Tuesday 11 July 2017

Auckland Islands Earthquake Shakes South Island

At 7:00pm NZST a moment magnitude (Mw) 6.5 earthquake struck approximately 190 kilometres southwest of the Snares Islands south of New Zealand. The earthquake was widely felt in the lower South Island, with nearly 2000 felt reports received by GeoNet and 19 felt report received by USGS. The shaking intensities reported were quite low (MM3 weak & MM4 light shaking most common, with 82 MM5 moderate reports from Stewart Island in the south to Wanaka in the north), but this is quite normal for a large earthquake more than 400 kilometres south of New Zealand.

This earthquake is most significant in regards to its relation to recent seismicity. On the 23 December 2004 a massive Mw 8.1 earthquake struck approximately 150 kilometres west of todays event, rupturing a 150km long fossil fracture zone (Robinson, 2011). This earthquake was a predominantly strike-slip event which did not rupture along the plate boundary (as most earthquake of such immense magnitude do) but along an ancient fracture zone which was the locus of sea-floor spreading ~25Ma. This earthquake was overshadowed by the 26 December 2004 Indian Ocean Earthquake and Tsunami.

The effect of this massive earthquake was that stress in adjacent areas of the crust were elevated. I hypothesize that one such area was the plate boundary 150 kilometres to the east. This is also a strike-slip fault, but thrust faulting events are also known to occur in this region. On the 30 September 2007 a Mw 7.4 earthquake struck on the plate boundary, followed four hours later by a Mw 6.6 earthquake 25km to the north. The mainshock occurred on a shallow thrust fault whereas the large aftershock struck on a strike-slip fault; both faults are parallel to the main plate boundary. An active aftershock sequence followed, with the largest aftershock (Mw 6.1 thrust faulting) seven months later.

Since the 2007 earthquakes seismicity has occurred both to the north and the south. Almost all of these have struck to the north and the largest have been Mw 5.9. Only two events (Mw 5.7, January 2010; Mw 5.9, September 2011) struck to the south and these were the result of strike-slip faulting at depths of 18-25 kilometres. These occurred very close to today's event and therefore I believe that all three have struck in the stress shadow of the 2007 earthquakes.

Today's Mw 6.5 Auckland Islands earthquake is the largest to have struck the region since 2007. A result of strike-slip faulting (with a minor thrust faulting component), it struck the main plate boundary between the Pacific and Indo-Australian Plates. It is highly likely that aftershocks </=M5.5 will be recorded in the next few days and weeks. It will probably not trigger any further earthquakes of similar size or larger, but this cannot be ruled out as the northern part of the Macquarie Ridge has not seen an earthquake >M7.5 since 1964 and 1981 (both of these north of the 2007 earthquakes).
 

Saturday 13 February 2016

Magnitude 5.1 Earthquake Rocks Northwest Oklahoma

The Mw 5.07 Fairview, OK Earthquake & Its Causes


All magnitude 3.0+ earthquake within 16km of 36.477N, 98.718W since the 1st October 2015 - there are 60 in total, 5 of which are magnitude 4.0 or greater
A moment magnitude 5.07 earthquake struck earlier 32km northwest of Fairview in northwestern Oklahoma, at a depth of 8 kilometres. It has been given a maximum intensity of MM7 (damaging) and was felt at least 500 kilometres away in Montana and northern Kansas.

Moment tensor for the Mw 5.07 earthquake at 17:07:05 UTC on the 13th February 2016 (today)
This earthquake is the third largest earthquake to strike Oklahoma in at least the last 50 years (only Prague in 2011 which was M5.7 and an aftershock have been larger). This earthquake's cause is very similar to Prague in 2011, both being caused by an increase in stress in the upper crust caused by gas extraction activities. Though not caused directly by hydraulic fracturing (otherwise known as fracking) which helps to release the gas and oil from the oil shales of Oklahoma and southern Kansas, it is associated with fracking.

