Relatively Compact Orbits and Compact Attractors for a Class of Nonlinear Evolution Equations

In the present paper we consider the nonlinear evolution equation u+AuG(u), where A:D(A)XX is m-accretive with (I+A)^–1 compact for some >0, and is continuous, and we prove that the orbit is relatively compact if and only if u is uniformly continuous, and both u and G^u are bounded on . In the same spirit, we derive conditions for orbits of bounded sets to have compact attractors. Some consequences and an example from age-structured population dynamics illustrate the effectiveness of the abstract result.     

Global Attractors: Topology and Finite-Dimensional Dynamics

Many dissipative evolution equations possess a global attractor with finite Hausdorff dimension d. In this paper it is shown that there is an embedding X of into , with N=[2d+2], such that X is the global attractor of some finite-dimensional system on with trivial dynamics on X. This allows the construction of a discrete dynamical system on which reproduces the dynamics of the time T map on and has an attractor within an arbitrarily small neighborhood of X. If the Hausdorff dimension is replaced by the fractal dimension, a similar construction can be shown to hold good even if one restricts to orthogonal projections rather than arbitrary embeddings.     

States of classical statistical mechanical systems of infinitely many particles. I

We study a general mathematical model of a classical system of infinitely many point particles. The space X of infinite particle configurations is equipped with a natural topology as well as a measurable structure related to it. It is also connected with a family {X _A } of local spaces of finite configurations indexed by bounded open sets A in the one-particle space E. A theorem analogous to Kolmogoroff's fundamental theorem for stochastic processes is proved, according to which a consistent family { _A } of local probability measures _A defined on the X _A gives rise to a unique probability measure on X. We also study the problem of integral representation for positive linear forms defined over some linear space of real functions on X. We prove that a positive linear form F(f), defined for functions f in the class C+P, admits a uniquely determined integral representation F(f)= f () d, where is a probability measure over X.     

Solvability of Degenerate Semilinear Parabolic Functional Differential Equations

We obtain local and global theorems on the existence and uniqueness of a solution of the semilinear functional differential equation in a Banach space with a parabolic pencil of operators A + B, where the operator A can be noninvertible. Abstract results are applied to partial functional differential equations.     

Regularity of invariant manifolds

Under mild conditions it is proved that an invariant submanifold ofX 0<1 for the equationdx/dt+Ax=f(x), A sectorial,fC'(X ,X),0<1, is a submanifold ofX ¹ as well. In addition, conditions are given for the semiflow of the equation to extend fromX toX and a new inertial manifold theorem is proved for the scalar reaction diffusion equation.     

Slip flow in the hydrodynamic entrance region of a tube and a parallel plate channel

Summary The problem of slip flow in the entrance region of a tube and parallel plate channel is considered by solving a linearized momentum equation. The condition is imposed that the pressure drop from momentum considerations and from mechanical energy considerations should be equal. Results are obtained for Kn=0, 0.01, 0.03, 0.05, and 0.1 and the pressure drop in the entrance region is given in detail.Nomenclature A cross-sectional area of duct - c mean value of random molecular speed - d diameter of tube - f _p - f _t - h half height of parallel plate channel - Kn Knudsen number - L molecular mean free path - n directional normal of solid boundary - p pressure - p ₀ pressure at inlet - r radial co-ordinate - r _t radius of tube - R non-dimensional radial co-ordinate - Re _p 4hU/ - Re _t 2r _t U/ - s direction along solid boundary - T absolute temperature - u velocity in x direction - u* non-dimensional velocity - U bulk velocity = (1/A) _A u dA - v velocity in y direction - x axial co-ordinate - x* stretched axial co-ordinate - X non-dimensional axial co-ordinate - X* non-dimensional stretched axial co-ordinate - Y non-dimensional channel co-ordinate - eigenvalue in parallel plate channel - stretching factor - eigenvalue in tube - density - kinematic viscosity - i index - p parallel plate - t tube - v velocity vector - gradient operator - ² Laplacian operator     

