What happens when magnetic north and true north align?
Paul Wilkes, from Australia’s CSIRO, has been inspired by a rare event.
At some point in recent weeks, a once-in-a-lifetime event happened for people at Greenwich in the United Kingdom.
This means that, for someone at Greenwich, magnetic north (the direction in which a compass needle points) would have been in exact alignment with geographic north.
Geographic north (also called “true north”) is the direction towards the fixed point we call the North Pole.
Magnetic north is the direction towards the north magnetic pole, which is a wandering point where the Earth’s magnetic field goes vertically down into the planet.
The north magnetic pole is currently about 400km south of the north geographic pole, but can move to about 1,000km away.
How do the norths align?
Magnetic north and geographic north align when the so-called “angle of declination”, the difference between the two norths at a particular location, is 0°.
Declination is the angle in the horizontal plane between magnetic north and geographic north. It changes with time and geographic location.
On a map of the Earth, lines along which there is zero declination are called agonic lines. Agonic lines follow variable paths depending on time variation in the Earth’s magnetic field.
Currently, zero declination is occurring in some parts of Western Australia, and will likely move westward in coming years.
That said, it’s hard to predict exactly when an area will have zero declination. This is because the rate of change is slow and current models of the Earth’s magnetic field only cover a few years, and are updated at roughly five-year intervals.
At some locations, alignment between magnetic north and geographic north is very unlikely at any time, based on predictions.
The ever-changing magnetic poles
Most compasses point towards Earth’s north magnetic pole, which is usually in a different place to the north geographic pole. The location of the magnetic poles is constantly changing.
Earth’s magnetic poles exist because of its magnetic field, which is produced by electric currents in the liquid part of its core. This magnetic field is defined by intensity and two angles, inclination and declination.
The relationship between geographic location and declination is something people using magnetic compasses have to consider. Declination is the reason a compass reading for north in one location is different to a reading for north in another, especially if there is considerable distance between both locations.
Bush walkers have to be mindful of declination. In Perth, declination is currently close to 0° but in eastern Australia it can be up to 12°. This difference can be significant. If a bush walker following a magnetic compass disregards the local value of declination, they may walk in the wrong direction.
The polarity of Earth’s magnetic poles has also changed over time and has undergone pole reversals. This was significant as we learnt more about plate tectonics in the 1960s, because it linked the idea of seafloor spreading from mid-ocean ridges to magnetic pole reversals.
Geographic north, perhaps the more straightforward of the two, is the direction that points straight at the North Pole from any location on Earth.
When flying an aircraft from A to B, we use directions based on geographic north. This is because we have accurate geographic locations for places and need to follow precise routes between them, usually trying to minimise fuel use by taking the shortest route. All GPS navigation uses geographic location.
Geographic coordinates, latitude and longitude, are defined relative to Earth’s spheroidal shape. The geographic poles are at latitudes of 90°N (North Pole) and 90°S (South Pole), whereas the Equator is at 0°.
An alignment at Greenwich
For hundreds of years, declination at Greenwich was negative, meaning compass needles were pointing west of true north.
At the time of writing this article I used an online calculator to discover that, at the Greenwich Observatory, the Earth’s magnetic field currently has a declination just above zero, about +0.011°.
The average rate of change in the area is about 0.19° per year, which at Greenwich’s latitude represents about 20km per year. This means next year, locations about 20km west of Greenwich will have zero declination.
It’s impossible to say how long compasses at Greenwich will now point east of true north.
Regardless, an alignment after 360 years at the home of the Prime Meridian is undoubtedly a once-in-a-lifetime occurrence.