Earth, our home, is the third planet from the sun. While scientists continue to hunt for clues of life beyond Earth, our home planet remains the only place in the universe where we’ve ever identified living organisms.
Earth is the fifth-largest planet in the solar system. It’s smaller than the four gas giants — Jupiter, Saturn, Uranus and Neptune — but larger than the three other rocky planets, Mercury, Mars and Venus.
Earth has a diameter of roughly 8,000 miles (13,000 kilometers) and is mostly round because gravity generally pulls matter into a ball. But the spin of our home planet causes it to be squashed at its poles and swollen at the equator, making the true shape of the Earth an «oblate spheroid.»
Related: How big is Earth?
Our planet is unique for many reasons, but its available water and oxygen are two defining features. Water covers roughly 71 percent of Earth’s surface, with most of that water located in our planet’s oceans. About a fifth of Earth’s atmosphere consists of oxygen, produced by plants.
Related: Check out some stunning images of Earth from space
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PLANET EARTH’S ORBIT AROUND THE SUN
While Earth orbits the sun, the planet is simultaneously spinning around an imaginary line called an axis that runs through the core, from the North Pole to the South Pole. It takes Earth 23.934 hours to complete a rotation on its axis and 365.26 days to complete an orbit around the sun — our days and years on Earth are defined by these gyrations.
Earth’s axis of rotation is tilted in relation to the ecliptic plane, an imaginary surface through the planet’s orbit around the sun. This means the Northern and Southern hemispheres will sometimes point toward or away from the sun depending on the time of year, and this changes the amount of light the hemispheres receive, resulting in the changing seasons.
Earth happens to orbit the sun within the so-called «Goldilocks zone,» where temperatures are just right to maintain liquid water on our planet’s surface. Earth’s orbit is not a perfect circle, but rather a slightly oval-shaped ellipse, similar to the orbits of all the other planets in our solar system. Our planet is a bit closer to the sun in early January and farther away in July, although this proximity has a much smaller effect on the temperatures we experience on the planet’s surface than does the tilt of Earth’s axis.
Statistics about Earth’s orbit, according to NASA:
Average distance from the sun: 92,956,050 miles (149,598,262 km)
Perihelion (closest approach to the sun): 91,402,640 miles (147,098,291 km)
Aphelion (farthest distance from the sun): 94,509,460 miles (152,098,233 km)
Length of solar day (single rotation on its axis): 23.934 hours
Length of year (single revolution around the sun): 365.26 days
Equatorial inclination to orbit: 23.4393 degrees
A diagram of Earth’s elliptical orbit around the sun.
A diagram of Earth’s elliptical orbit around the sun. (Image credit: NOAA)
EARTH’S FORMATION AND DEVELOPMENT
Scientists think Earth was formed at roughly the same time as the sun and other planets some 4.6 billion years ago when the solar system coalesced from a giant, rotating cloud of gas and dust known as the solar nebula. As the nebula collapsed under the force of its own gravity, it spun faster and flattened into a disk. Most of the material in that disk was then pulled toward the center to form the sun.
Other particles within the disk collided and stuck together to form ever-larger bodies, including Earth. Scientists think Earth started off as a waterless mass of rock.
«It was thought that because of these asteroids and comets flying around colliding with Earth, conditions on early Earth may have been hellish,» Simone Marchi, a planetary scientist at the Southwest Research Institute in Boulder, Colorado, previously told Space.com.
However, in recent years, new analyses of minerals trapped within ancient microscopic crystals suggest that there was liquid water already present on Earth during its first 500 million years, Marchi said.
Radioactive materials in the rock and increasing pressure deep within the Earth generated enough heat to melt the planet’s interior, causing some chemicals to rise to the surface and form water, while others became the gases of the atmosphere. Recent evidence suggests that Earth’s crust and oceans may have formed within about 200 million years after the planet took shape.
Artist’s conception of the dust and gas surrounding a newly formed planetary system.
Artist’s conception of the dust and gas surrounding a newly formed planetary system. Most of the mass of this former nebula becomes the star at the center of the system. Other clumps and collisions form the planets. (Image credit: NASA)
EARTH’S INTERNAL STRUCTURE
Earth’s core is about 4,400 miles (7,100 km) wide, slightly larger than half the Earth’s diameter and about the same size as Mars. The outermost 1,400 miles (2,250 km) of the core are liquid, while the inner core is solid. That solid core is about four-fifths as big as Earth’s moon, at some 1,600 miles (2,600 km) in diameter. The core is responsible for the planet’s magnetic field, which helps to deflect harmful charged particles shot from the sun.
Above the core is Earth’s mantle, which is about 1,800 miles (2,900 km) thick. The mantle is not completely stiff but can flow slowly. Earth’s crust floats on the mantle much as a piece of wood floats on water. The slow motion of rock in the mantle shuffles continents around and causes earthquakes, volcanoes and the formation of mountain ranges.
Above the mantle, Earth has two kinds of crust. The dry land of the continents consists mostly of granite and other light silicate minerals, while the ocean floors are made up mostly of a dark, dense volcanic rock called basalt. Continental crust averages some 25 miles (40 km) thick, although it can be thinner or thicker in some areas. Oceanic crust is usually only about 5 miles (8 km) thick. Water fills in low areas of the basalt crust to form the world’s oceans.
Earth gets warmer toward its core. At the bottom of the continental crust, temperatures reach about 1,800 degrees Fahrenheit (1,000 degrees Celsius), increasing about 3 degrees F per mile (1 degree C per km) below the crust. Geologists think the temperature of Earth’s outer core is about 6,700 to 7,800 degrees F (3,700 to 4,300 degrees C) and that the inner core may reach 12,600 degrees F (7,000 degrees C) — hotter than the surface of the sun.
