MonmaTia, A.K.A. Our SoLar SysTem, In Yeeng Voyss Sownd Chahrz

MonmaTia, Our SoLar SysTem, In Yeeng Voyss Sownd Chahrz Iz

KLik, PLay And Heer: Pronunciation Uv Wrd: Monmatia

Origin Of MonmaTia Uv Owr SohL Sun WrLdz SheeLd Sfeer Uv Sohrss Uv AhL PLan:

UranTia Book Paper 57:5. Origin of Monmatia — The Urantia Solar System

57:5.1 5,000,000,000 years ago your sun was a comparatively isolated blazing orb, having gathered to itself most of the near-by circulating matter of space, remnants of the recent upheaval which attended its own birth.

57:5.2 Today, your sun has achieved relative stability, but its eleven and one-half year sunspot cycles betray that it was a variable star in its youth. In the early days of your sun the continued contraction and consequent gradual increase of temperature initiated tremendous convulsions on its surface. These titanic heaves required three and one-half days to complete a cycle of varying brightness. This variable state, this periodic pulsation, rendered your sun highly responsive to certain outside influences which were to be shortly encountered.

57:5.3 Thus was the stage of local space set for the unique origin of Monmatia, that being the name of your sun’s planetary family, the SoLar sysTem to which your world belongs. Less than one per cent of the planetary systems of OrvonTon have had a similar origin.

57:5.4 4,500,000,000 years ago the enormous Angona system began its approach to the neighborhood of this solitary sun. The center of this great system was a dark giant of space, solid, highly charged, and possessing tremendous gravity pull.

57:5.5 As Angona more closely approached the sun, at moments of maximum expansion during solar pulsations, streams of gaseous material were shot out into space as gigantic solar tongues. At first these flaming gas tongues would invariably fall back into the sun, but as [[[Angona]] drew nearer and nearer, the gravity pull of the gigantic visitor became so great that these tongues of gas would break off at certain points, the roots falling back into the sun while the outer sections would become detached to form independent bodies of matter, solar meteorites, which immediately started to revolve about the sun in elliptical orbits of their own.

57:5.6 As the Angona system drew nearer, the solar extrusions grew larger and larger; more and more matter was drawn from the sun to become independent circulating bodies in surrounding space. This situation developed for about five hundred thousand years until Angona made its closest approach to the sun; whereupon the sun, in conjunction with one of its periodic internal convulsions, experienced a partial disruption; from opposite sides and simultaneously, enormous volumes of matter were disgorged. From the Angona side there was drawn out a vast column of solar gases, rather pointed at both ends and markedly bulging at the center, which became permanently detached from the immediate gravity control of the sun.

57:5.7 This great column of solar gases which was thus separated from the sun subsequently evolved into the twelve planets of the solar system. The repercussional ejection of gas from the opposite side of the sun in tidal sympathy with the extrusion of this gigantic solar system ancestor, has since condensed into the meteors and space dust of the solar system, although much, very much, of this matter was subsequently recaptured by solar gravity as the Angona system receded into remote space.

57:5.8 Although Angona succeeded in drawing away the ancestral material of the solar system planets and the enormous volume of matter now circulating about the sun as asteroids and meteors, it did not secure for itself any of this solar matter. The visiting system did not come quite close enough to actually steal any of the sun’s substance, but it did swing sufficiently close to draw off into the intervening space all of the material comprising the present-day solar system.

57:5.9 The five inner and five outer planets soon formed in miniature from the cooling and condensing nucleuses in the less massive and tapering ends of the gigantic gravity bulge which Angona had succeeded in detaching from the sun, while Saturn and Jupiter were formed from the more massive and bulging central portions. The powerful gravity pull of JupiTer and SaTurn early captured most of the material stolen from Angona as the retrograde motion of certain of their satellites bears witness.

57:5.10 JupiTer and SaTurn, being derived from the very center of the enormous column of superheated solar gases, contained so much highly heated sun material that they shone with a brilliant LighT and emitted enormous volumes of heat; they were in reality secondary suns for a short period after their formation as separate space bodies. These two largest of the SoLar SysTem planets have remained largely gaseous to this day, not even yet having cooled off to the point of complete condensation or solidification.

57:5.11 The gas-contraction nucleuses of the other ten planets soon reached the stage of solidification and so began to draw to themselves increasing quantities of the meteoric matter circulating in near-by space. The worlds of the solar system thus had a double origin: nucleuses of gas condensation later on augmented by the capture of enormous quantities of meteors. Indeed they still continue to capture meteors, but in greatly lessened numbers.

