Title: Oscillating axion bubbles as alternative to supermassive black holes at galactic centers Authors: Anatoly A. Svidzinsky
Recent observations of near-infrared and X-ray flares from Sagittarius A*, which is believed to be a supermassive black hole at the Galactic centre, show that the source exhibits about 20-minute periodic variability. Here we provide arguments based on a quantitative analysis that supermassive objects at galactic centers are bubbles of dark matter axions, rather then black holes. An oscillating axion bubble can explain periodic variability of Sagittarius A* and with no free parameters yields the axion mass about 1 meV in agreement with our previous findings obtained from quasar observations. The bubble scenario naturally explains lack of supermassive "black holes" with M < 10^6M_{Sun}. Low-mass bubbles decay fast and as a result are very rare. We also found that the mass of an axion bubble can not exceed 2.5 x 10^9M_{Sun}, in agreement with the largest supermassive "black hole" masses measured for active galactic nuclei. Our finding, if confirmed, suggests that Einstein general relativity is invalid for strong gravity and the gravitational force effectively becomes repulsive at large potential. Imaging a shadow of the "black hole" at the Galactic centre with VLBI within the next few years will be capable to distinguish between the black hole and the oscillating axion bubble scenarios. In the case of axion bubble, a steady shadow will not be observed. Instead, the shadow will appear and disappear periodically with a period of about 20 min.
Title: Catching a bullet: direct evidence for the existence of dark matter Authors: D. Clowe (Ohio University), S. W. Randall, M. Markevitch (CFA)
We present X-ray and weak lensing observations of the merging cluster system 1E0657-556. Due to the recently collision of a merging subcluster with the main cluster, the X-ray plasma has been displaced from the cluster galaxies in both components. The weak lensing data shows that the lensing surface potential is in spatial agreement with the galaxies (~10% of the observed baryons) and not with the X-ray plasma (~90% of the observed baryons). We argue that this shows that regardless of the form of the gravitational force law at these large distances and low accelerations, these observations require that the majority of the mass of the system be some form of unseen matter.
Title: Constraints on parameters of radiatively decaying dark matter from the galaxy cluster 1E0657-56 Authors: Alexey Boyarsky, Oleg Ruchayskiy, Maxim Markevitch
We derived constraints on parameters of a radiatively decaying warm dark matter particle, e.g., the mass and mixing angle for a sterile neutrino, using Chandra X-ray spectra of a galaxy cluster 1E0657-56 (the ''bullet'' cluster). The constraints are based on nondetection of the sterile neutrino decay emission line. This cluster exhibits spatial separation between the hot intergalactic gas and the dark matter, helping to disentangle their X-ray signals. It also has a very long X-ray observation and a total mass measured via gravitational lensing. This makes the resulting constraints on sterile neutrino complementary to earlier results that used different cluster mass estimates. Our limits are comparable to the best existing constraints.
Title: Light Element Signatures of Sterile Neutrinos and Cosmological Lepton Numbers Authors: Christel J. Smith, George M. Fuller, Chad T. Kishimoto, Kevork N. Abazajian Revision v2
We study primordial nucleosynthesis abundance yields for assumed ranges of cosmological lepton numbers, sterile neutrino mass-squared differences and active-sterile vacuum mixing angles. We fix the baryon-to-photon ratio at the value derived from the cosmic microwave background (CMB) data and then calculate the deviation of the 2H, 4He, and 7Li abundance yields from those expected in the zero lepton number(s), no-new-neutrino-physics case. We conclude that high precision (< 5% error) measurements of the primordial 2H abundance from, e.g., QSO absorption line observations coupled with high precision (< 1% error) baryon density measurements from the CMB could have the power to either: (1) reveal or rule out the existence of a light sterile neutrino if the sign of the cosmological lepton number is known; or (2) place strong constraints on lepton numbers, sterile neutrino mixing properties and resonance sweep physics. Similar conclusions would hold if the primordial 4He abundance could be determined to better than 10%.
Title: A New Force in the Dark Sector? Authors: Glennys R. Farrar, Rachel A. Rosen
We study the kinematics of dark matter using the massive cluster of galaxies 1E0657-56. The velocity of the "bullet" subcluster has been measured by X-ray emission from the shock front, and the masses and separation of the main and sub-clusters have been measured by gravitational lensing. The velocity with gravity alone is calculated in a variety of models of the initial conditions, mass distribution and accretion history; it is much higher than expected, by at least 2.4 sigma. The probability of so large a subcluster velocity in cosmological simulations is <~ 10^-7. A long range force with strength ~ 0.4 - 0.8 times that of gravity would provide the needed additional acceleration.
