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Analysis of gravity data from the Cienega Creek area, Pima and Santa Cruz counties, ArizonaBittson, Andrew George, 1951- January 1976 (has links)
No description available.
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Η βαρύτητα ως θερμοδυναμικό φαινόμενοΜούστος, Δημήτριος 27 May 2014 (has links)
Η αναλογία μεταξύ των νόμων της μηχανικής της μελανής οπής και των νόμων της θερμοδυναμικής οδήγησε τους Bekenstein και Hawking να υποστηρίξουν ότι οι μελανές οπές θα πρέπει να θεωρηθούν ως πραγματικά θερμοδυναμικά συστήματα, τα οποία χαρακτηρίζονται από εντροπία και θερμοκρασία. Πιο συγκεκριμένα, ο Bekenstein υποστήριξε ότι η εντροπία μίας μελανής οπής ισούται με S=(k_BAc^3)/(4G\hbar), όπου A είναι το εμβαδό της επιφάνειας του ορίζοντά της, ενώ ο Hawking ότι η θερμοκρασία μιας μελανής οπής είναι T=(\hbar\grk)/(2\pi ck_B), όπου κ είναι η επιφανειακή της βαρύτητα.
Η αντιστοιχία μεταξύ των νόμων της μηχανικής της μελανής οπής και αυτών της θερμοδυναμικής υποδηλώνει την ύπαρξη μιας βαθύτερης σχέσης μεταξύ της θερμοδυναμικής και της βαρύτητας. Η προοπτική αυτή παρακίνησε τη διατύπωση αρκετών ιδεών που υποστηρίζουν ότι συνολικά η βαρύτητα μπορεί να ερμηνευθεί ως ένα θερμοδυναμικό φαινόμενο. Η πρωτότυπη ιδέα ανήκει στον Jacobson, ο οποίος αντέστρεψε τη λογική και έδειξε ότι η εξίσωση του Einstein μπορεί να θεωρηθεί ως μία καταστατική εξίσωση. Αργότερα, σε μία σειρά δημοσιεύσεων, ο Padmanabhan έδειξε ότι σε ορισμένες περιπτώσεις οι εξισώσεις της βαρύτητας μπορούν να ερμηνευθούν με όρους της θερμοδυναμικής ή ακόμη και να εξαχθούν από τη θερμοδυναμική του χωροχρόνου. Πιο πρόσφατα, ο Verlinde υπόστηριξε ότι η βαρύτητα είναι μία εντροπική δύναμη. Τα παραπάνω επιχειρήματα αποτελούν συνιστώσες της ευρύτερης απόψης που διατυπώθηκε αρχικά από τον Sakharov και υποστηρίζει ότι η βαρύτητα δεν είναι μία θεμελιώδη δύναμη, αλλά αντίθετα μία αναδυόμενη (emergent) δύναμη, η οποία προκύπτει ως το όριο κάποιας υποκείμενης μικροσκοπικής άγνωστης προς το παρόν θεωρίας, υπό την ίδια έννοια που η υδροδυναμική ή η θεωρία της ελαστικότητας αναδύονται από τη μοριακή φυσική.
Στην παρούσα εργασία μελετάμε τα επιχειρήματα των Jacobson, Padmanabhan και Verlinde που υποστηρίζουν την ερμηνεία της βαρύτητας ως μια θερμοδυναμική θεωρία. / The analogy between the laws of black hole mechanics and the laws of thermodynamics
led Bekenstein and Hawking to argue that black holes should be
considered as real thermodynamic systems that are characterised by entropy and
temperature. In particular, Bekenstein argued that the entropy of a black hole
is S = (k_BAc^3)=(4G\hbar), where A is the area of its horizon. In addition, Hawking
showed that the temperature of a black hole is T = (\hbar κ)=(2πck_B), where κ is its
surface gravity.
