Abgerundet wird der neue Patch mit diversen Bugfixes. Die offiziellen Patchnotes zum neuen Empire Universe 3-Update sind im EU3-Forum gelistet. Mit diesen. Godspeed - Die Ankunft (Across The Universe, #3) on unifor950.com *FREE* shipping on qualifying offers. Godspeed - Die Ankunft (Across The Universe, #3). Empire Universe 3. K likes. Die offizielle Facebook-Seite zum Scifi-Browser-MMORPG Empire Universe 3 von Looki.
Empire Universe 3Im Weltall erwarten dich herausfordernde Abenteuer! In Empire Universe 3 ziehst du in deinem Raumschiff los und landest auf einem fremden Planeten. In Empire Universe werden die Spieler zum Herrscher über zahlreiche Planeten. Sie begeben sich in die unendlichen Weiten des. Abgerundet wird der neue Patch mit diversen Bugfixes. Die offiziellen Patchnotes zum neuen Empire Universe 3-Update sind im EU3-Forum gelistet. Mit diesen.
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According to estimation of this theory, space and time emerged together Dark matter gradually gathered, forming a foam -like structure of filaments and voids under the influence of gravity.
Giant clouds of hydrogen and helium were gradually drawn to the places where dark matter was most dense , forming the first galaxies, stars, and everything else seen today.
It is possible to see objects that are now further away than This means that objects which are now up to From studying the movement of galaxies, it has been discovered that the universe contains much more matter than is accounted for by visible objects; stars, galaxies, nebulas and interstellar gas.
This unseen matter is known as dark matter  dark means that there is a wide range of strong indirect evidence that it exists, but we have not yet detected it directly.
It suggests that about There are many competing hypotheses about the ultimate fate of the universe and about what, if anything, preceded the Big Bang, while other physicists and philosophers refuse to speculate, doubting that information about prior states will ever be accessible.
Some physicists have suggested various multiverse hypotheses, in which our universe might be one among many universes that likewise exist. The physical universe is defined as all of space and time [a] collectively referred to as spacetime and their contents.
The universe is often defined as "the totality of existence", or everything that exists, everything that has existed, and everything that will exist.
The word universe derives from the Old French word univers , which in turn derives from the Latin word universum.
The same synonyms are found in English, such as everything as in the theory of everything , the cosmos as in cosmology , the world as in the many-worlds interpretation , and nature as in natural laws or natural philosophy.
The prevailing model for the evolution of the universe is the Big Bang theory. The model is based on general relativity and on simplifying assumptions such as homogeneity and isotropy of space.
A version of the model with a cosmological constant Lambda and cold dark matter , known as the Lambda-CDM model , is the simplest model that provides a reasonably good account of various observations about the universe.
The Big Bang model accounts for observations such as the correlation of distance and redshift of galaxies, the ratio of the number of hydrogen to helium atoms, and the microwave radiation background.
During the Planck epoch, all types of matter and all types of energy were concentrated into a dense state, and gravity —currently the weakest by far of the four known forces —is believed to have been as strong as the other fundamental forces, and all the forces may have been unified.
Objects in space did not physically move; instead the metric that defines space itself changed. Although objects in spacetime cannot move faster than the speed of light , this limitation does not apply to the metric governing spacetime itself.
This initial period of inflation is believed to explain why space appears to be very flat, and much larger than light could travel since the start of the universe.
Within the first fraction of a second of the universe's existence, the four fundamental forces had separated. As the universe continued to cool down from its inconceivably hot state, various types of subatomic particles were able to form in short periods of time known as the quark epoch , the hadron epoch , and the lepton epoch.
Together, these epochs encompassed less than 10 seconds of time following the Big Bang. These elementary particles associated stably into ever larger combinations, including stable protons and neutrons , which then formed more complex atomic nuclei through nuclear fusion.
This process, known as Big Bang nucleosynthesis , only lasted for about 17 minutes and ended about 20 minutes after the Big Bang, so only the fastest and simplest reactions occurred.
Any other element was only formed in very tiny quantities. After nucleosynthesis ended, the universe entered a period known as the photon epoch.
