Planetary atmospheres are composed of layers with different properties, such as specific gaseous composition, temperature gradients, and pressure.
Terrestrial planets For Earth, Mars, and Venus, the lowest level of the atmosphere is the
troposphere, where most of the planet's clouds and weather are found. This extends from the ground up to 65 km on Venus, 40 km on Mars, and 17 km on Earth. Temperature varies by altitude according to the
lapse rate, as thermal energy from the ground is transported upward via
convection. Infrared radiation becomes trapped by molecules of gas and water vapor. Above the troposphere-stratosphere, the next layer of the atmosphere is termed the
mesosphere. In this region, the water vapor and carbon dioxide serves as a heat sink that radiates energy in the infrared. As a result, the temperature of the mesosphere decreases with altitude, reaching the coldest layer of the atmosphere at the top. Beyond the mesosphere is a region of the atmosphere called the
thermosphere that absorbs X-rays and extreme UV from the Sun, causing temperature to rise with altitude. The thermal properties of this layer vary daily and with solar activity cycles. The atmospheric region from the ground through the thermosphere is referred to as the
barosphere, since the
barometric law holds throughout. The outermost layer of a planetary atmosphere is termed the
exosphere. Here, the air pressure is so low at this altitude that the distance travelled between molecule collisions, the
mean free path, is greater than the atmospheric scale height. In this region, lower mass components with a thermal velocity exceeding the
escape velocity can
escape into space. For the Earth, the exosphere is at an altitude of 500 km, while it is around 210 km for Venus and Mars. On Earth, the exosphere extends to roughly 10,000 km, where it interacts with the
magnetosphere of Earth. All three planets have an
ionosphere, which is an
ionized region of the upper atmosphere. The ionospheres for Mars and Venus are closer to the surface and are less dense than on the Earth. The density of the Earth's ionosphere is greater at short distances from the planetary surface in the daytime and decreases as the ionosphere rises at night-time, thereby allowing a greater range of radio frequencies to travel greater distances.
Gas giants Gas giants are primarily composed of hydrogen and helium with traces of other elements, giving the planets a low
bulk density. Many of the molecules observed in the outer atmosphere are
hydrides, and most of these (with the exception of H2O and H2S) are
photochemically destroyed by solar UV in the stratosphere of Jupiter and Saturn. These
compounds get re-created by
thermo-chemical reactions within the hotter, lower regions of the atmosphere. Complex organic compounds are recycled back to methane by the highly
reducing atmosphere. A common feature of the gas giant planets are cloud layers that form where the combination of temperature and pressure are appropriate for condensing a particular volatile. For Jupiter and Saturn, the outermost cloud layer consists of ice particles of ammonia (NH3), with an underlying layer of ammonium hydrosulfide (NH4SH), then a deep layer of water clouds (H2O). For Uranus and Neptune, the top layer is a methane (CH4) layer of ice particles, followed by the same cloud layers as Jupiter and Saturn. One difference for Uranus and Neptune is that hydrogen sulfide (H2S) mixes at the same level as the condensed ammonia. These cloud layers are optically thick, absorbing light at all wavelengths. The result is a shallower scale height for the outer atmosphere. Models for the interiors of Jupiter and Saturn suggest that at a certain depth the hydrogen undergoes a phase change to a
metallic hydrogen fluid mixed with ice. There is possibly a diffuse or solid core of more massive elements. For Uranus and Neptune, there is no metallic hydrogen; instead there are interior layers of ice, placing these worlds in the sub-category of
ice giants. At sufficient depth, the ice may transition to a
supercritical fluid. Within the Solar System, gas giant planets formed beyond the
frost line, where the temperature from the young Sun was low enough for volatiles to condense into solid grains. In some star systems, dynamic processes in the
protoplanetary disk can cause a gas giant to migrate much closer to the central star, creating a
hot Jupiter. A prototype example is
51 Pegasi b. Through gravitational interaction, the orbit of the planet becomes circularized and it is
tidally locked into a synchronous rotation with one side constantly facing the star. The heated side becomes swollen, and high velocity winds distribute the thermal energy around the planet. The atmosphere may eventually be stripped away by the star's gravity, leaving behind a
super Earth. At the upper mass extreme of gas giants is a class of objects known as
brown dwarfs. There is no universal consensus on how to distinguish a brown dwarf from a gas giant, although a commonly used criteria is the ability to
fuse deuterium at around 13 times the
mass of Jupiter. Once the initial deuterium burning phase of a brown dwarf is concluded, the internal store of heat gradually makes its way to the surface then is radiated away over time. Convection occurs around the core, and possibly at the surface if the brown dwarf is receiving energy from a nearby star. Radiative energy transfer occurs throughout the remainder of the brown dwarf. Chemistry can occur throughout the atmosphere, which, depending on the chemical species, can change the opacity to radiative energy transfer. As with gas giants, in the cooler outer regions of a brown dwarf, some molecules can condense to form clouds. ==Circulation==