Black hole thermodynamics shows a deeper connection between thermodynamics
and gravity. This perspective motivated several ideas that suggest an
interpretation of gravity as a thermodynamic phenomenon. The original idea is
due to Jacobson. He first inverted the reasoning and showed that the Einstein's
equation can be viewed as an equation of state. Later, Padmanabhan showed
that the gravitational equations can be interpreted in terms of thermodynamics.
He also showed that one can derive the gravitational equations from the thermodynamics
of spacetime. More recently, Verlinde argued that gravity is an entropic
force. The above arguments are components of the broader view, first formulated
by Sakharov, that gravity is not a fundamental force, but an emergent one. It
arises in the limit of some underlying--- yet unknown--- microscopic theory, in
the same sense that hydrodynamics or elasticity emerge from molecular physics.
In this thesis, we examine the arguments of Jacobson, Padmanabhan and
Verlinde that suggest an interpretation of gravity as a thermodynamic theory.
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Μελέτη της ροής υγρών σε συσκευές έγχυσης υπό την επίδραση της βαρύτηταςΠρουνιάς, Γεώργιος 15 December 2008 (has links)
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The Effects of Gravity Modulation on The Instability of Double-Diffusive Convection in a Horizontal TankYu, Youmin January 2006 (has links)
The effects of gravity modulation on the instability of double-diffusive convections in a horizontal tank with aspect ratio (width/height) of 11 have been investigated by experiments and numerical simulations. The stably stratified fluid layer is set up with ethanol-water solution of 0.0 and 2.0% (by weight). The tank is fixed on a platform that can oscillate in the vertical direction. A constant temperature difference is maintained across the tank at thermal Rayleigh number . The fluid layer becomes unstable as the initially stable solute gradient slowly decreases due to the non-diffusive boundary conditions. The experiments determine that the instability onset under steady gravity is at with onset vortices of wavelength and oscillatory frequency . When the tank is oscillated at modulation frequency and amplitude , the fluid layer is destabilized slightly with a critical and onset vortices of and . A two-dimensional numerical simulation has accurately reproduced the experimental results of steady gravity, and demonstrated that the slight destability effect of gravity modulation is contributed by the asymmetry of the actual gravity modulation.Further simulations have yielded following results: (1) Under steady gravity, the kinetic energy and mechanical work components oscillate synchronously with . Under modulated gravity, they only oscillate synchronously with when is low, whereas not only synchronously with locally but also synchronously with globally when is high; (2) The resonance phenomenon predicted by Chen (2001) also exists under the present lab conditions. Such instability is in the sub-harmonic mode and the destability effect increases as increases. (3) The double-diffusive fluid layer may experience density-mode instability before the double-diffusive instability onset at certain and . Such density-mode instability is generally in the sub-harmonic mode, although it may be in the synchronous mode when is low and is large. This instability accelerates the mixing of the density gradient across the fluid layer and thus affects the succeeding double-diffusive instability; (4) When the background gravity is absent, the purely modulated gravity destabilizes the fluid layer when is low. On the contrary, it stabilizes the fluid layer when is high and the instability onset is in the synchronous mode.
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Euroland - The effect of Euro on international trade : Are there winners and losers in this ''Euro-game''?Gkoutsampasoulis, Nikolaos January 2014 (has links)
This paper examines whether European Monetary Union (EMU) countries share fairly the effect of their membership in Eurozone (EZ) or whether are winners and losers in this ''Euro-game''. By using panel data of 27 European Union (EU) Member States for the period 2001-2012 in the context of a gravity model, we focus on estimating the Euro’s effect on bilateral trade and we detect whether this effect differs across the Member States of EZ. Two estimation methods are applied: Pooled OLS estimator and Fixed Effects estimator. The empirical results come to the conclusion that the individual country effects differ and are statistically significant, indicating that EMU’s effect on trade differs across the Member States of EZ. The overall effect of the Euro is statistically insignificant, regardless the estimation method, demonstrating that the common European currency may have no effect on bilateral trade.
