22 The Reykjavík Grapevine Issue 7 — 2011 Which country starting with the letter ‘I’ has caused the most international havoc due to volcanic eruptions in the modern age? As you may have surmised, this is indeed a trick question, for the answer is not Iceland, but Indonesia. In 1816, when Europe and North America were just starting to recover from the Napo- leonic Wars (the US and Canada, not to be outdone by the Europeans, had also taken part and fought each other), both continents suffered through natural disasters which very much resembled a nuclear winter. This was not due to a revenge-bent Bonaparte smuggling some sort of steam driven dirty bomb out of St. Helen, but rather because of a volcanic eruption on the other side of the world. The year before, Mount Tambora went off on the island of Sumbawa in what is now Indonesia, the biggest vol- canic eruption for 1300 years, with the result that 1816 became known as the “Year Without Summer”. Temperatures went down and harvests failed in the biggest famine of the century. The Irish suffered greatly as usual during disas- ters, and even the peaceful Swiss ex- perienced riots on an unheard of scale. It is estimated that 200.000 people died as a result in Europe alone. In North America, people fled their initial settle- ments close to the coast and moved inland. VOLCANOES AND BICYCLES The eruption has several other unfore- seen consequences. Since there was no hay to feed the horses, a German by the name of Karl Drais invented the precursor to the modern bicycle. The Americans were equally inven- tive, and one of the volcanic refugees from Vermont, Joseph Smith, came up with Mormonism during his trip west. Equally spectacularly, in Switzerland, a girl named Mary Shelley was forced to stay indoors with some of her friends and wrote Frankenstein, the first mod- ern horror novel. However, the volcanoes of Indone- sia had not had their last say. In 1883, the island of Krakatoa exploded, creat- ing the loudest noise in modern history (sorry to all you Manowar fans). The blast was heard all the way to Australia, and the event caused tem- peratures to drop all over the world, not recovering fully until five years later. At least 40.000 people are said to have died as a result, although some esti- mates put the figure at three times as high. VOLCANOES AND REVOLUTIONS If an Indonesian volcano created a postscript to the Napoleonic Wars, an Icelandic one may well have been its preface. In 1783-84, Lakagígar (Laki), close to the village of Kirkjubær, erupt- ed for a whole eight months. The result has gone down in Icelandic history as the ‘Mist Hardships’, due to the sun be- ing blocked from the sky. Half of all live- stock and a quarter of the population died. The Danes even thought about moving the remaining population to Jutland, out of harm’s way, and on some days you kind of wish they had. But they didn't, which is why we are still here to worry about volcanoes. The repercussions of the ‘Mist Hardships’ reached far outside of Ice- land. It led to famine as far away as Japan and about a sixth of Egypt's pop- ulation died. The total death toll is esti- mated to be around six million, making it the deadliest eruption on record. The greatest historical consequences, how- ever, were to be found in France. The poor harvests in the years after 1784 led to increasing discontent and may have been a significant contribution to the Great Revolution of 1789 breaking out. Even this might not be Iceland's most historic eruption, however, for some scholars believe that the Hekla eruption of ca. 1000 BC and the resul- tant fallout contributed to the general decline in Bronze Age cultures of the time, not least in Ancient Egypt. Add to this the spot of bother airlines have been having for the past two years, and it really seems that Iceland might be the most dangerous earthquake island. Then again, others think that the Lake Toba eruption in Indonesia about 70.000 years ago left only around 10.000 human beings alive. Not even our President, quite given to doomsday predictions, would prophesise an Ice- landic volcano doing this. Volcanology? That’s from Star Trek, right? By James Ashworth | Photo by Anna Andersen Killer Volcanoes: A Comparative History By Valur Gunnarsson | Photo by Anna Andersen Sigh. If I had a penny for every time someone has made that joke when I tell them I study ‘volcanology’ (or worst still, ‘vulcanology’) then Iceland would not be in debt right now. And neither would I. So allow me a few minutes, if you will, to persuade you that yes, vol- canology is a real science and no, it’s nothing to do with pointy-eared sci- ence fiction characters! WHO STARTED STUDYING THESE THINGS? The beginnings of volcanology as a science can perhaps be traced back thousands of years. Back in 79 AD, Pliny the Elder recorded the series of events leading up to the huge erup- tion of Italy’s Mt. Vesuvius, which of course famously decimated the Roman town of Pompeii. His nephew, Pliny the Younger, took over after his uncle died from gas inhalation. Their letters are considered so important to the field of volcanology as a whole that they have a major type of eruption named after them—so-called Plinian events. In the following centuries little advance was made due largely to re- ligious beliefs, but some