Air Temperatures – The following high temperatures (F) were recorded across the state of Hawaii Thursday…along with the low temperatures Thursday:

8472  Lihue, Kauai
87 – 76  Honolulu, Oahu
85 – 69  Molokai
8866  Kahului AP, Maui
86 – 75  Kailua Kona
83 – 67  Hilo AP, Hawaii

Here are the latest 24-hour precipitation totals (inches) for each of the islands as of Thursday evening:

0.26  Waimea Heights, Kauai
0.02  Moanalua RG, Oahu
 0.00  Molokai
0.00  Lanai
 0.00  Kahoolawe
0.01  Lahainaluna, Maui
0.02  Honaunau, Big Island

The following numbers represent the strongest wind gusts (mph) as of Thursday evening:

21  Port Allen, Kauai
18  Waianae Harbor, Oahu
18  Molokai
18  Lanai
28  Kahoolawe
13  Maalaea Bay, Maui
25  Puu Mali, Big Island

Hawaii’s MountainsHere’s a link to the live webcam on the summit of our tallest mountain Mauna Kea (nearly 13,800 feet high) on the Big Island of Hawaii. This webcam is available during the daylight hours here in the islands, and at night whenever there’s a big moon shining down. Also, at night you will be able to see the stars — and the sunrise and sunset too — depending upon weather conditions.


Aloha Paragraphs

http://weather.unisys.com/satellite/sat_ir_enh_west_loop-12.gif
Counter-clockwise rotating gale low pressure system northwest

http://www.ssd.noaa.gov/goes/west/cpac/ir4.jpg
Thunderstorms west, southwest and south

http://www.ssd.noaa.gov/goes/west/hi/ir4.jpg
Most clouds are over the offshore waters west and southwest

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Just a few showers…here and there
Looping image


Small Craft Advisory…windiest coasts and channels in Maui County and the Big Island