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Cosmic Acceleration As Quantum Gravity PhenomenologyPrescod-Weinstein, Chanda Rosalyn Sojourner January 2010 (has links)
The discovery of cosmic acceleration has prompted the need for a new understanding of cosmology. The presence of this acceleration is often described as the dark energy problem or the Lambda problem.The simplest explanation is that the acceleration is due to addition of a cosmological constant to Einstein's equation, but this resolution is unsatisfactory as it leaves several unanswered questions. Although General Relativity has been tested in the strong-field limit, the apparent dark energy may be urging us to consider experimental cosmology as such a test for large scales. In this vein, I have pursued a study of modifications to Einstein's gravity as well as possible related quantum gravity phenomenology.
Not only must the details of modified gravities be worked out, but their impact on other astrophysics must be checked. For example, structure formation provides a strong test of any cosmic acceleration model because a successful dark energy model must not inhibit the development of observed large-scale structures. Traditional approaches to studies of structure formation in the presence of dark energy or a modified gravity implement the Press & Schechter formalism. I explore the potential for universality in the Press & Schechter formalism and what dark matter haloes may be able to tell us about cosmology.
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Cosmic Acceleration As Quantum Gravity PhenomenologyPrescod-Weinstein, Chanda Rosalyn Sojourner January 2010 (has links)
The discovery of cosmic acceleration has prompted the need for a new understanding of cosmology. The presence of this acceleration is often described as the dark energy problem or the Lambda problem.The simplest explanation is that the acceleration is due to addition of a cosmological constant to Einstein's equation, but this resolution is unsatisfactory as it leaves several unanswered questions. Although General Relativity has been tested in the strong-field limit, the apparent dark energy may be urging us to consider experimental cosmology as such a test for large scales. In this vein, I have pursued a study of modifications to Einstein's gravity as well as possible related quantum gravity phenomenology.
Not only must the details of modified gravities be worked out, but their impact on other astrophysics must be checked. For example, structure formation provides a strong test of any cosmic acceleration model because a successful dark energy model must not inhibit the development of observed large-scale structures. Traditional approaches to studies of structure formation in the presence of dark energy or a modified gravity implement the Press & Schechter formalism. I explore the potential for universality in the Press & Schechter formalism and what dark matter haloes may be able to tell us about cosmology.
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Investigation of Gravity Drainage in Fractured Porous MediaZendehboudi, Sohrab 20 September 2010 (has links)
The oil production from well fractured carbonate reservoirs is a considerable part of the total oil production in the world. The petroleum resource base in naturally fractured reservoirs is estimated to be in the range of billions of barrels in the U.S and in addition, a multibillion- barrel international oil resource base exists in naturally fractured reservoirs.
Gravity drainage is important in some of oil recovery processes, either acting as the driving force in processes using horizontal wells or altering the displacement patterns during water-flooding, chemical flooding, CO2 flooding and other EOR methods. The gravity drainage process has a major effect on oil recovery from oil reservoirs. Gravity drainage driven oil production in naturally fractured and other complex reservoirs falls into two regimes: the balk flow regime and the film flow regime. Oil recovery by gravity drainage in a fractured reservoir strongly depends on the capillary height of the porous medium. Capillarity and gravity forces are usually the major driving forces in fractured reservoirs.
This PhD thesis consists of two main parts namely: 1) Experimental works on gravity drainage, and 2) Modeling and simulation of the gravity drainage processes using COMSOL® software.
An appropriate design of experiment (DOE) method was selected to find the most important parameters contributing in gravity drainage and then conduct the experiments in a useful as well as economic manner. A two-dimensional experimental setup was employed to investigate free fall gravity drainage (FFGD) and controlled gravity drainage (CGD) using unconsolidated glass beads fractured porous media having various fractures configurations. Flow visualization measurements were carried out. Following the flow visualization experiments, parametric sensitivity analysis was performed considering the effects of different system parameters such as fracture aperture, matrix height, permeability, and fluid properties on the dependent variables including drainage rate, critical pumping rate, maximum drainage rate, recovery factor and so on. These experiments enabled us to capture some aspects of the recovery mechanism and the flow communication between matrix block and fracture during gravity drainage. After analyzing the experimental data for the FFGD test runs, it was found that the rate of liquid flowing from matrix to fracture is proportional to the difference of liquid levels in the matrix and in the fracture. In addition, the characteristic rate and the maximum liquid drainage rate from the fractured models were determined for such a stable gravity-dominated process. The experiments showed that the presence of fracture is more influential in lower matrix permeability systems. For a given fracture-matrix system with different initial liquid saturation conditions, it was seen that the production history can be correlated by plotting the fraction of recoverable liquid as a function of time. Furthermore, the recovery factor can be correlated using dimensionless numbers such as the Bond number and the dimensionless time.