important observations were made such as the first recording of a pyroclastic flow (a fast-moving flow of hot gases, ash and rock most commonly generated by ex- plosive eruptions or collapse of certain features). However, it would not be until perhaps the mid-20th century when the science of volcanology would really be- gin to take off. THE BEGINNING OF THE BEGINNING The first major building block came in the form of Plate Tectonic theory, which gathered large-scale acceptance with- in the scientific community during the 1960s. This divided the Earth’s crust into many large ‘plates’ that drifted about on the surface, presumably driv- en by forces within the Earth. New crust was created along some edges and old crust was pulled (subducted) down into the Earth along others. In some areas two plates simply slid past each other. These three types of ‘plate boundary’ explained many types of geophysical and geological activity including earth- quakes of different kinds, mountain for- mation and of course volcanology. As the science grew, more detailed explanations began to arise as to why certain volcanoes developed at certain places. Explosive volcanoes were often constrained to areas where subduction was taking place, whereas volcanoes producing more fluid lavas and spec- tacular fire fountains were often found on or near boundaries where new plate was being constructed. However, there was still one great riddle—why were some volcanoes right in the middle of plates? IS IT HOT (SPOT) IN HERE, OR…? An explanation for these isolated volca- noes was proposed in 1963 but it was not until some years later, following the general acceptance of Plate Tec- tonic theory, that more detail was put in place. The general idea was that there was a ‘hot spot’ on the Earth’s surface, for whatever reason, which was causing melting where there shouldn’t be any and therefore triggering volcanism. In fact, coupled with plate tectonics, it ap- peared that the hot spot was not fixed to the plates—rather, their origin was somewhat deeper. As the plates moved on the surface, the hot spot remaining in one location, creating a chain of vol- canoes on the overlying plate. Perhaps the most famous example of this is the Hawaiian Islands, lying right in the mid- dle of the Pacific Ocean—far from any plate boundary—but there are many others worldwide. In fact, this hot spot theory can be used to explain much of the volcanism in Iceland, too. Here the hot spot lies almost directly beneath a constructive plate boundary, so rather than creating an isolated area of volcanism it instead supplements the activity already going on along the ocean ridge. BUT WHY DO THESE HOT SPOTS ExIST? Truthfully, we don’t really know. There are many theories, one of which is generally far more convincing than the rest. The generally accepted proposal is for ‘mantle plumes’—rising columns of hot material within the Earth’s mantle (the layer beneath the crust). But there is still a lot of argument as to why exactly they are there and even where they originate. Some believe they begin near to the Earth’s core while others believe they are much shallower. Further work is needed to answer these questions and that work will itself surely raise more questions than it answers—the ongoing cycle of scientific research continuing as ever! BUT WE REALLY KNOW A LOT NOW, RIGHT? Well, we certainly know a lot more than we did 50 years ago. However, we just keep figuring out new things. Stuff that was practically taken as being scientific fact some decades ago is now proven to be wrong. For example, when Mt. St. Helens blew up so spectacularly in May 1980, collapsing and blowing out a whole side of the mountain, we thought that was an isolated incident. But the more we look at other volcanoes world- wide, the more we see that this is actu- ally a relatively common event. Far from being of interest to just the scientific community, such advance- ments in the science can actually bring huge benefits to the general public, too. As we learn to better understand volcanoes we also learn to better pre- pare for eruptions and to guess at what they may do in the future. Indeed the science of volcano forecasting and prediction is a rapidly advancing one and I feel privileged to be able to work within that field. From next year I hope to be working on Sakurajima volcano in southern Japan, where some stunning science is being done—they have even developed a system that can predict regular eruptions with a good degree of accuracy. This is something we would never have dreamed about some years ago! The science of volcanology is an imperfect one. Volcanoes can never be perfectly predicted or fully under- stood, but we can try. And try we must, because with a growing global popu- lation, more and more people will be exposed to the hazards associated with volcanoes. Now, more than ever, volca- nology is truly at the forefront of pro- tecting the public in many countries— something many Icelanders will be all too familiar with. James Ashworth is our resident volcanologist, and he also writes some great copy! Here's to James, and science! Car provided for our trip to the volcano eruption was provide by Cheap Jeep. You can book cars at www. cheapjeep.is or call +354-5626555.

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