During this period, the universe was still far too hot for matter to form neutral atoms , so it contained a hot, dense, foggy plasma of negatively charged electrons , neutral neutrinos and positive nuclei.
After about , years, the universe had cooled enough that electrons and nuclei could form the first stable atoms. This is known as recombination for historical reasons; in fact electrons and nuclei were combining for the first time.
Unlike plasma, neutral atoms are transparent to many wavelengths of light, so for the first time the universe also became transparent.
The photons released " decoupled " when these atoms formed can still be seen today; they form the cosmic microwave background CMB. As the universe expands, the energy density of electromagnetic radiation decreases more quickly than does that of matter because the energy of a photon decreases with its wavelength.
At around 47, years, the energy density of matter became larger than that of photons and neutrinos , and began to dominate the large scale behavior of the universe.
This marked the end of the radiation-dominated era and the start of the matter-dominated era. In the earliest stages of the universe, tiny fluctuations within the universe's density led to concentrations of dark matter gradually forming.
Ordinary matter, attracted to these by gravity , formed large gas clouds and eventually, stars and galaxies, where the dark matter was most dense, and voids where it was least dense.
After around - million years, [ citation needed ] the first stars formed, known as Population III stars. These were probably very massive, luminous, non metallic and short-lived.
They were responsible for the gradual reionization of the universe between about million years and 1 billion years, and also for seeding the universe with elements heavier than helium, through stellar nucleosynthesis.
After about 9. Of the four fundamental interactions , gravitation is the dominant at astronomical length scales. Gravity's effects are cumulative; by contrast, the effects of positive and negative charges tend to cancel one another, making electromagnetism relatively insignificant on astronomical length scales.
The remaining two interactions, the weak and strong nuclear forces , decline very rapidly with distance; their effects are confined mainly to sub-atomic length scales.
The universe appears to have much more matter than antimatter , an asymmetry possibly related to the CP violation. These laws are Gauss's law and the non-divergence of the stress-energy-momentum pseudotensor.
This diagram shows Earth's location in the universe on increasingly larger scales. The images, labeled along their left edge, increase in size from left to right, then from top to bottom.
The size of the universe is somewhat difficult to define. According to the general theory of relativity, far regions of space may never interact with ours even in the lifetime of the universe due to the finite speed of light and the ongoing expansion of space.
For example, radio messages sent from Earth may never reach some regions of space, even if the universe were to exist forever: space may expand faster than light can traverse it.
Distant regions of space are assumed to exist and to be part of reality as much as we are, even though we can never interact with them. The spatial region that we can affect and be affected by is the observable universe.
The observable universe depends on the location of the observer. By traveling, an observer can come into contact with a greater region of spacetime than an observer who remains still.
Nevertheless, even the most rapid traveler will not be able to interact with all of space. Typically, the observable universe is taken to mean the portion of the universe that is observable from our vantage point in the Milky Way.
The proper distance —the distance as would be measured at a specific time, including the present—between Earth and the edge of the observable universe is 46 billion light-years  14 billion parsecs ,  making the diameter of the observable universe about 93 billion light-years 28 billion parsecs.
Because we cannot observe space beyond the edge of the observable universe, it is unknown whether the size of the universe in its totality is finite or infinite.
Astronomers calculate the age of the universe by assuming that the Lambda-CDM model accurately describes the evolution of the Universe from a very uniform, hot, dense primordial state to its present state and measuring the cosmological parameters which constitute the model.
Over time, the universe and its contents have evolved; for example, the relative population of quasars and galaxies has changed  and space itself has expanded.
Due to this expansion, scientists on Earth can observe the light from a galaxy 30 billion light-years away even though that light has traveled for only 13 billion years; the very space between them has expanded.
This expansion is consistent with the observation that the light from distant galaxies has been redshifted ; the photons emitted have been stretched to longer wavelengths and lower frequency during their journey.
Analyses of Type Ia supernovae indicate that the spatial expansion is accelerating. The more matter there is in the universe, the stronger the mutual gravitational pull of the matter.
If the universe were too dense then it would re-collapse into a gravitational singularity. However, if the universe contained too little matter then the self-gravity would be too weak for astronomical structures, like galaxies or planets, to form.
