A repost from the archives, with minor updates
Uturunca, in Bolivia, has risen by 50cm over the past 20 year.
When the ground starts to rise beneath your feet, it is time to sit up. Fishermen would be the first to notice, being unable to leave their harbours due to lack of sea. Governments would discuss the risk of reduction in tax income from fishing, and would commission research. The scientists report evidence of widespread withdrawal of the sea but their findings leave some uncertainty and they need more funding. An intergovernmental Panel of Ground Change (IPGC) is set up, and their first report, issued after 20 years, proposes that ground changes should be limited to two meters; it leads to animated and emotional discussions. A strong rebuttal is published in the Daily Mail and Fox News which report that no change in sea level is seen in Paris, Texas, an unchanging 300 miles from the sea, and can we now stop this nonsense? The next day the Daily Mail in a lapse of memory reports that scientists have found that rising ground cures cancer. The Financial Times writes that the inflation is creating free land which can be sold for profit and save the hapless banks. The Washington Post reports that the President seems out of touch and is unaware of the danger of the ground getting too close to the Sun and burning up. The Sun runs the headlines ‘Sun saves our bacon’ and ‘The Sun has won’. The Department of Homeland Security claims that there is no evidence that the land is rising but that the sea may be going down; it demands funding to build a wall to keep out the falling sea. The Canadian government orders all scientists to cease talking about ground level change, or, preferably, stop talking altogether. The Dutch are delighted; they also renew their historical claim on England. The Solid Earth Society puts out a press release which no one reads. And in the mean time, no one wonders what is pushing up the ground.
In the real world, some towns do have to cope with changing ground levels. Naples is best known for this: the submerged Roman city of Baiae, once the Panama City Beach of its days, is now a diving destination and underwater archaeological park as much as 12 meter below the sea; but nearby is evidence of clams having grown on pillars which are now 6 meter above the sea. Not many modern seaside towns could cope with those kind of ups and downs!
Inflating ground is a well-known precursor of volcanic activity. It may be caused by a growing magma chamber, or by circulating water; one may expect the former to lead to an eruption, and the latter to a phreatic explosion. Often such expectations are correct. Basaltic volcanoes especially inflate before erupting. But volcanoes often show inflation without a subsequent eruption. The magma may fail to reach some critical pressure, or a dyke is stopped in its tracks. And sometimes a volcano erupts without any inflationary sign. Turning inflation into a sure-sign prediction of a specific eruption date (or even eruption decade) is still beyond us.
This post is about inflation and the causes of inflation, and at the end describes some volcanoes which are inflation hot spots. It is a bit longer than the average VC post – you may want to get yourself a coffee first.
Uplift and rebound
That shifting ground underneath you may not be volcanic. The most dramatic long-term uplift is a memory from the ice age. Rock is strong – but 2 kilometer of ice is heavy, and the rock, and especially the more fluid mantle underneath, had difficulty accommodating the weight of those enormous ice sheets that covered the frozen north. The mantle, essentially hot sand, is not as stiff as the lithosphere above it, and gives away first. The ice pushes down, and the mantle slowly moves sideways (not down: sand doesn’t compress much). As if on treacle, the ground slowly sinks, until a new equilibrium is achieved when it has gone down by a third of the thickness of the oppressive ice sheet. Indeed, parts of Antartica but also Greenland have been pushed below sea level by the immense weight of the ice.
Raised beaches due to glacial rebound, in Nunavut, Canada.
Once the ice sheets melt, the mantle and the ground rebound. But anything that involves the mantle is slow; it takes many thousands of years before the memory of the ice age has been completely erased. North Scandinavia is still rebounding from the last ice age, even after 10,000 year. There are ancient beaches -and harbours- now well above the water line. In Gotland, Sweden, the uplift is still about 2 mm per year. It was much faster immediately after the ice age, of course. The ground here became depressed by 300 meter, and the uplift has so far recovered 270 meter. 30 meter is still to come.
On the other side of the Atlantic, the Hudson Bay is the remnant of the depression left by the Canadian ice cap. The ice cap was 2 km thick. At the centre of the ice cap, the ground was depressed by 700 meters. Much of this has been recovered, but not all. The Hudson Bay is still 270 meter deep at its deepest point; the average is around 100 meter. But getting less.
Depressing volcanoes
This weight effect can also affect volcanoes. A kilometers-tall mountain depresses the ground on which it rests. A volcano is a lot less heavy than an ice sheet and therefore the weight can be carried by the lithosphere: it doesn’t reach the mantle. The lithosphere is stiff and can carry a bit of extra weight, so at first the volcanoes don’t depress the crust, even as they grow. But once they get huge, the lithosphere does give way. Mauna Loa, the world’s largest volcano, is sinking by 2cm per year as the underlying lithosphere adjusts to the weight of the mountain. (But the lava flows on top make Mauna Loa grow at the same rate, so the net effect is no change.)
Now assume that Mauna Loa has just exploded, and the explosion has removed tens of cubic kilometers of rock. (Don’t worry: this is an experiment in imagination. Mauna Loa is completely safe.) What happens to the ground below? Suddenly the weight is gone. And the lithosphere rises in response. But in practice, this is exceedingly slow. The lithosphere is stiffer than the mantle, and adjusts even slower. 10,000 year is nothing to it. If Mauna Loa were to lose 1 kilometer of its height, the recovery from the depressed ground would be no faster than 1 mm per year. So even after extreme eruptions, this can be ignored. Sudden weight loss does not change your height – at first. Still, in the end gravity always wins. Mauna Loa is destined to sink below the sea, even if it will take a few million years. It is like a slightly slow version of the Titanic.
Resurgent domes
Resurgent calderas. From http://www.geology.sdsu.edu/how_volcanoes_work/Calderas.html
But in reality, large volcanoes can show quite a bit of reflation after a caldera-forming eruption. So if this is not the lithosphere re-adjusting, what is it? As always with volcanoes, it is the magma. (A good line to win any debate: “It is the magma, stupid”.) After the explosion/eruption, there is less weight pressing down on the magma reservoir. Less pressure means that the melting temperature drops a bit, and this allows more melt. The newly melted magma rises, and creates a new magma chamber underneath the caldera. It may slowly re-solidify there. The final result is a large bulge in the centre of the caldera, pushed up by this risen decompression magma; the bulge is called a resurgent dome.
A good example is the huge Toba caldera. It is filled with an enormous lake, and the lake is filled with a large central island. This island is the resurgent dome. There are three resurgent calderas in the US, namely Yellowstone, Long Valley, and Valles Caldera. The resurgence can be very large. Toba resurged by well over a kilometer. But it is also rather slow (although not as slow as gravity): the resurgence may take 10,000 year or longer. After its stupendous eruption (the largest for the past million year), Toba resurged by 10 cm per year; this lasted many millennia.