Scheme of Investigation of the Spectrum of a Family of Perturbed Operators and Its Application to Spectral Problems in Thick Junctions

We develop a scheme for the investigation of the asymptotic behavior of eigenvalues and eigenvectors of a family of self-adjoint compact operators {A: > 0} that act in different spaces and lose their compactness in the limit case 0. We prove the Hausdorff convergence of the spectrum of the operator A to the spectrum of the limit operator A₀, obtain asymptotic estimates for this convergence both to points of the discrete spectrum and to points of the essential spectrum of the operator A₀, and prove asymptotic estimates for eigenvectors of A. This scheme is applied to the investigation of the asymptotic behavior of eigenvalues and eigenfunctions of the Neumann problem in a thick singularly degenerate junction that consists of two domains connected by an -periodic system of thin rods of fixed length.     

Global solvability of one degenerate semilinear differential operator equation

We consider the Cauchy problem for the abstract semilinear differential equation where A and B are linear closed, generally speaking, degenerate operators acting from a Banach space X into a Banach space Y and f(t, u) is a continuously differentiable function. We assume that the resolvent (A + B)^–1 has a pole of at most second order at the point = 0. Global conditions for the existence and uniqueness of a solution of the Cauchy problem are obtained. The results are applied to a nonlinear degenerate initial boundary-value problem with partial derivatives and to a system of differential-algebraic equations of a nonlinear electric circuit.Translated from Neliniini Kolyvannya, Vol. 7, No. 3, pp. 414–429, July–September, 2004.     

Homologies of Intersections of Pseudomanifolds with Local Homotopic Conditions on Links of Strata

In terms of local homotopic properties of the links of strata of an n-dimensional PL-pseudomanifold X, we obtain a sufficient condition for the natural homomorphisms of the jth intersection homology groups with perversity multiindices and to be isomorphisms for all j i, where i < n – 3.     

The microscopic analysis of high forchheimer number flow in porous media

High Forchheimer number flow through a rigid porous medium is numerically analysed by means of the volumetric averaging concept. The microscopic flow mechanisms, which must be known in order to understand the macroscopic flow phenomena, are studied by utilising a periodic diverging-converging representative unit cell (RUC). The detailed information for the microscopic flow field, in association with the locally averaged momentum balance, makes it possible to quantitatively demonstrate that the microscopic inertial phenomenon, which leads to distorted velocity and pressure fields, is the fundamental reason for the onset of nonlinear (non-Darcy) effects as velocity increases. The hydrodynamic definitions for Darcy's law permeabilityk, the inertial coefficient and Forchheimer number Fo are obtained by applying the averaging theorem to the pore level Navier-Stokes equations. Finally, these macroscopic parameters are numerically calculated at various combinations of micro-geometry and flow rate, and graphically correlated with the relevant microscopic parameters.Nomenclature a _i body force acceleration (m/s²) - A viscous integral term defined in (4.6) - A _f area of entrance and exist of RUC (m²) - A _fs interfacial area between the fluid and solid phases (m²) - B pressure integral term defined in (4.4) - d throat diameter of RUC (m) - D pore diameter of RUC (m) - Fo Forchheimer number defined in (4.1) and (4.10) - g gravitational acceleration (m/s²) - i, j microscopic unit vector for RUC - k Darcy's law permeability (m²) - k _v velocity dependent permeability defined in (4.1) (m²) - L length of a unit cell (m) - L _p pore length of RUC (m) - L _t throat length of RUC (m) - n unit outwardly directed vector for the fluid phase - p microscopic fluid pressure (N/m²) - P macroscopic fluid pressure (N/m²) - _en mean pressure at entrance of RUC (N/m²) - _ex mean pressure at exit of RUC (N/m²) - r _i,r coordinate on the macroscopic scale (m) - Re _d Reynolds number defined in (4.5) - u _i,u microscopic velocity (m/s) - specific discharge (m/s) - _d mean velocity at the throat of RUC (m/s) - v microscopic velocity (m/s) - V _b representative elementary volume (REV) (m³) - V _f volume occupied by the fluid within REV (m³) - V _s volume occupied by the solid within REV (m³) - x _i,x coordinate on the microscopic scale (m) - X _i,X coordinate on the macroscopic scale (m) Greek the inertia coefficient (1/m) - viscosity coefficient (Ns/m²) - _i microscopic unit vector - areosity at the entrance and the exit cross-section of RUC - fluid density (kg/m³) - porosity - _f a general property of the fluid phase Symbols ^f intrinsic phase average - the fluctuating part of _f - the mean value of _f - _f ^* the dimensionless value of _f     

