North Pole
The
North Pole is the northernmost point on the
Earth and is on the opposite side of the Earth from the
South Pole.
The
North Pole can be defined in five different ways:
# The
Geographic North Pole, also known as
True North, is the basis for the astronomic north pole, which is defined as approximately the point at which the axis of rotation meets the surface rotating counter-clockwise around the axis as observed from space. It is also the northernmost point on Earth; the point at which any linear direction of travel is south. The term
North Pole by itself usually refers to this definition.# The
Magnetic North Pole is one of the two poles of the Earth's geomagnetic field's
dipole moment, specifically the one that is closest to the geographic north pole. Navigators refer to it as the magnetic north pole because by knowing the angular declination from it to the geographic north pole where they are (usually printed on maps) they can determine the direction of the geographic north pole. Ironically, the magnetic north pole happens to be the Earth's south dipole moment, because by custom the magnetic poles are named after the geographic poles they are nearest. This pole moves in various ways, in ellipses, in a random motion over
eons, and by the two poles switching places, as explained in the article below. # The
Geophysical North Pole is a term designed to clarify the ambiguity caused by term
magnetic north pole as used by navigators to find the geographic north pole, when the Earth is treated as a magnet, as in physics. Ironically, the geophysical north pole is the same as the magnetic south pole, since the south end of magnets (such as the end of compass needles marked
N) are attracted to the geophysical north pole. The reason for this confusion is in the origin of the terms north and south pole in physics. The north and south poles of magnets (the dipoles) are named for the poles of the earth they are attracted to when used as compasses, which was one of the original uses of magnets (see
magnetism).# The
Geomagnetic North Pole is the north end of the axis of the magnetosphere, the geomagnetic field that surrounds earth, currently at latitude 78°30' North, 69°, which is north of Qaanaaq (Thule) in Greenland. Compasses are not affected significantly by this magnetic field.# The
Northern Pole of Inaccessibility is defined as the point in the Arctic farthest from any coastline, and is at . Similar poles exist in the
Pacific and
Indian oceans, and there is a dry land pole of inaccessibility in the
Antarctic.
The Geographic North Pole, also known as
True North, commonly called the
North Pole, lies in the
Arctic Ocean. Unlike its
antipode the
South Pole, it doesn't lie on a polar continent (
Antarctica means
anti-, i.e. opposite,
Arctis, the northern polar region), nor is it part of any (sub)continent or island, so there is no land, just waters which are almost permanently frozen. It is close to the northern point at which the Earth's axis of rotation meets the surface. Geographic North defines
latitude 90° North. In whichever direction you travel from there, you are always heading south. Classically (19th century) this pole was exactly where people believed the pole of rotation met the Earth's surface, but soon astronomers noticed a small apparent
variation of latitude as determined for a fixed point on Earth by observing stars. This variation had a period of about 435 days and the periodic part of it is now called the
Chandler wobble after its discoverer. It is desirable to tie the system of Earth coordinates (
latitude,
longitude, and elevations or
orography) to fixed landforms. Of course, given
continental drift and the rising and falling of land due to
volcanos,
erosion and so on, there is no system in which all geographic features are fixed. Yet the
International Earth Rotation and Reference Systems Service and the
International Astronomical Union have defined a framework called the
International Terrestrial Reference System that does an admirable job. The North pole of this system now defines geographic North and it does not quite coincide with the rotation axis. Also see
polar motion.
On the basis of the
sector principle,
Canada claims its sovereignty to extend all the way to the Geographic North Pole. There is no land at this location, which is usually covered by
sea ice. The theory under which Canada has claimed sovereignty to the North Pole is controversial as there is in fact 770 km of ocean between the pole and Canada's northernmost land point, and several nations, most notably the
United States, have challenged the notion that the North Pole does not lie in international waters.
Expeditions
The
Polaris expedition, an American attempt in
1871 led by
Charles Francis Hall, ended in disaster.
In April
1895 Fridtjof Nansen reached the latitude 86° 14´ N.
The first expedition to the pole was generally accepted to have been made on
April 6,
1909 by Anglo-American Navy engineer
Robert Edwin Peary, African-American
Matthew Henson, and four
Inuit men named
Ootah,
Seegloo,
Egingway, and
Ooqueah. However the party that accompanied Peary on the final stage of the journey included no one who was trained in navigation and could independently confirm his own navigational work, which some have controversially claimed to be particularly sloppy as he approached the Pole.