The Long Valley caldera. The 500-meter tall hill in the centre is the resurgent dome.
Although the resurgent dome may erupt, often it doesn’t: in itself, the resurgence is an afterthought from the original explosion, and not a sign of an impending new eruption. Resurgence is comparatively safe, as volcanoes go; it takes so long that the magma has time to solidify in its new place. So when large, long-term inflation inside an old caldera is seen, it tends to be identified as a resurgent dome: this model works, can explain the observed changes, and there is no need to panic. What more could you want?
Inflation in volcanoes
But non-resurgent volcanoes also show uplift. This happens when magma is accumulating, and it is a warning sign for a potential eruption. The basic model for the uplift was devised by a Japanese seismologist called Mogi, and with all the creativity of scientific language, is called the Mogi model. It assumes a spherical magma chamber, with a certain diameter and pressure, located at a depth below the surface which is much larger than its diameter. This round blob pushes up the surface over an area beyond its own diameter.
The Mogi source model for uplift from a magma chamber
The size and shape of the uplifted bulge depends on the volume of the magma chamber, the pressure, and the strength of the rock, all of which are approximately known. There are equations where you plug in the measured surface motion, in three directions, and out comes the depth and size of the magma chamber. It involves a few questionable assumptions: magma chambers are probably not round, and they may be closer to the surface than the equation wants, but in the right circumstances the model has worked well enough. (Rumour has it that the mathematics of horse racing, developed for the gambling industry, began with the sentence ‘Let’s assume a spherical horse..’) (Mogi himself wrote It is the writer’s opinion that the assumed spherical origin seems to harmonize well with the idea of the magma reservoir under the earth’s surface.) There is however an obvious problem. It begs the question how did the new magma get there? Magic? Did Scotty beam it down (or up)? Or did it achieve reality as an ‘alternative fact’? None of this seems quite compatible with physics, geology, or even volcanology. Either the magma migrated from elsewhere, or it formed in situ from newly melted rock. If it migrated, the observed inflation will be compensated by deflation somewhere else.
New melt will often start with an impulse of heat from below, perhaps carried up by magma rising from the deep. The heat seeps into the existing magma chamber, and causes more rock to melt, enlarging the chamber or increasing the melt fraction. Magma has a lower density than the rock it forms from: the magma expands. It is the pressure from this expansion that causes the rock above to rise, to accommodate the increased volume. At the same time the growing magma flows upward through any cracks in the rock it finds, carrying the heat with it. The speed of the rise depends on the size of the cracks. For a typical size of 2 mm, the ‘speed’ is somewhere around 1 meter per year. It beats Continental drift, but not much else. Enlarge the cracks or break the rock with a well-timed earthquake, and it can go much faster. As the magma rises, the inflation becomes more focussed on the area directly above the chamber. Whilst it was deeper, it pushed up a larger area. This gives the funny effect that as the magma rises, some distance away the inflation turns to deflation, while in the centre it increases. Think sombrero.
The new heat can also affect any water inside the volcano. Hot water can circulate much faster than magma, and this can therefore cause fast inflation when the water enters new areas. Large, intermittent variations inside a caldera are often due to circulating hot water. Gases should also not be ignored: underground volatiles can add tremendous pressure. An earthquake may rupture an underground layer or rock, allowing gas underneath to escape, and cause sudden deflation. Or shake the magma, allow volatiles to come out, and up goes the mountain. In volcanoes, nothing is simple.
So there are at least three ways a volcano can inflate: resurgence, a magma/heat pulse (with or without volatiles), or hydrothermal circulation. How can you tell which one is happening in your favourite volcano? That is not so easy! The only reliable way to see underground is to wait for an eruption and analyse what comes out: new magma, recycled and reheated magma, gas, and/or water. Obviously, that only works if there is an eruption. Non-erupting volcanoes are the bane of volcanology.
Volcanoes in inflation
Let’s look at some real-world examples inflation, a round-up of the usual suspects.
Nowadays, measuring inflation is fairly easy, using GPS or radar. But those only go back a few decades. How do you determine inflation which predates GPS? Actually, just as in glacial rebound: it is best seen at the coast, from historic water lines, like the dirt rims in an empty bath tub. The known cases of prehistoric inflation are indeed all at sea (or at least at water). The following are the best known, and largest, cases.
Siwi caldera, Vanuatu
Siwi caldera and its resurging block. Source: Brothelande 2016, Journal of Volcanology and Geothermal Research
At the southern end of the 1200 km long Vanuatu volcanic arc lies Tanna Island, a land of rain forests, beautiful beaches, and coffee plantations – my kind of paradise. Lonely Planet calls it ‘an extraordinary place‘ with ‘the world’s most accessible active volcano‘. The volcano in question is Yasur, an 800-year old dome which is indeed the most active volcano in Vanuatu – and that says something. it is an open-vent volcano, in effect continuously active. The Yasur cone is located inside a 2-km wide caldera. An eruption some 20,000 year ago (not well dated) formed this much larger Siwi caldera; Yasur lies on the rim of this caldera. Within the ancient caldera is the Yenkahe block, 6 by 3 kilometer wide and 250 meter high. The block contains a series of coral terraces, all well above the sea level. Coral does not form on dry land, or even in the wetness of a rain forest: clearly much of this block was once below the sea, and it came up step-wise. The dates of the terraces show that the area has been rising for a period of 1000 year or more, at a rate of 16 cm per year, by more than 150 meter overall. The inflation rate is the second largest known in the world over such a long period. In 1878, a series of earthquakes caused major inflation at the local harbour, Port Resolution. There were three major earthquakes over 8 months, together raising the port by 15 meters and raising the bottom of the harbour to above sea level. One of these events also caused a 12-meter high tsunami. Even Naples would be impressed. And perhaps even worried.
Naturally, this inflation occurring on a horst inside a caldera, it is called a resurgent dome. But it wasn’t a massive caldera eruption (1-2 km3), and it is an area of very active volcanism – there is plenty of new magma sloshing around. It has been proposed that the magma chamber underneath Yasur may be migrating east, pushing up Yenkahe in the process.
There are no obvious signs of an impending eruption. In fact, Yasur’s open vent provides a safety valve, and this would limit the pressure which can build up. But there is another danger. The area is prone to landslides, and the continuing uplift can destabilize the slope. There is a risk that a large landslide would enter the sea, and the resulting tsunami, modeled as up to 4-5 meter high, would put some of the tourist areas at risk. The 1878 events indicates this is not a remote risk, but the dense rain forest makes it difficult to assess the stability of the slope.