 

~~~ Hawaii Weather Narrative ~~~

 

Broad Brush Overview: The cold front northwest of Kauai remains stalled, and will keep light winds and humid conditions over Kauai and Oahu, while dry trade winds prevail over the Big Island and Maui County. Strengthening trade winds will return to all islands Friday, becoming stronger this weekend as the cold front gradually dissipates. Windward areas may be more showery Friday night and Saturday. A trend toward a more typical trade wind weather pattern is expected statewide by Friday, with locally breezy trade winds bringing relief from the recent muggy weather.

Details: A small high northeast of the islands has an associated ridge, which extends over the central part of the island chain, supporting moderate trade winds near the Big Island and Maui County, while lighter south to southeast winds prevail over the remainder of the state. A stalled and gradually weakening cold front is several hundred miles northwest of Kauai, supported by a deep low centered to the distant northwest. These features appear to be shifting north. As this trend continues through Friday, trades will gradually strengthen and spread to all islands, humidity will diminish…and vog will slowly clear the smaller islands.

Latest satellite and radar images indicate a dry pattern statewide, and little change is expected. Trade winds will deliver little moisture to windward Maui County and the Big Island. Light southeast to southerly winds over Kauai and Oahu, will allow afternoon sea breezes to promote the development of clouds and a few showers over island interiors…although a stabilizing air mass should preclude the development of most showers.

Looking Further Ahead: A stabilizing ridge over the eastern islands will shift west and remain very close to the islands well into next week. Despite this, the trade wind flow may be somewhat showery Friday night and Saturday. Moisture pooled to the north of the islands is expected to become embedded within the trade wind flow, fueling these showers…with some being carried over into the leeward areas. The expectation is that light to moderate trade winds will continue into the middle of next week.

Here’s a wind profile of the Pacific Ocean – Closer view of the islands / Here’s the vog forecast animation / Here’s the latest weather map

Marine environment details: Trade winds and drier air are expected to return through the second half of the week into the upcoming weekend, as high pressure builds north of the islands. The stalled cold front west of Kauai will shift west and away from the islands.

The local winds are forecast to remain southeast in the light to moderate range, then increase through the weekend as the trades return. Small craft advisory conditions will become a possibility across the typically windier waters between Maui County and the Big Island beginning Friday.

Surf is expected to remain below average through the  weekend into early next week. The current swell that peaked yesterday along north and west facing shores will continue to trend down through Friday.

A small west-northwest swell associated a hurricane-force low that developed near the Kuril Islands this past Monday as Typhoon Saola lifted north, is expected to tonight…holding into the weekend before lowering into next week.

Surf along east facing shores will begin to rise Friday through the weekend as the trades return and strengthen locally and upstream of the islands. This, combined with a northeast swell associated with a batch of strong winds that is forecast to setup across the eastern Pacific this weekend…is expected to fill in and impact the beaches early next week. Surf may near advisory levels Monday through Tuesday.

South swells along south facing will remain small through the weekend.

 

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World-wide Tropical Cyclone activity

>>> Here’s the latest PDC Weather Wall Presentation, covering Typhoon Damrey, and a tropical disturbance in the South China Sea

>>> Here’s the latest PDC Weather Wall Presentation, covering the Atlantic Ocean, Caribbean Sea…and the Gulf of Mexico


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>>> Atlantic Ocean: No active tropical cyclones

>>> Caribbean Sea:  No active tropical cyclones

>>> Gulf of Mexico: No active tropical cyclones

Here’s a satellite image of the Caribbean Sea…and the Gulf of Mexico

Here’s the link to the National Hurricane Center (NHC)

>>> Eastern Pacific: No active tropical cyclones

Here’s a wide satellite image that covers the entire area between Mexico, out through the central Pacific…to the International Dateline.

Here’s the link to the National Hurricane Center (NHC)

>>> Central Pacific: No active tropical cyclones

Here’s a link to the Central Pacific Hurricane Center (CPHC)

>>> Northwest Pacific Ocean:

Typhoon 28W (Damrey) remains active…which will be moving inland over Vietnam

Here’s a satellite image of this system, along with a looping satellite image…and what the computer models are showing

>>> South Pacific Ocean: No active tropical cyclones

>>> North and South Indian Oceans / Arabian Sea: No active tropical cyclones


Here’s a link to the Joint Typhoon Warning Center (JTWC)


Interesting: Future volcanic eruptions could cause more climate disruptions – Major volcanic eruptions in the future have the potential to affect global temperatures and precipitation more dramatically than in the past because of climate change, according to a new study led by the National Center for Atmospheric Research (NCAR).

The study authors focused on the cataclysmic eruption of Indonesia’s Mount Tambora in April 1815, which is thought to have triggered the so-called “year without a summer” in 1816. They found that if a similar eruption occurred in the year 2085, temperatures would plunge more deeply, although not enough to offset the future warming associated with climate change. The increased cooling after a future eruption would also disrupt the water cycle more severely, decreasing the amount of precipitation that falls globally.

The reason for the difference in climate response between 1815 and 2085 is tied to the oceans, which are expected to become more stratified as the planet warms, and therefore less able to moderate the climate impacts caused by volcanic eruptions.

“We discovered that the oceans play a very large role in moderating, while also lengthening, the surface cooling induced by the 1815 eruption,” said NCAR scientist John Fasullo, lead author of the new study. “The volcanic kick is just that — it’s a cooling kick that lasts for a year or so. But the oceans change the timescale. They act to not only dampen the initial cooling but also to spread it out over several years.”

The research was published today in the journal Nature Communications. The work was funded in part by the National Science Foundation, NCAR’s sponsor. Other funders include NASA and the U.S. Department of Energy. The study co-authors are Robert Tomas, Samantha Stevenson, Bette Otto-Bliesner, and Esther Brady, all of NCAR, as well as Eugene Wahl, of the National Oceanic and Atmospheric Administration.

A detailed look at a deadly past

Mount Tambora’s eruption, the largest in the past several centuries, spewed a huge amount of sulfur dioxide into the upper atmosphere, where it turned into sulfate particles called aerosols. The layer of light-reflecting aerosols cooled Earth, setting in motion a chain of reactions that led to an extremely cold summer in 1816, especially across Europe and the northeast of North America. The “year without a summer” is blamed for widespread crop failure and disease, causing more than 100,000 deaths globally.

To better understand and quantify the climate effects of Mount Tambora’s eruption and to explore how those effects might differ for a future eruption if climate change continues on its current trajectory, the research team turned to a sophisticated computer model developed by scientists from NCAR and the broader community.

The scientists looked at two sets of simulations from the Community Earth System Model. The first was taken from the CESM Last Millennium Ensemble Project, which simulates Earth’s climate from the year 850 through 2005, including volcanic eruptions in the historic record. The second set, which assumes that greenhouse gas emission continue unabated, was created by running CESM forward and repeating a hypothetical Mount Tambora eruption in 2085.

The historical model simulations revealed that two countervailing processes helped regulate Earth’s temperature after Tambora’s eruption. As aerosols in the stratosphere began blocking some of the Sun’s heat, this cooling was intensified by an increase in the amount of land covered by snow and ice, which reflected heat back to space. At the same time, the oceans served as an important counterbalance. As the surface of the oceans cooled, the colder water sank, allowing warmer water to rise and release more heat into the atmosphere.

By the time the oceans themselves had cooled substantially, the aerosol layer had begun to dissipate, allowing more of the Sun’s heat to again reach Earth’s surface. At that point, the ocean took on the opposite role, keeping the atmosphere cooler, since the oceans take much longer to warm back up than land.

“In our model runs, we found that Earth actually reached its minimum temperature the following year, when the aerosols were almost gone,” Fasullo said. “It turns out the aerosols did not need to stick around for an entire year to still have a year without a summer in 1816, since by then the oceans had cooled substantially.”

The oceans in a changed climate

When the scientists studied how the climate in 2085 would respond to a hypothetical eruption that mimicked Mount Tambora’s, they found that Earth would experience a similar increase in land area covered by snow and ice.

However, the ocean’s ability to moderate the cooling would be diminished substantially in 2085. As a result, the magnitude of Earth’s surface cooling could be as much as 40 percent greater in the future. The scientists caution, however, that the exact magnitude is difficult to quantify since they had only a relatively small number of simulations of the future eruption.

The reason for the change has to do with a more stratified ocean. As the climate warms, sea surface temperatures increase. The warmer water at the ocean’s surface is then less able to mix with the colder, denser water below.

In the model runs, this increase in ocean stratification meant that the water that was cooled after the volcanic eruption became trapped at the surface instead of mixing deeper into the ocean, reducing the heat released into the atmosphere.

The scientists also found that the future eruption would have a larger effect on rainfall than the historical eruption of Mount Tambora. Cooler sea surface temperatures decrease the amount of water that evaporates into the atmosphere and, therefore, also decrease global average precipitation.

Though the study found that Earth’s response to a Tambora-like eruption would be more acute in the future than in the past, the scientists note that the average surface cooling caused by the 2085 eruption (about 1.1 degrees Celsius) would not be nearly enough to offset the warming caused by human-induced climate change (about 4.2 degrees Celsius by 2085).

Study co-author Otto-Bliesner said, “The response of the climate system to the 1815 eruption of Indonesia’s Mount Tambora gives us a perspective on potential surprises for the future, but with the twist that our climate system may respond much differently.”