Since the Big Bang, the universe has expanded monotonically. Perhaps unsurprisingly , our universe has just the right mass-energy density , equivalent to about 5 protons per cubic metre, which has allowed it to expand for the last There are dynamical forces acting on the particles in the universe which affect the expansion rate.
Before , it was expected that the expansion rate would be decreasing as time went on due to the influence of gravitational interactions in the universe; and thus there is an additional observable quantity in the universe called the deceleration parameter , which most cosmologists expected to be positive and related to the matter density of the universe.
In , the deceleration parameter was measured by two different groups to be negative, approximately Spacetimes are the arenas in which all physical events take place.
The basic elements of spacetimes are events. In any given spacetime, an event is defined as a unique position at a unique time. A spacetime is the union of all events in the same way that a line is the union of all of its points , formally organized into a manifold.
Events, such as matter and energy, bend spacetime. Curved spacetime, on the other hand, forces matter and energy to behave in a certain way.
There is no point in considering one without the other. The universe appears to be a smooth spacetime continuum consisting of three spatial dimensions and one temporal time dimension an event in the spacetime of the physical universe can therefore be identified by a set of four coordinates: x , y , z , t.
On average, space is observed to be very nearly flat with a curvature close to zero , meaning that Euclidean geometry is empirically true with high accuracy throughout most of the Universe.
However, present observations cannot exclude the possibilities that the universe has more dimensions which is postulated by theories such as the string theory and that its spacetime may have a multiply connected global topology, in analogy with the cylindrical or toroidal topologies of two-dimensional spaces.
Spacetime events are not absolutely defined spatially and temporally but rather are known to be relative to the motion of an observer. Minkowski space approximates the universe without gravity ; the pseudo-Riemannian manifolds of general relativity describe spacetime with matter and gravity.
General relativity describes how spacetime is curved and bent by mass and energy gravity. The topology or geometry of the universe includes both local geometry in the observable universe and global geometry.
Cosmologists often work with a given space-like slice of spacetime called the comoving coordinates. The section of spacetime which can be observed is the backward light cone , which delimits the cosmological horizon.
The cosmological horizon also called the particle horizon or the light horizon is the maximum distance from which particles can have traveled to the observer in the age of the universe.
This horizon represents the boundary between the observable and the unobservable regions of the universe. These are called, respectively, the flat, open and closed universes.
The universe may be fine-tuned ; the Fine-tuned universe hypothesis is the proposition that the conditions that allow the existence of observable life in the universe can only occur when certain universal fundamental physical constants lie within a very narrow range of values, so that if any of several fundamental constants were only slightly different, the universe would have been unlikely to be conducive to the establishment and development of matter , astronomical structures, elemental diversity, or life as it is understood.
The universe is composed almost completely of dark energy, dark matter, and ordinary matter. Other contents are electromagnetic radiation estimated to constitute from 0.
The proportions of all types of matter and energy have changed over the history of the universe. Dark matter, a mysterious form of matter that has not yet been identified, accounts for Dark energy, which is the energy of empty space and is causing the expansion of the universe to accelerate, accounts for the remaining Matter, dark matter, and dark energy are distributed homogeneously throughout the universe over length scales longer than million light-years or so.
Between the larger structures are voids , which are typically 10— Mpc 33 million— million ly in diameter. The observable universe is isotropic on scales significantly larger than superclusters, meaning that the statistical properties of the universe are the same in all directions as observed from Earth.
The universe is bathed in highly isotropic microwave radiation that corresponds to a thermal equilibrium blackbody spectrum of roughly 2.
An explanation for why the expansion of the universe is accelerating remains elusive. It is often attributed to "dark energy", an unknown form of energy that is hypothesized to permeate space.
However, in the present dark-energy era, it dominates the mass—energy of the universe because it is uniform across space. Two proposed forms for dark energy are the cosmological constant , a constant energy density filling space homogeneously,  and scalar fields such as quintessence or moduli , dynamic quantities whose energy density can vary in time and space.
Contributions from scalar fields that are constant in space are usually also included in the cosmological constant. The cosmological constant can be formulated to be equivalent to vacuum energy.