Iwo Jima (Io To)
Source: Kenneth R.LaJoie, Coastal Tectonics
What can I say? This is the most extreme, but also least understood, currently on-going long-term uplift. The island, 4 by 8 km long, is famous as a war shrine. In the US, it will always be known as Iwo Jima, but in Japan, an older name (with the same spelling) has been re-instated: Io To. The different names call out a common heritage, a memory to be kept alive in order to prevent a future madness. Painful memories have turned into a common purpose, and made friends out of sworn enemies of the past. But there is also a volcanic heritage here: there is much more island now than there used to be. Iwo Jima is coming up at an average rate of 25 cm per year, and appears to have done this for at least 1000 year. The island is covered in old beaches, many of which are now far above the water line. Some of the old beach lines are bent vertically, indicating that inflation was not always uniform across the coast. But every part of the island has seen some uplift. One of the beach lines dates from the time when Iwo Jima was discovered, in 1779. This is now 50 meter above the sea. A beach 100 meter high is carbon-dated to 750 year BP. The average long-term uplift is about 15 cm per year. But the rate does fluctuate. Between 1779 and 1887 the uplift was significantly less than 10 meter and possibly zero, and a carbon-dated beach 1350 year old seems not much higher than the one at 750 meter.
Over time the uplift seems to have accelerated, based on the rate of 25 cm per year since 1952. Between 2006 and 2012 there was an episode with an uplift of 3 meter. Since that time the uplift has continued, and inn recent years there have been eruptions along the caldera rim which encircles the island. We do not know whether such an episode is unusual. Tallis has written a recent post on Io To.
Two satellite images of Iwo Jima, from 2005 and 2014. Beware of the small scaling difference. Comparing beach lines relative to the position squares shows the pattern of expansion. (Source: Google Earth. Credit: Geolurking.) Click on the image for higher resolution
The rate and duration have lead to the suggestion that Iwo Jima is the perfect example of a resurgent dome. However, this is not universally accepted, and Newhall & Dzurisin in a US Geological Bulletin of 1988 write An important and unanswered question is whether the historical uplift is rebound since the last caldera-forming eruption, or rather a precursory signal of another caldera-forming eruption to come. The literature mentions that Iwo Jima sits inside a 9-km caldera. This comes from a bathymetric map published in 1983. This map and two profiles are reproduced here. It shows that Iwo Jima is part of a flat-topped area, 9 kilometer wide, beyond which the mountain drops steeply down, but there is not much evidence of a clear caldera ring. One profile shows two symmetric bumps, 9 kilometer apart, but profiles in other directions do not. If there is no clear caldera, the case for post-caldera resurgence is not strong. The flat top can also have formed through wave erosion. Even if there is a caldera, we still don’t know what is going on.
The uplift affects more than just the main island. The small island just to the northwest is also growing and is now close to becoming attached to the main island. Battle ships which were grounded during the US invasion now sit on the beach. We don’t know what happens under the sea but the entire top of the undersea mountain may be coming up. You’re gonna need a bigger boat.
Is Iwo Jima the most dangerous volcano in the world? Perhaps it is.
Laguna del Maule
Laguna del Maule. The horizontal line is the old shore line. The shore has been uplifted by 75 meter (Source: Brad Singer)
This Chilean lake is a relief in a thirsty semi-desert. The landscape is a geological treasure, but not a touristic highlight. It still made world news, when the southern shore was found to have been uplifted by 1.5 meter in 8 years, from 2007 to 2014. Further uplift occurred in 2019/2020. This has been attributed to 0.037km
There have been over 50 eruptions here during the past 25,000 year – once every 600 year. The largest of these eruptions, 23,000 year ago, ejected 20 km3 of ash, amounting to a few km3 of rock. This puts the magma supply rate in context: it has by now recovered the loss from that eruption. Laguna del Maule has not erupted since the Spanish arrived, 450 year ago. It seems a strong candidate for an eruption, even if fairly minor, in the next few centuries. You read it here first.
Socorro, New Mexico
The magma of the Rio Grande rift valley. From http://www.earth-of-fire.com/new-mexico-6-lucero-volcanic-field-and-socorro-magma-body.html
Socorro is perhaps not the liveliest place in the world. The main excitement is floating down the Rio Grande on a tube, looking at the big ‘M’ painted on the local hill, or watching the sandhill cranes and roadrunners in the Bosque del Apache. To the east is the site of the first nuclear explosion in the world, an attraction perhaps best avoided (it is open to the public for two days each year), and a town to the south is called Truth or Consequences, reportedly the only town in the world named after a TV show. With the American penchant for shortening names, it quickly became ‘T or C’. Still, Socorro grows on you. And the locals appreciate visitors, as I found out during a hike, when sitting down for lunch. Immediately three vultures started circling above us, visibly thinking: “They stopped moving! Lunch!”.
Socorro also grows underneath you. The excitement is all underground. The area shows slow inflation, at 1.5 mm per year, which is caused by a magma sill 19 km deep and 150 meter thick. The sill may be the largest magma chamber in the US, with a length of 60 km stretching along the Rio Grande rift valley. The volume is between 100 and 1000 km3. The enlargement of the magma body has caused earthquakes, with a swarm between 1999 and 2004, but also a M5.8 in 1906. The inflation has been going on since at least 1911, but the magma intrusion itself has an estimated age of 1400 year. (Albuquerque, to the north, is subsiding, but this is attributed to over-extraction of ground water.) For more information about Socorro’s inflation, see this post.
The area is littered with volcanic cones, a sign of things to come. But in Socorro, nothing happens fast. It takes its time. Still, we’re not in Kansas anymore.
The Taupo Volcanic Zone
Taupo Volcanic Zone and the area of inflation. Source: Ian Hamling
New Zealand is volcanically hyperactive. The source of its problem is the Taupo Volcanic Zone on North Island, terminating in what is appropriately called the Bay of Plenty. Based on its history, this is the area (relative to its size) most likely to host the Earth’s next problematic eruption. But detailed monitoring has shown that the entire area is deflating, due to cooling of magma. The entire area? No. One region, away from the known volcanoes, and discovered only last year, shows inflation. It is just on the coast or perhaps centred in the Bay of Plenty. The uplift is at a rate of 0.5-1 cm per year, over an area of close to 300 km2. The required magma supply rate is around 0.01 km3 per year. Geological evidence indicates that this has been going on for at least 1700 years! Just when you think New Zealand is safe, it isn’t. You can’t trust sheep.
