Watch 25 years of Arctic Sea ice disappear in 1 minute

References: Charctic Interactive Sea Ice Graph.
National Snow and Ice Data Center.
Animation by NOAA Climate.gov team, based on research data provided by Mark Tschudi, CCAR, University of Colorado.
Sea ice age is estimated by tracking of ice parcels using satellite imagery and drifting ocean buoys.

Since the 1980s, the amount of perennial ice in the Arctic has declined.
This animation tracks the relative amount of ice of different ages from 1987 through early November 2015.
The oldest ice is white; the youngest (seasonal) ice is dark blue.
Key patterns are the export of ice from the Arctic through Fram Strait and the melting of old ice as it passes through the warm waters of the Beaufort Sea.
In 1985, 20% of the Arctic ice pack was very old ice, but in March 2015, old ice only constituted 3% of the ice pack.

NASA-supported researchers have found that ice covering Greenland is melting faster than previously thought. The action is happening out of sight, below the surface.

Links :

• How is climate change affecting the Arctic ?

Pacific Ocean time lapse : Glittering blue, watch this hypnotic view of Earth from space over 24 hours

Clouds swirl across the Pacific Ocean in this time lapse. The data is from Himawari-8, a Japanese weather satellite in geostationary orbit over New Guinea. Every 10 minutes, it photographs the hemisphere below it. This animation is a loop of yesterday’s images. Strong winds head from East Asia, in the upper left, toward Alaska, hidden by clouds in the upper right. Australia is in the bottom center, with the edge of the Antarctic ice sheet below it and tropic storm Ula to its right. The reflection of the sun on smooth water, called sunglint, moves east to west across the Pacific just south of the Equator. At this time of year – the Southern Hemisphere’s summer – the North Pole is never sunlit, but the South Pole always is.

A video posted by mapbox (@mapbox) on Jan 6, 2016 at 1:39pm PST

From Mapbox’s Instagram account (via).

Always wanted to be an astronaut, but never quite made it to space?
A new site can at least make you feel like you went.
Glittering Blue is a beautiful, simple website that shows 24 hours of observations of Earth from the Japanese weather satellite Himawari-8 like you’ve never seen before.
It’s in stunning high-definition and gives a glimpse at what you might see if you were stationed 22,300 miles above the equator.

 The 12-second clip is a time-lapse of one section of the globe, constructed from a number of photos taken by the Japanese Himawari 8 satellite over a 24-hour period.

It shows the Earth as the sun rises over the western Pacific , travels past Australia (somewhere about here) and eventually sets on the other side.

The clip also shows a Category 5 typhoon captured in pictures that day -- August 3, 2015 -- called Typhoon Soudelor.

Sit back, relax, and watch from above : glittering.blue

Built by Charlie Loyd, who works on satellite imagery at Mapbox, the process used to create the beautiful animation is open source.
Loyd says that “Himawari-8 has the best sensor of its kind in space today” and that it’s how Earth “really looks” over 24 hours… except sped up.

Canada CHS update in the GeoGarage platform

20 nautical charts updated

see GeoGarage News

A new human-machine interface for the bridge

 CASCADe project

From Maritime Executive

Drawing directly from the experience of seafarers, the E.U.-funded project CASCADe has developed new adaptive bridge displays and design methodologies that treat humans and electronic equipment as parts of a cooperative system.

To date, the development of ship bridge systems is characterized by being non-harmonious and far from guaranteed to be of optimal design for the actual users of them. Existing regulations for system and procedure design are disconnected and defined on a level which is not informative for bridge design. Research has shown clearly, that in many cases, accidents and incidents were caused by human error due to non-optimal design of the human-machine interaction leading to degraded situation awareness.

CASCADe addressed the design of bridges as an integrated whole with holistic perspective that allowed the detection and solving of potential conflicts including human error and inconsistencies and redundancies in the information presented on screens.

Beside cognitive ergonomics, CASCADe also pays deep attention to physical ergonomics and to the interplay between physical postures, physical moves and cognitive behavior and communications on the bridge.

The three-year project, which is coming to a close this month, then developed a set of adaptive bridge displays including a touch screen “Shared Display” intended to aid communication and co-operation on the bridge. This tool is fully customizable and allows one screen to show multiple sources of information in whatever configuration is most suitable for a particular situation.

 Pilot with PPU - Adaptative perspective display, shared for cooperation and bridge layout 

seen as an integrated whole

"It offers functionality to graphically annotate maps, leave notes for other crew members or complete checklists electronically."

The “Shared Display” provides functionality to graphically annotate maps, leave notes for other crew members or complete checklists electronically.

The CASCADe console was integrated with tools used by pilots in their Portable Pilot Units (PPUs). Firstly, CASCADe developed a protocol to share pilotage routes between the PPU and the ship’s electronic charts. Secondly, a link was established between the PPU and the bridge screens to allow mirroring of information from the PPU screen, enabling crew members to see extra information normally only available to the pilot.

All of these CASCADe tools were tested on both a physical simulator (a ship simulator used for training) and a virtual simulator (a software-based simulation of a ship bridge). The virtual simulation platform made it possible to test new bridge designs at the earliest stages of development, based purely on computational models.

