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Author: Kenneth Moody Publisher: ISBN: Category : Languages : en Pages : 104
Book Description
Three body dynamics are of particular interest in clusters where the density of stars provides many opportunities for interactions. Globular clusters, which have had densities of tens to hundreds of thousands of stars per cubic parsec for billions of years, are the ideal laboratory for studying dynamics in systems which at best have solutions in only the mathematical sense of the word. Modelling these systems in a realistic way which includes all stars individually represented, with their evolution and inclusion into a comparable number of binaries as is seen in observed clusters, has driven computer hardware and software for decades (Heggie & Hut 2003). In this thesis, I have used several techniques to answer the following questions: How many black hole binaries will a cluster produce, and will they have the required properties to be seen by our gravitational wave detectors? How often does the crowded environment of star forming cluster allow the exchange of a planet between stars? To answer these questions, I have studied three scenarios: the interaction of black holes in clusters, the effect of the Kozai mechanism on pulsars in clusters, and the effect of an exchanged planetary body on a planetary system. I have examined the interactions of a system of black holes in a globular cluster in which the black holes have different masses with a more realistic distribution. This is an advance over previous studies which assumed that all black holes have the same mass, and as such when interacting tended to eject all but one or two from the cluster. The previous paradigm for black holes was that all black holes were 10 solar masses. In my thesis, black hole masses are derived from population synthesis models and span a range of a few up to 50 or 80 M [solar mass] depending on metallicity. My new calculations have reduced the efficiency of three-body interactions in ejecting the binary due to their non-equal masses. I also use timescales derived from earlier simulations of clusters (Sigurdsson 1995) to determine the end state of individual binaries interacting with single black holes. While N-body simulations of black hole systems such as in O'Leary et al. (2006) are less model dependent, my method can easily adapt to advances in the understanding of the processes that make black holes and rapidly produce results on rates of binary black hole mergers for gravitational wave observations and the possibilities of intermediate mass black hole seeds. Numerous black hole binaries are produced by clusters, they are hardened in the potential of the cluster, and the most massive black holes survive the interactions. Interactions with the other black holes preferentially produce binaries with higher eccentricities. I found that as many as one in seven binaries will coalesce within a Hubble time, and with the strength of signal that their higher mass gives they would rival galactic black hole binaries as a background source. Compare this to the more pessimistic forecast in Kulkarni et al. (1993) that they would not be a significant background source. I also found that the binaries are ejected from the cluster with, for the most part, a velocity just above the escape speed of the cluster which is a few tens of km/sec. These gravitational wave sources are thus constrained in their host galaxies as the galactic escape velocity is some hundreds of km/sec which only a very few binaries achieve in special cases (i.e. originally forming as a tight binary, their first three-body interaction liberates a large amount of kinetic energy). It is therefore fitting to perhaps take a census of galaxies and their clusters within the radius the binaries would be visible to LIGO to estimate the how many sources could be seen, especially considering the first extra-galactic black hole in a globular cluster being recently discovered (Maccarone et al. 07). I studied the effect of the Kozai mechanism on two pulsars, one in the globular cluster M4, and the other J1903+0327. The M4 pulsar pulsar was found to have an unusually large orbital eccentricity, given that it is in a binary with a period of nearly 200 days. This unusual behavior led to the conclusion that a planet-like third body of much less than a solar mass was orbiting the binary. Dynamical exchanges can deposit the planet in a highly inclined orbit, which can lead to eccentricity pumping by the Kozai effect. The Kozai effect requires a minimum inclination of the two orbits of about 40 degrees. I used my own code to integrate the secular evolution equations with a broad set of initial conditions to determine the first detailed properties of the third body; namely that the mass of the planet is about that of Jupiter. The second pulsar J1903+0327 consists of a 2.15ms pulsar and a near solar mass companion in an e = 0.44 orbit. A preliminary study of this pulsar showed that the high eccentricity can be reproduced by my models, and there are three candidate clusters from which this pulsar could have originated. My third project was a study of the effect of a planet at 50 AU on the inner solar system. The origin of this planet is assumed to be from an exchange with another solar system in the early stages of the sun's life while it was still in the dense star forming region where it was born. Similar studies have been done with the exchange of stars among binaries by Malmberg et al. (2007b). The exchange once again allows the Kozai effect to bring about drastic change in the inner system. A planet is chosen as the outer object as, unlike a stellar companion, it would remain unseen by current radial velocity and direct observation methods, although it could be detected by upcoming astrometric missions. My study uses an outer body from the size of a super Earth to a brown dwarf, in various inclinations, and exerting its influence on an inner object modelled on the Earth or Jupiter. The 50 AU size of the outer orbit corresponds with the sharp drop off in Kuiper Belt objects. This result represents the first step in a much larger project to fully explore the parameter space. I found that the size of the outer orbit drastically affects the eccentricity obtained by the inner object due to the beating of the Kozai and general relativistic precessions. I also found that four-body calculation are needed for a full understanding of how the change in the outer native object's eccentricity is propagated to the inner native object, native planets being those which are formed along with their host star. Simulations of young dense star forming clusters should illustrate how planetary sized objects are exchanged between stars. I explored the dynamics of exchanges between objects and the workings of the Kozai mechanism in my first two projects. These tools prepared me for work on a crucial issue in planet formation, that of how a peculiar subset of observed planets were formed. I have shown that exchanges and the Kozai mechanism can work together to produce the observed eccentricities of exoplanets. This is a new approach to the study of the dynamics of planet formation.