Recently inflating volcanoes
The ones above are long-lasting uplifts, but where eruptions do not seem particularly imminent. Ground level measurements have revealed other cases, not as long lasting, but increasing the chance of an eruption. Here are some. This list is certainly not complete!
South Sister, Oregon
The area of inflation is just west of South Sister, which is one of the three sisters in Central Oregon. The inflation began in 1996; it is caused by a growing magma chamber 5-7 km underground. Measurements from the European Space Agency (don’t tell the new administration – they might ban these immigrant data) shows that it started at a restrained 1 cm per year in 1996, and quadrupled after 1998. From 2004 the uplift has slowed but not ceased; the total uplift has been 25 cm. The magma volume responsible for the uplift amounts to 0.06 km3. Eruptions here are relatively infrequent, with the last one 1200 year ago. The inflation is centered several kilometers from South Sister – there is no volcano directly above it. Either the magma will find a sideways outlet, or a new cone will form once the magma decides to come up. A younger Sister to join the family.
Uturuncu
There are (too) many volcanoes at the Altiplano, the unlivably high plane in the Chilean/Bolivian Andes. A few birds live here, drawing whatever oxygen they can from the thin, bone-dry and frigid air. Be careful, and acclimatise, or the altitude sickness can kill you. Monitoring these volcanoes is a Herculean job, assuming Hercules could live on this little oxygen. (Excessive muscles put a lot of oxygen demand on the body, whilst turning off the brain only saves 25 per cent of your body’s oxygen needs, so the net effect is that Hercules would do better at sea level.)
Monitoring in the Altiplano began in 1980. It quickly revealed a lurking danger. One of the volcanoes, double-peaked Uturuncu, was growing at a rate of 1-1.5 cm per year, starting in the early 1990’s. That is not that much for what is now an (almost exactly) 6km tall volcano (at that rate it would have taken half a million year to get to its current size, which is not unreasonable), and it is a well-behaved volcano which has not erupted for 300,000 year and shows no sign of impending doom apart from a sickening sulphur smell. (Until recently there was an active sulphur mine on the mountain.) Still, something is going on.
Uturuncu and its monitor
The inflation is remarkably stable, and although there is some microseismicity, there are no major earthquakes. Perhaps a ductile layer is allowing the magma chamber to quietly expand without building up large stress. The magma chamber is 15 km deep, and may be as much as 100 km wide which would make it the largest magma body in the world. The uplift is centred just southeast of the peak. The region of uplift is surrounded by a ring of deflation: this means that the magma is rising – slowly, but notably. When it reaches the surface, perhaps in another 1,000 year, things could get very interesting. Watch this space.
Uturuncu tends not to do explosive eruptions. It seems that magma usually stalls at shallow depths, and has time to exhale its volatiles, before deciding to erupt. A big friendly giant.
Campi Flegrei
Campi Flegrei with its plethora of eruption scars
To VC readers, this will be a familiar name: Henrik wrote his magnificent post on this, one of the most dangerous volcanoes in the world. Campi Flegrei is where the phenomenon of the ground moving up and down was discovered. The entrance to the in-land harbour, Portus Julios, is now 12 meter below the sea, which shows the local deflation over 2000 years, although this deflation did not happen the same everywhere. But what goes down can come up. All eruptions here are preceded by rapid uplift. Before the 3700 BP eruption phase (which lasted 900 year), there was 40 meter of uplift. We don’t precisely know when the post-Roman deflation began. It was long lasting but not uninterrupted. In 1502, the astonished locals noticed that the sea was receding. This motion continued for over 30 years, and in 1534 the first earthquakes began. In 1538, during one week the ground came up by 6 meters, a rate reminiscent of magic beans. The rise was uncontainable and an eruption followed, building the Monte Nuovo (new mountain). One week later, when the eruption ended, this new mountain was over 100 meter tall. Somewhat ironic, the mountain grew in the middle of what had been the main lake of Portus Julios’s inland harbour.
But what comes up must go down and renewed subsidence followed the eruption. Between 1820 and 1968 the sea shore subsided at 1.5 cm per year. There was a brief reversal in the 1950’s. In 1968, the reversal came back with a vengeance; 1 meter of uplift had happened by 1970. Between 1982 and 1984 a further 2 meter of uplift occurred. Slow inflation returned in 2005, accelerating in 2012 to 8 cm per year. This is not dramatic by Campi Flegrei standards, enough to be noticed but nothing to raise alarm bells. Up-and-down movements by several meters are common in large calderas; it can caused by underground water moving around. Yellowstone in particular is known for this.
But now, there may be more going on. Fumarole temperatures have been rising, and new gas vents have opened in the burning fields. There is more heat underground. A decade ago, a paper by Chiodini and collaborators, reported that the pressure is increasing, on a trajectory that would make an eruption possible by 2020. They pointed out strong similarities to the pre-eruption phases of Rabaul and Sierra Negra (Galapagos), with similar accelerating inflation over years to a decade prior to the eruption. The eruption did not happen, but over recent years seismic activity has increased dramatically.
This prediction didn’t seem to worry the locals who have too much in common with Californians. Here, tomorrow is another day. Vedi Napoli e poi muori. A city to die for.
Indonesia
There are too many volcanoes to list them all! In 2012, a radar study by Estelle Chausard and Falk Amelung measured ground elevation across the entire West Sunda Arc, Indonesia, between 2006 and 2012, an heroic effort. In this region (Java and Sumatra) six volcanoes showed significant inflation, with magma accumulating at 1-3 km depth. Four of these subsequently erupted.
The six were Sinabung, Kerinci, Slamet (these three erupted within 2 years after), Lawu, Lamongan, Agung (which erupted in 2017). Anak Krakatau showed deflation, related to a number of eruptions. (It subsequently collapsed in its entirety.) In all cases, the inflation was around 10 cm. The inflation was centred on the summits, apart from Lamongan where it arose north of the summit: this is also the only case where the uplift happened in one fast episode, rather than continuously.
Interestingly, one could say sneakingly, Merapi showed no inflation, but still erupted afterwards.
Sakurajima
This overactive Japanese volcano on the southern rim of Aira caldera is a strong case study of a link between inflation and eruption. There were significant eruptions in 1914 (1.5 km3) and 1779. The 1914 event was preceded by strong inflation of the caldera. The eruption caused subsidence, but inflation restarted and the volcano is again at roughly the level it was before the earlier eruption. The inflation was at a rate of 1.5cm per year from 1996 to 2007. The magma inflow rate is estimated at 0.01 km3 per year, filling up a 10-km deep chamber. Modeling shows that the current activity of Sakurajima is not keeping up with the inflow: the volcano is charging up. The same model predicts 130 years between eruptions, which does fit the previous events well (scientists generally prefer to predict the past: Niels Bohr warned that “Prediction is very difficult, especially about the future.” Einstein had similar doubts: “I never think of the future. It comes soon enough.”) The inflating reservoir is not located underneath Sakurajima, but within the northeast part of the caldera. But there is clearly a good connection between this reservoir and Sakurajima.