Moment tensor for the Mw 4.32 earthquake at 9:45:31 UTC on the 15th November 2015
During fracking water with chemicals is injection down the borehole to aid the process of extracting the gas and oil from the shale. After its use this mixture of chemicals and water is pumped into the pore spaces formerly occupied by the gas and oil within the shale; this process is known as wastewater injection. In the case of this earthquake wastewater injection nearby has been leading to numerous earthquakes greater than magnitude 3.0, with several more than magnitude 4.0.
Moment tensor for the Mw 4.42 earthquake at 4:27:27 UTC on the 7th January 2016
On the 7th January this year a doublet earthquake (Mw 4.42 and Mw 4.80) at 4:27am UTC struck on a southwest-northeast trending left-lateral (dextral) strike-slip fault. In the next 48 hours 11 more event of magnitude 3.5 or larger struck (including a second Mw 4.42 earthquake). Unlike after the Edmond, Oklahoma earthquakes of 29th December 2015, there does not appear to have been media reports of Oklahoma oil regulators stepping in to stop wastewater injection, although I suspect this may well have been the case locally. If they did, the affect of the added wastewater into the shale of this region has still increased the stress below it (an analogy could be progressively putting books onto a bookshelf to the stage where it is creaking, then not putting any more on thereafter). This increased hydrostatic stress has led to today's Mw 5.1 and the Mb 3.9 aftershock.

Moment tensor for the Mw 4.80 earthquake at 4:27:56 UTC on the 7th January 2016
There may well be more earthquakes, although it is likely that today's quake will be the largest. However this large earthquake will have increased stress in the region on its own, adding it to the already increased crustal stresses from the wastewater injection, increasing the chances of another M4.5 or larger event in the next few weeks.

Moment tensor for the Mw 4.42 earthquake at 8:37:11 UTC on the 7th January 2016

All data courtesy of United States Geological Survey.

Written by J H Gurney, 21:31 UTC, 13th February 2016.
From Devon, United Kingdom.

Monday 12 October 2015

Moderate Earthquake Strikes North Island, New Zealand

Moderate Ml 5.8 Earthquake Strikes North Island, New Zealand


A local magnitude 5.8 (GNS, New Zealand; moment magnitude 5.4 - GFZ, Germany) earthquake has struck the North Island of New Zealand, about 10 kilometres east of the small village of Pongaroa. The earthquake was the result of a shallow-dip reverse fault.

This earthquake was preceded by several foreshocks, the largest of which was a M3.8 six hours prior to the mainshock. A smattering of aftershocks have followed this moderate-size earthquake, the largest 74 minutes after the mainshock with a magnitude of 4.1.

The earthquake was felt across most of the lower and central North Island, gaining at least 4990 felt reports (likely to exceed 5000 soon). The M4.1 aftershock has gained only 50 felt reports.

It is my expectation that the M4.1 aftershock may only be exceeded by one or two earthquakes hereafter; the maximum is a M4.6, but my preferential forecast is for an aftershock to reach ~M4.3 at maximum. This would agree with Bath's Law for mainshock-aftershock relationship.

This earthquake (or more strictly true, an earthquake of similar magnitude in New Zealand) was anticipated by myself, but only on the basis of a comparative lack of such events in the past 4-6 months. The chances of this Pongaroa earthquake being a foreshock are small, but not impossible; if any further large earthquakes are to follow, it would be in a swarm-like manner, much like the Weber Earthquakes of 1990-1992.

Addendum: Whilst writing, a M4.4 aftershock struck, fulfilling my prediction:


Moment Tensor Solution for the Pongaroa Ml 5.8 Earthquake, as given by the GEOFON Program, GFZ Potsdam, Germany. It shows shallow-dip reverse faulting, corresponding well with the tectonic regime of the eastern North Island.Written by J H Gurney, 11:03 BST (23:03 NZDT), 12th October 2015.

