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- The definition of “habitable zone” is the distance from a star at which liquid water could exist on orbiting planets’ surfaces. Habitable zones are also known as Goldilocks’ zones, where conditions might be just right – neither too hot nor too cold – for life.
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The definition of “habitable zone” is the distance from a star at which liquid water could exist on orbiting planets’ surfaces. Habitable zones are also known as Goldilocks’ zones, where conditions might be just right – neither too hot nor too cold – for life.
- What Is the Habitable Zone? - NASA Science
For a planet, the habitable zone is the distance from a star...
- What is the habitable zone or “Goldilocks zone”? - NASA Science
The habitable zone is the area around a star where it is not...
- What Is the Habitable Zone? - NASA Science
In astronomy and astrobiology, the habitable zone (HZ), or more precisely the circumstellar habitable zone (CHZ), is the range of orbits around a star within which a planetary surface can support liquid water given sufficient atmospheric pressure.
Mar 10, 2021 · For a planet, the habitable zone is the distance from a star that allows liquid water to persist on its surface – as long as that planet has a suitable atmosphere. In our solar system, Earth sits comfortably inside the Sun’s habitable zone.
The habitable zone is the area around a star where it is not too hot and not too cold for liquid water to exist on the surface of surrounding planets. Imagine if Earth was where Pluto is. The Sun would be barely visible, and Earth’s ocean and much of its atmosphere would freeze.
- Overview
- Boundaries
- Changes in the Sun’s habitable zone
habitable zone, the orbital region around a star in which an Earth-like planet can possess liquid water on its surface and possibly support life. Liquid water is essential to all life on Earth, and so the definition of a habitable zone is based on the hypothesis that extraterrestrial life would share this requirement. This is a very conservative (but observationally useful) definition, as a planet’s surface temperature depends not only on its proximity to its star but also on such factors as its atmospheric greenhouse gases, its reflectivity, and its atmospheric or oceanic circulation. Moreover, internal energy sources such as radioactive decay and tidal heating can warm a planet’s surface to the melting point of water. These energy sources can also maintain subsurface reservoirs of liquid water, so a planet could contain life without being within its star’s habitable zone. Earth, for instance, has a thriving subsurface biosphere, albeit one that is composed almost exclusively of simple organisms that can survive in oxygen-poor environments. Jupiter’s moon Europa has a liquid water ocean tens of kilometres below its surface that may well be habitable for some organisms.
About 40 planets, including the nearest extrasolar planet, Proxima Centauri b, and three planets in the TRAPPIST-1 system, have been found that are both roughly Earth-sized and orbiting within the habitable zones of their stars. Astronomers have also used simulations of the climates of other extrasolar planets such as Kepler-452b to determine that they could have surface water under the right climatic conditions.
The inner boundary of a habitable zone is where water would be lost as a result of a runaway greenhouse effect, in which greenhouse gases in a planet’s atmosphere would trap incoming infrared radiation, leading to the planet’s becoming hotter and hotter until the water boiled away. The outer boundary is where such greenhouse warming would not be able to maintain surface temperatures above freezing anywhere on the planet. Astronomers have calculated the extent of the habitable zone for many different types of stars. For example, at present, the habitable zone of the Sun is estimated to extend from about 0.9 to 1.5 astronomical units (the distance between Earth and the Sun).
The location of a star’s habitable zone depends upon its luminosity. Because a star’s luminosity increases with time, both the inner and outer boundaries of its habitable zone move outward. Thus, a planet that is in the habitable zone when a star is young may subsequently become too hot. Venus may have been such a planet; however, because it is geologically active, its current surface is too young to show any evidence that a more clement climate may have existed billions of years ago. Other planets could be too cold for liquid water to exist when their star is young but might warm up enough to have liquid water on their surface later as their star’s luminosity increases. This may happen to Mars a few billion years hence. Thus, the most promising region to find Earth-like life would be in a “continuously habitable zone,” where liquid water could have been present from early in the star’s life up to the current epoch. The continuously habitable zone of the Sun (from four billion years ago to the present) is from about 0.9 to 1.2 astronomical units.
Britannica Quiz
Space Odyssey
Earth has had liquid water on its surface for much of the past four billion years. However, four billion years ago the Sun’s luminosity was only about 75 percent as intense as it is at present, and climate models suggest that Earth should have been frozen over at such a low solar luminosity. This apparent disagreement between theory and observation...
The habitable zone is the region around a star where liquid water can exist on a planet’s surface. Learn how stars, planets, and moons affect the habitable zone, and explore some examples of exoplanets and our own solar system.
Feb 16, 2023 · The Goldilocks zone or habitable zone is the region around a star where an orbiting planet could host liquid water and, therefore, possibly support life.
