/02\/030-035_capa-energia-0-desktop-1.png\")
\n <\/picture>Alexandre Affonso<\/span>\n