Saturday 13 June 2015

Earthquake Forecast For June 2015 & Beyond

As a new post I have decided to give an attempt at forecasting global seismicity for the rest of this month of June, alongside some forecast for more local regions, which are likely to be less accurate than the global forecast,

As of the 12th June 2015 there have been 36 earthquakes worldwide with a moment magnitude (Mw) of 5.0 or larger according to GEOFON (GFZ Potsdam) in this month. This number includes four events of moment magnitude 6.0 or larger, all of which in fact have been moment magnitude 6.0 earthquakes. These have struck in the following locations:

  • Borneo, Malaysia (4th June, depth 14km, Mw 6.0) - killed 18 people

  • Offshore Hokkaido, Japan (8th June, depth 58km, Mw 6.0)

  • Antofagasta, Northern Chile (10th June, depth 122km, Mw 6.0)

  • South of Samoa (12th June, depth 49km, Mw 6.0)

Of the 36 events, only 3 have actually been onshore - the Mw 6.0 Borneo Earthquake on the 4th June, the Mw 6.0 Antofagasta Earthquake on the 10th June & the Mw 5.0 Borneo Earthquake on the 12th June (an aftershock of the 4th June event). This means that there have been no Mw 5.0 or larger events, which would be aftershocks, striking Nepal so far this month. My expectations for Nepal are that there is a 50/50 chance of a Mw 5.0 or larger event striking before the end of the month.

Globally my expectations are the following for the month of June 2015 (as qualifying & recorded by GEOFON):

  • Mw 5.0 or larger: 84-96 events

  • Mw 6.0 or larger: 8-10 events

  • Mw 7.0 or larger: 0-2 events

  • Largest magnitude: M6.7-7.6 (most likely at a guess is ~M7.0)
In terms of long-term global expectations I expect there to be at least two more Mw 7.0 or larger earthquakes; the current total of seven is a little below average annual totals of ten events.

There are some regions which have not suffered significant seismic activity thus far this year. Europe is a key region which has only seen a single event over Mw 6.0 (16th April, 29km depth, Mw 6.1: Crete, Greece). In all honesty I do not expect an event of such size to occur this month, but I do expect at least one more to strike somewhere in Europe this year, with likely locations being Greece, Italy & Turkey.

Another region with few events this year is Indonesia. There have been very few large events at shallow depths this year; a Mw 6.9 (27th February, depth 544km) struck the Flores Sea, a Mw 6.2 (3rd March, depth 30km) struck west of Southern Sumatra, a Mw 6.0 (15th March, depth 24km) struck the Minahassa Peninsula, Sulawesi & a Mw 6.2 (17th March, depth 38km) struck the Northern Molucca Sea. Since the Northern Molucca Sea Earthquake there have been no earthquakes over Mw 6.0, the largest in Indonesia since that event was either the Mw 5.9 in Sulawesi (28th March, depth 132km) or the Mw 5.9 in Southern Sumatra (15th May, depth 143km). Therefore this is a likely region to expect a Mw 6.0 or larger event this month.

Again, the Philippines have had relatively few earthquakes; there have only been 11 events of Mw 5.0 or larger, the largest a Mw 5.8 on the 10th January striking offshore of Luzon. This is quite unusual to have so few events in the Philippines, and like my expectations for Europe, I believe there will be a Mw 6.0 or larger event this year, though not necessary this month.

For my two countries of specific interest the past five and a bit months have been relatively interesting. The United Kingdom saw a Mw 3.7 (Ml 4.2) earthquake strike near Ramsgate, Kent, on the 22nd May, the largest earthquake to strike the country since the 2008 Market Rasen Earthquake. I do not expect any further earthquake with a magnitude 4.0 (of any kind), but there may yet be a small number (below six) of M3-3.9 events.

New Zealand has seen three significant earthquakes strike onshore; a Mw 5.6 on the 5th January near Arthur's Pass, South Island; a Mw 6.1 on the 24th April near St Arnaud, South Island; & a Mw 5.6 on the 4th May near Wanaka, South Island. The largest earthquake on the North Island was a Mw 4.6 near Ruatoria on the 14th April.

By a very simple process of deduction (by the simple absence of such events so far this year) I believe there will be at least one Mw 4.8 or larger event which will strike the North Island of New Zealand. Such events may be shallow earthquakes near Whanganui, Wellington, Hawkes Bay or Gisborne, or alternatively moderate depth (70-300km) events beneath the North Island.