Predicting the future (un-Bohr-like and un-wise), a significant eruption can be expected by 2044. And that’s all I have to say about that.
Longonot and Paka
Longonot inflation
InSAR data from the European Space Agency has shown inflation of 10 cm in Longonot between 2004 and 2006, and 20 cm in Paka in 2006 and 2007, both in Kenya. Paka, in the Kenyan rift valley, is a shield volcano with several small craters and cones. The last major eruption (VEI4) was over 7000 year ago but some of the cones may only be a few hundred years old. The recent uplift was preceded by similar uplift nearby, which subsequently reversed: magma flowed into the volcano sideways.
Longonot, 60 kilometer from Nairobi, is more impressive. It has a 10-kilometer wide caldera, 21,000 year old, in which a new summit has grown with its own 2-kilometer crater. It may have been active as recent as the 1860’s.
The summit crater of Mount Longonot
In both cases the uplift ceased and has not restarted. The 2-5 kilometer-deep magma chambers are clearly still active, and an eruption may be possible but we do not know what the chances are. African volcanoes are not well-monitored: we will need much more such data just to know which ones need a warning system. They are volcanoes in the mist.
Conclusion
Volcanoes inflate for all kind of reasons, and inflation does not necessarily equate to danger. Large calderas commonly show ups and downs, largely driven by water circulation, and not related to an eruption. There is little need to be worried about Yellowstone (neither does it show anything which would warrant its inclusion in this post.) But inflation can be an eruption precursor, a warning sign that should not be ignored, hoping that if you do nothing for long enough, it will go away. It is part of the puzzle of volcanoes: if the inflationary piece fits with other pieces that indicate increasing activity, it may be time to update the tourist accommodation and dust off the emergency plans. Up – and away.
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That’s a great article here. I think there’s also a odd gravity anomoly at the Hudson Bay area due to the compression from the ice sheet…
Speaking of up, the South vent at Kīlauea is really active (though not Ep. 40 yet), could Ep.40 come right aways here? Reminds me of the last episode.
Looks like Episode 40 has begun!
North vent is starting to really get going.
And it has died just as quickly, but it could restart again. We are so close.
Fountains are starting to get more intense. I believe episode 40 is just starting.
The fountains are still at size of park water fountains. But I assume that E40 will be stronger than E39 and more like E38, because SDH has inflated more. It didn’t deflate much during E39.
Thanks for these volcano lessons, Albert & Archive!
The resurgent domes with potential aftermath eruptions remind me to Wizard Island of Crater Lake, Tambora 1819 and the Askja Fires of the 1920s. Do the high magma inflow rates of Kilauea after big caldera collapses also apply to this rule? Does this reflation explain why Kilauea became weak after the period of highly above-average activity?
An important example for uplift outside the realm of volcanism are megathrust quakes along subduction zones. They can drown or rise a coast line or an island. An example is the 1700 Cascadia earthquake west of California to Vancouver, where the coast line was drowned by ~20m. Sometimes islands can sink, until a megathrust quake throws them up again. In this case it can be difficult to distinguish how much of apparant sea level rise comes from actual inflation of water and how much from deflation of land. A similar effect can be observed after glaciation in the southern parts of the North Sea, where as a counter-movement to Scanindavia’s inflation the Frisian lands deflated at the same time, as sea level rose.
With megathrust events, the land sinks during the earthquake but is pushed up in between them. Over the full cycle, the land comes back to the same level.
This is very unusual. North vent is producing a somewhat powerful fountain (not tall) continuously while the South vent has been periodically been overflowing. Looked at the tilt meters and SDH is still rising (might’ve slowed a little), while UWD has begun to inflate after a plateau. IKI is in a similar situation to UWD. Either the precursor part of the episode is wasting gas for the main course, there’s so much gas that it couldn’t wait, or we are in Ep. 40. I honestly have no idea.
While waiting for episode 40 to start, here’s Mayon doing a nice PDC:
https://youtu.be/cUZa6VM5B9c?si=Cem41yNvG5uvfN2U
Does anyone know a proper way to get overpressure calculations using uplift? Curious to see how overpressurized Iwo-jima is. Referencing Laguna Del Maule’s calculated pressurizing rates, kinetic energy, and potential energy, i get numbers that are too high in my opinion.
The north vent is two vents, one is erupting strongly but most of its output goes into the other vent and net output is not that much. Although its still enough to feed a fast moving lava river. The south vent is behaving pretty much as expected.
If I had to guess, E40 will begin properly by the drain side of the north vent erupting too. But it could also just do this for a while, then run out of gas poor magma and runaway
South vent is overflowing big time.
The volume of the pre-deflation part of the current episode looks very big. If I remember correctly, also E38 had a relatively high volume before the moment of deflation. Does the volume before deflation and the volume during deflation correlate positive?
Kilauea has been weird today. The UWD tiltmeter was going down rapidly earlier, but now it seems to have leveled off. And the south vent has been releasing major overflows of lava. Perhaps we’re not gonna see high fountaining this time around?
I’d assume that E40 is going to be very large. Large episodes seem to be preceded by major effusive activity before the climactic phase. The volume of degassed magma/lava is perhaps higher than that of previous episodes. This means that this volume and mass of degassed magma also prohibits the rise of gasrich magma. The more gasrich magma is contained, the more explosive will be the fountaining phase afterwards and the higher will be the output rate during the deflation phase.
The degassed magma works a bit like the skin of a ballon. The thicker the skin, the more air pressure you need to explode the ballon … and the louder will be the bang. It’s a bit like in Plinian eruptions, where gasrich magma suddenly gets out after it was blocked by something. The tall lava fountains both of Kilauea Iki and the current eruption resemble Plinian ash plumes a bit, but with fire.
After Kilauea’s E40 Piton is likely going to erupt:
Episode 40 might be starting! (Might’ve jinxed it if this ends quickly…)
I think you’re right. The north vent is getting really vigorous
I mean, it looks like it’s trying to do something…
The southern vent does several repeated “Red Carpet” lava floods. But they’re not the big thing yet.
Mayon: Looks to be a subterminal vent on the southwest (near left) side of the cone, a few meters below the summit. Still no legit lava flows, the mountain is just too steep and the lava too viscous. Still, a nice carpet of clinkers just waiting for the next monsoon. Daylight in another hour or so.