Mass transport and reaction in catalyst pellets

When heterogeneous chemical reactions take place in porous catalysts, mass transport can occur by bulk diffusion, Knudsen diffusion, and convective transport. Previous studies of these phenomena have been largely based on Maxwell's dusty gas model with the convective transport or Darcy flow added to the diffusive transport. This is done in order to satisfy one of the limiting conditions encountered in the study of flow in porous media. A more fundamental approach consists of the use of the method of volume averaging and the general form of the species momentum equation. For an N-component system, this leads to N independent flux relations to be used in conjunction with the volume-averaged species continuity equations.Roman Letters _A (t) surface area of a species body, m² - a _v interfacial area per unit volume, m^-1 - A _e area of entrances and exits for the -phase contained within the averaging volume, m² - A _K area of the - surface contained within the averaging volume, m² - b _A species A body force, N/kg - b mass average body force, N/kg - B inverse tortuosity tensor for bulk diffusion - c total molar concentration, moles/m³ - c _A species A molar concentration, moles/m³ - _A surface concentration of species A, moles/m² - C_A² intrinsic phase average molar concentration, moles/m³ - c _A – C_A², spatial deviation concentration, moles/m³ - c _A mean molecular speed for species A, m/s - binary diffusion coefficient, m²/s - D _A ^{K, eff} Knudsen diffusion coefficient for species A, m²/s - f vector that maps P _A into P _A , m - g gravitational vector, m/s² - G second order tensor that maps N _A into N _A for free molecule flow conditions - H inverse tortuosity tensor for Knudsen diffusion - I unit tensor - j _A c _A u _A ^* , molar diffusive flux, moles/m²s - K Darcy's Law permeability tensor, m² - L macroscopic length scale, m - L _D diffusive length, m - l characteristic length for the -phase, m - l _A mean free path for species A, m - M _A molecular weight of species A, kg/mole - n outwardly directed unit normal vector - n _K unit normal vector directed from the -phase toward the -phase - n outwardly directed unit normal vector at the entrances and exits of the -phase contained within the averaging volume - N _A c _A v _A molar flux of species A, moles/m²s - N _A intrinsic phase average of the species A molar flux, moles/m²s - \~N _A spatial deviation of the molar flux of species A, moles/m²s - p total pressure, N/m² - P p + , total pressure over and above the hydrostatic pressure, N/m² - P _A partial pressure of species A, N/m² - p _A intrinsic phase average partial pressure, N/m² - P_A – p _A, spatial deviation partial pressure, N/m² - P _A p_A + _AA partial pressure of species A over and above the hydrostatic pressure of species A, N/m² - p _ab diffusive force exerted by species B on species A, N/m³ - universal gas constant, N m/moles K - R _A molar rate of production of species A owing to homogeneous chemical reaction, moles/m³s - molar rate of production of species A owing to heterogeneous chemical reaction, moles/m²s - r _A mass rate of production of species A owing to homogeneous chemical reaction, kg/m³s - r ₀ radius of the averaging volume, m - r position vector, m - t time, s - t _A species stress vector, N/m² - T _A species stress tensor, N/m² - T total stress tensor, N/m² - T temperature, K - T spatial average temperature, K - u _A v _A – v, mass diffusion velocity, m/su _A ^* v_A – v^*, molar diffusion velocity, m/s - u _o velocity of the rigid, solid phase relative to some inertial frame, m/s - v _A species velocity, m/s - v mass average velocity, m/s - v ^* molar average velocity, m/s - v _A ^* species velocity of those molecules of species A generated by chemical reaction, m/s - _A (t) volume of a species A body, m³ - averaging volume, m³ - V volume of the -phase contained within the averaging volume, m³ - V volume of the -phase contained within the averaging volume, m³ - v phase average, mass average velocity, m/s - w arbitrary velocity vector, m/s - x _A c _A /c mole fraction of species A - X _A intrinsic phase average mole fraction - X _A – X _A , spatial deviation mole fraction Greek Letters V/V volume fraction of the -phase - _A sum of all terms in the species A momentum equation that are small compared to the diffusive force, N/m³ - viscosity of the -phase, Ns/m² - _A mass density of species A, kg/m³ - total mass density, kg/m³ - _a species viscous stress tensor, N/m² - total viscous stress tensor, N/m² - tortuosity factor - total body force potential function, Nm/kg - _a species body force potential function, Nm/kg - 3.1416 - _{a a} / mass fraction of species A     