The distances and speeds Peary claimed to have achieved once the last support party turned back border on the incredible, almost three times that which he had accomplished up to that point. Peary's account of a beeline journey to the pole and back is contradicted by Henson's account of tortuous detours to avoid pressure ridges and open leads. But the controversy swung back in Peary's favour in
2005 when the British explorer
Tom Avery and four companions recreated Peary's journey with replica wooden sleds and
Canadian Eskimo Dog teams, reaching the North Pole in 36 days, 22 hours - nearly five hours faster than Peary.
The first undisputed sight of the pole was on
May 12 1926 by
Norwegian explorer
Roald Amundsen and his
American sponsor
Lincoln Ellsworth from the
airship Norge.
Norge, though Norwegian owned, was designed and piloted by the
Italian Umberto Nobile. The flight started from
Svalbard and crossed the icecap to
Alaska. Nobile, along with several scientists and crew from the
Norge overflew the Pole a second time on
May 24 1928 in the
Airship Italia.
|
USS Charlotte at the North Pole in 2005 |
On
May 3,
1952 U.S. Air Force Lieutenant Colonel
Joseph O. Fletcher and Lieutenant
William P. Benedict landed a plane at the geographic North Pole. Flying with them was scientist
Albert P. Crary.
The United States Navy submarine
USS Nautilus (SSN-571) crossed the North Pole on
August 3,
1958, and on
March 17,
1959, the
USS Skate (SSN-578) surfaced at the pole, becoming the first naval vessel to reach it.
Sir Wally Herbert led the team that made the first surface crossing of the Arctic Ocean (1968-69) - and by its longest axis - a feat that has never been repeated. In so doing the team became the first to reach the North Geographic Pole by surface travel without the assistance of airlifts. In addition no one alive today has personally surveyed and mapped on the ground a larger area of Antarctica than Sir Wally. He has been awarded the Polar Medal and was knighted in 2000 for services to polar exploration.
Ralph Plaisted made the first
confirmed surface conquest of the North Pole on
April 19,
1968.
The
Soviet nuclear powered icebreaker Arktika on
August 17,
1977, completed the first surface vessel journey to the North pole.
In 2005, the United States Navy submarine
USS Charlotte (SSN-766) surfaced through 61 inches of ice at the North Pole and spent 18 hours there. [
1]
The North Magnetic Pole is one of several locations on the
Earth's surface known as the "North Pole". Its definition, as the point where the
geomagnetic field points vertically downwards, i.e. the
dip is 90°, was proposed in
1600 by Sir
William Gilbert, a courtier of
Queen Elizabeth I, and is still used. It should not be confused with the less frequently used
North Geomagnetic Pole. Magnetic North is the place to which all
magnetic compasses point, although since the pole marked "N" on a bar magnet points north, and only opposite magnetic poles are attracted to each other, the Earth's magnetic north is actually a south magnetic pole.
The orientation of magnetic fields of planets can flip over, an event which is called a
geomagnetic reversal. The Earth's poles have done this repeatedly throughout history, and 500,000 years ago, the south magnetic pole was at the
South Pole. It is thought that this occurs when the circulation of liquid
nickel/
iron in the Earth's outer core is disrupted and then reestablishes itself in the opposite direction. It is not known what causes these disruptions. Proof of this can be seen at
mid-ocean ridges where
tectonic plates move apart, and the sea bed is filled in with
magma. As the magma comes out of the
mantle, the magnetic particles in it are attracted slightly to the North Pole, and when the poles switch, so does the direction in which the metallic elements face. Therefore, on the sea bed, parallel bands of alternating magnetic fields are found.
The first expedition to reach this pole was led by
James Clark Ross, who found it at Cape Adelaide on the Boothia Peninsula on
June 1,
1831.
Roald Amundsen found Magnetic North in a slightly different location in
1903. The third observation of Magnetic North was by
Canadian government scientists Paul Serson and Jack Clark, of the
Dominion Astrophysical Observatory, who found the pole at Allen Lake on Prince of Wales Island.