Author: Kenneth Moody Publisher: ISBN: Category : Languages : en Pages : 104
Book Description
Three body dynamics are of particular interest in clusters where the density of stars provides many opportunities for interactions. Globular clusters, which have had densities of tens to hundreds of thousands of stars per cubic parsec for billions of years, are the ideal laboratory for studying dynamics in systems which at best have solutions in only the mathematical sense of the word. Modelling these systems in a realistic way which includes all stars individually represented, with their evolution and inclusion into a comparable number of binaries as is seen in observed clusters, has driven computer hardware and software for decades (Heggie & Hut 2003). In this thesis, I have used several techniques to answer the following questions: How many black hole binaries will a cluster produce, and will they have the required properties to be seen by our gravitational wave detectors? How often does the crowded environment of star forming cluster allow the exchange of a planet between stars? To answer these questions, I have studied three scenarios: the interaction of black holes in clusters, the effect of the Kozai mechanism on pulsars in clusters, and the effect of an exchanged planetary body on a planetary system. I have examined the interactions of a system of black holes in a globular cluster in which the black holes have different masses with a more realistic distribution. This is an advance over previous studies which assumed that all black holes have the same mass, and as such when interacting tended to eject all but one or two from the cluster. The previous paradigm for black holes was that all black holes were 10 solar masses. In my thesis, black hole masses are derived from population synthesis models and span a range of a few up to 50 or 80 M [solar mass] depending on metallicity. My new calculations have reduced the efficiency of three-body interactions in ejecting the binary due to their non-equal masses. I also use timescales derived from earlier simulations of clusters (Sigurdsson 1995) to determine the end state of individual binaries interacting with single black holes. While N-body simulations of black hole systems such as in O'Leary et al. (2006) are less model dependent, my method can easily adapt to advances in the understanding of the processes that make black holes and rapidly produce results on rates of binary black hole mergers for gravitational wave observations and the possibilities of intermediate mass black hole seeds. Numerous black hole binaries are produced by clusters, they are hardened in the potential of the cluster, and the most massive black holes survive the interactions. Interactions with the other black holes preferentially produce binaries with higher eccentricities. I found that as many as one in seven binaries will coalesce within a Hubble time, and with the strength of signal that their higher mass gives they would rival galactic black hole binaries as a background source. Compare this to the more pessimistic forecast in Kulkarni et al. (1993) that they would not be a significant background source. I also found that the binaries are ejected from the cluster with, for the most part, a velocity just above the escape speed of the cluster which is a few tens of km/sec. These gravitational wave sources are thus constrained in their host galaxies as the galactic escape velocity is some hundreds of km/sec which only a very few binaries achieve in special cases (i.e. originally forming as a tight binary, their first three-body interaction liberates a large amount of kinetic energy). It is therefore fitting to perhaps take a census of galaxies and their clusters within the radius the binaries would be visible to LIGO to estimate the how many sources could be seen, especially considering the first extra-galactic black hole in a globular cluster being recently discovered (Maccarone et al. 07). I studied the effect of the Kozai mechanism on two pulsars, one in the globular cluster M4, and the other J1903+0327. The M4 pulsar pulsar was found to have an unusually large orbital eccentricity, given that it is in a binary with a period of nearly 200 days. This unusual behavior led to the conclusion that a planet-like third body of much less than a solar mass was orbiting the binary. Dynamical exchanges can deposit the planet in a highly inclined orbit, which can lead to eccentricity pumping by the Kozai effect. The Kozai effect requires a minimum inclination of the two orbits of about 40 degrees. I used my own code to integrate the secular evolution equations with a broad set of initial conditions to determine the first detailed properties of the third body; namely that the mass of the planet is about that of Jupiter. The second pulsar J1903+0327 consists of a 2.15ms pulsar and a near solar mass companion in an e = 0.44 orbit. A preliminary study of this pulsar showed that the high eccentricity can be reproduced by my models, and there are three candidate clusters from which this pulsar could have originated. My third project was a study of the effect of a planet at 50 AU on the inner solar system. The origin of this planet is assumed to be from an exchange with another solar system in the early stages of the sun's life while it was still in the dense star forming region where it was born. Similar studies have been done with the exchange of stars among binaries by Malmberg et