Its pushing out older lava that is still hot but mostly solid. Fresh lava at Mayon is muvh less viscous than spiny dome lava. At least in 2018 it did lava fountains and lava flowed to its base within days.
Its lava is 50% crystal basaltic andesite, with the melt being apparently between 60-69% SiO2, mostly at 68%. So its mostly dacite melt that has a lot of mafic crystals that bring it to 54% SiO2 average. Although its also really hot when fresh, well over 1000°C which is very hot for dacite and greatly reduces the viscosity compared to some other volcanoes with similar composition magma like Merapi, which is kinda stuck in the spiny dome stage for some reason.
Although its obviously not super fluid still, maybe in that gray zone where it cant make free standing domes, but also doesnt make convecting lava lakes. I wonder if it could do it if the crystals could settle out though, a hot dacite lava lake would be super cursed lol…
This article has quite a lot of good data actually.
https://link.springer.com/article/10.1007/s00445-021-01486-9
Small world–I was reading that paper yesterday! 🙂
https://agupubs.onlinelibrary.wiley.com/doi/10.1029/2025JE009047?fbclid=IwZnRzaAPRbpBleHRuA2FlbQIxMQBzcnRjBmFwcF9pZAo2NjI4NTY4Mzc5AAEelW-eUJnz5bmlVC3hRMbzmo9cVESu-qfVuu5V44JrkUH41dKzlNeceCJJyHM_aem_r10_wdbgrhodlzeJ-ng2DQ
Io s gigantic volcanism connected lava lakes this is something for Albert
https://earth.google.com/web/@5.68411051,-47.76222935,14.20510772a,91586.26087795d,35y,-68.83620418h,38.95928876t,0r/data=CgRCAggBQgIIAEoNCP___________wEQAA
https://earth.google.com/web/@6.88619303,-48.7287611,17.64497839a,45953.95701962d,35y,-45.14149689h,62.30186122t,0r/data=CgRCAggBQgIIAEoNCP___________wEQAA
https://earth.google.com/web/@43.27051376,-130.58771978,12.12223037a,194565.68914689d,35y,4.64903306h,12.82085345t,0r/data=CgRCAggBQgIIAEoNCP___________wEQAA
VERY intresting river like channels on the basaltic deep sea abyssal seafloors in the worlds great oceans, these looks just like river formations on land just underwater so presumabely formed through the same way: presistent deep sea currents carving on the seafloor substrates
Looks like Ep. 40 might be starting. Fireworks at the secondary north vent.
There is indeed a small fountain. But the other vent is still overflowing vigorously and is not yet ready, I think. We live in hope
I guess. Maybe there’s some other factor. The last episode started when the north vent was building a hornito, hence creating a cork for it to blast though, like it tried yesterday but pre-emptively burst, henceforth the episode is delayed (and also the secondary vent is also active too). At least the overflows are quite spectacular…
Ep. 40 is definitely starting and quickly!!!
Tremor is increasing…
She’s really going now.
This is tall. There seem to be two fountains but I can’t quite tell where they come from.
To me the fountains look like they are coming from the two north vents, the smaller one from the lower one and the taller one from the upper.
One more source for uplift – orogenic plate movements, i know it is fairly obvious, but just thought it should probably be mentioned for completeness. India crashing north seems the most clear example.
And episode 40 is over.
Remarkeble that only one vent was fountaining this time, while the other had many pre episode overflows. Did USGS mention some explanation about the difference between the two main vents already?
Yes, the source of the southern vent has maybe “chosen” to do something else with its magma. It’s still there. So the E40b part is still possible to follow. But maybe this magma failed to reach there and is going to find an alternative exit in the southern summit region.
It was a half episode. Only 5.5 million m³, while E38 had 12 million. Deflation was only 50% of what was to expect. Added to this there happened earthquakes towards Keanakakoi Crater at ~1km depth. Is a part of magma trying to escape there? 7/19/1974 there occured a three day eruption.
https://www.nps.gov/havo/learn/nature/july-1974-eruption.htm
1974 had both eruption on the location of the current 2024-2026… eruption and in the Keanakakoi Crater area. Is there a relation of the two locations that allows for eruptions on both in short time?
This looks like an interesting change. The UWD tilt had not gone up by as much as before previous episodes but went down to closer to normal values. The tilt so the of the caldera showed a normal starting value but much less decline. It looks to me that there was a magma supply deficit: some was diverted. The fountaining starts when the magma has become partly degassed. At this point, the Southern vent was too far down the supply line and ran out. The northern vents took it all. Episode 40 happened pretty much on time though.
The southern part of the caldera and summit region continues to be more inflated than the northern part with UWD station. Is the remaining magma seeking a new exit? Earthquakes continue to occure frequently in the summit region. HVO counted 22 and interpreted them as “likely related to re-pressurization of Kīlauea summit region follow the end of episode 40”.
Now the map shows 33 earthquakes between Magnitude 1 and 2, there are 29 earthquakes more shallow than 5 km.
Nice pic.
Its hard not to compare the internal plumbing to that of a geyser, water/steam variety. I imagine the basic principles may be the same.
Yes, very much so. Kilauea’s lava geysers and Yellowstone’s water geysers are driven by the same process. In the case of geysers, the gas comes from boiling water. In the case of magma, it is from degassing. But they both increase with decreasing pressure. The gas content is low enough that the gas is contained by the liquid, so both spout out together. The main difference is that the lava geysers continue for many hours. This is because it comes from a continuous supply through the conduit and the degassing happens in the conduit. That is unlike Yellowstone
There are geysers which can continue for hours (e.g. Sawmill, which has 1-3 eruptions daily up to 6½ hours in length as part of its eruptive cycle; Grotto in so-called “marathon” eruptions which can last up to two days) or even have known continuous eruptions (“perpetual spouters”) as their regular behavior. Though I do agree these are among the exceptions and some geysers have this many hours to days’ length only in rare instances (e.g. Fountain can last up to three hours if two nearby geysers also erupt).
The aftershocks in Kamchatka and the Kuriles have been increasing over the past weeks
Is there precedence for this at any other subduction zone post-major quake? (i.e. the aftermaths of Japan 2011, Sumatra 2004, etc.)
Any indication this could be a precursor to another major quake near where the previous one happened? (i.e. somewhere in the Kuriles)
Meant to say precedent, not precedence.
I would not know how to tell the difference between aftershocks and foreshocks in such cases. Maybe Mike can, but in general it says that stress caused by the Kamchatka earthquake is still being resolved, with a chance of a larger aftershock. This can go on for years.
Yes, for instance some of the recent Japan seismicity can be considered ‘consequent’ (but not exactly ‘aftershock’) of the great 2011 earthquake.
