Even on the eve of the debate, the discussion on the popular initiative “Electricity for Everyone, All the Time (Stop the Blackouts)” under consideration by the National Council promised to be heated, with nearly a hundred interventions by parliamentarians. The discussions in Bern will continue next Monday, when we will learn the direction Parliament intends to take regarding the future of nuclear energy in Switzerland.
The topic is highly topical, and to help us understand the current state of this much-discussed energy source, we are turning to Maurizio Barbato, Full Professor of Thermodynamics, Fluid Dynamics, and Energy Systems. Barbato, director of the Institute of Mechanical Engineering and Materials Technology at SUPSI, will be among the speakers at the public event "Nuclear. Photovoltaic. What Future for Energy?", to be held at the Asilo Ciani on June 18.
What is the current state of nuclear power plants in Switzerland?
“There are three nuclear power plants and four reactors in Switzerland: Leibstadt, which began commercial operation in 1984; Gösgen, in 1979; and Beznau 1 and 2. Beznau is home to the world’s oldest operating reactor: the first unit went into service in 1969. The safety status of Swiss plants is considered good, thanks in part to regular maintenance and ongoing upgrades. In nuclear power, what matters most is the actual condition of the components, inspections, investments in safety, and the regulatory authority’s ability to impose conditions on plant operations.
Regular maintenance and the presence of independent bodies that verify the condition of the plants and, if necessary, impose restrictions on their operation are fundamental requirements for this technology. From this perspective, we can say that the regulatory system in Switzerland is robust.”
(An aerial view of the Gösgen power plant, 1984. Source: ETH Library Zurich, Image Archive)
How long does it take, both in theory and in practice, to build a nuclear power plant from scratch?
“If we were to limit ourselves to the engineering work, it would technically be possible to build and connect a new plant to the grid in 5–7 years. In China, plants have been built within this timeframe. The reality in Europe, however, is different. From the moment the decision is made to build a new plant, one must factor in a timeframe exceeding 10 years: there is the design phase, the selection of the site, gaining public acceptance, the entire bureaucratic process, and any potential opposition or appeals.
One aspect must also be emphasized: nuclear power plants cannot be viewed merely as facilities for electricity generation. They are infrastructures designed to last for many decades, even between 60 and 80 years. Precisely for this reason, they require long-term planning. In Western countries, the total time required to build them often ranges between 10 and 15 years, and the most recent European examples, such as Flamanville in France and Olkiluoto in Finland, have taken even longer.”
(Construction work on the Gösgen nuclear power plant, 1974. Source: ETH Library Zurich, Image Archive)
To address the current challenges of the energy transition, which solution makes the most technical sense: building new power plants or continuing to operate existing ones, as indicated in a recent report by the Federal Council?
“The most sensible policy is to keep existing power plants running. Countries that shut them down in a hurry likely acted on gut instinct, without much foresight. If we have sound facilities, let’s keep them running, provided they are constantly monitored and upgraded.
Talking about new construction today means looking ahead to at least 2040. And in the meantime, what do we do? Gösgen and Leibstadt can still have a long life ahead of them; Beznau is a bit older, but even in that case, we can determine how long it can operate. In my opinion, at this stage, if properly monitored, the current power plants can help us with the energy transition.”
(The reactor pressure vessel at the Leibstadt Nuclear Power Plant, 1984. Source: ETH Library Zurich, Image Archive)
People often refer to “third-generation-plus” nuclear power: what does that mean, and what examples do we have in Europe?
“Third-generation nuclear power is an evolution of earlier reactors. The technology remains based on fission, but compared to the second generation, significant progress has been made in safety, the standardization of certain components, and the plants’ ability to respond even under critical conditions.
The third-generation-plus further strengthens these aspects. The goal is to reduce reliance on human intervention in emergency situations as much as possible and to increase the plant’s ability to contain any accidents.
In Europe, the best-known examples are Flamanville, in France, and Olkiluoto, in Finland. Both are EPRs, or European Pressurized Reactors. These plants have two separate circuits: one connected to the reactor core and one where heat is converted into steam to produce mechanical energy and then electricity.
These projects clearly demonstrate both the potential and the challenges of the new European nuclear sector. On the one hand, they offer high safety standards; on the other, they have required many years of design, construction, and commissioning, partly because they are complex plants and, in some respects, new to the European industrial sector.
There are other examples of advanced reactors in Russia and China as well, all sharing the goal of making systems safer and more standardized.”
(The Olkiluoto nuclear power plant, which houses a third-generation-plus reactor. Source: Wikimedia Commons)
There is also talk of fourth-generation nuclear power. What are its characteristics, and how far along are we in its deployment?
“The term ‘fourth generation’ refers to a family of technologies still in the development, demonstration, or prototype phase. It does not encompass a single type of reactor. For example, there are liquid-metal-cooled reactors using sodium or lead, gas-cooled reactors, molten-salt reactors, and supercritical-water reactors, all of which share, among other things, very high operating temperatures.
The idea is to have more efficient plants capable of using fuel more effectively and, in some cases, reducing some of the most problematic radioactive waste. This does not, however, mean eliminating waste entirely: the issue of radioactive waste management would still remain.
One of the most interesting aspects concerns temperatures. Fourth-generation reactors, operating at higher temperatures than current power plants, would not only allow for more efficient electricity production but also provide heat for industrial uses, such as chemical processes and hydrogen production.
At the moment, however, we are still far from large-scale commercial deployment. Some projects could reach the industrial demonstration phase in the coming years, but it would be premature to speak of true commercialization before the mid-2030s.”
(Control room at the Beznau power plant, photographed with a fisheye lens, 1969. Source: ETH Library Zurich, Image Archive)
Nuclear power does not produce greenhouse gases, but the issue of radioactive waste is a significant concern. What solutions are in place in Switzerland for managing this waste, and has a permanent solution been found?
“In Switzerland today, there is the Zwilag interim storage facility in the canton of Aargau. It is used to store spent fuel and radioactive waste of various categories, originating from nuclear power plants as well as from medicine, industry, and research. It is a temporary solution, pending the development of a deep geological repository.
NAGRA, the company tasked with identifying a suitable location, has proposed the Nördlich Lägern site in northern Switzerland. The permitting process is still underway, and the final decision will also involve political approval, with the possibility of a referendum.
Internationally, the most advanced project is Onkalo in Finland. It is a deep geological repository designed to isolate spent fuel for extremely long periods. The containers are placed at a depth of over 400 meters, within a stable rock formation, with multiple protective barriers: the metal container, bentonite clay, and the rock itself.”
Public event on the country’s energy future
Nuclear energy is one of the potential building blocks of the energy transition, the future of which remains to be seen. Nuclear power is intertwined with renewables, energy sources that will in turn require upgrades to the grid. We will discuss these and other topics on Thursday, June 18, in Lugano, alongside four experts.
The event is free. For organizational purposes, we ask that you register at this link.