Topic: Around the Globe in Real Time

[Nichi]

On May 31, the widest tornado in US (perhaps all?) history crossed through El Reno, Oklahoma - a rural area outside Oklahoma City. It was an EF-5 and 2.6 miles wide.

It has been much discussed because 3 storm chasers (scientists, not hot shots) were killed by it. Another controversial point haunts the event as well: a local radio/tv station advised folks to get into their cars and outrun it. They told the folks to drive south immediately, and apparently many obeyed. The result was a gridlock on one of the interstate freeways, where a few more folks were killed as they were stopped in traffic and got sucked out of it. It's been noted many times since: a car is the worst place to be in a tornado.

The tornado behaved very unpredictably, suddenly changing direction 45 degrees. Some say that the weather chasers would not have been so much prey to the storm had this not occurred. (As well, one of the Weather Channel's vehicles got lifted up, and they were tossed about, airborne for a while.)

Here's an amateur's video ... the first part is set to 16x speed.  You can see how enormous the thing was.

<span data-s9e-mediaembed="youtube" style="display:inline-block;width:100%;max-width:640px"><span style="display:block;overflow:hidden;position:relative;padding-bottom:56.25%"><iframe allowfullscreen="" loading="lazy" scrolling="no" style="background:url(https://i.ytimg.com/vi/mPYVzhSEgAI/hqdefault.jpg) 50% 50% / cover;border:0;height:100%;left:0;position:absolute;width:100%" src="https://www.youtube.com/embed/mPYVzhSEgAI"></iframe></span></span><br /><a href="http://www.youtube.com/v/mPYVzhSEgAI" target="_blank" rel="noopener noreferrer" class="bbc_link bbc_flash_disabled new_win">http://www.youtube.com/v/mPYVzhSEgAI</a>

[Nichi]

Global Warming is Spurring Sea Ice Expansion at the South Pole

Climate change's polar opposite effects.
By Alisa Opar
Published: 06/12/2013

 Sea ice in the Arctic is disappearing quickly, but the opposite is happening in Antarctica, where the reaches of frozen water have actually been growing. Counterintuitive as it may seem, global warming is driving very different changes at each pole, cooling the south while heating the north. Two recent studies in Nature Geosciencesought to tease out which mechanisms are spurring the cooling and sea ice expansion. Richard Bintanja and colleagues at the Royal Netherlands Meteorological Institute report that deep warm water is melting ice shelves that extend from the continent; cold water from the melted ice, in turn, insulates the surface water, keeping it cooler. Yet a group led by Paul Holland of the British Antarctic Survey says that another mechanism is at work: Fierce winds blasting the South Pole are pushing the ice farther north. While the answer isn’t yet clear, the groups agree that cooler waters will mean more sea-level rise, since less moisture will evaporate. Understanding what’s driving the cooling will strengthen sea-level forecasts. Says Bintanja, “Identifying climate mechanisms helps to make these climate models more accurate.”

This story originally ran in the July-August 2013 issue as "Antarctica on the Rocks."

http://mag.audubon.org/articles/climate/global-warming-spurring-sea-ice-expansion-south-pole

[Michael]

There is a complexity about Antarctica. There seem to be contradictory reports, but from what I've read, it's not contradictory to the scientists studying it. I'm always curious with new studies, as the overall situation is confusing for a layman like myself. But it is important to not draw too much from a small selection of research.

[Nichi]

There is a complexity about Antarctica. There seem to be contradictory reports, but from what I've read, it's not contradictory to the scientists studying it. I'm always curious with new studies, as the overall situation is confusing for a layman like myself. But it is important to not draw too much from a small selection of research.

I am similarly intrigued - and similarly confused.
What is the most intriguing thing to me is the old maps they have found, wherein Antarctica was not under ice, and was, in fact, a populated continent who did business with the tradesmen who could sail there. (Of course, this may not be "in fact" at all, but a dream...)