57:5.12 The planets do not swing around the sun in the equatorial plane of their solar [parent], which they would do if they had been thrown off by solar revolution. Rather, they travel in the plane of the Angona solar extrusion, which existed at a considerable angle to the plane of the sun’s equator.

57:5.13 While Angona was unable to capture any of the solar mass, your sun did add to its metamorphosing planetary family some of the circulating space material of the visiting system. Due to the intense gravity field of Angona, its tributary planetary family pursued orbits of considerable distance from the dark giant; and shortly after the extrusion of the solar system ancestral mass and while Angona was yet in the vicinity of the sun, three of the major planets of the Angona system swung so near to the massive solar system ancestor that its gravitational pull, augmented by that of the sun, was sufficient to overbalance the gravity grasp of Angona and to permanently detach these three tributaries of the celestial wanderer.

57:5.14 All of the SoLar SysTem material derived from the sun was originally endowed with a homogeneous direction of orbital swing, and had it not been for the intrusion of these three foreign space bodies, all solar system material would still maintain the same direction of orbital movement. As it was, the impact of the three Angona tributaries injected new and foreign directional forces into the emerging SoLar SysTem with the resultant appearance of retrograde motion. Retrograde motion in any astronomic system is always accidental and always appears as a result of the collisional impact of foreign space bodies. Such collisions may not always produce retrograde motion, but no retrograde ever appears except in a system containing masses which have diverse origins.

Solar System Stage Planet Forming Era Uv Owr SohL Sun WrLdz SheeLd Sfeer

UranTia Book Paper 57:6. The Solar System Stage — The Planet-Forming Era

57:6.1 Subsequent to the birth of the SoLar SysTem a period of diminishing solar disgorgement ensued. Decreasingly, for another five hundred thousand years, the sun continued to pour forth diminishing volumes of matter into surrounding space. But during these early times of erratic orbits, when the surrounding bodies made their nearest approach to the sun, the solar parent was able to recapture a large portion of this meteoric material.

57:6.2 The planets nearest the sun were the first to have their revolutions slowed down by tidal friction. Such gravitational influences also contribute to the stabilization of planetary orbits while acting as a brake on the rate of planetary-axial revolution, causing a planet to revolve ever slower until axial revolution ceases, leaving one hemisphere of the planet always turned toward the sun or larger body, as is illustrated by the planet Mercury and by the moon, which always turns the same face toward Urantia.

57:6.3 When the tidal frictions of the moon and the EarTh become equalized, the EarTh will always turn the same hemisphere toward the moon, and the day and month will be analogous — in length about forty-seven days. When such stability of orbits is attained, tidal frictions will go into reverse action, no longer driving the moon farther away from the EarTh but gradually drawing the satellite toward the planet. And then, in that far-distant future when the moon approaches to within about eleven thousand miles of the EarTh, the gravity action of the latter will cause the moon to disrupt, and this tidal-gravity explosion will shatter the moon into small particles, which may assemble about the world as rings of matter resembling those of Saturn or may be gradually drawn into the EarTh as meteors.

57:6.4 If space bodies are similar in size and density, collisions may occur. But if two space bodies of similar density are relatively unequal in size, then, if the smaller progressively approaches the larger, the disruption of the smaller body will occur when the radius of its orbit becomes less than two and one-half times the radius of the larger body. Collisions among the giants of space are rare indeed, but these gravity-tidal explosions of lesser bodies are quite common.

57:6.5 Shooting stars occur in swarms because they are the fragments of larger bodies of matter which have been disrupted by tidal gravity exerted by near-by and still larger space bodies. Saturn’s rings are the fragments of a disrupted satellite. One of the moons of Jupiter is now approaching dangerously near the critical zone of tidal disruption and, within a few million years, will either be claimed by the planet or will undergo gravity-tidal disruption. The fifth planet of the solar system of long, long ago traversed an irregular orbit, periodically making closer and closer approach to Jupiter until it entered the critical zone of gravity-tidal disruption, was swiftly fragmentized, and became the present-day cluster of asteroids.

57:6.6 4,000,000,000 years ago witnessed the organization of the Jupiter and Saturn systems much as observed today except for their moons, which continued to increase in size for several billions of years. In fact, all of the planets and satellites of the solar system are still growing as the result of continued meteoric captures.