Title: Spin alignment of dark matter haloes in filaments and walls Authors: Miguel A. Aragón-Calvo, Rien van de Weygaert, Bernard J. T. Jones, J.M. Thijs van der Hulst
The MMF technique is used to segment the cosmic web as seen in a cosmological N-body simulation into wall-like and filament-like structures. We find that the spins and shapes of dark matter haloes are significantly correlated with each other and with the orientation of their host structures. The shape orientation is such that the halo minor axes tend to lie perpendicular to the host structure, be it a wall or filament. The orientation of the halo spin vector is mass dependent. Low mass haloes in walls and filaments have a tendency to have their spins oriented within the parent structure, while higher mass haloes in filaments have spins that tend to lie perpendicular to the parent structure.
Lefthand panel: Particles inside a sub-box of 37.5 × 75 × 100 h-1 Mpc. For reasons of clarity only a small fraction of the total number of particles is shown. Central panel: filaments delineated by a subsample of the particle distribution. At each particle location we have plotted the filament vector eF, indicating the direction locally parallel to the filament. Righthand panel: wall particles detected in the same sub-box: at each wall particle we plot the wall vector eW. Two walls can be clearly delineated: one seen edge-on (dashed outline) and one seen face-on (solid outline).
New analysis by physicists at Caltech and the University of Toronto show that dark matter obeys the same gravitational laws as regular matter, to within an error of 10 percent.
The researchers studied the distribution of stars in the Sagittarius dwarf galaxy that orbits our Milky Way, and concluded that if dark matter experienced different forces from normal matter, it would change the relative amounts of stars kicked out ahead and behind the dwarf galaxy as a result of its interaction with our own galaxy. The analysis also helps to eliminate MOND models that explains the distribution of material in the universe by proposing exotic forms of gravitational interactions for dark matter.
The tidal disruption of smaller galaxies by our own Milky Way could be the most sensitive probe yet of long-range forces affecting dark matter. The report is being presented at the 208th meeting of the American Astronomical Society (AAS) held in Calgary, Alberta, by Michael H. Kesden of the Canadian Institute for Theoretical Astrophysics (CITA) at the University of Toronto in Toronto, Ontario. The work was begun in collaboration with Marc Kamionkowski, professor of theoretical physics and astrophysics, while Kesden was a graduate student at Caltech. This result is of special interest because the detection of such long-range forces could help to finally identify the origin of the mysterious dark matter, one of the great unsolved problems of modern physics.
Credit University of Toronto
The Sagittarius (Sgr) dwarf spheroidal galaxy is located approximately 78,000 light-years from Earth on the opposite side of the Milky Way. Detailed observations of the Sgr dwarf and its tidal streams have been undertaken by both the Two Micron All-Sky Survey (2MASS) and the Sloan Digital Sky Survey (SDSS). 2MASS observations were performed using 1.3-meter (50-inch) telescopes at the Whipple Observatory on Mt. Hopkins, Arizona, and the Cerro Tololo Inter-American Observatory in Chile, while SDSS observations made use of a dedicated 2.5-meter (100-inch) telescope at the Apache Point Observatory in the Sacramento Mountains of New Mexico. Both surveys were funded by the National Aeronautics and Space Administration (NASA) and the National Science Foundation, among other institutions.
Title: Can Cosmic Structure form without Dark Matter? Authors: Scott Dodelson, Michele Liguori
One of the prime pieces of evidence for dark matter is the observation of large overdense regions in the universe. Since we know from the cosmic microwave background that the regions that contained the most baryons when the universe was ~400,000 years old were overdense by only one part in ten thousand, perturbations had to have grown since then by a factor greater than (1+z*) = 1180 where z* is the epoch of recombination. This enhanced growth does not happen in general relativity, so dark matter is needed in the standard theory. We show here that enhanced growth can occur in alternatives to general relativity, in particular in Bekenstein's relativistic version of MOdified Newtonian Dynamics (MOND). The vector field introduced in that theory for a completely different reason plays a key role in generating the instability that produces large cosmic structures today.