We can sometimes identify events as definite aftershocks even several decades after the initial mainshock.
But in general, you can’t speak of any event as being a ‘foreshock’ until after the mainshock occurs. There were biggish events prior to Tohoku which were only recognised as foreshocks after the mainshock had occurred.
Only recently.
South of the main aftershock zone, the Kamchatka-Kuril trench and the Izu-Bonin fracture zones all suddenly went aseismic immediately following the Kamchatka Mega -Thrust 7 months ago. Not sure if this period of quiescence was mere coincidence…but for years prior to the KMT (especially following Tohoku in 2010), the entire western edge of the northern Pacific plate was quite active with M5’s+ occurring somewhere at least on a weekly basis.
IMHO, it appears that only now are moderate EQ’s starting to return in numbers prior to the KMT.
Very curious. If there is any linkage between the KMT and the recent respite (now ending?) of seismicity, it must involve some other form of stress transfer or commonality that I’m unfamiliar with. It just seems implausible to me that a single event like the KMT can affect seismicity over an area thousands of miles away? But then again…..
In Iceland, IMO has gotten the DAS live stream up and running again. I must warn you, it’s not the most exiting thing to watch, but if you’re into extremely slow tv, then here you go 🙂
Hi Albert how fast woud en unlucky astronaut be destroyed if that persons spacesuit was exposed in the solar surface gas photosphere? just at the top layer of the solar granules. Im very familar with it being an incredibley hot enviroment about as hot as the surface of Earths inner core, but its also incredibley low in plasmas density meaning there is not much matter around you to bump into your own atoms and heat you up too. The particle density in upper photosphere is very low compared to anything like fire at Earths sealevel! only 1/5000 th of Earths sealevel pressure so the solar material at that depth in the sun should not carry that much energy at all
But the radiation from the sun maybe a completely diffirent thing!
Terminal velocity in upper solar photosphere is extraordinary high because of the suns enormous gravity well, you will fall extremely quickly into a insanely bright gas furnace below your feet.. fast enough for the gas flow wind to likey ripple in straps in your spacesuit a completely utterly terrfying fact and sight to think about.
In the deeper depths you “decompose” incredibley quickly in the extreme heat, thats because of the matter reaching is incredibley densities with incredible heat transfer to your body. You wont make it very far into the sun before the solar materials gets as dense as water
Lots of the solar convective zone below the photosphere is much denser than air at Earths sealevel, so its equal to being inside a very hot plasma torch at much higher plasma density than any plasma under one Earth atmosphere. A very quick way to destroy an unlucky astronaut. Small compressed stars are more like liquid matter than plasma and thats very true with Red Dwarfs these are much much denser than diamond
Really tiny stars even tiny active stars are incredibely tightly packed barely held up by fusion. EBLM J0555-57Ab is an extremely dense, Saturn-sized red dwarf star, notable as one of the smallest hydrogen-burning stars known, with a density around 187 g/cm³, making it far denser than Jupiter and comparable to white dwarfs due to electron degeneracy. In that star you wont sink
much at all due to the extreme density
Falling into the sun feels very attractive now when Europe is under a siberian polar outbreak, its freaking so cold that I can barely be outside. A denser atmopshere coud make our winters warmer but then you woud have to move earth to balance the greenhouse effect from that
As another five episodes have come and gone, here’s an update to the graph I’ve shared previously:
(Google Drive link for the less fortunate among us: https://drive.google.com/file/d/1hZUkwcDHWJmqoFPzqTPxwafsT0mC6RJQ/view?usp=drive_link)
The biggest change is that the graph now shows the volume per µrad, which is used to calculate the data displayed. This volume number is determined by HVO’s UWD µrad number of the tilt drop and their stated volume effused, and is dynamic. At this point in time, however, it shouldn’t vary too much update to update. It’s additionally only for those episodes where the µrad number I get from UWD and what HVO gets from it differs by at most 0.5 µrad up or down – anything else is not taken into consideration as I find the difference too large to just be explained by the difference between, basically, pixel-counting and what the HVO determines with access to the raw data.
With that said, here are the numbers from episode 36 to 40:
* Episode 36: Recharged ahead was 10.4 million m³ (27.6 µrad) at 5.4 m³/s on average; effused during was 8.9 million m³ (23.5 µrad) at 468.2 m³/s.
* E37: Recharged 8.3 million m³ (22.0 µrad) @ 6.0 m³/s avg.; effused 6.2 million m³ (16.5 µrad) @ 189.2 m³/s avg.
* E38: Recharged 6.5 million m³ (17.1 µrad) @ 7.2 m³/s avg.; effused 12.8 million m³ (33.8 µrad) @ 292.7 m³/s avg.
* E39: Recharged 12.0 million m³ (31.8 µrad) @ 8.2 m³/s avg.; effused 10.2 million m³ (27.0 µrad) @ 481.5 m³/s avg.
* E40: Recharged 8.7 million m³ (22.9 µrad) @ 5.2 m³/s avg.; effused 6.6 million m³ (17.6 µrad) @ 190.3 m³/s avg.
Some things of note: The highest average effusion rate up until episode 40, was episode 39’s 481.5 m³/s. I believe it also demonstrates the total average capacity of the plumbing currently sits around 500 m³/s, with approximately 200 m³/s from north vent and 300 m³/s from south vent, the latter if it wants to play ball. As a side note, the HVO stated 190 m³/s on average for episode 39, but considering the short duration and the high volume effused, it should be obvious this number cannot be true.
The fifth-highest recharge rate (excluding, due to drainback, that between episodes 1 and 2, and 2 and 3) also belongs to the interval between episodes 38 and 39, at 8.2 m³/s on average. On the contrary, the recharge rate ahead of episode 40 (5.2 m³/s) was the third-lowest; the last time it was this low was ahead of episode 23, with just 3.4 m³/s (coincidentally also the lowest across the eruption so far).
The interesting thing here is that I’m calling a recharge rate of 5.2 m³/s “low”, considering if one takes long-lasting eruptions like Maunaulu, Pu’u’o’o or even ‘Aila’au, their average effusion rates sit below 5 m³/s. This number, I believe, one can also use to approximate the recharge rate, as a form of steady-state was reached. A dirty calculation – 0.2 km³ for the year divided by 366 × 86400 – to get an average effusion rate as if there was no fountaining, yields 6.3 m³/s, which I’d call significantly higher than any of those other long-lasting eruptions. I do expect this number to drop when fountaining gives way to constant lava effusion or a lava lake, but for the time being Kilauea is certainly honoring its name, “spewing” or “much spreading”.
Thank-you for your new analysis J.O.!