[Nichi]

Waterspouts: they aren't just for water. They can come ashore, as the folks filming this one near Tampa Bay, Florida, discovered, as it moved inland.  I think a good rule of thumb is this: if you can see the thing this clearly, get out of Dodge.

[Nichi]

This is the earth and moon, playing the role of stars, as seen from Saturn. Look at how we shine!


http://apod.nasa.gov/apod/ap130722.html

[Nichi]

Connection Between Gulf Stream and Sea Level Rise Confirmed by ODU Study

By Jim Raper

Recent studies have identified a "hot spot" of accelerated sea level rise from Cape Hatteras, N.C., to Boston, and researchers have speculated that a diminished flow of the Gulf Stream might be partly to blame. Now, data analysis by a team of oceanographers led by Tal Ezer of Old Dominion has given that hypothesis new scientific footing.

The team's findings were published in January by the Journal of Geophysical Research: Oceans, and have been reported by the websites of numerous media that cover climate and weather, such as Climate Central (www.climatecentral.org), Discover Magazine and the Weather Channel.

"There have been several papers showing the acceleration of sea level rise in the mid-Atlantic. This new paper confirms the hypothesis for why it's happening," Ezer said.

"The importance of the study is that in addition to the well-known causes for coastal sea level rise - global sea level rise and land subsidence in some places - the study points to a new source of sea level rise that is not yet fully understood: changes in ocean currents," Ezer added.

Findings of the researchers can explain why in some regions, such as Hampton Roads, the sea level has been rising two to three times faster than the average global sea level, and why the rate of the rise has increased in recent years.

Additionally, Ezer said, the findings can explain why unusually high sea levels that cause floods during high tides can persist for months in areas such as Norfolk, with no apparent weather event to cause them, and can help to improve projections of sea level rise for flood-prone regions.

Ezer, professor of ocean, earth and atmospheric sciences at ODU 's Center for Coastal Physical Oceanography (CCPO), has research specialties in numerical ocean modeling and coastal circulation and has been active in the 3-year-old ODU Climate Change and Sea Level Rise Initiative (CCSLRI). His co-authors on the latest publication are Larry Atkinson, Slover Professor of Oceanography and director of ODU's CCSLRI; William Bryce Corlett, a former ODU undergraduate student and now a graduate student at the University of Southampton in England; and José Blanco, a Chilean scientist who has worked extensively with ODU's CCPO.

The Gulf Stream flows like a huge river - a half-mile deep and more than 50 miles across - at about 100-200 miles off the eastern coast of the United States. It transports about 500 times the volume of water of the Amazon River. After flowing along the Florida eastern coast, the Gulf Stream separates from the coast at Cape Hatteras, N.C., and then turns northeastward, bringing large amounts of warm tropical waters into the cold North Atlantic Ocean. This causes it to play an important role in Earth's climate and weather.

When the Gulf Stream turns eastward it pulls water away from the mid-Atlantic shore, and the water level on the inshore side of the Gulf Stream, along the mid-Atlantic coast, is kept about 3-5 feet lower than the water on the other side of the Gulf Stream. Basic dynamic oceanography implies that this water elevation difference across the Gulf Stream is proportional to the speed of the stream, so the theory is that changes in the flow of the Gulf Stream would affect the coastal sea level in the mid-Atlantic more than any other coast.

"But does it really happen? And can observations confirm this theory? Those were the challenging issues tackled in this latest research," Ezer said.

Based on computer climate models, scientists have hypothesized for some time that a warming climate in the Arctic will slow the Atlantic Ocean circulation and reduce the Gulf Stream transport. The new study analyzed data that suggest that slowing of the Gulf Stream may have started already, and the accelerated sea level rise that has been measured in the area over the last few years is related to the changing Gulf Stream.

The research involves a new data analysis method that was developed by Ezer and Corlett, and published in Geophysical Research Letters in October 2012. The method can separate between long-term variations that may relate to climatic changes and faster changes such as seasonal cycles.

