The New Minimal Standard Model
... (Ωm − Ωb )h2 = 0.11 as curves in Fig. 1 for various mS . Note that mS = 75 GeV allows for annihilation through Higgs pole and has a special behavior. To be consistent with the triviality and stability bounds, we find mS ≃ 5.5 GeV–1.8 TeV. Now we have demonstrated that all new elements we have added ...
... (Ωm − Ωb )h2 = 0.11 as curves in Fig. 1 for various mS . Note that mS = 75 GeV allows for annihilation through Higgs pole and has a special behavior. To be consistent with the triviality and stability bounds, we find mS ≃ 5.5 GeV–1.8 TeV. Now we have demonstrated that all new elements we have added ...
First Light for May, 2001 - South Bay Astronomical Society
... The transit method can only find systems that are aligned with our line of sight. The Stellar Wobble Method can find planetary systems that are not fully aligned with our line of sight but still have a component that provides a relative motion towards or away from Earth. Thus, the Wobble method pro ...
... The transit method can only find systems that are aligned with our line of sight. The Stellar Wobble Method can find planetary systems that are not fully aligned with our line of sight but still have a component that provides a relative motion towards or away from Earth. Thus, the Wobble method pro ...
The Milky Way Galaxy (ch. 23)
... nearly spherical shape, rest of gas collapsed to disk which has formed stars continuously since that time. (Think about how above properties suggest this.) More recently it was discovered that our Galaxy has a weak but detectable bar structure in the bulge. This rotating bar is important, because it ...
... nearly spherical shape, rest of gas collapsed to disk which has formed stars continuously since that time. (Think about how above properties suggest this.) More recently it was discovered that our Galaxy has a weak but detectable bar structure in the bulge. This rotating bar is important, because it ...
WFIRST-2.4: What Every Astronomer Should Know
... A constant energy component, a.k.a. a “cosmological constant,” could arise from the gravitational effects of the quantum vacuum. An evolving energy component would imply a new type of dynamical field. Gravitational explanations could come from changing the action in Einstein’s GR equation, or from s ...
... A constant energy component, a.k.a. a “cosmological constant,” could arise from the gravitational effects of the quantum vacuum. An evolving energy component would imply a new type of dynamical field. Gravitational explanations could come from changing the action in Einstein’s GR equation, or from s ...
Lecture Notes – Galaxies
... Masses of clusters can be measured from the dynamics of the constituent galaxies; by gravitational lensing; and by X-ray observations. All three methods indicates masses ∼ 10× the visible mass ⇒ dark matter. Superclusters Over the last 10–15 years, the 3D structure of the local Universe has been map ...
... Masses of clusters can be measured from the dynamics of the constituent galaxies; by gravitational lensing; and by X-ray observations. All three methods indicates masses ∼ 10× the visible mass ⇒ dark matter. Superclusters Over the last 10–15 years, the 3D structure of the local Universe has been map ...
Gravity, General Relativity, and Dark Matter
... Don’t worry too much if you feel like you are not completely grasping this concept. It is very non-intuitive, and no scientist understood it properly before Einstein. What is important is that, in later chapters, we will be able to use the idea of curved space-time to explain the data we have gather ...
... Don’t worry too much if you feel like you are not completely grasping this concept. It is very non-intuitive, and no scientist understood it properly before Einstein. What is important is that, in later chapters, we will be able to use the idea of curved space-time to explain the data we have gather ...
Getting to Know: Structure of the Universe
... orbit that star. Scientists have found several solar systems in our galaxy, many of which have planets surrounding them. If the Milky Way galaxy were the size of a quarter, the Sun would be the size of a single speck of dust on that quarter. The Sun and our solar system are just one tiny part of the ...
... orbit that star. Scientists have found several solar systems in our galaxy, many of which have planets surrounding them. If the Milky Way galaxy were the size of a quarter, the Sun would be the size of a single speck of dust on that quarter. The Sun and our solar system are just one tiny part of the ...
Dark Matter Experiments
... 1 Introduction 2 Dark Matter Phenomenology and Appeal 2.1 Zwicky and the Coma Cluster . . . . . . . 2.2 Rubin, Ford and the Andromeda Galaxy . 2.3 The WIMP and Genesis of Dark Matter . ...
... 1 Introduction 2 Dark Matter Phenomenology and Appeal 2.1 Zwicky and the Coma Cluster . . . . . . . 2.2 Rubin, Ford and the Andromeda Galaxy . 2.3 The WIMP and Genesis of Dark Matter . ...
Dark matter
Dark matter is a hypothetical kind of matter that cannot be seen with telescopes but would account for most of the matter in the universe. The existence and properties of dark matter are inferred from its gravitational effects on visible matter, on radiation, and on the large-scale structure of the universe. 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. According to the Planck mission team, and based on the standard model of cosmology, the total mass–energy of the known universe contains 4.9% ordinary matter, 26.8% dark matter and 68.3% dark energy. Thus, dark matter is estimated to constitute 84.5% of the total matter in the universe, while dark energy plus dark matter constitute 95.1% of the total mass–energy content of the universe.Astrophysicists hypothesized the existence of dark matter to account for discrepancies between the mass of large astronomical objects determined from their gravitational effects, and their mass as calculated from the observable matter (stars, gas, and dust) that they can be seen to contain. Their gravitational effects suggest that their masses are much greater than the observable matter survey suggests. Dark matter was postulated by Jan Oort in 1932, albeit based upon insufficient evidence, to account for the orbital velocities of stars in the Milky Way. In 1933, Fritz Zwicky was the first to use the virial theorem to infer the existence of unseen matter, which he referred to as dunkle Materie 'dark matter'. More robust evidence from galaxy rotation curves was discovered by Horace W. Babcock in 1939, but was not attributed to dark matter. The first hypothesis to postulate ""dark matter"" based upon robust evidence was formulated by Vera Rubin and Kent Ford in the 1960s–1970s, using galaxy rotation curves. Subsequently, many other observations have indicated the presence of dark matter in the universe, including gravitational lensing of background objects by galaxy clusters such as the Bullet Cluster, the temperature distribution of hot gas in galaxies and clusters of galaxies and, more recently, the pattern of anisotropies in the cosmic microwave background. According to consensus among cosmologists, dark matter is composed primarily of a not yet characterized type of subatomic particle.The search for this particle, by a variety of means, is one of the major efforts in particle physics today.Although the existence of dark matter is generally accepted by the mainstream scientific community, some alternative theories of gravity have been proposed, such as MOND and TeVeS, which try to account for the anomalous observations without requiring additional matter. However, these theories cannot account for the properties of galaxy clusters.