Concerning volume E38 has been the king of the episodes until now. It effused nearly the 2x amount of volume that had been recharged in the weeks before. Contrary to this E40 effused little volume, but had higher recharge.
Deflation on SDH was only -11 µrad during E40, but inflation before E40 +24 µrad. UWD had inflation of +22 µrad and deflation of -17 µrad. SDH was after E40 +14 µrad inflated compared to the end of E39.
Does this mean that the southern part of Kilauea’s summit still waits for its eruption? Is the series of small quakes in the summit region an indicator for new unrest? The old (pre-2018) map of the summit shows lava flows f.e. of Keanakakoi eruption 7/74 or the 9/82 eruption in the southern region of the summit. The 7/74 eruption also had a fissure inside Kilauea Caldera:
This map shows a semicircle of earthquake points on the east side of Halema’uma’u and towards the southern summit region.
I don’t know, to be honest. HVO wrote in their updates ahead of E40 that the continued inflation seen on SDH, while UWD and SMC had stalled, may be related to the deeper magma chamber, with that seen on UWD and SMC being related to the shallow one. SDH does deflate less during a given episode, though to me it looked rather little even after E40 had ended. Granted, at the start of an episode, SDH sits well above the point where the prior episode started, so it does compensate. I do wonder if south vent has a more direct connection to the deep chamber (I believe this was first suggested by someone here, can’t remember when or who), while north’s connection might be more convoluted, as, when south is also active (or on its own I recall), the deflation is more than with north alone.
I don’t think, however, the southern part of the caldera will erupt anytime soon as long as these two vents are capable of relieving the built-up pressure, and they’re more than capable of doing so. That’s to me also indicated by south vent not being active in any significant capacity for a good chunk of episodes and more looks like an efficient pressure relief vent which, unlike the satellite fissures seen at Pu’u’o’o, has managed to establish itself as one of the central vents, thereby significantly decreasing the risk any ephemeral satellites pop up. It also helps the eruption is on the ring fault, which, to me, should prevent the eruption from migrating to either rift zone or go to the southern caldera, unless all else fails.
Both the 1974 and the 1982 eruptions had two parallel fissures (one in the caldera and one above the caldera rim). They were too short to create two vents like the longterm eruption 2024-2026. The eruptions 1974 and 1982 happened just after Mauna Ulu resp. just before Pu’u O’o. They were likely a sign of high magma inflow to the summit, when the path to the ERZ was not open anymore resp. still not open.
On the eve of E40 both vents were very active during the stage of positive deformation. On 10th January HVO wrote: “Overflows from both vents are feeding a lava flow about 250-500 ft (75 m) wide that extends over a half a mile (1 km) into the crater.”
These overflows of degassed lava during inflation were relatively voluminous. The vents behaved different during the positive deformation than during the negative deformation. Degassed magma can obviously better use both vents, while gasrich magma tends to do a monopoly eruption on one vent.
one vent runs out of lava and the other out of gas
The interesting bit is theres no indication this is actually that close to changing. Kilauea Iki and Pu’u O’o both stopped fountaining because of breakouts at lower elevation. Mauna Ulu didnt exactly do this but its vent was more unstable, and it did intrude downrift too prior to its final fountain that did terminal damage to its narrow conduit. And it did seem to be returning to fountaining in the final weeks.
By comparison the current vents are very stable and dont sit directly on the rift zone faults, so the only option is if the magma system as a whole is pressurized enough to go back into the rifts which may take a while with an open vent.
As a side, the vents are presently 2/3 of the way to overtoping the caldera rim nearest to them. It will take about 2 more years in theory to fill the 2018 caldera, but it could begin within 6 months on the most southwestern side. The summit of the tephra cone is also only 40m from being Kilaueas new summit full stop 🙂
Both the 1974 and 1982 eruptions had two parallel fissures, that were comparable to the present twin cones. So I think that these two eruptions were more like the current eruption, but an exception during their time.
The lava shield grows relatively fast now. Pu’u O’o cone also grew fast during the first three years. The later eruptions didn’t add much to the cone, but had rather flank eruptions, long running lava flows and tubes. So we can assume that the current shield will grow mainly vertical as long as the episodes continue. If the episodes shift to a continuous eruption style, the vertical growth of the lava shield will decrease and the horizontal growth of the lava shield will increase.
HVO has now commented on the earthquake swarms which they are say are related to magma pressure.
Calming down now so the magma attempt to break towards the east rift zone has not succeeded at this time. It remains on orange warning level, though
There is still some seismic noise. The tilt and the caldera length both show a fast recovery: the next episode could well be as early as next week. The various GPS signals are not easy to interpret but I think are consistent with some magma migration towards the southeast in the caldera. This would be away from the vents.
Many quakes are below the flooded down-dropped block east of Halmea’uma’u and towards Keanakoki crater and B1 webcam. Can volcanic-tectonic changes create new chances?
The relatively new SMC tiltmeter on the east side of the caldera shows a steep inflation:
We can with also discuss the economic inflation/deflation of volcanoes. Concerning public attention and its media value, a volcano deflates (increases its prize) if it inflates geologically. If volcanoes do something, they create opportunities on the news market.
If a volcano becomes a tourist attraction, it deflates economically further. But if the volcano kills tourists or becomes too inpredictable (White Island), it gets a sharp inflation (a decreasing price).
Volcanoes can in more fields of economy have a value: f.e. fruitable soils for agriculture or useful rocks and tephra deposits. The Romans found a recipe for the very solid cement “Opus caementicium”, that needs volcanic tephra.
That cement built the roman world.
Must have been worth a fortune.
Its even found in britain in roman buildings, of which there are a surprising number.
Chiles-Cerro Negro just had 190,000 quakes in 2025. On par with the beta, gamma, and delta swarms volume wise but definitely not even close energy wise.
Noteworthy that VLP spike of 2024 finally ended in 2025 but it transitioned into doing far more LPs and tremor episodes
Tectonic quakes along the Chiles-Cumbal and Chiles-Cerro Negro faults. Deformation changes in the same locations not good.
Swarms keep coming increasingly strong pulses. Either this will go like alpha swarm or beta swarm. No in-between
Well after a few weeks of false alerts, Piton de la Fournaise has finally started a new eruption
https://m.facebook.com/story.php?story_fbid=pfbid0uBhKdGyCjFkXVDHypQZHcVoCzrzGqmqtZShnLemho3JugP3Q9YNUPCMNkszZoYVLl&id=100044446300716
For whatever reason the official website of the volcanic observatory and the webcams are down so that’s all we’ve got for now…
thanks!
New post is up! Paradise ?
https://www.volcanocafe.org/the-caribbean-paradise/