For the controlled gravity drainage (CGD) test runs conducted, the experimental results indicated that higher pumping rates cause a higher difference between the liquid levels in the fracture and in the matrix, thus the gas breakthrough happens sooner. Moreover, it was found that as long as the porous medium is drained with a constant liquid pumping rate but lower than critical rate, the height difference between the G-L interfaces in matrix and fracture remains constant. In this study, a new concept of “Critical Pumping Rate” (CPR) was defined at which each particular porous medium has recovery factor equal to the recovery factor for higher rates just before gas breakthrough. The difference between liquid levels in fracture and matrix remains unchanged at rates higher than CPR. Known this particular withdrawal rate, there are two main advantages, namely: 1) choosing a pumping rate lower than it to drain the reservoir without getting gas breakthrough; and 2) understanding the physics of pumping behaviour from fractured media and extending the concept to the real cases. In addition, the maximum liquid pumping rate from each physical model was studied and it was found that the rate depends strongly on the storage capacity of the fractures, petrophysical properties of each model as well as physical properties of test fluids. The critical rate, maximum rate, recovery factor at gas breakthrough and difference of gas liquid interface positions in matrix and fracture were correlated by dimensionless numbers such as Bond number, Capillary, and the ratio of permeabilities. Linear regression correlations presented in this study can predict production history and flow behaviour in the fractured porous media for a wide range of dimensionless numbers.
The COMSOL® software was used to numerically simulate the gravity drainage processes in the two-dimensional flow experiments for fractured porous media. The parameters of the model were based on theory, as well as on the results of the two-dimensional gravity drainage experiments. The simulation results for the gravity drainage processes compared favourably with the experimental results, as a good match between the numerical solution and the experimental data was found. The simulation model developed provides a basis for further modeling of gravity drainage process in more complicated porous media.
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The static self-force in Schwarzschild-de Sitter and Schwarzschild-Anti-de Sitter spacetimesKuchar, Joseph 21 August 2013 (has links)
I investigate the self-force acting on static scalar and electric charges in Schwarzschild-de Sitter and Schwarzschild-Anti-de Sitter spacetimes. The self-force occurs when a charged particle's field interacts with the curvature of spacetime so that the particle interacts with its own field. Because the field of a point particle is singular at the location of the particle, it is necessary to decompose the field into a regular part responsible for the self-force and a singular part that does not contribute to the self-force. To do this, I use the mode-sum regularization scheme introduced by Barack and Ori, in which the field is decomposed into a sum over modes, and the singular part is removed from each mode using so-called regularization parameters.
I find that the electrostatic self-force in Schwarzschild-de Sitter and Schwarzschild-Anti-de Sitter behaves similarly to Schwarzschild self-force near the black hole, but can deviate strongly at larger distances. This is especially true in Schwarzschild-Anti-de Sitter, where the self-force is seen to increase linearly with distance. I provide an explanation for this behaviour using conformal transformations. A particular feature evident in Schwarzschild-Anti-de Sitter is that the self-force can become negative (attractive) at small distances when the Schwarzschild radius and the cosmological length scale are of a similar order. I find that the scalar self-force in Schwarzschild-de Sitter can not actually be computed, and in Schwarzschild-Anti-de Sitter the asymptotic behaviour is similar to its electrostatic counterpart.
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A theoretical investigation of gravity-wave-generated stress and vorticity in the planetary boundary layerNappo, Carmen Joseph 05 1900 (has links)
No description available.
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