Tuesday, 26 April 2016
Thursday, 21 April 2016
WASHINGTON RISING
Over vast expanses of time, powerful tectonic forces have
massaged the western edge of the continent, smashing together a seemingly
endless number of islands to produce what we now know as North America and the
Pacific Northwest.
Intuition tells us that the earth’s crust is a permanent,
fixed outer shell – terra firma. Aside from the rare event of an earthquake or
the eruption of Mount St. Helen’s, our world seems unchanging, the landscape constant.
In fact, it has been on the move for billions of years and continues to shift
each day.
As the earth’s core began cooling, some 4.5 billion years
ago, plates, small bits of continental crust, have become larger and smaller as
they are swept up in or swept under their neighboring plates. Large chunks of
the ocean floor have been uplifted, shifted and now find themselves thousands
of miles in the air, part of mountain chains far from the ocean today or carved
by glacial ice into valleys and basins.
Two hundred million years ago, Washington was two large islands, bits of continent on the move westward, eventually bumping up against the North American continent and calling it home.
Two hundred million years ago, Washington was two large islands, bits of continent on the move westward, eventually bumping up against the North American continent and calling it home.
Even with their new fixed address, the shifting continues;
the more extreme movement has subsided laterally and continues vertically. The
upthrusting of plates continues to move our mountain ranges skyward – the path
of least resistance.
This dynamic movement has created the landscape we see today and helped form the fossil record that tells much of Washington’s relatively recent history – the past 50 million years. Chuckanut Drive is much younger than other parts of Washington. The fossils found there lived and died some 40-55 million years ago, very close to where they are now, but in a much warmer, swampy setting. The exposures of the Chuckanut Formation were once part of a vast river delta; imagine, if you will, the bayou country of the Lower Mississippi.
This dynamic movement has created the landscape we see today and helped form the fossil record that tells much of Washington’s relatively recent history – the past 50 million years. Chuckanut Drive is much younger than other parts of Washington. The fossils found there lived and died some 40-55 million years ago, very close to where they are now, but in a much warmer, swampy setting. The exposures of the Chuckanut Formation were once part of a vast river delta; imagine, if you will, the bayou country of the Lower Mississippi.
The siltstones, sandstones, mudstones and conglomerates of
this formation were laid down about 40-54 million years ago during the Eocene
epoch, a time of luxuriant plant growth in the subtropical flood plain that
covered much of the Pacific Northwest.
This ancient wetland provided ideal conditions to preserve
the many trees, shrubs and plants that thrived here. Plants are important in
the fossil record because they are more abundant and can give us a lot of information
about climate, temperature, the water cycle and humidity of the region. The
Chuckanut flora is made up predominantly of plants whose modern relatives live
in tropical areas such as Mexico and Central America.
While less abundant, evidence of the animals that called
this ancient swamp home are also found here. Rare bird, reptile, and mammal
tracks have been immortalized in the outcrops of the Chuckanut Formation.
Tracks of a type of archaic mammal of the Orders Pantodonta or Dinocerata (blunt foot herbivores), footprints from a small shorebird, and tracks from an early equid or webbed bird track give evidence to the vertebrates that inhabited the swamps, lakes and river ways of the Pacific Northwest 50 million years ago.
Tracks of a type of archaic mammal of the Orders Pantodonta or Dinocerata (blunt foot herbivores), footprints from a small shorebird, and tracks from an early equid or webbed bird track give evidence to the vertebrates that inhabited the swamps, lakes and river ways of the Pacific Northwest 50 million years ago.
Fossil mammals from Washington do get most of the press. The
movement of these celebrity vertebrates was captured in the soft mud on the
banks of a river, one of the only depositional environments favorable for track
preservation.
The bone record is actually far less abundant that the plant
record, except near shell middens, given the preserving qualities of calcium
and an alkaline environment. While calcium rich bones and teeth fossilize well,
they often do not get laid down in a situation that makes this possible.
Hence the terrestrial paleontological record of Washington State
at sites like Chuckanut is primarily made up of plant material.
Monday, 11 April 2016
CETACEA: HUMPBACK WHALE
Look at this lovely maternal bond between an adult Humpback whale female, Megaptera novaeangliae, and her young. Humpbacks are a species of baleen whale for whom I hold a special place in my heart.
Baleens are whales who feed on plankton and other wee oceanic tasties that they consume through their baleens, a specialised filter of keratin that frames their mouths.
There are fifteen species of baleen whales. They inhabit all major oceans, in a wide band running from the Antarctic ice edge to 81°N latitude.
In the Kwak̓wala language of the Kwakiutl or Kwakwaka'wakw, speakers of Kwak'wala, of the Pacific Northwest, whales are known as g̱wa̱'ya̱m. Both the California grey and the Humpback whale live on the coast. Only a small number of individuals in First Nation society had the right to harpoon a whale. It was generally only the Chief who was bestowed this great honour. Humpback whales like to feed close to shore and enter the local inlets. Around Vancouver Island and along the coast of British Columbia, this made them a welcome food source as the long days of winter passed into Spring.
Humpback whales are rorquals, members of the Balaenopteridae family that includes the blue, fin, Bryde's, sei and minke whales. The rorquals are believed to have diverged from the other families of the suborder Mysticeti during the middle Miocene.
While cetaceans were historically thought to have descended from mesonychids— which would place them outside the order Artiodactyla— molecular evidence supports them as a clade of even-toed ungulates — our dear Artiodactyla. Baleen whales split from toothed whales, the Odontoceti, around 34 million years ago.