Vine–Matthews–Morley hypothesis

Harry Hess proposed the seafloor spreading hypothesis in 1960 (published in 1962); the term "spreading of the seafloor" was introduced by geophysicist Robert S. Dietz in 1961. According to Hess, seafloor was created at mid-oceanic ridges by the convection of the Earth's mantle, pushing and spreading the older crust away from the ridge. Geophysicist Frederick John Vine and the Canadian geologist Lawrence W. Morley independently realized that if Hess's seafloor spreading theory was correct, then the rocks surrounding the mid-oceanic ridges should show symmetric patterns of magnetization reversals using newly collected magnetic surveys. Both of Morley's letters to Nature (February 1963) and Journal of Geophysical Research (April 1963) were rejected, hence Vine and his PhD adviser at Cambridge University, Drummond Hoyle Matthews, were first to publish the theory in September 1963. Some colleagues were skeptical of the hypothesis because of the numerous assumptions made—seafloor spreading, geomagnetic reversals, and remanent magnetism—all hypotheses that were still not widely accepted. The Vine–Matthews–Morley hypothesis describes the magnetic reversals of oceanic crust. Further evidence for this hypothesis came from Allan V. Cox and colleagues (1964) when they measured the remanent magnetization of lavas from land sites. Walter C. Pitman and J. R. Heirtzler offered further evidence with a remarkably symmetric magnetic anomaly profile from the Pacific-Antarctic Ridge. ==Marine magnetic anomalies==

The Vine–Matthews-Morley hypothesis correlates the symmetric magnetic patterns seen on the seafloor with geomagnetic field reversals. At mid-ocean ridges, new crust is created by the injection, extrusion, and solidification of magma. After the magma has cooled through the Curie point, ferromagnetism becomes possible and the magnetization direction of magnetic minerals in the newly formed crust orients parallel to the current background geomagnetic field vector. Once fully cooled, these directions are locked into the crust and it becomes permanently magnetized. Typically there are positive magnetic anomalies over normally magnetized crust and negative anomalies over reversed crust. Local anomalies with a short wavelength also exist, but are considered to be correlated with bathymetry. Magnetic anomalies over mid-ocean ridges are most apparent at high magnetic latitudes, over north-south trending ridges at all latitudes away from the magnetic equator, and east-west trending spreading ridges at the magnetic equator. The intensity of the remanent magnetization in the crust is greater than the induced magnetization. Consequently, the shape and amplitude of the magnetic anomaly is controlled predominately by the primary remanent vector in the crust. In addition, where the anomaly is measured on Earth affects its shape when measured with a magnetometer. This is because the field vector generated by the magnetized crust and the direction of the Earth's magnetic field vector are both measured by the magnetometers used in marine surveys. Because the Earth's field vector is much stronger than the anomaly field, a modern magnetometer measures the sum of the Earth's field and the component of the anomaly field in the direction of the Earth's field. Sections of crust magnetized at high latitudes have magnetic vectors that dip steeply downward in a normal geomagnetic field. However, close to the magnetic south pole, magnetic vectors are inclined steeply upwards in a normal geomagnetic field. Therefore, in both these cases the anomalies are positive. At the equator the Earth's field vector is horizontal so that crust magnetized there will also align horizontal. Here, the orientation of the spreading ridge affects the anomaly shape and amplitude. The component of the vector that effects the anomaly is at a maximum when the ridge is aligned east-west and the magnetic profile crossing is north-south. == Impact ==

The hypothesis links seafloor spreading and geomagnetic reversals in a powerful manner, with each expanding knowledge of the other. Early in the history of investigating the hypothesis only a short record of geomagnetic field reversals was available for studies of rocks on land. == See also ==