Scalar fields having only a slight amount of spatial inhomogeneity would be difficult to distinguish from a cosmological constant.
Dark matter is a hypothetical kind of matter that is invisible to the entire electromagnetic spectrum , but which accounts for most of the matter in the universe.
The existence and properties of dark matter are inferred from its gravitational effects on visible matter, radiation, and the large-scale structure of the universe.
Other than neutrinos , a form of hot dark matter , dark matter has not been detected directly, making it one of the greatest mysteries in modern astrophysics.
Dark matter neither emits nor absorbs light or any other electromagnetic radiation at any significant level.
Dark matter is estimated to constitute The remaining 4. This matter includes stars , which produce nearly all of the light we see from galaxies, as well as interstellar gas in the interstellar and intergalactic media, planets , and all the objects from everyday life that we can bump into, touch or squeeze.
Ordinary matter commonly exists in four states or phases : solid , liquid , gas , and plasma. However, advances in experimental techniques have revealed other previously theoretical phases, such as Bose—Einstein condensates and fermionic condensates.
Ordinary matter is composed of two types of elementary particles : quarks and leptons. An atom consists of an atomic nucleus , made up of protons and neutrons, and electrons that orbit the nucleus.
Because most of the mass of an atom is concentrated in its nucleus, which is made up of baryons , astronomers often use the term baryonic matter to describe ordinary matter, although a small fraction of this "baryonic matter" is electrons.
Soon after the Big Bang , primordial protons and neutrons formed from the quark—gluon plasma of the early universe as it cooled below two trillion degrees.
A few minutes later, in a process known as Big Bang nucleosynthesis , nuclei formed from the primordial protons and neutrons. This nucleosynthesis formed lighter elements, those with small atomic numbers up to lithium and beryllium , but the abundance of heavier elements dropped off sharply with increasing atomic number.
Some boron may have been formed at this time, but the next heavier element, carbon , was not formed in significant amounts. Big Bang nucleosynthesis shut down after about 20 minutes due to the rapid drop in temperature and density of the expanding universe.
Subsequent formation of heavier elements resulted from stellar nucleosynthesis and supernova nucleosynthesis. Ordinary matter and the forces that act on matter can be described in terms of elementary particles.
A true force-particle "theory of everything" has not been attained. A hadron is a composite particle made of quarks held together by the strong force.
Hadrons are categorized into two families: baryons such as protons and neutrons made of three quarks, and mesons such as pions made of one quark and one antiquark.
Of the hadrons, protons are stable, and neutrons bound within atomic nuclei are stable. Other hadrons are unstable under ordinary conditions and are thus insignificant constituents of the modern universe.
Most of the hadrons and anti-hadrons were then eliminated in particle-antiparticle annihilation reactions, leaving a small residual of hadrons by the time the universe was about one second old.
A lepton is an elementary , half-integer spin particle that does not undergo strong interactions but is subject to the Pauli exclusion principle ; no two leptons of the same species can be in exactly the same state at the same time.
Electrons are stable and the most common charged lepton in the universe, whereas muons and taus are unstable particle that quickly decay after being produced in high energy collisions, such as those involving cosmic rays or carried out in particle accelerators.
The electron governs nearly all of chemistry , as it is found in atoms and is directly tied to all chemical properties.
Neutrinos rarely interact with anything, and are consequently rarely observed. Neutrinos stream throughout the universe but rarely interact with normal matter.
The lepton epoch was the period in the evolution of the early universe in which the leptons dominated the mass of the universe. It started roughly 1 second after the Big Bang , after the majority of hadrons and anti-hadrons annihilated each other at the end of the hadron epoch.
The mass of the universe was then dominated by photons as it entered the following photon epoch. A photon is the quantum of light and all other forms of electromagnetic radiation.
This update includes 2 new tools and updates to 4 existing tools — not to mention a whole bunch of awesome presets to help get you started.
With this release there are a total of 89 tools included in Universe. If you already have Red Giant Application Manager installed, updating is simple.
Just follow these steps:. Visit the Universe Compatibility page to learn more about specific versions and OS support. If you have trouble to run Universe 3, read the abandonware guide first!
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