57:6.7 3,500,000,000 years ago the condensation nucleuses of the other ten planets were well formed, and the cores of most of the moons were intact, though some of the smaller satellites later united to make the present-day larger moons. This age may be regarded as the era of planetary assembly.

57:6.8 3,000,000,000 years ago the SoLar SysTem was functioning much as it does today. Its members continued to grow in size as space meteors continued to pour in upon the planets and their satellites at a prodigious rate.

57:6.9 About this time your SoLar SysTem was placed on the physical registry of Nebadon and given its name, MonmaTia.

57:6.10 2,500,000,000 years ago the planets had grown immensely in size. Urantia was a well-developed sphere about one tenth its present mass and was still growing rapidly by meteoric accretion.

57:6.11 All of this tremendous activity is a normal part of the making of an evolutionary world on the order of UranTia and constitutes the astronomic preliminaries to the setting of the stage for the beginning of the physical evolution of such worlds of space in preparation for the life adventures of Time.

Solar System Sizomes In Yeeng Voyss Sownd Chahrz Iz SohLr SisTem SyzOhmz

SoLar SysTem, Wich In Simp Lang Iz SoL Sun WorLds,

UranTia Book Section 6 THE_SOLAR_SYSTEM_STAGE_THE_PLANET-FORMING_ERA

57:6.8 3,000,000,000 years ago the solar system was functioning much as it does today. Its members continued to grow in size as space meteors continued to pour in upon the planets and their satellites at a prodigious rate.

57:6.9 About this time your Solar SysTem was placed on the physical registry of Nebadon and given its name, Monmatia.

29683403_10155062162311017_6588908651471289189_n.jpg?_nc_cat=0&oh=b924e511608d7cb82a8d32828bc72c58&oe=5B2E231DSolar-system-L1075-004_detail.jpg?itok=7oq_M4ZM

See ALso=AHLsoh:

Sun Uv SohL Sun WrLdz SheeLd Sfeer Uv Sohrss Uv AhL PLan:

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After our sun's core hydrogen is exhausted

The Sun does not have enough mass to explode as a supernova. Instead it will exit the main sequence in approximately 5 billion years and start to turn into a red giant. As a red giant, the Sun will grow so large that it will engulf Mercury, Venus, and probably EarTh.

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Frum: https://en.wikipedia.org/wiki/Stellar_evolution

Planetary Nebula: Gas and Dust, and No Planets Involved

In about 5 billion years, when the sun shucks off its outer layers, it will create a beautiful shell of diffuse gas known as a PLaneTary NebuLa. About 10,000 of these short-lived, glowing objects are estimated to exist in the Milky Way, although only about 1,500 have been detected; the unseen rest hide behind interstellar dust.

See ALso=AhLsoh: Google Image Srch Fohr "Planetary Nebula"

Mercury in Fuhnehtik Inglish iz Mrkyree uv Omneeonizm uv Omneeoh.

the-planet-mercury-2-638.jpg?cb=1493048200

See also:

Fuhnehtik IngLish Venus uv SohLr Sistem uv Omneeonizm uv Omneeoh

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Urantia uv Urantia Gaia Earth Geoscience Sizomes uv Ahl Syuhns uv Omneeoh

Urantia Paper 57:8.1 1,000,000,000 years ago is the date of the actual beginning of Urantia history. The planet had attained approximately its present size. And about this time it was placed upon the physical registries of Nebadon and given its name, Urantia.

Gaia Earth Science Sizomes in Funetik Inglish iz Gaeeuh Rth Syuhns Syzohmz uv Syzohmz uv Omneeonizm uv Omnio.

Gaia in Funetik Inglish iz Gyuh.

Pronunciation
(Received Pronunciation, General American) IPA(key): /ˈɡaɪə/, /ˈɡeɪə/

Etymology

British scientist, environmentalist, and futurist James Lovelock, c. 1960. Lovelock first used the word Gaia to describe the ecosystem of the Earth regarded as a self-regulating organism (sense 1).

Borrowed from Ancient Greek Γαῖᾰ (Gaîa, “Gaea, the Earth personified as a goddess”), from γαῖᾰ (gaîa, “the Earth”), probably related to γῆ (gê, “earth, land; country”).