Non-persistence of Homoclinic Connections for Perturbed Integrable Reversible Systems

The dynamics of an analytic reversible vector field (X,) is studied in with one real parameter close to 0; X=0 is a fixed point. The differential D_x (0,0) generates an oscillatory dynamics with a frequency of order 1—due to two simple, opposite eigenvalues lying on the imaginary axis—and it also generates a slow dynamics which changes from a hyperbolic type—eigenvalues are —to an elliptic type—eigenvalues are —as passes trough 0. The existence of reversible homoclinic connections to periodic orbits is known for such vector fields. In this paper we study a particular subclass of such vector fields, obtained by small reversible perturbations of the normal form. We give an explicit condition on the perturbation, generically satisfied, which prevents the existence of a homoclinic connections to 0 for the perturbed system. The normal form system of any order admits a reversible homoclinic connection to 0, which then does not survive under perturbation of higher order. It will be seen that normal form essentially decouples the hyperbolic and elliptic part of the linearization to any chosen algebraic order. However, this decoupling does not persist arbitrary reversible perturbation, which finally causes the appearance of small amplitude oscillations.     

Determination of the orthotropic plate parameters of stiffened plates and grillages in free vibration

Summary It is well known that the analysis of vibration of orthogonally stiffened rectangular plates and grillages may be simplified by replacing the actual structure by an orthotropic plate. This needs a suitable determination of the four elastic rigidity constants D _x, D _y, D _xy, D ₁ and the mass of the orthotropic plate. A method is developed here for determining these parameters in terms of the sectional properties of the original plate-stiffener combination or the system of interconnected beams. Results of experimental work conducted on aluminium plates agree well with the results of the theory developed here.Notation a, b span and width of stiffened plates, grillages and orthotropic plates - c, spacing of beams in the y and x directions - D rigidity of an unstiffened isotropic plate - D _x, D _y rigidities in the x and y directions of an orthotropic plate - D _xy torsional rigidity of an orthotropic plate - D ₁ a parameter associated with a poisson type ratio - e depth of the common neutral axis of the beam-plate combination below the middle surface of the plate - E, G modulus of elasticity and modulus of shear - H =D ₁+2D _xy - i, j integers - I, , I _i, I _j moment of inertia of beams - J, J _i, J _j polar moment of inertia of beams - m, n integers referring to mode numbers in the x and y directions - p _{m n} natural frequency of an orthotropic plate - r, s number of beams in the transverse and longitudinal direction - T _g, T _o, T _s kinetic energy of grillages, orthotropic plates and stiffened plates - u frequency parameter of grillages - V _g, V _o, V _s potential energy of grillages, orthotropic plates and stiffened plates - W=W(x, y, t) deflection of an orthotropic plate - w=w(x, y) amplitude of vibration of orthotropic plates, stiffened plates and grillages - x, y, x _i, y _i cartesian coordinates - X _m, Y _n beam eigen functions - X _mj, Y _ni X _mand Y _nat x=x _jand y=y _i - X _m, Y _n; X_m, Y_n first and second derivatives of X _mand Y _nrespectively - Y _mn plate eigen functions - _n, _n parameters occurring in the expression for the beam functions - , , _i, _j mass per unit length of beams - _mn = frequency parameter of beam and slab bridges - = - Poisson's ratio - , mass per unit area of unstiffened plates and orthotropic plates - _mn natural frequency of stiffened plates and grillages     