To obtain the Gulf Stream flow, the researchers pulled together available data on the total water transport of the Gulf Stream taken by a sea-floor cable across the Florida Strait, where the Gulf Stream starts, as well as observations of sea level obtained from satellite data further upstream. These data were compared with observations obtained from 10 tide gauges, some of which have continuously measured water levels for more than 100 years.

Somewhat to the surprise of the researchers, long-term sea level changes from far-apart stations, from Atlantic City, N.J., to Duck, N.C., on the Atlantic coast, and from Baltimore to Norfolk on the Chesapeake Bay, all seem to fluctuate up and down together within a period of about six to eight years.

"These results indicate that sea levels at all those stations are driven by the same force, and the candidate for that force was clearly the Gulf Stream," Ezer said. "Even more surprising was the very high statistical correlation found between changes in the Gulf Stream strength and the coastal sea level. The result was exactly as predicted by the theory, but real data rarely show such clear results.

"Another finding was that about 10 years ago the pattern of both sea level and the Gulf Stream suddenly changed from a fluctuating cycle to a continuously weakening Gulf Stream, and at the same time sea level rise rates seemed to increase."

These findings open the door for more studies that will try to better understand the causes of regional sea level changes and how best to predict future changes. "These scientific studies will help places like Norfolk to prepare for the increasing frequency of flooding that the city has seen in recent years," Ezer said.

http://blue.odu.edu/ao/ia/insideodu/20130221/feature1.php


Seems to me that the ramifications are for more than the East Coast ...
But the question remains, what slowed the Gulf stream?

[Nichi]

Of possible interest.... the point where the Gulf stream turns northeastward (where it meets the labrador currents):

<span data-s9e-mediaembed="youtube" style="display:inline-block;width:100%;max-width:640px"><span style="display:block;overflow:hidden;position:relative;padding-bottom:56.25%"><iframe allowfullscreen="" loading="lazy" scrolling="no" style="background:url(https://i.ytimg.com/vi/JnnH-f1IpDw/hqdefault.jpg) 50% 50% / cover;border:0;height:100%;left:0;position:absolute;width:100%" src="https://www.youtube.com/embed/JnnH-f1IpDw"></iframe></span></span><br /><a href="http://www.youtube.com/v/JnnH-f1IpDw" target="_blank" rel="noopener noreferrer" class="bbc_link bbc_flash_disabled new_win">http://www.youtube.com/v/JnnH-f1IpDw</a>

The Gulf Stream as seen here is on the right, and the convergence has been known for centuries as the "Graveyard of the Atlantic".

[erik]

It seems to happen sooner than expected?

[Nichi]

It seems to happen sooner than expected?

That's the consensus!

[erik]

Hopefully, the rise of sea levels will leave sufficient time for people to find other accommodation on higher ground. It seems about time to start setting intent for coming changes.

[Nichi]

<span data-s9e-mediaembed="youtube" style="display:inline-block;width:100%;max-width:640px"><span style="display:block;overflow:hidden;position:relative;padding-bottom:56.25%"><iframe allowfullscreen="" loading="lazy" scrolling="no" style="background:url(https://i.ytimg.com/vi/utDERYua404/hqdefault.jpg) 50% 50% / cover;border:0;height:100%;left:0;position:absolute;width:100%" src="https://www.youtube.com/embed/utDERYua404"></iframe></span></span><br /><a href="http://www.youtube.com/v/utDERYua404" target="_blank" rel="noopener noreferrer" class="bbc_link bbc_flash_disabled new_win">http://www.youtube.com/v/utDERYua404</a>

[Nichi]

Which Hurricane Forecast Model Should You Trust?
Posted by: Dr. Jeff Masters, 1:05 PM GMT on August 07, 2013    
    
The National Hurricane Center (NHC) set a new record in 2012 for accuracy of their 1, 2, 3, and 4-day Atlantic tropical cyclone track forecasts, but had almost no skill making intensity forecasts, according to the 2012 National Hurricane Center Forecast Verification Report, issued in March 2013. The new records for track accuracy were set despite the fact that the season’s storms were harder than average to forecast. The average error in a 1-day forecast was 46 miles, and was 79 miles for 2 days, 116 miles for 3 days, 164 miles for 4 days, and 224 miles for 5 days. The official track forecast had a westward bias of 10 - 17 miles for 1 - 3 day forecasts (i.e., the official forecast tended to fall to the west of the verifying position), and was 38 and 75 miles too far to the northeast for the 4- and 5-day forecasts, respectively.