Earth’s layers shown in this modified NASA image.
In an image modified from NASA, an artist reveals the Earth’s inner structure of core, mantle, and crust. (Image credit: Shutterstock)
EARTH’S MAGNETIC FIELD
Earth’s magnetic field is generated by currents flowing in Earth’s outer core. The magnetic poles are always on the move, with the magnetic North Pole accelerating its northward motion to 24 miles (40 km) annually since tracking began in the 1830s. It will likely exit North America and reach Siberia in a matter of decades.
Earth’s magnetic field is changing in other ways, too. Globally, the magnetic field has weakened 10 percent since the 19th century, according to NASA.
But these changes are mild compared to what Earth’s magnetic field has done in the past. A few times in every million years or so, the field completely flips, with the North and the South poles swapping places. The magnetic field can take anywhere from 100 to 3,000 years to complete the flip.
The strength of Earth’s magnetic field decreased by about 90 percent when a field reversal occurred in ancient past, according to Andrew Roberts, a professor at the Australian National University. The drop makes the planet more vulnerable to solar storms and radiation, which could significantly damage satellites as well as communication and electrical infrastructure.
«Hopefully, such an event is a long way in the future and we can develop future technologies to avoid huge damage,» Roberts said in a statement.
When charged particles from the sun get trapped in Earth’s magnetic field, they smash into air molecules above the magnetic poles, causing them to glow. This phenomenon is known as the aurorae, the northern and southern lights.
Earth is surrounded by a thin layer of atmosphere.
Earth’s atmosphere surrounds the planet but gets thinner and thinner farther away from the surface. (Image credit: NASA)
Earth’s atmosphere is roughly 78 percent nitrogen and 21 percent oxygen, with trace amounts of water, argon, carbon dioxide and other gases. No other planet in the solar system has an atmosphere loaded with free oxygen, which is vital to one of the other unique features of Earth: life.
Related: Earth’s atmosphere: Composition, climate & weather
Air surrounds Earth and becomes thinner farther from the surface. Roughly 100 miles (160 km) above Earth, the air is so thin that satellites can zip through the atmosphere with little resistance. Still, traces of atmosphere can be found as high as 370 miles (600 km) above the planet’s surface.
The lowest layer of the atmosphere is known as the troposphere, which is constantly in motion and why we have weather. Sunlight heats the planet’s surface, causing warm air to rise into the troposphere. This air expands and cools as air pressure decreases, and because this cool air is denser than its surroundings, it then sinks and gets warmed by the Earth again.
Above the troposphere, some 30 miles (48 km) above the Earth’s surface, is the stratosphere. The still air of the stratosphere contains the ozone layer, which was created when ultraviolet light caused trios of oxygen atoms to bind together into ozone molecules. Ozone prevents most of the sun’s harmful ultraviolet radiation from reaching Earth’s surface, where it can damage and mutate life.
Water vapor, carbon dioxide and other gases in the atmosphere trap heat from the sun, warming Earth. Without this so-called «greenhouse effect,» Earth would probably be too cold for life to exist, although a runaway greenhouse effect led to the hellish conditions of Venus’ current surface.
Earth-orbiting satellites have shown that the upper atmosphere actually expands during the day and contracts at night due to heating and cooling.
EARTH’S CHEMICAL COMPOSITION
Oxygen is the most abundant element in rocks in Earth’s crust, composing roughly 47 percent of the weight of all rock. The second most abundant element is silicon, at 27 percent, followed by aluminum, at 8 percent; iron, at 5 percent; calcium, at 4 percent; and sodium, potassium and magnesium, at about 2 percent each.
Earth’s core consists mostly of iron and nickel and potentially smaller amounts of lighter elements, such as sulfur and oxygen. The mantle is made of iron and magnesium-rich silicate rocks. (The combination of silicon and oxygen is known as silica, and minerals that contain silica are known as silicate minerals.)
This photo, taken by astrophotographer Chirag Upreti shows the 2020 Flower Moon rising over Times Square in NYC.
This photo, taken by astrophotographer Chirag Upreti shows the 2020 Flower Moon rising over Times Square in NYC. (Image credit: Chirag Upreti)
Earth’s moon is 2,159 miles (3,474 km) wide, about one fourth of Earth’s diameter. Our planet has one moon, while Mercury and Venus have none and all the other planets in our solar system have two or more.
The leading explanation for how Earth’s moon formed is that a giant impact knocked the raw ingredients for the moon off the primitive, molten Earth and into orbit. Scientists have suggested that the object that hit the planet had roughly 10 percent the mass of Earth — about the size of Mars.
LIFE ON EARTH
Earth is the only planet in the universe known to possess life. The planet boasts several million described species, living in habitats ranging from the bottom of the deepest ocean to a few miles up into the atmosphere. Researchers think far more species remain that have yet to be described to science.
Researchers suspect that other candidates for hosting life in our solar system — such as Saturn’s moon Titan or Jupiter’s moon Europa — could house primitive living creatures. Scientists have yet to precisely nail down exactly how our primitive ancestors first showed up on Earth, although most believe that a chemical soup on the planet gave rise to the building blocks of living organisms. (The precise set of circumstances necessary to create life from a lifeless planet are pretty unlikely, so it seems we got very lucky.)
Read more from Live Science: How did life arise on Earth?
Another theory suggests that life first evolved on the nearby planet Mars, which could once have been habitable, then traveled to Earth on meteorites hurled from the Red Planet by impacts from other space rocks.
«It’s lucky that we ended up here, nevertheless, as certainly Earth has been the better of the two planets for sustaining life,» biochemist Steven Benner, of the Westheimer Institute for Science and Technology in Florida, told Space.com. «If our hypothetical Martian ancestors had remained on Mars, there might not have been a story to tell.»