Title: A direct empirical proof of the existence of dark matter Authors: Douglas Clowe (1), Marusa Bradac (2), Anthony H. Gonzalez (3), Maxim Markevitch (4), Scott W. Randall (4), Christine Jones (4), Dennis Zaritsky (1) ((1) Steward Observatory, Tucson, (2) KIPAC, Stanford, (3) Department of Astronomy, Gainesville, (4) CfA, Cambridge)
We present new weak lensing observations of 1E0657-558 (z=0.296), a unique cluster merger, that enable a direct detection of dark matter, independent of assumptions regarding the nature of the gravitational force law. Due to the collision of two clusters, the dissipationless stellar component and the fluid-like X-ray emitting plasma are spatially segregated. By using both wide-field ground based images and HST/ACS images of the cluster cores, we create gravitational lensing maps which show that the gravitational potential does not trace the plasma distribution, the dominant baryonic mass component, but rather approximately traces the distribution of galaxies. An 8-sigma significance spatial offset of the centre of the total mass from the centre of the baryonic mass peaks cannot be explained with an alteration of the gravitational force law, and thus proves that the majority of the matter in the system is unseen.
Dark matter and normal matter have been wrenched apart by the tremendous collision of two large clusters of galaxies. The discovery, using NASA's Chandra X-ray Observatory and other telescopes, gives direct evidence for the existence of dark matter.
"This is the most energetic cosmic event, besides the Big Bang, which we know about" - team member Maxim Markevitch of the Harvard-Smithsonian Centre for Astrophysics in Cambridge, Massachusetts, US.
These observations provide the strongest evidence yet that most of the matter in the universe is dark. Despite considerable evidence for dark matter, some scientists have proposed alternative theories for gravity where it is stronger on intergalactic scales than predicted by Newton and Einstein, removing the need for dark matter. However, such theories cannot explain the observed effects of this collision.
"A universe that's dominated by dark stuff seems preposterous, so we wanted to test whether there were any basic flaws in our thinking. These results are direct proof that dark matter exists" - Doug Clowe of the University of Arizona at Tucson, and leader of the study.
In galaxy clusters, the normal matter, like the atoms that make up the stars, planets, and everything on Earth, is primarily in the form of hot gas and stars. The mass of the hot gas between the galaxies is far greater than the mass of the stars in all of the galaxies. This normal matter is bound in the cluster by the gravity of an even greater mass of dark matter. Without dark matter, which is invisible and can only be detected through its gravity, the fast-moving galaxies and the hot gas would quickly fly apart.
The team was granted more than 100 hours on the Chandra telescope to observe the galaxy cluster 1E0657-56. The cluster is also known as the bullet cluster, because it contains a spectacular bullet-shaped cloud of hundred-million-degree gas. The X-ray image shows the bullet shape is due to a wind produced by the high-speed collision of a smaller cluster with a larger one. In addition to the Chandra observation, the Hubble Space Telescope, the European Southern Observatory's Very Large Telescope and the Magellan optical telescopes were used to determine the location of the mass in the clusters. This was done by measuring the effect of gravitational lensing, where gravity from the clusters distorts light from background galaxies as predicted by Einstein's theory of general relativity. The hot gas in this collision was slowed by a drag force, similar to air resistance. In contrast, the dark matter was not slowed by the impact, because it does not interact directly with itself or the gas except through gravity. This produced the separation of the dark and normal matter seen in the data. If hot gas was the most massive component in the clusters, as proposed by alternative gravity theories, such a separation would not have been seen. Instead, dark matter is required.
"This is the type of result that future theories will have to take into account. As we move forward to understand the true nature of dark matter, this new result will be impossible to ignore" - Sean Carroll, a cosmologist at the University of Chicago, who was not involved with the study.
This result also gives scientists more confidence that the Newtonian gravity familiar on Earth and in the solar system also works on the huge scales of galaxy clusters.
"We've closed this loophole about gravity, and we've come closer than ever to seeing this invisible matter" - Doug Clowe.
These results are being published in an upcoming issue of The Astrophysical Journal Letters. NASA's Marshall Space Flight Centre, Huntsville, Ala., manages the Chandra program. The Smithsonian Astrophysical Observatory controls science and flight operations from the Chandra X-ray Centre, Cambridge, Massachusetts, US.