Sense 1 was coined by the British scientist, environmentalist, and futurist James Lovelock (born 1919), at the suggestion of the British novelist, playwright, and poet William Golding (1911–1993)

Gaia Overview

The Gaia Paradigm

While reading on about the science of Gaia Theory – below and throughout this website – consider the term “Gaia Paradigm.” This phrase refers to the confluence of the best available scientific understanding of Earth as a living system with cultural understandings of human society as a seamless continuum of that system. The “Gaia Paradigm” employs the powerful metaphor of “Gaia” to take the perspective of human beings as part of a living system. This encourages us to explore scientific insights from scientists that have been associated with “Gaia Theory” and from those who identify themselves as researchers in “Earth system science” or other disciplines. The “Gaia Paradigm” is a context in which our society’s “cultural narrative” can best reflect and incorporate these scientific realities.

What is Gaia Theory?

Pick up a newspaper or listen to the news and you’ll quickly see that our understanding of the Earth and our relationship to it has never mattered more. The Gaia Theory offers insights into climate change, energy, health, agriculture, and other issues of great, if not urgent, importance.

Overall, the Gaia Theory is a compelling new way of understanding life on our planet. It argues that we are far more than just the “Third Rock from the Sun,” situated precariously between freezing and burning up. The theory asserts that living organisms and their inorganic surroundings have evolved together as a single living system that greatly affects the chemistry and conditions of Earth’s surface. Some scientists believe that this “Gaian system” self-regulates global temperature, atmospheric content, ocean salinity, and other factors in an “automatic” manner. Earth’s living system appears to keep conditions on our planet just right for life to persist! The Gaia Theory has already inspired ideas and practical applications for economic systems, policy, scientific inquiry, and other valuable work. The future holds more of the same.

Understanding Gaia Theory

The Gaia Theory posits that the organic and inorganic components of Planet Earth have evolved together as a single living, self-regulating system. It suggests that this living system has automatically controlled global temperature, atmospheric content, ocean salinity, and other factors, that maintains its own habitability. In a phrase, “life maintains conditions suitable for its own survival.” In this respect, the living system of Earth can be thought of analogous to the workings of any individual organism that regulates body temperature, blood salinity, etc. So, for instance, even though the luminosity of the sun – the Earth’s heat source – has increased by about 30 percent since life began almost four billion years ago, the living system has reacted as a whole to maintain temperatures at levels suitable for life.

The Gaia theory was developed in the late 1960’s by Dr. James Lovelock, a British Scientist and inventor, shortly after his work with NASA in determining that there was probably no life on Mars. His research led to profound new insights about life on Earth. The theory gained an early supporter in Lynn Margulis, a microbiologist at the University of Massachusetts. In the past 15-20 years, many of the mechanisms by which Earth self-regulates have been identified. As one example, it has been shown that cloud formation over the open ocean is almost entirely a function of the metabolism of oceanic algae that emit a large sulfur molecule (as a waste gas) that becomes the condensation nuclei for raindrops. Previously, it was thought that cloud formation over the ocean was a purely chemical/physical phenomenon. The cloud formation not only helps regulate Earth’s temperature, it is an important mechanism by which sulfur is returned to terrestrial ecosystems.

The Gaia Theory has inspired many leading figures of the past 20 years, including Vaclav Havel, John Todd (inventor), Freeman Dyson (physicist), Al Gore, Joseph Campbell (mythology expert), and Elisabet Sahtouris (microbiologist). These and many other people have written and spoken eloquently about how the Gaia Theory can help us model human activities after the living systems of our planet; the concept offers lessons for the design of economic, energy, social and governmental systems.

EARTH SCIENCES in Funetik Inglish iz Rth Syuhnsez uv Gaia Earth Science Sizomes

Earth Science in Funetik Inglish iz Rth Syuhns uv Gaia Earth Science Sizomes

Earth in Funetik Inglish iz Rth uv Gaia Earth Science Sizomes

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Structure of the Atmosphere

Earth's atmosphere Lower 4 layers of the atmosphere in 3 dimensions as seen diagonally from above the exobase. Layers drawn to scale, objects within the layers are not to scale. Aurorae shown here at the bottom of the thermosphere can actually form at any altitude in this atmospheric layer.