My final region of interest is the Pacific West Coast of the United States. I still believe that the next Mw 6.0 or larger event to hit the Los Angeles region is due within the next three years. Currently my focus is on the Newport-Inglewood Fault, which has seen an unusual increase in small magnitude tremors recently. Other parts of the Pacific West Coast at risk of decent earthquake (M5.0 or greater) include the San Francisco Bay Area - in particular the Concord FaultCape Mendocino & the vast central area of the San Andreas system, particularly around Soledad & Coalinga.

As a note, these are personal opinions and no official forecasts. They definitely are NOT predictions!

Written by J H Gurney, 14:20 BST, 13th June 2015.

Friday 24 April 2015

On the Late April 2015 Seddon & St Arnaud Earthquakes, New Zealand

This is just a short update on recent seismic activity, with an unsurprising focus at present on New Zealand.

On Wednesday night at 10:36pm BST a local magnitude 4.4 earthquake struck due east of Cape Campbell on the north-east coast of the South Island of New Zealand. This earthquake is a bit of a surprise – it has been 21 months since the first Mw 5.5 earthquake struck in the Cook Straits & began the Seddon sequence (18th July 2013 in the UK). This Cape Campbell earthquake proved to be a foreshock to a larger local magnitude 5.1 earthquake, which struck about 7km north-east of Lake Grassmere.

This second Seddon earthquake is probably the more interesting; it struck on what I assumed in my Extended Project was the second fault to rupture with the 21st July 2013 Mw 6.5 earthquake. This second fault was strike-slip, trending roughly 233° (NE-SW) with a dip of about 70-80°. Though GeoNet have not yet released a moment tensor solution for this earthquake, USGS did give one: Mw 4.65, nodal plane 1 trending 234° (NE-SW), dipping 62°. This matches what I would expect, and its location at the epicentre of the Mw 6.0 earthquake which struck on the 16th August 2013 (after the second mainshock underneath Lake Grassmere on the same day) seems to infer that this earthquake was indeed on the second fault to rupture during the 2013 sequence.

This morning, at 4:36am BST a large earthquake struck underneath the Kaikoura Ranges in the north-east of New Zealand’s South Island, about 35km south-east of St Arnaud. This earthquake had a local magnitude of 6.2 (GeoNet) - moment magnitude of 6.0 (GEOFON) & 6.1 (USGS) and had a focal depth of 52km (GeoNet). The earthquake was a long one due to its location, depth and magnitude – most people who felt it in New Zealand reported on Twitter that shaking lasted at least 20 seconds. The earthquake was felt across the whole country – over 6500 felt reports were received by GeoNet, from Auckland in the north, to Dunedin in the south.

As soon as I saw it (I was unfortunately awake when the earthquake struck!) I could discern several things. First of all, there was unlikely to be any structural damage. If the earthquake had struck Christchurch or Wellington city centres (as the Port Hills quake did in February 2011) then there would have been severe damage and likely fatalities; however the quake struck in the sparsely populated Kaikoura Ranges between Kaikoura and St Arnaud, whilst the depth meant there was unlikely to be any damage regardless to modern structures in New Zealand (and probably only very minor damage to older buildings).

Secondly, the type and depth of earthquake indicated that there would be few aftershocks and those which did occur would not follow Båth’s Law. Generally the largest aftershock is expected to be one magnitude unit below that of the mainshock – in this case it would be about magnitude 5.0. However, moderate depth earthquakes rarely follow such a rule – generally the largest aftershock is 1.5-2 magnitudes below that of the mainshock. So far there have been three major aftershocks – a M3.7 (32km depth, 4:46am BST), a M3.8 (36km depth, 4:53am BST) & a M4.2 (96km depth, 3:35pm BST – not revised). I immediately wrote this tweets on my UKEQ account:
“M6.3 strikes upper South Island, NZ, ~70km depth. Large aftershock (M5+) are unlikely #eqnz”

Unsurprisingly, when the first detailed news article was put out by GeoNet (http://info.geonet.org.nz/display/quake/2015/04/24/Quake+hits+inland+Marlborough), they agreed with my assessment entirely. So far my assessment for aftershocks has proven correct and will very likely remain accurate.