The final evaluation of the CASCADe results took place in Kiel, Germany, late last year. The new ship bridge (including the handover and annotation tools) was presented to a group of nine local pilots, officers and cadets. The feedback was generally positive.

Under the coordination of OFFIS (Oldenburg Research and Development Institute for Information Technology Tools and Systems), CASCADe included a consortium of seven project partners from five E.U. countries including BMT Group, Raytheon Anschuetz, Mastermind Shipmanagement, the University of Cardiff, Marimatech and Symbio Concepts & Products.

Four further associated partners including the Maritime Cluster Northern Germany, Nautilus International, NSB Niederelbe Schiffahrtsgesellschaft mbH & Co. KG and the University of Tasmania also supported the project.

Remains of lost 1800s whaling fleet discovered off Alaska's Arctic coast

Scanned images from original Harper’s Weekly, Robert Schwemmer Maritime Library.

From NOAA

NOAA archaeologists have discovered the battered hulls of two 1800s whaling ships nearly 144 years after they and 31 others sank off the Arctic coast of Alaska in one of the planet's most unexplored ocean regions.

 Abandonment of the whalers in the Arctic Ocean, September 1871, including the George, Gayhead, and Concordia. 

Scanned from the original Harper’s Weekly 1871, courtesy of Robert Schwemmer Maritime Library.

The shipwrecks, and parts of other ships, that were found are most likely the remains of 33 ships trapped by pack ice close to the Alaskan Arctic shore in September 1871.
The whaling captains had counted on a wind shift from the east to drive the ice out to sea as it had always done in years past.
The ships were destroyed in a matter of weeks, leaving more than 1,200 whalers stranded at the top of the world until they could be rescued by seven ships of the fleet standing by about 80 miles to the south in open water off Icy Cape.
No one died in the incident but it is cited as one of the major causes of the demise of commercial whaling in the United States.

 This map shows the area that was surveyed during the Search for the Lost Whaling Fleets expedition. Image courtesy of M. Lawrence/NOAA.

With less ice in the Arctic as a result of climate change, archaeologists now have more access to potential shipwreck sites than ever before.
In September, a team of archaeologists from the Maritime Heritage Program in NOAA's Office of National Marine Sanctuaries scoured a 30-mile stretch of coastline in the nearshore waters of the Chukchi Sea, near Wainwright, Alaska.
Previous searches for the ships had found traces of gear salvaged from the wrecks by the local Inupiat people, as well as scattered timbers stranded high on the isolated beaches that stretch from Wainwright to Point Franklin.

 The shipwreck remains located off Point Franklin represent 19th century wooden ship construction. The wood frames are likely from the lower portion of the vessel near the turn of the bilge.

The wooden pegs, seen here on a section of ship hull, are known as treenails and were used to fasten pieces of wood together, and in this case they were used to attach the exterior hull planking or interior ceiling planks.

Image courtesy of Robert Schwemmer/NOAA .

Using state-of-the-art sonar and sensing technology, the NOAA team was able to plot the "magnetic signature" of the two wrecks, including the outline of their flattened hulls.
The wreck site also revealed anchors, fasteners, ballast and brick-lined pots used to render whale blubber into oil.
"Earlier research by a number of scholars suggested that some of the ships that were crushed and sunk might still be on the seabed," said Brad Barr, NOAA archaeologist and project co-director.
"But until now, no one had found definitive proof of any of the lost fleet beneath the water. This exploration provides an opportunity to write the last chapter of this important story of American maritime heritage and also bear witness to some of the impacts of a warming climate on the region's environmental and cultural landscape, including diminishing sea ice and melting permafrost."

 Seahorse islands with the GeoGarage nautical chart platform

James Delgado, maritime heritage director for NOAA's Office of National Marine Sanctuaries, said he believes the wrecks were pressed against a submerged sand bar that rests about 100 yards from shore.
Working from first-hand accounts of the loss of the fleet, he said the ice opened the hulls to the sea and tore away the upper portions of the ships, scattering their timbers on the beach, while the lower hulls, weighted down with ballast, and in some cases still anchored, stayed in place against the sand bar.
"Usually, the Arctic does not destroy ships if there is a natural obstacle like a sand bar, large rocks or a sheltered cove to partially divert the force of tons of ice," Delgado said.

 Abandonment of the whalers in the Arctic Ocean, September 1871, including the Monticello, Kohoa, Eugenia, Julian, Awashonks Thom Dickason, Minerva, Wm. Rotch, Victoria, and Mary.

Wainwright Inlet is in the background.

Courtesy of Ted and Ellie Congdon, Huntington Library.

On Sept. 12, 1871, the captains of the 33 whaling ships caught in the ice convened aboard the Champion to consider their options for saving the 1,219 officers, crew, and in some cases, families, from their fate.
Although, their situation was dire, there was some small glimmer of hope for rescue by seven nearby ships.
However, to save such a large party, the rescuing whale ships had to jettison their precious cargoes of whale oil, bone and their expensive whaling gear to make room for the survivors.
The rescue ships were able to sail safely out of the Arctic and back to Honolulu, where hundreds of native Hawaiian whalers aboard the stranded vessels lived, while others sailed on to San Francisco, New Bedford and other cities.

Links :

• NOAA :  http://oceanexplorer.noaa.gov/explorations/15lostwhalingfleets/.