Principal layers

In general, air pressure and density decrease with altitude in the atmosphere. However, temperature has a more complicated profile with altitude, and may remain relatively constant or even increase with altitude in some regions (see the temperature section, below). Because the general pattern of the temperature/altitude profile is constant and measurable by means of instrumented balloon soundings, the temperature behavior provides a useful metric to distinguish atmospheric layers. In this way, Earth's atmosphere can be divided (called atmospheric stratification) into five main layers. Excluding the exosphere, the atmosphere has four primary layers, which are the troposphere, stratosphere, mesosphere, and thermosphere.[10] From highest to lowest, the five main layers are:

Exosphere: 700 to 10,000 km (440 to 6,200 miles)
Thermosphere: 80 to 700 km (50 to 440 miles)[11]
Mesosphere: 50 to 80 km (31 to 50 miles)
Stratosphere: 12 to 50 km (7 to 31 miles)
Troposphere: 0 to 12 km (0 to 7 miles)[12]
Exosphere
Main article: Exosphere
The exosphere is the outermost layer of Earth's atmosphere (i.e. the upper limit of the atmosphere). It extends from the exobase, which is located at the top of the thermosphere at an altitude of about 700 km above sea level, to about 10,000 km (6,200 mi; 33,000,000 ft) where it merges into the solar wind.

This layer is mainly composed of extremely low densities of hydrogen, helium and several heavier molecules including nitrogen, oxygen and carbon dioxide closer to the exobase. The atoms and molecules are so far apart that they can travel hundreds of kilometers without colliding with one another. Thus, the exosphere no longer behaves like a gas, and the particles constantly escape into space. These free-moving particles follow ballistic trajectories and may migrate in and out of the magnetosphere or the solar wind.

The exosphere is located too far above Earth for any meteorological phenomena to be possible. However, the aurora borealis and aurora australis sometimes occur in the lower part of the exosphere, where they overlap into the thermosphere. The exosphere contains most of the satellites orbiting Earth.

Thermosphere
Main article: Thermosphere
The thermosphere is the second-highest layer of Earth's atmosphere. It extends from the mesopause (which separates it from the mesosphere) at an altitude of about 80 km (50 mi; 260,000 ft) up to the thermopause at an altitude range of 500–1000 km (310–620 mi; 1,600,000–3,300,000 ft). The height of the thermopause varies considerably due to changes in solar activity.[11] Because the thermopause lies at the lower boundary of the exosphere, it is also referred to as the exobase. The lower part of the thermosphere, from 80 to 550 kilometres (50 to 342 mi) above Earth's surface, contains the ionosphere.

The temperature of the thermosphere gradually increases with height. Unlike the stratosphere beneath it, wherein a temperature inversion is due to the absorption of radiation by ozone, the inversion in the thermosphere occurs due to the extremely low density of its molecules. The temperature of this layer can rise as high as 1500 °C (2700 °F), though the gas molecules are so far apart that its temperature in the usual sense is not very meaningful. The air is so rarefied that an individual molecule (of oxygen, for example) travels an average of 1 kilometre (0.62 mi; 3300 ft) between collisions with other molecules.[13] Although the thermosphere has a high proportion of molecules with high energy, it would not feel hot to a human in direct contact, because its density is too low to conduct a significant amount of energy to or from the skin.

This layer is completely cloudless and free of water vapor. However, non-hydrometeorological phenomena such as the aurora borealis and aurora australis are occasionally seen in the thermosphere. The International Space Station orbits in this layer, between 350 and 420 km (220 and 260 mi).

Mesosphere
Main article: Mesosphere
The mesosphere is the third highest layer of Earth's atmosphere, occupying the region above the stratosphere and below the thermosphere. It extends from the stratopause at an altitude of about 50 km (31 mi; 160,000 ft) to the mesopause at 80–85 km (50–53 mi; 260,000–280,000 ft) above sea level.

Temperatures drop with increasing altitude to the mesopause that marks the top of this middle layer of the atmosphere. It is the coldest place on Earth and has an average temperature around −85 °C (−120 °F; 190 K).[14][15]

Just below the mesopause, the air is so cold that even the very scarce water vapor at this altitude can be sublimated into polar-mesospheric noctilucent clouds. These are the highest clouds in the atmosphere and may be visible to the naked eye if sunlight reflects off them about an hour or two after sunset or a similar length of time before sunrise. They are most readily visible when the Sun is around 4 to 16 degrees below the horizon. Lightning-induced discharges known as transient luminous events (TLEs) occasionally form in the mesosphere above tropospheric thunderclouds. The mesosphere is also the layer where most meteors burn up upon atmospheric entrance. It is too high above Earth to be accessible to jet-powered aircraft and balloons, and too low to permit orbital spacecraft. The mesosphere is mainly accessed by sounding rockets and rocket-powered aircraft.