The only remaining thing which I immediately asked was if there was a relationship between the Kaikoura Ranges earthquake & the Seddon earthquakes the day before. I concluded that though it was very unlikely the M4.4 & M5.1 earthquakes directly triggered the M6.2 Kaikoura Ranges earthquake, it was plausible that the Seddon earthquakes as a whole could have been a catalyst or contributor to this morning’s shake. This may well be investigated by seismologists in the next few months to years (perhaps a journal article will appear). Once again, the news article above corroborated with my own beliefs. It is therefore very evident that my experience with New Zealand seismicity – particularly South Island seismicity – has meant that my conclusions and assumptions are well founded from observations over the past 50 or so months.

Saturday 21 February 2015

Recent Japan Earthquakes A Reason For Concern

A map of the Northern Japan earthquakes according to GEOFON. The information given for each quake is the focal depth, the faulting type (OR = Oblique Reverse, R = Reverse, SS = Strike-Slip) & dip of the fault plane. Important geographical features are named and located clearly (Hokkaido, Honshu & Japan Trench).
A quick analysis of the recent Northern Japan Earthquake has revealed three important things. 

The first is that all of the events offshore of Honshu follows clear patterns; firstly, depth increases with distance westwards from the Japan Trench, concurrent with the subduction model. Whilst this may be fine for the easternmost three events, the Mw 6.7 earthquake on the 16th February is too shallow, as is the Mw 5.4 close to the Honshu coast. Both of these must have occurred within the Eurasian Plate, not in the Pacific Plate or within/near the plate interface.

Secondly, the events offshore of Honshu also follow a pattern in terms of fault plane dip; the three events closest to the Japan Trench have extremely shallow dip angles, consistent with a shallow dipping interface (thrust fault) at the onset of subduction of the Pacific Plate. The Mw 6.7 mainshock (as it is at present - future quakes may change this determination) has a dip angle which would be more expected for its location if it were on the subduction interface, but as it has been determined this is not the case then this is probably a thrust fault caused by compression of the Eurasian Plate in response to the subduction further to the east. The Mw 5.4 Honshu quake is much more difficult to analyse & will be discussed later; by depth it is likely within the asthenosphere above the plate interface & not the overlying Eurasian Plate.

The second revelation from this map is the triggering of other earthquakes by the 16th February moderate subduction event. The Mw 5.4 Hokkaido Earthquake (20th February) is not directly related to the Mw 6.7 Japan Trench event; however it is likely that it was triggered by the moderate M6+ event. Similar instances occurred during the onset of the final foreshock series in March last year preceding the Mw 8.1 Iquique Earthquake. These kind of events were shown by two small M5 events at depth, likely within the overlying South American Plate. It is likely these are stress alleviations at depth to compensate the stress release in the uppermost part of the subduction zone (i.e the shallow earthquakes). Unlike the Chile examples, this earthquake follows the expected subduction characteristics of an event at a more moderate depth (reverse, shallow fault plane angle).

The first of the two "moderate depth" Northern Chile earthquakes in March 2014. This event has either a strike-slip or an oblique normal faulting mechanism; by strike of the nodal plane it is more likely to be strike-slip (see NP1).

The second of the two "moderate depth" Northern Chile earthquakes in March 2014. This event has either a slightly oblique normal or very oblique normal faulting mechanism; by strike of the nodal plane it is more likely to be slightly oblique normal (see NP1).
The third & final revelation adds to a growing picture that has been emerging since I began my records at the beginning of 2014. That is the enigma of moderate depth earthquakes with indeterminable faulting mechanisms. The Honshu Coast Earthquake shows this enigma perfectly; one fault plane suggests strike-slip at an improbably angle of 30 degrees (which would be more consistent with reverse faulting); the other fault plane suggests reverse faulting (or slightly oblique reverse faulting) at an angle of 78 degrees (which would be more consistent with strike-slip faulting). This has puzzled me for months, but I may have a solution - something I have realised in the course of writing this.
The "enigma" Honshu, Japan earthquake of the 17th February 2015. This event either had a strike-slip or slightly oblique reverse faulting mechanism; by strike of the nodal plane it is more likely to be strike-slip (see NP1).
Published this month in Nature, a team from GNS Science in New Zealand (who else would I end up mentioning on the 4th Anniversary of the Port Hills Earthquake? - the earthquake in Christchurch on the 22nd February 2011 at 12:51pm NZDT) have discovered a semi-liquid layer, 5-6 kilometres thick, which lies at the plate interface of subduction zones. Here the two plates can, as such, "slide" past one another. This would cause a strike-slip event (lateral movement) at many different possible depths, with a fault plane angle consistent with the subduction interface angle (5-35 degrees). Therefore, it is tentatively suggested that the Mw 5.4 Honshu earthquake (17th February) may be associated with this layer. Whether the depth remains consistent (quakes at the distance this quake occurred at from the subduction trench are generally around 100-150km deep in New Zealand) with this hypothesis is much more difficult to determine.