Figure 1. Verification of official NHC hurricane track forecasts for the Atlantic, 1990 - 2012. Over the past 15 - 20 years, 1 - 3 day track forecast errors have been reduced by about 60%. Track forecast error reductions of about 50% have occurred over the past ten years for 4- and 5-day forecasts. Image credit: 2012 National Hurricane Center Forecast Verification Report.

NHC Intensity Forecasts: Little Improvement Since 1990

Official NHC intensity forecasts did better than usual in 2012, and had errors lower than the 5-year average error for 1, 2, 3, 4, and 5-day forecasts. However, 2012's storms were easier to predict than usual, due to due to a lack of rapidly intensifying hurricanes. These rapid intensifiers are typically the source of the largest forecast errors. The skill of official NHC 24-hour intensity forecasts made in 2012 for the Atlantic basin were only about 15% better than a "no-skill" forecast; 2, 3, 4, and 5-day intensity forecasts had no skill.


Figure 2. Verification of official NHC hurricane intensity forecasts for the Atlantic, 1990 - 2012. Intensity forecasts have shown little to no improvement since 1990. Image credit: 2012 National Hurricane Center Forecast Verification Report.

Which Track Model Should You Trust?

As usual, in 2012 the official NHC forecast for Atlantic storms was almost as good as or better than any individual computer models--though NOAA's GFS model did slightly better than the NHC official forecast at 12, 24, and 48-hour periods, and the European model forecast was slightly better at 12-hour forecasts. Despite all the attention given to how the European Center (ECMWF) model outperformed the GFS model for Hurricane Sandy's track at long ranges, the GFS model actually outperformed the European model in 2012 when summing up all track forecasts made for all Atlantic named storms. This occurred, in part, because the European model made a few disastrously bad forecasts for Tropical Storm Debby when it was in the Gulf of Mexico and steering currents were weak. For several runs, the model predicted a Texas landfall, but Debby ended up moving east-northeast to make a Northwest Florida landfall, like the GFS model had predicted. However, the best-performing model averaged over the past three years has been the European Center model, with the GFS model a close second. Wunderground provides a web page with computer model forecasts for many of the best-performing track models used to predict hurricane tracks. The European Center does not permit public display of tropical storm positions from their hurricane tracking module of their model, so we are unable to put ECMWF forecasts on this page.**No wonder I can never find it.
Here are some of the better models NHC regularly looks at:

ECMWF: The European Center's global forecast model
GFS: NOAA's global forecast model
NOGAPS: The Navy's global forecast model (now defunct, replaced by the NAVGEM model in 2013)
UKMET: The United Kingdom Met Office's global forecast model
GFDL: The Geophysical Fluid Dynamics Laboratory's hurricane model, initialized using GFS data
HWRF: The intended successor for the the GFDL hurricane model, also initialized using GFS data
CMC: The Canadian GEM model
BAMM: The very old Beta and Advection Model (Medium layer), which is still useful at longer ranges

If one averages together the track forecasts from the first six of these models, the NHC official forecast will rarely depart much from it. As seen in Figure 3, the HWRF and UKMET were well behind the ECMWF and GFS in forecast accuracy in 2012, but were still respectable. The simple BAMM model did well at 3, 4, and 5-day forecasts. The GFDL and CMC models did quite poorly compared to the ECMWF, GFS, UKMET, and HWRF. The Navy's NOGAPS model also did poorly in 2012, and has been retired. Its replacement for 2013 is called the NAVGEM model.



