1,158 research outputs found
Collisional interaction limits between dark matters and baryons in `cooling flow' clusters
Presuming weak collisional interactions to exchange the kinetic energy
between dark matter and baryonic matter in a galaxy cluster, we re-examine the
effectiveness of this process in several `cooling flow' galaxy clusters using
available X-ray observations and infer an upper limit on the heavy dark matter
particle (DMP)proton cross section . With a relative
collisional velocity dependent power-law form of where , our inferred upper
limit is \sigma_0/m_{\rm x}\lsim 2\times10^{-25} {\rm cm}^2 {\rm GeV}^{-1}
with being the DMP mass. Based on a simple stability analysis of
the thermal energy balance equation, we argue that the mechanism of
DMPbaryon collisional interactions is unlikely to be a stable
nongravitational heating source of intracluster medium (ICM) in inner core
regions of `cooling flow' galaxy clusters.Comment: 8 pages, 2 figures, MNRAS accepte
Mass and Mean Velocity Dispersion Relations for Supermassive Black Holes in Galactic Bulges
Growing evidence indicate supermassive black holes (SMBHs) in the mass range
of lurking in central bulges of many
galaxies. Extensive observations reveal fairly tight power laws of
versus the mean stellar velocity dispersion of the host bulge. The
dynamic evolution of a bulge and the formation of a central SMBH should be
physically linked by various observational clues. In this contribution, we
reproduce the empirical power laws based on a self-similar
general polytropic quasi-static bulge evolution and a sensible criterion of
forming a SMBH surrounding the central density singularity of a general
singular polytropic sphere (SPS) \cite{loujiang2008}. Other properties of host
bulges and central SMBHs are also examined. Based on our model, we discuss the
intrinsic scatter of the relation and a scenario for the
evolution of SMBHs in different host bulges.Comment: 8 pages, 2 figures, accepted for publication in the Proceedings of
Science for VII Microquasar Workshop: Microquasars and Beyon
Cardiac Remodeling Of Conduction, Repolarization and Excitation-Contraction Coupling: From Animal Model to Failing Human Heart
Heart failure is one of the leading causes of death worldwide, with rising impact with the increasing ageing population. This is in sharp contrast with the limited and non-ideal therapies available. Approximately 50% of deaths from heart failure are sudden and unexpected, and presumably the consequence of lethal ventricular arrhythmias. Despite significant reduction of mortality from sudden cardiac death achieved by ICDs and drugs such as beta-blockers, there remains a large room for improving the survivability of heart failure patients by advancing our understanding of arrhythmogenesis from molecular level to multi-cellular tissue level. Another important aspect of heart failure is abnormal excitation-contraction: EC) coupling and calcium handling, functional changes of which exert great impact on both arrhythmia vulnerability and pump failure. Advancing the understanding the remodeling of EC coupling and calcium handling might provide potential molecular and anatomical targets for clinical intervention. In this dissertation, I first developed two optical imaging systems: both hardware and software) for quantifying the conduction, repolarization and excitation-contraction coupling. The first one is the panoramic imaging system for mapping the entire ventricular epicardium of a rabbit heart. The second one is the dual imaging system for simultaneous measurement of action potential and calcium transient. Using the systems I developed, I conducted two rabbit studies to investigate the role electrical instability and structural heterogeneity in the induction and maintenance of arrhythmias. We first identified the importance of both dynamic instability and effective tissue size in the spontaneous termination of arrhythmia in the normal rabbit heart. We then identified novel mechanism of how healed myocardial infarction promotes the induction of ventricular arrhythmia. Finally, guided by the knowledge from the animal studies, I studied the failing human heart with the aim to advance our understanding of cardiac electrophysiology in human heart failure. We first demonstrated the transmural heterogeneity of EC coupling in nonfailing heart and identified potential mechanisms of electrical and mechanical dysfunction by quantifying the remodeling of EC coupling. We then studied the remodeling of conduction and repolarization with the aim to determine of the role of dispersion of repolarization and electrical instability in the induction of arrhythmia in human heart failure
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