What seems to be easy to conclude from this simple map and the associated GEOFON data is that these events are all linked together and likely something quite major. The similarities to the March 2014 Chile swarm are startling, whilst the identification of these events as being directly related to the subduction zone is inescapable.

What remains to be seen is how this develops in the next few days. From the Mw 6.7 Northern Chile earthquake in March 2014 to the Mw 8.1 Iquique earthquake in April 2014, there were 16 days. If things follows suit, a large Japan Trench megathrust earthquake would be anticipated on the 4th March 2015. I am very hesitant to say this large earthquake will even happen - these quakes are, after all, just within the aftershock zone of the March 2011 Mw 9.0 Tohoku Earthquake. Nevertheless, this is unusual aftershock behaviour four years after a mainshock.

Written by J H Gurney, 22:51 UTC, 21/02/2015

Tuesday 10 February 2015

Earthquake Swarm Strikes Near Yedisu Fault, Eastern Turkey

A minor earthquake swarm has afflicted a part of Eastern Turkey which has probably the highest risk of a major earthquake along the North Anatolian Fault other than the Marmara Sea.
At 9:58pm UTC last night a Ml 3.6 earthquake struck in Tunceli Province, about 35 kilometres (22 miles) due west of the town of Yedisu. In the next two hours four further earthquakes, the largest a Ml 4.1 event at 10:52pm UTC, struck in the same location. All of these events are located perilouslyclose to the as-yet unruptured 65-kilometres long Yedisu Fault.
In 1939 a massive earthquake (Mw 7.9) struck west of the city of Erzincan. Ever since, twelve large earthquake (>Mw 6.5) have unzipped the North Anatolian Fault from east of Erzincan to Izmit on the Marmara Sea. The last major earthquakes on the fault was the Mw 7.4 earthquake near Izmit in August 1999 & the Mw 7.2 near Duzce in November 1999.
Prior to the Izmit earthquakes, Stein et al. had published a paper in the Geophysics Journal (Progressive failure on the North Anatolian fault since 1939 by earthquake stress triggering, 1996) which had noted how each earthquake along the North Anatolian Fault had increased stress on the adjacent segments which subsequently ruptured. They therefore successfully predicted the Izmit earthquakes three years before they struck.
In their paper Stein et al. also noted that there was one major seismic gap still remaining - the 65-km long Yedisu Fault, bounded by previous events which occurred in 1949 (Mw 7.1) & 1992 (Mw 6.5). These events, alongside all the other major earthquakes since 1939, had increased stress on the Yedisu Fault by a massive 10.1 bars - this is the equivalent to 10.1 atmospheres. Other stress increase caused by the 1949 & 1992 events had led to the 1971 Bingol earthquake (M 6.3) & 2003 Bingol earthquake (Mw 6.4) to the south-east of the Yedisu Fault.
It is therefore possible that these earthquakes which occurred last night may well be precursors to the expected >M7 Yedisu earthquake. If this were to strike, much like the 1939 & 1992 Erzincan earthquakes they would be expected to cause serious damage to the city of Erzincan and likely kill hundreds if not thousands of people.

Post Scriptum: The Moment Tensor Solution provided by the Kandilli Observatory seems to indicate these earthquakes did not occur on the Yedisu Fault but likely on a nearby strike-slip fault with an alignment more akin to the faults which ruptured in 1971 with the M 6.3 Bingol earthquake.