The Canadian government has made several measurements since, which show that the North Magnetic Pole is continually moving northwest. In 1996 an
expedition certified its location by magnetometer and theodolite at 78°35.7' North, 104° 11.9' West. Its location (in
2005) is 82°07' North, 114° 04' West, near
Ellesmere Island, the biggest of the
Queen Elizabeth Islands, in Canada. During the 20th century it has moved 1100 km, and since
1970 its rate of motion has accelerated from 9 km/
year to 41 km/year (
2001-
2003 average; see also
Polar drift). If it maintains its present speed and direction it will reach
Siberia in about 50 years, but it is expected to veer from its present course and slow down.
This movement is on top of a daily or
diurnal variation in which Magnetic North describes a rough ellipse, with a maximum deviation of 80 km from its mean position. This effect is due to disturbances of the geomagnetic field by the sun. A line drawn from one magnetic pole to the other does not go through the centre of the Earth; it actually misses it by about 530 km.
The angular difference between Magnetic North and true North varies with location, and is called the
magnetic declination.
The North Geomagnetic Pole is the pole of the
Earth's geo
magnetic field closest to true north. The first-order approximation of the Earth's magnetic field is that of a single magnetic
dipole (like a bar magnet), tilted about 11° with respect to Earth's rotation axis and centered at the Earth's core. The residuals form the nondipole field. The Geomagnetic poles are the places where the axis of this dipole intersects the Earth's surface. Because the dipole approximation is far from a perfect fit to the Earth's magnetic field, the magnetic field is not quite vertical at the geomagnetic poles. The locations of true vertical field orientation are the magnetic poles, and these are about 30 degrees of longitude away from the geomagnetic poles.
Like the North Magnetic Pole, the geomagnetic north pole is a south magnetic pole, because it attracts the north pole of a bar
magnet. It is the centre of the region in the
magnetosphere in which the
Aurora Borealis can be seen. Its present location is 78°30' North, 69° West, near
Qaanaaq in
Greenland, however it is now drifting away from North America and toward Siberia. The first voyage to this pole was by David Hempleman-Adams in
1992.
The Northern
Pole of Inaccessibility, located at 84°03'
north, 174°51'
west, is the point farthest from any northern coastline, about 1100 km from the nearest coast. It is a geographic construct, not an actual physical phenomenon. It was first reached by Sir
Hubert Wilkins, who flew by
aircraft in
1927; in
1958 a
Russian
icebreaker reached this point.
Astronomers define the north "geographic" pole of a
planet or other object in the
solar system by the planetary pole that is in the same ecliptic hemisphere as the Earth's north pole. More accurately, «The north pole is that pole of rotation that lies on the north side of the invariable plane of the solar system» [
2]. This means some objects will have directions of rotation opposite the "normal" (i.e., not counter-clockwise as seen from above the north pole). Another frequently used definition uses the right-hand rule to define the north pole: it is then the pole around which the object rotates counterclockwise [
3]. When using the first definition (the
IAU's), an object's
axial tilt will always be 90° or less, but its rotation period may be negative (
retrograde rotation); when using the second definition, axial tilts may be greater than 90° but rotation periods will always be positive.
For the
magnetic poles, their names are decided upon by the direction that their field lines emerge or enter the planet's crust. If they enter the same way as they do for Earth at the north pole, we call this the planet's north magnetic pole.
Some bodies in the solar system, including
Saturn's
moon Hyperion and the asteroid
4179 Toutatis, lack a stable geographic north pole. They rotate
chaotically because of their irregular shape and
gravitational influences from nearby planets and moons, and as a result the instantaneous pole wanders over their surface, and may vanish altogether for brief periods (when the object comes to a complete standstill with respect to the distant stars).
The projection of a planet's north geographic pole onto the
celestial sphere gives its north
celestial pole.
In the particular (but frequent) case of
synchronous satellites, four more poles can be defined. They are the
near,
far,
leading, and
trailing poles. Take
Io for example; this moon of
Jupiter rotates synchronously, so its orientation with respect to Jupiter stays constant. There will be a single, unmoving point of its surface where Jupiter is at the
zenith, exactly overhead —this is the
near pole, also called the
sub- or
pro-Jovian point. At the
antipode of this point is the
far pole, where Jupiter lies at the
nadir; it is also called the
anti-Jovian point. There will also be a single unmoving point which is furthest along Io's orbit (best defined as the point most removed from the plane formed by the north-south and near-far axes, on the leading side) —this is the
leading pole. At its antipode lies the
trailing pole. Io can thus be divided into north and south hemispheres, into pro- and anti-Jovian hemispheres, and into leading and trailing hemispheres. Note that these poles are
mean poles because the points are not, strictly speaking, unmoving: there is constant jiggling about the mean orientation, because Io's orbit is slightly eccentric and the gravity of the other moons disturbs it regularly.