Figure 3. Skill of computer model forecasts of Atlantic named storms in 2012, compared to a "no skill" model called "CLIPER5" that uses just climatology and persistence to make a hurricane track forecast (persistence means that a storm will tend to keep going in the direction it's current going.) OFCL=Official NHC forecast; GFS=Global Forecast System model; GFDL=Geophysical Fluid Dynamic Laboratory model; HWRF=Hurricane Weather Research Forecasting model; UKMET=United Kingdom Met Office model; ECMWF=European Center for Medium Range Weather Forecasting model; TVCA=one of the consensus models that lends together several of the above models; CMC=Canadian Meteorological Center (GEM) model; BAMM=Beta Advection Model (Medium depth.) Image credit: National Hurricane Center 2012 verification report.

Which Intensity Model Should You Trust?

Don't trust any of them. NHC has two main statistical intensity models, LGEM and DSHP (the SHIPS model with inland decay of a storm factored in.) In addition, four dynamical models that are also use to track hurricanes--the GFS, ECMWF, HWRF, and GFDL models--all offer intensity forecasts. With the exception of the GFS model, which had a skill just 5% better than a "no-skill" intensity forecast for predictions going out 36 hours, all of these models had no skill in their intensity forecasts during 2012. The ECMWF and HWRF models were the worst models for intensity forecasts of 3, 4, and 5 days, with a skill of 20% - 60% lower than a "no-skill" forecast. The LGEM model, which was a decent intensity model in 2011, tanked badly in 2012 and had near-zero skill. The only model that was any good in 2012 was the IVCN "consensus" model, which averages together the intensity forecasts of two or more of the intensity models such as LGEM, GFDL, HWRF, and DSHP.

Some Promising Models From the Hurricane Forecast Improvement Project (HFIP)

Last year was the fourth year of a ten-year project, called the Hurricane Forecast Improvement Project (HFIP), aimed at reducing hurricane track and intensity errors by 50%. The new experimental models from HFIP generally performed poorly in 2012. However, the new FIM9 15-km global model was competitive with the ECMWF and GFS models for track, and the new CIRA Statistical Intensity Consensus (SPC3) model for intensity performed better than many of the traditional intensity models.

For those interested in learning more about the hurricane forecast models, NOAA has a 1-hour training video (updated for 2011.) Additional information about the guidance models used at the NHC can be found at NHC and the NOAA/HRD Hurricane FAQ.

Sources of Model Data

You can view 7-day ECMWF and 16-day GFS forecasts on wunderground's wundermap with the model layer turned on.
Longer ten-day ECMWF forecasts are available from the ECMWF web site.
FSU's experimental hurricane forecast page (CMC, ECMWF, GFDL, GFS, HWRF, and NAVGEM models)
NOAA's HFIP model comparison page (GFS, ECMWF, FIM, FIM9, UKMET, and CMC models.)
Experimental HFIP models

Quiet in the Atlantic

There are no tropical cyclone threat areas in the Atlantic to discuss today, and none of the reliable models for tropical cyclone formation is predicting development during the coming seven days. I plan on having a detailed update on Friday to discuss the latest long-range forecasts for the coming peak part of hurricane season.

Jeff Masters

http://www.wunderground.com/blog/JeffMasters/comment.html?entrynum=2482

[Nichi]

Poor Mexico.

[Nichi]

National Aeronautics and Space Administration - NASA

Earthquake creates a new island: Off the coast of Pakistan, a new island rose from the seafloor on Tuesday. The “mud island” rose from the seafloor near Gwadar on September 24, shortly after a magnitude 7.8 earthquake rattled the Balochistan province of northwestern Pakistan. The Advanced Land Imager (ALI) on NASA’s Earth Observing-1 (EO-1) captured this image of a new island off the coast of Pakistan on September 26, 2013.

The Earth Observing-1 (EO-1) satellite is an advanced land-imaging mission that demonstrates new instruments and spacecraft systems. EO-1 was launched from Vandenberg Air Force Base, California on November 21, 2000.

Image credit: NASA


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