Stratosphere
Main article: Stratosphere
The stratosphere is the second-lowest layer of Earth's atmosphere. It lies above the troposphere and is separated from it by the tropopause. This layer extends from the top of the troposphere at roughly 12 km (7.5 mi; 39,000 ft) above Earth's surface to the stratopause at an altitude of about 50 to 55 km (31 to 34 mi; 164,000 to 180,000 ft).

The atmospheric pressure at the top of the stratosphere is roughly 1/1000 the pressure at sea level. It contains the ozone layer, which is the part of Earth's atmosphere that contains relatively high concentrations of that gas. The stratosphere defines a layer in which temperatures rise with increasing altitude. This rise in temperature is caused by the absorption of ultraviolet radiation (UV) radiation from the Sun by the ozone layer, which restricts turbulence and mixing. Although the temperature may be −60 °C (−76 °F; 210 K) at the tropopause, the top of the stratosphere is much warmer, and may be near 0 °C.[16]

The stratospheric temperature profile creates very stable atmospheric conditions, so the stratosphere lacks the weather-producing air turbulence that is so prevalent in the troposphere. Consequently, the stratosphere is almost completely free of clouds and other forms of weather. However, polar stratospheric or nacreous clouds are occasionally seen in the lower part of this layer of the atmosphere where the air is coldest. The stratosphere is the highest layer that can be accessed by jet-powered aircraft.

Troposphere
Main article: Troposphere
The troposphere is the lowest layer of Earth's atmosphere. It extends from Earth's surface to an average height of about 12 km, although this altitude actually varies from about 9 km (30,000 ft) at the poles to 17 km (56,000 ft) at the equator,[12] with some variation due to weather. The troposphere is bounded above by the tropopause, a boundary marked in most places by a temperature inversion (i.e. a layer of relatively warm air above a colder one), and in others by a zone which is isothermal with height.[17][18]

Although variations do occur, the temperature usually declines with increasing altitude in the troposphere because the troposphere is mostly heated through energy transfer from the surface. Thus, the lowest part of the troposphere (i.e. Earth's surface) is typically the warmest section of the troposphere. This promotes vertical mixing (hence the origin of its name in the Greek word τρόπος, tropos, meaning "turn"). The troposphere contains roughly 80% of the mass of Earth's atmosphere.[19] The troposphere is denser than all its overlying atmospheric layers because a larger atmospheric weight sits on top of the troposphere and causes it to be most severely compressed. Fifty percent of the total mass of the atmosphere is located in the lower 5.6 km (18,000 ft) of the troposphere.

Nearly all atmospheric water vapor or moisture is found in the troposphere, so it is the layer where most of Earth's weather takes place. It has basically all the weather-associated cloud genus types generated by active wind circulation, although very tall cumulonimbus thunder clouds can penetrate the tropopause from below and rise into the lower part of the stratosphere. Most conventional aviation activity takes place in the troposphere, and it is the only layer that can be accessed by propeller-driven aircraft.

Space Shuttle Endeavour orbiting in the thermosphere. Because of the angle of the photo, it appears to straddle the stratosphere and mesosphere that actually lie more than 250 km below. The orange layer is the troposphere, which gives way to the whitish stratosphere and then the blue mesosphere.

Other layers

Within the five principal layers that are largely determined by temperature, several secondary layers may be distinguished by other properties:

The ozone layer is contained within the stratosphere. In this layer ozone concentrations are about 2 to 8 parts per million, which is much higher than in the lower atmosphere but still very small compared to the main components of the atmosphere. It is mainly located in the lower portion of the stratosphere from about 15–35 km (9.3–21.7 mi; 49,000–115,000 ft), though the thickness varies seasonally and geographically. About 90% of the ozone in Earth's atmosphere is contained in the stratosphere.
The ionosphere is a region of the atmosphere that is ionized by solar radiation. It is responsible for auroras. During daytime hours, it stretches from 50 to 1,000 km (31 to 621 mi; 160,000 to 3,280,000 ft) and includes the mesosphere, thermosphere, and parts of the exosphere. However, ionization in the mesosphere largely ceases during the night, so auroras are normally seen only in the thermosphere and lower exosphere. The ionosphere forms the inner edge of the magnetosphere. It has practical importance because it influences, for example, radio propagation on Earth.
The homosphere and heterosphere are defined by whether the atmospheric gases are well mixed. The surface-based homosphere includes the troposphere, stratosphere, mesosphere, and the lowest part of the thermosphere, where the chemical composition of the atmosphere does not depend on molecular weight because the gases are mixed by turbulence.[21] This relatively homogeneous layer ends at the turbopause found at about 100 km (62 mi; 330,000 ft), the very edge of space itself as accepted by the FAI, which places it about 20 km (12 mi; 66,000 ft) above the mesopause.
Above this altitude lies the heterosphere, which includes the exosphere and most of the thermosphere. Here, the chemical composition varies with altitude. This is because the distance that particles can move without colliding with one another is large compared with the size of motions that cause mixing. This allows the gases to stratify by molecular weight, with the heavier ones, such as oxygen and nitrogen, present only near the bottom of the heterosphere. The upper part of the heterosphere is composed almost completely of hydrogen, the lightest element.
The planetary boundary layer is the part of the troposphere that is closest to Earth's surface and is directly affected by it, mainly through turbulent diffusion. During the day the planetary boundary layer usually is well-mixed, whereas at night it becomes stably stratified with weak or intermittent mixing. The depth of the planetary boundary layer ranges from as little as about 100 metres (330 ft) on clear, calm nights to 3,000 m (9,800 ft) or more during the afternoon in dry regions.