al. (2007b). The exchange once again allows the Kozai effect to bring about drastic change in the inner system. A planet is chosen as the outer object as, unlike a stellar companion, it would remain unseen by current radial velocity and direct observation methods, although it could be detected by upcoming astrometric missions. My study uses an outer body from the size of a super Earth to a brown dwarf, in various inclinations, and exerting its influence on an inner object modelled on the Earth or Jupiter. The 50 AU size of the outer orbit corresponds with the sharp drop off in Kuiper Belt objects. This result represents the first step in a much larger project to fully explore the parameter space. I found that the size of the outer orbit drastically affects the eccentricity obtained by the inner object due to the beating of the Kozai and general relativistic precessions. I also found that four-body calculation are needed for a full understanding of how the change in the outer native object's eccentricity is propagated to the inner native object, native planets being those which are formed along with their host star. Simulations of young dense star forming clusters should illustrate how planetary sized objects are exchanged between stars. I explored the dynamics of exchanges between objects and the workings of the Kozai mechanism in my first two projects. These tools prepared me for work on a crucial issue in planet formation, that of how a peculiar subset of observed planets were formed. I have shown that exchanges and the Kozai mechanism can work together to produce the observed eccentricities of exoplanets. This is a new approach to the study of the dynamics of planet formation.
Author: Wang Sang Koon Publisher: Springer ISBN: 9780387495156 Category : Mathematics Languages : en Pages : 336
Book Description
This book considers global solutions to the restricted three-body problem from a geometric point of view. The authors seek dynamical channels in the phase space which wind around the planets and moons and naturally connect them. These low energy passageways could slash the amount of fuel spacecraft need to explore and develop our solar system. In order to effectively exploit these passageways, the book addresses the global transport. It goes beyond the traditional scope of libration point mission design, developing tools for the design of trajectories which take full advantage of natural three or more body dynamics, thereby saving precious fuel and gaining flexibility in mission planning. This is the key for the development of some NASA mission trajectories, such as low energy libration point orbit missions (e.g., the sample return Genesis Discovery Mission), low energy lunar missions and low energy tours of outer planet moon systems, such as a mission to tour and explore in detail the icy moons of Jupiter. This book can serve as a valuable resource for graduate students and advanced undergraduates in applied mathematics and aerospace engineering, as well as a manual for practitioners who work on libration point and deep space missions in industry and at government laboratories. the authors include a wealth of background material, but also bring the reader up to a portion of the research frontier.
Author: Bonnie Steves Publisher: CRC Press ISBN: 1420033301 Category : Science Languages : en Pages : 403
Book Description
The Restless Universe: Applications of Gravitational N-Body Dynamics to Planetary Stellar and Galactic Systems stimulates the cross-fertilization of ideas, methods, and applications among the different communities who work in the gravitational N-body problem arena, across diverse fields of astrophysics. The chapters and topics cover three broad the
Author: Zdzislaw Musielak Publisher: Springer ISBN: 3319582267 Category : Science Languages : en Pages : 115
Book Description
This brief book provides an overview of the gravitational orbital evolution of few-body systems, in particular those consisting of three bodies. The authors present the historical context that begins with the origin of the problem as defined by Newton, which was followed up by Euler, Lagrange, Laplace, and many others. Additionally, they consider the modern works from the 20th and 21st centuries that describe the development of powerful analytical methods by Poincare and others. The development of numerical tools, including modern symplectic methods, are presented as they pertain to the identification of short-term chaos and long term integrations of the orbits of many astronomical architectures such as stellar triples, planets in binaries, and single stars that host multiple exoplanets. The book includes some of the latest discoveries from the Kepler and now K2 missions, as well as applications to exoplanets discovered via the radial velocity method. Specifically, the authors give a unique perspective in relation to the discovery of planets in binary star systems and the current search for extrasolar moons.
Author: Sverre J. Aarseth Publisher: Cambridge University Press ISBN: 1139441078 Category : Science Languages : en Pages : 431
Book Description
This book presents basic methods for numerical simulation of gravitational systems, demonstrating how to develop clear and elegant algorithms. It explains the fundamental mathematical tools needed to describe the dynamics of a large number of mutually attractive particles, and the techniques needed to model various known planetary and astrophysical phenomena.
