This idea, described as ‘"ingenious" by geologist Arthur Holmes,^[2] is now of historical interest only, being finally refuted by that same Holmes (see reference 7). It attempted to explain apparent anomalies in the distribution of land and water on the Earth's surface:^[3]

• More than 75% of the Earth's land area is in the northern hemisphere.
• Continents are roughly triangular.
• Oceans are roughly triangular.
• The north pole is surrounded by water, the south pole by land.
• Exactly opposite the Earth from land is almost always water.
• The Pacific Ocean occupies about one third of the Earth's surface.

To understand its appeal, consider the "regular solids": the sphere and the 5-member set of Platonic Solids. The solid with the lowest number of sides is the tetrahedron (four equilateral triangles); progressing through the hexahedron or cube, the octahedron, the dodecahedron and the icosahedron (20 sides), the sphere can be considered to have an infinite number of sides. All six regular solids share many symmetries.

Now, for each regular solid, we may relate its surface area and volume by the equation:

${\displaystyle V=k\times A\times {\sqrt {A}}}$ 

where k is a characteristic of each solid, V its volume, and A its area. As we traverse the set in order of increasing number of faces, we find that k increases for each member; it is 0.0227 for a tetrahedron and 0.0940 for a sphere. Thus the tetrahedron is the regular solid with the largest surface area for a given volume, and makes a reasonable endpoint for a shrinking spherical Earth.^[4]

The theory was first proposed by William Lowthian Green in 1875.^[1] It was still popular in 1917 when summarized as:

"The law of least action … demands that the somewhat rigid crustal portion of the earth keep in contact with the lessening interior with the least possible readjustment of its surface. … a shrinking sphere tends by the law of least action to collapse into a tetrahedron, or a tetra-hedroid, a sphere marked by four equal and equidistant triangular projections; and the earth with its three about equal and equidistant double continental masses triangular southward with three intervening depressed oceans triangular northward, its northern ocean and southern continent, with land everywhere antipodal to water, realizes the tetrahedroid status remarkably.“^[5]

This is suggesting that a cooling spherical Earth might have shrunk to form a tetrahedron, with its vertices and edges forming the continents, and four oceans (Pacific Ocean, Atlantic Ocean, Indian Ocean and Arctic Ocean) on its faces.

By 1915 German Alfred Wegener (1880–1930) had proposed in his continental drift theory that land masses moved great distances over the Earth's history. Wegener was also at first met with hostile reactions.^[6] By the mid-1920s Holmes had developed theories on what could cause the drift.^[7][8] The plate tectonics theory is now generally accepted to explain the dynamic nature of the Earth's surface; the tetrahedral shape plays no special role in modern theories.^[9] Explanations of details such as water to land ratios, the precise shape of continents and their sizes continue to be developed.

• Edna Kenton. The Tetrahedral Earth. Forgotten Books. ISBN 978-1-60506-415-4. Retrieved August 4, 2010. {{cite book}}: |work= ignored (help)