During the
summer months, the North Pole experiences
twenty-four hours of daylight daily but during the
winter months the North Pole experiences
twenty-four hours of darkness daily. Sunrise and sunset do not occur in a twenty-four hour cycle. At the north pole, sunrise begins at the
Vernal equinox taking three months for the sun to reach its highest point at the
summer solstice when sunset begins, taking three months to reach sunset at the
Autumnal equinox. A similar effect can be observed at the
South Pole, with a six month difference. This day/night effect is in stark contrast to what is observed at the
Equator.
This effect is caused by a combination of the
Earth's
axial tilt and its rotation around the sun. The direction and angle of axial tilt of the Earth remains fairly constant (on a yearly basis) in its plane of rotation around the sun. Hence during the summer, the North Pole is always facing the sun's rays but during the winter, it always faces away from the sun.
In
1925, based upon the
Sector Principle,
Canada became the first country to extend its boundaries northward to the North Pole, at least on paper, between 60°W and 141°W
longitude, a claim that is not universally recognized. In addition, Canada claims the water between its
Arctic Islands as internal waters. The claim is not recognized by the
United States, which argues the
Northwest Passage is an international waterway, despite its minimal usage for shipping.
Denmark (
Greenland),
Russia and
Norway have made similar claims, which are also opposed by the United States and by the
European Union.
Otherwise, until
1999, the North Pole and
Arctic Ocean had been generally considered international territory. However, as the polar ice has begun to recede at a rate higher than expected (see
global warming), several countries have made moves to claim, or to enforce pre-existing claims to, the waters or seabed at the Pole. Russia made its first claim in
2001, claiming
Lomonosov Ridge, an
underwater mountain ridge underneath the Pole, as a natural extension of
Siberia. This claim was contested by
Norway,
Canada, the
United States and
Denmark in
2004. The Danish autonomous province of
Greenland has the nearest coastline to the North Pole, and Denmark argues the Lomonosov Ridge is in fact an extension of Greenland.
The potential value of the North Pole and the area around resides not so much in shipping but in the possibility that lucrative
petroleum and
natural gas reserves exist below the sea floor. Such reserves are known to exist under the
Beaufort Sea, and further exploration elsewhere in the Arctic might become more feasible if global warming opens up the Northwest Passage as a regular channel of international shipping and commerce, particularly if Canada is not able to enforce her claim to it.
Magnetic north is determined by the earth's magnetic field and is not the same as true (or geographic) north. The location of the magnetic north pole changes slowly over time, but it is currently northwest of
Hudson Bay in northern
Canada (approximately 700 km [450 mi] from the true north pole). Maps are based on the geographic north pole because it does not change over time, so north is always at the top of a quadrangle map. However, if you were walk a straight line following the direction your compass needle indicates as north, you would find that you didn't go from south to north on the map.
How far your path varied from true north depends on where you started from; the angle between a straight north-south line and the line you walked is the
magnetic declination in the area you were walking.
Magnetic declination has been measured throughout the U.S. and can be corrected for on your
compass. The line of zero declination runs from magnetic north through
Lake Superior and across the western panhandle of
Florida. Along this line, true north is the same as magnetic north. If you are working west of the line of zero declination, your compass will give a reading that is east of true north. Conversely, if you are working east of the line of zero declination, your compass reading will be west of true north. The exact amount that you need to adjust the declination on your compass to reconcile magnetic north to true north is given in the map legend to the left of the map scale.
In many versions of the
Santa Claus mythos, the North Pole is the place where Santa Claus lives, and where his workshop is located.
*
South Pole*
Arctic Ocean*
List of firsts*
Inuit Circumpolar Conference*
Arctic Council*
Circumpolar arctic*
Arctic Council*
The Northern Forum*
North Pole Web Cam*
The short Arctic summer of 2004 *
The puzzling Arctic summer of 2003 *
FAQ on the Arctic and the North Pole *
Polar Controversies Still Rage article by Roderick Eime
*
Magnetic Poles locations since 1600 Download the KMZ file. For Google Earth Users.
*
The Polar Race a biennial race to the 1996 certified position of the Magnetic North Pole
*
Daylight, Darkness and Changing of the Seasons at the North Pole zh-yue:北極