Author: Mauri Valtonen Publisher: Springer ISBN: 3319227262 Category : Science Languages : en Pages : 183
Book Description
This book, written for a general readership, reviews and explains the three-body problem in historical context reaching to latest developments in computational physics and gravitation theory. The three-body problem is one of the oldest problems in science and it is most relevant even in today’s physics and astronomy. The long history of the problem from Pythagoras to Hawking parallels the evolution of ideas about our physical universe, with a particular emphasis on understanding gravity and how it operates between astronomical bodies. The oldest astronomical three-body problem is the question how and when the moon and the sun line up with the earth to produce eclipses. Once the universal gravitation was discovered by Newton, it became immediately a problem to understand why these three-bodies form a stable system, in spite of the pull exerted from one to the other. In fact, it was a big question whether this system is stable at all in the long run. Leading mathematicians attacked this problem over more than two centuries without arriving at a definite answer. The introduction of computers in the last half-a-century has revolutionized the study; now many answers have been found while new questions about the three-body problem have sprung up. One of the most recent developments has been in the treatment of the problem in Einstein’s General Relativity, the new theory of gravitation which is an improvement on Newton’s theory. Now it is possible to solve the problem for three black holes and to test one of the most fundamental theorems of black hole physics, the no-hair theorem, due to Hawking and his co-workers.
Author: Mauri J. Valtonen Publisher: Cambridge University Press ISBN: 9780521852241 Category : Mathematics Languages : en Pages : 366
Book Description
How do three celestial bodies move under their mutual gravitational attraction? This problem has been studied by Isaac Newton and leading mathematicians over the last two centuries. Poincaré's conclusion, that the problem represents an example of chaos in nature, opens the new possibility of using a statistical approach. For the first time this book presents these methods in a systematic way, surveying statistical as well as more traditional methods. The book begins by providing an introduction to celestial mechanics, including Lagrangian and Hamiltonian methods, and both the two and restricted three body problems. It then surveys statistical and perturbation methods for the solution of the general three body problem, providing solutions based on combining orbit calculations with semi-analytic methods for the first time. This book should be essential reading for students in this rapidly expanding field and is suitable for students of celestial mechanics at advanced undergraduate and graduate level.
Author: Douglas Heggie Publisher: Cambridge University Press ISBN: 9780521774864 Category : Science Languages : en Pages : 376
Book Description
The globular star clusters of the Milky Way contain hundreds of thousands of stars held together by gravitational interactions, and date from the time when the Milky Way was forming. This 2003 text describes the theory astronomers need for studying globular star clusters. The gravitational million-body problem is an idealised model for understanding the dynamics of a cluster with a million stars. After introducing the million-body problem from various view-points, the book systematically develops the tools needed for studying the million-body problems in nature, and introduces the most important theoretical models. Including a comprehensive treatment of few-body interactions, and developing an intuitive but quantitative understanding of the three-body problem, the book introduces numerical methods, relevant software, and current problems. Suitable for graduate students and researchers in astrophysics and astronomy, this text also has important applications in the fields of theoretical physics, computational science and mathematics.
Author: B.A. Steves Publisher: Springer Science & Business Media ISBN: 1402047061 Category : Science Languages : en Pages : 342
Book Description
Based on the recent NATO Advanced Study Institute "Chaotic Worlds: From Order to Disorder in Gravitational N-Body Dynamical Systems", this state of the art textbook, written by internationally renowned experts, provides an invaluable reference volume for all students and researchers in gravitational n-body systems. The contributions are especially designed to give a systematic development from the fundamental mathematics which underpin modern studies of ordered and chaotic behaviour in n-body dynamics to their application to real motion in planetary systems. This volume presents an up-to-date synoptic view of the subject.
Author: Ignacio Ferreras Publisher: UCL Press ISBN: 1911307614 Category : Science Languages : en Pages : 200
Book Description
Galaxies, along with their underlying dark matter halos, constitute the building blocks of structure in the Universe. Of all fundamental forces, gravity is the dominant one that drives the evolution of structures from small density seeds at early times to the galaxies we see today. The interactions among myriads of stars, or dark matter particles, in a gravitating structure produce a system with fascinating connotations to thermodynamics, with some analogies and some fundamental differences. Ignacio Ferreras presents a concise introduction to extragalactic astrophysics, with emphasis on stellar dynamics, and the growth of density fluctuations in an expanding Universe. Additional chapters are devoted to smaller systems (stellar clusters) and larger ones (galaxy clusters). Fundamentals of Galaxy Dynamics, Formation and Evolution is written for advanced undergraduates and beginning postgraduate students, providing a useful tool to get up to speed in a starting research career. Some of the derivations for the most important results are presented in detail to enable students appreciate the beauty of maths as a tool to understand the workings of galaxies. Each chapter includes a set of problems to help the student advance with the material.
Author: Kenneth Moody
Author: Kenneth Moody
Author: Wang Sang Koon
Author: Bonnie Steves
Author: Zdzislaw Musielak
Author: Sverre J. Aarseth
Author: Mauri Valtonen
Author: Mauri J. Valtonen
Author: Douglas Heggie
Author: B.A. Steves
Author: Ignacio Ferreras