The flow regime in the turbulent near wake of a hemisphere

The work presented is a wind tunnel study of the near wake region behind a hemisphere immersed in three different turbulent boundary layers. In particular, the effect of different boundary layer profiles on the generation and distribution of near wake vorticity and on the mean recirculation region is examined. Visualization of the flow around a hemisphere has been undertaken, using models in a water channel, in order to obtain qualitative information concerning the wake structure.List of symbols C _p pressure coefficient, - D diameter of hemisphere - n vortex shedding frequency - p pressure on model surface - p ₀ static pressure - Re Reynolds number, - St Strouhal number, - U, V, W local mean velocity components - mean freestream velocity inX direction - U ^* shear velocity, - u, v, w velocity fluctuations inX, Y andZ directions - X Cartesian coordinate in longitudinal direction - Y Cartesian coordinate in lateral direction - Z Cartesian coordinate in direction perpendicular to the wall - it* boundary layer displacement thickness, - diameter of model surface roughness - elevation angleI - O boundary layer momentum thickness, - _w wall shearing stress - dynamic viscosity of fluid - density of fluid - streamfunction - _x longitudinal component of vorticity, - _y lateral component of vorticity, - _z vertical component of vorticity, This paper was presented at the Ninth symposium on turbulence, University of Missouri-Rolla, October 1–3, 1984     

Fast Decaying Solutions of the Navier-Stokes Equation and Asymptotic Properties

While the basic global existence problem for the Navier-Stokes equations seems to remain open, there are related questions of some interest which are amenable to discussion: find large initial data giving rise to global solutions. Such initial data are known in the literature. A study shows that they have a peculiar property: they give rise to solutions which decay fast in very short time. A major result to be proved states that the set of trajectories induced by such initial data is dense in every open set (with respect to some fractional power norm). A further result states that if the exterior force f is zero, then such rapid decays cannot occur infinitely often along trajectories. This follows from some inequalities, connecting and , with A the Stokes operator.     

On K-BKZ and other viscoelastic models as continuum generalizations of the classical spring-dashpot models

An alternate constitutive formulation for visco-elastic materials, with particular emphasis on macromolecular viscoelastic fluids, is presented by generalizing Maxwell's idealized separation of elastic and relaxation mechanisms. The notion ofrelative rate of change of elastic stress is identified, abstracted, and formulated with the help of the established theory of finitely elastic isotropic materials. This given a local rate-type constitutive relation for an elastic mechanism in a simple material.For the simplest class of viscoelastic polymer melts, the notion of rate of change of elastic stress and its damped accumulation is identified and formulated. Under conditions of moderate strain rates, this scheme implies the reliable K-BKZ model for a class of polymer melts. An obvious extension generalizes the remaining classical spring-dashpot models. I Set of second-order tensors.A I is identified with a 3 × 3 matrix in a Cartesian co-ordinate system - I ^sym Set of symmetric second order tensors - Q Orthogonal tensor, i.e.Q ^T=Q ^–1. - Symbol for the value of the functional H:X I ^sym, whereX is the set of piecewise continuous and differentiable strain historiesF _to : [t ₀,t] I Other functionals, unless otherwise specified, should be interpreted in a similar manner.     