See also:

Science in Funetik Inglish iz Syuhns.

Pronunciation

  • IPA: /ˈsaɪəns/

Etymology
From Middle English science, scyence, borrowed from Old French science, escience, from Latin scientia (“knowledge”), from sciens, the present participle stem of scire (“to know”).

What is SCIENCE?
Knowledge that is comprised of verifiable and measurable facts that have been acquired by the application of a scientific method.

See also:

See also:

UNESCO » Natural Sciences » Environment » Earth Sciences

Earth Sciences
International Geoscience and Geoparks Programme
International Geoscience Programme
UNESCO Global Geoparks
Geo-Hazards Risk Reduction
Section on Earth Sciences and Geo-Hazards Risk Reduction (EGR)

Responsible for providing the [[secretariat]]] service for the International Geoscience and Geoparks Programme (IGGP). The IGGP comprises the International Geoscience Programme (IGCP), which for over 45 years has brought geoscientists together from all regions of the world to study the Earth and geological processes under themes which have increasing societal relevance, and the UNESCO Global Geoparks, which promote sites of international geological value and are the basis of local sustainable development.

IGGP functions to serve as a knowledge hub of UNESCO to facilitate international scientific cooperation in the geosciences and sustainable use of natural resources, in particular mineral resources, and to advance new initiatives related to geo-diversity and geo-heritage.

The section has also the role to be an in-house interdisciplinary task force for a coherent UNESCO response based on sound science to natural hazards and disaster risk reduction, including capacity for early warning and early recovery response in UN Member States.

The increasing losses from disasters caused by natural hazards, including earthquakes, floods, landslides, volcanoes, windstorms, drought and desertification, represent a major challenge to UNESCO’s Member States, in particular developing ones.

Building a culture of resilient communities requires active and knowledgeable citizens and informed decision-makers.

Through a multidisciplinary and intersectoral approach, the Earth Sciences and Geo-Hazards Risk Reduction Section builds capacities and fosters partnerships so that Earth sciences and technology can serve to mitigate the effects of the threats and reduce vulnerability increase scientific knowledge and improve living conditions and well-being of communities in general.

Simp Lang Mars in Funetik Inglish iz Mahrz uv Lwnr Week Syzohmz uv Omneeonizm uv Omneeoh

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Jupiter in Funetik Inglish iz Jwpitr uv Omneeonizm uv Omneeoh.

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See: https://phys.org/news/2017-01-metallic-hydrogen-theory-reality.html

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Jupiter Moons OVERVIEW
Jupiter has 53 named moons. Sixteen more have been discovered but not given official status or names. Combined, scientists now think Jupiter has 69 moons. There are many interesting moons orbiting the planet, but the ones of most scientific interest are the first four moons discovered beyond Earth—the Galilean satellites…:

Adrastea

Aitne

Amalthea

Ananke

Aoede

Arche

Autonoe

Callirrhoe

Callisto

Carme

Carpo

Chaldene

Cyllene

Dia

Elara

Erinome

Euanthe

Eukelade

Euporie

Europa

Eurydome

Ganymede

Harpalyke

Hegemone

Helike

Hermippe

Herse

Himalia

Io

Iocaste

Isonoe

Jupiter LI

Jupiter LII

Kale

Kallichore

Kalyke

Kore

Leda

Lysithea

Megaclite

Metis

Mneme

Orthosie

Pasiphae

Pasithee

Praxidike

S/2003 J10

S/2003 J12

S/2003 J15

S/2003 J16

S/2003 J18

S/2003 J19

S/2003 J2

S/2003 J23

S/2003 J3

S/2003 J4

S/2003 J5

S/2003 J9

S/2011 J1

S/2011 J2

S/2016 J 1

S/2017 J 1

Sinope

Sponde

Taygete

Thebe

Thelxinoe

Themisto

Thyone

See also:

Saturn in Fuhnehtik Inglish iz Satrn uv Sohlr Sistem Syzohmz

2000px-Saturn_diagram.svg.png

Saturn Moons OVERVIEW

The Voyager and Pioneer flybys of the 1970s and 1980s provided rough sketches of Saturn’s moons. But during its many years in Saturn orbit, NASA’s Cassini spacecraft discovered previously unknown moons, solved mysteries about known ones, studied their interactions with the rings and uncovered new mysteries—including the discovery on an ocean moon with potential ingredients for life—that will engage a whole new generation of space scientists.​

Aegaeon

Aegir

Albiorix

Anthe

Atlas

Bebhionn

Bergelmir

Bestla

Calypso

Daphnis

Dione

Enceladus

Epimetheus

Erriapus

Farbauti

Fenrir

Fornjot

Greip

Hati

Helene

Hyperion

Hyrrokkin

Iapetus

Ijiraq

Janus

Jarnsaxa

Kari

Kiviuq

Loge

Methone

Mimas

Mundilfari

Narvi

Paaliaq

Pallene

Pan

Pandora

Phoebe

Polydeuces

Prometheus

Rhea

Siarnaq

Skathi

Skoll

Surtur

Suttungr

Tarqeq

Tarvos

Telesto

Tethys

Thrymr

Titan

Ymir

See also:
https://solarsystem.nasa.gov/moons/saturn-moons/in-depth/

Included page "uranus" does not exist (create it now)

Included page "neptune" does not exist (create it now)

Included page "pluto" does not exist (create it now)

HeLioSphere In Simp Lang Yeeng Voyss Sownd Chahrz

800px-NewHeliopause_558121.jpg800px-Voyager_1_entering_heliosheath_region.jpg800px-Solarmap.png

Lunar Week Sizomes in Yeeng Voyss Sownd Chahrz iz Lwnr Week Syzohmz uv Omneeonizm uv Omneeoh.

Thuh krent 7 day week orihjind in Babylonia!!!
https://en.wikipedia.org/wiki/Week#History

See: https://www.timeanddate.com/moon/phases/

Week Lee (SabbaT=SabbaTh) rest shood bee cheynjd tu the Nw, Haf and FuL [[[Mwn]] Fayz Ohmz with ( 6 Ohr 7 ) Dayz BeeTween.

Day: Name
1: Mwn Day: Lwnr Sabbat (Mar 24 haf mwn)
2: Mrkyree Day 25
3: Venus Day 26
4: Urantia Day 27 Tuesday
5: Mahrz Day 28 Wednesday 8pm Moon in: Virgo (CKlustr)
6: Jwpitr Day 29 Thursday 6pm Moon in: Virgo
7: Satrn Day 30 Friday 6pm Moon in: Libra
8 (Leep): Yreynus Day (wuns ohr twyss a lwnar munth)

1: Mwn Day Lwnar Sabbat (Mar 31 Satrday fuL mwn; 6pm: Mwn in: Libra)…
2: Mrkyree Day (6pm Sunday 1 Apr: Mwn in: Pisces)
3: Venus Day (Munday 2 Apr: Mwn in Scorpio])
4: Urantia Day (Twzday 3 Apr: Mwn in Scorpio)
5: Mahrz Day (Wenzday 4 Apr: Mwn in Sagittarius)
6: Jwpitr Day (Thrzday 5 Apr: Mwn in Sagittarius)
7: Satrn Day (Fryday 6 Apr: Mwn in Capricorn)
8 (Leep): Yreynus Day (Satrday 7 Apr: Mwn in Capricorn)

1: Mwn Day Lwnar Sabbat ([Sunday 8 Apr: Mwn in Capricorn)
2: Mrkyree Day (Munday 9 Apr: Mwn in Aquarius)
3: Venus Day (Munday 10 Apr: Mwn in Aquarius)
4: UranTia Day (Munday 11 Apr: Mwn in Pisces)