dic Met Office, when the Grapevine tagged along with him to Reykjanes in July 2020. “My first project was to map out the gas-emitting areas around Hekla, and I don’t know how many hours I spent at this,” Baldur recalled. “Putting an instrument on the ground, waiting a minute and a half, picking it up and walking ten steps, and doing it again. But now we know where the gas-emit- ting places are. It just took 22 trips to the summit of Hekla.” Most of his job entails exactly that: laying down instruments, taking measurements, and submitting them to the general data base. “It’s a lot of repetition,” he said with a laugh. “But that’s science. These readings will probably give the same results as last week, but we’ll never know unless we try, again and again and again.” Not so quiet anymore As readers are aware, the situation is anything but boring right now. The earthquakes and possible eruption in Reykjanes have made international headlines, and many people have been deeply concerned about what this could mean. Eyjafjallajökull is still fresh in people’s minds, a volcano which erupted and began to spew a gigan- tic ash cloud into the atmosphere in March 2010, crippling air traffic across the European continent. For the record, there is no danger of that happening if an eruption happens in Reykjanes—the peninsula tends to have effusive erup- tions; mostly lava plumes but very little ash—and there are a few things we can safely predict about what an eruption in the area would look like. "The volcanic systems here on the Reykjanes peninsula, the eruptions in these systems are fissure eruptions,” Kristín Jónsdóttir, earthquake hazards coordinator at the Icelandic Met Office, told Grapevine’s Reykjavík Newscast on March 4th, the day after scientists announced an eruption was now more likely. “It's essentially cracks opening and the magma coming up. There's very little ash. The good thing about this scenario is that, what we've seen so far, is that they're far from the roads and far from the populated areas. So if we model the system of the magma flowing, it is not going to reach the populated areas and it's not going to reach the roads. As the situation is now, from our modelling, this is what we presume." "or vald ur "ór!ar son, a professor of volcanology and petrology at the University of Iceland, echoed these sentiments in a separate interview with the Grapevine, when asked how scien- tists determine just how dangerous an eruption may or may not be. "We use a lot of different tools for that,” he said. “First of all, we use geological history and our knowledge of previous events. When we look at any one area, we think in terms of worst case scenarios. When we know that, we start to think about 'OK, what measures do we need to put in place to make sure that people are safe? And what measures can we put in place in terms of response?'" "orvaldur cited the eruption of Öræfajökull, describing it as a very explosive eruption. "If you're there, you don't have any response time. So our assessment in that case is, if you suspect there's an eruption imminent, you evacuate the whole place and get everyone to safety. That's quite a dramatic and drastic measure, but that's the best we can do at the moment anyway. "In Reykjanes, it's quite different, because we know from the history of eruptions here that most of those erup- tions are fairly moderate in size, and they're mostly effusive, or lava-produc- ing, eruptions. Our main concern there is not the explosive activity but the lava flow activity. We need to know how much time we have in a lava flow crisis and that, of course, depends on where the lava comes up relative to populated areas or important infrastructure. In a nutshell, we use the worst case scenario to make sure we have the right response to ensure everyone's safety." It’s a gas Of course, lava is not the only danger that can arise from an eruption. They also release toxic gases, especially sulphur dioxide, also called SO2. "For populated areas around the region where a possible eruption could occur, we do not need to worry [about gas] in particular,” Kristín told us. “From our modelling—and again, we are using the models based on the best knowledge of what kinds of erup- tions we can expect in the area, and our knowledge from previous erup- tions—the gas we are concerned about is SO2 [sulphur dioxide]. It's not very nice. It can hurt a bit in the throat. The concentrations we can expect here will not be that dense, and also where we are farther away from the lava, it gets diluted. So the most probable scenario is that there will be days where this will be annoying. People with underlying conditions, such as asthma, will have to take care of themselves. Importantly, the Icelandic Met Office will show gas pollution forecasts. It depends on the wind. We'll just have to take it one day at a time." "For an average eruption of an average duration, the level of pollu- tion could [become] uncomfortable for people,” "orvaldur told the Grape- vine. “For a big eruption, it may reach a level where you would have to react to it and move people away from the area. Gas pollution is an issue, but how big of an issue it is really depends on the scenario, and if you have a very long lasting eruption—which we can have on the Reykjanes peninsula, we've had eruptions there that have lasted many months, years and even decades— depending on your position relative to the event, that may cause major prob- lems. Then again, the likelihood of such events happening in our lifetime is very, very small." When asked about how an eruption could affect drinking water or geother- mal energy—which relies on under- ground water heated by magma to turn turbines—Kristín also assuaged fears. "I think all the scientists are looking into this,” she said. “Right now, there isn't a great concern about this. The main drinking water does not come from this area." How can we know? Despite lurid headlines that you might see elsewhere—such as any particu- lar volcano being “overdue” for an eruption—volcano science is still in large part based on history, predictive models and best estimations. Even with all of our advanced technology, knowing when a volcano may erupt is still not exactly pinpoint accurate. How come? "orvaldur uses meteorology as a comparison. He points out that study- ing the weather began centuries ago, but that the first weather map wasn’t published until the late 19th century. This developed into weather forecasts in the 20th century, but it wasn’t until the late 20th century that we even began to be able to accurately predict, to the minute, when a storm might touch down in a particular area. "What we try to do in the field of volcanology is a similar thing; to be able to forecast eruptions,” he says. “We started trying to do that in the early years of the 20th century, so we've only been able to work on this for just over 100 years. We don't have daily observa- tions, because volcanoes are not erupt- ing daily. We get very few events that we can actually observe. We have to use remote sensing techniques, using tools that will hopefully give us information on what's happening in the Earth." It’s a bit like trying to measure the movement of clouds based on second- ary data. "Earthquakes are not property of the magma,” "orvaldur continues. “They're a consequence of a stress build up in the crust. We don't see the magma move. You can see the clouds move, and we try to do the same thing [with magma], but with far less clarity. That's one of the reasons why we haven't yet gotten to the point where we can forecast or even predict volcanic eruptions. Each erup- tion, which is basically our laboratory, 9 The Reykjavík Grapevine Issue 03— 2021 "For us, it's a very long period of time. For the volcano, it's an instant."

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