Some refinements concerning the boundary conditions at the macroscopic level

The study of boundary effects initiated in a previous paper is continued. New assumptions regarding the geometrical structure of the boundary surface are introduced. Under these assumptions, it is shown that macroscopic Neumann conditions do not generally affect the determination of the macroscopic field in the case of the transport process considered — heat conduction. For this type of boundary condition, the boundary effect is generally confined within a thin layer near the boundary. When heat sources are taken into account within the porous domain, the result is different. In this case, making use of a Neumann boundary condition, expressed in terms of macroscopic variables, amounts to introducing an extra flux. Under normal circumstances, however, this additional flux is negligible.Roman Letters A cross-sectional area of a unit cell - A _e cross-sectional area of a unit cell at the boundary surface - A _sf interfacial area of the s-f interface contained within the averaging volume - surface area per unit volume (A _sf/ ) - A _sf interfacial area of the s-f interface contained within the macroscopic system - g closure vector - h closure vector - k heat transfer coefficient at the s-f interface - K_eff effective thermal conductivity tensor - _x unit cell length - n unit vector - n_e outwardly directed unit normal vector at the boundary - n_sf outwardly directed unit normal vector for thes-phase at f-s interface - q heat flux density - T ^* macroscopic temperature defined by the macroscopic problem - s closure variable - V volume of the macroscopic system - V boundary surface of the macroscopic domain - V ₁ macroscopic sub-surface of the boundary surface - x local coordinate Greek Letters _s,_f volume fraction - _s, gl_f microscopic thermal conductivities - true microscopic temperature - ^* microscopic temperature corresponding toT ^* - microscopic error temperature - vector defined by Equation (34) - < > spatial average     

Shakedown analysis of shell structures of kinematic hardening materials

It is of great practical importance to analyze the shakedown of shell structures under cyclic loading, especially of those made of strain hardening materials.In this paper, some further understanding of the shakedown theorem for kinematic hardening materials has been made, and it is applied to analyze the shakedown of shell structures. Though the residual stress of a real state is related to plastic strain, the time-independent residual stress field as we will show in the theorem may be unrelated to the time-independent kinematically admissible plastic strain field . For the engineering application, it will be much more convenient to point this out clearly and definitely, otherwise it will be very difficult. Also we have proposed a new method of proving this theorem. The above theorem is applied to the shakedown analysis of a cylindrical shell with hemispherical ends. According to the elastic solution, various possible residual stress and plastic strain fields, the shakedown analysis of the structure can be reduced to a mathematical programming problem. The results of calculation show that the shakedown load of strain hardening materials is about 30–40% higher than that of ideal plastic materials. So it is very important to consider the hardening of materials in the shakedown analysis, for it can greatly increase the structure design capacity, and meanwhile provide a scientific basis to improve the design of shell structures.     

On the relationship between Lorentz's theorem for viscous flow and Onsager's reciprocal theorem

This paper views the Lorentz reciprocal theorem of slow viscous flow as a thermodynamic theorem and shows that it is a special case of the more general (and powerful) reciprocal theorem of non-equilibrium thermodynamics due to Onsager, applied at the global (as opposed to local) level. The point is illustrated with two simple problems in viscous flow theory.Nomenclature a particle radius - A area of control surface or cross-sectional area of tube - C conductance coefficient - e specific internal energy - F force on moving plate or particle - h distance between plates - n number of particles per unit length - p, hydrostatic pressure (modified pressure, Eq. (23)) - p _ij stress tensor - P _ij surface traction tensor - q(Q) local (global) heat flow rate - r ₀ tube radius - R resistance coefficient - s specific entropy - T,(T ₀) temperature (reference temperature) - u fluid velocity - U velocity of moving plate or particle - u _j velocity vector - v Specific volume - V volume flow rate - W work rate - induction coefficient - fluid thermal conductivity - fluid viscosity - fluid density - ,() Local (global) entropy generation rate     

The Spectrum of the Frobenius–Perron Operator and Its Discretization for Circle Diffeomorphisms

To investigate the dynamical behaviour of a discrete dynamical system given by a map f, it is nowadays a standard method to look at the discretization of the Frobenius–Perron operator _f w.r.t. a box-partition of the state space resulting in a transition matrix P _{f, N} of a finite Markov chain. We are interested in information about the dynamics of f obtained from the spectrum of P _{f, N} , especially for circle diffeomorphisms. Therefore the spectra of _f and P _{f, N} are investigated.