When the sun erupts
The sun is susceptible to a number of different eruptions — including solar flares — that spew particles into space.
Solar eruptions can be beautiful, but they are also highly unpredictable. And they can affect our daily lives in ways most people dont realize.
Sunspots: An early warning
One such eruption starts with sunspots, which are cooler regions on the suns surface.
Like Earth, the sun is essentially a magnet with north and south poles.
But the sun is not a solid mass, so different parts of it rotate at different speeds. As a result, the suns magnetic field lines can become entangled, and sometimes, these sunspots release a sudden explosion of energy called a solar flare.
Often, a solar flare is followed by huge bursts of charged particles, called a coronal mass ejection (CME). These charged particles move incredibly fast sometimes more than 3,000 kilometres per second on what astronomers refer to as the solar wind.
Another way particles can be expelled is through coronal holes. These regions on the suns surface are cooler and less dense than the surrounding areas. As in the case of sunspots, the sun's magnetic lines provide an opening where the solar wind is able to escape more easily into space.
Earths magnetic field
When a wave of these particles travels toward Earth, it disrupts our magnetic field. Earths magnetic field is pushed backward until it snaps, and charged particles are funneled toward the poles.
Lights in the sky
When charged particles from the sun collide with molecules in our atmosphere, they excite the electrons of those molecules. When the electrons return to their original charge, they emit visible light.
The colour of that light depends on the kind of molecule and the altitude of the collision.
Green is the most common colour, produced when the particles collide with oxygen at an altitude of around 100 to 300 km. At about 300 to 400 km, the interaction with oxygen produces red. Pink occurs below 100 km when nitrogen atoms are struck.
All these individual interactions combine to make waves or curtain effects along magnetic field lines.
This activity can result in a dazzling spectacle, but waves of charged particles can also disrupt satellites and power grids.
The Carrington Event
At 11:18 a.m. on Sept. 1, 1859, English astronomers Richard Carrington and Richard Hodgson independently recorded the earliest observations of a solar flare on the surface of the sun.
Carrington sketched what he saw.
Hours later, a geomagnetic storm hit Earth.
Like lightning, charged particles always take the path of least resistance. When the Carrington coronal mass ejection reached our planet, that path was telegraph wires. Telegraphs all over Europe and North America failed; in some cases, they burst into flames. Telegraph operators received electric shocks.
In some cases, their machines mysteriously continued to work, even after they disconnected the batteries. In a way, the telegraph machines were temporarily solar-powered.
Blackout in Quebec
Today, electronic networks are interwoven with almost every aspect of our lives.
If a solar storm as powerful as the Carrington Event comes, it will affect everything weve come to depend on in our daily lives, such as our cellphones, GPS and electricity.
Weve actually seen what it can do here in Canada. On March 9, 1989, a coronal mass ejection struck Earth. The particles travelled along the Canadian Shield and eventually found a weakness in the long transmission lines of Hydro-Qubec's power grid. Breakers tripped all over the province. The power failure lasted nine hours.
Solar eruptions are a wondrous, in many ways still mysterious phenomenon, which is why scientists are working hard to understand them.
Editing: Andre Mayer | Design and Development: Richard Grasley and Dwight Friesen, CBC News Labs | Top image: NASA