29,104 research outputs found

    Infinitely Many Strings in De Sitter Spacetime: Expanding and Oscillating Elliptic Function Solutions

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    The exact general evolution of circular strings in 2+12+1 dimensional de Sitter spacetime is described closely and completely in terms of elliptic functions. The evolution depends on a constant parameter bb, related to the string energy, and falls into three classes depending on whether b<1/4b<1/4 (oscillatory motion), b=1/4b=1/4 (degenerated, hyperbolic motion) or b>1/4b>1/4 (unbounded motion). The novel feature here is that one single world-sheet generically describes {\it infinitely many} (different and independent) strings. The world-sheet time τ\tau is an infinite-valued function of the string physical time, each branch yields a different string. This has no analogue in flat spacetime. We compute the string energy EE as a function of the string proper size SS, and analyze it for the expanding and oscillating strings. For expanding strings (S˙>0)(\dot{S}>0): E0E\neq 0 even at S=0S=0, EE decreases for small SS and increases S\propto\hspace*{-1mm}S for large SS. For an oscillating string (0SSmax)(0\leq S\leq S_{max}), the average energy over one oscillation period is expressed as a function of SmaxS_{max} as a complete elliptic integral of the third kind.Comment: 32 pages, Latex file, figures available from the authors under request. LPTHE-PAR 93-5

    Semi-Classical Quantization of Circular Strings in De Sitter and Anti De Sitter Spacetimes

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    We compute the {\it exact} equation of state of circular strings in the (2+1) dimensional de Sitter (dS) and anti de Sitter (AdS) spacetimes, and analyze its properties for the different (oscillating, contracting and expanding) strings. The string equation of state has the perfect fluid form P=(γ1)E,P=(\gamma-1)E, with the pressure and energy expressed closely and completely in terms of elliptic functions, the instantaneous coefficient γ\gamma depending on the elliptic modulus. We semi-classically quantize the oscillating circular strings. The string mass is m=C/(πHα),  Cm=\sqrt{C}/(\pi H\alpha'),\;C being the Casimir operator, C=LμνLμν,C=-L_{\mu\nu}L^{\mu\nu}, of the O(3,1)O(3,1)-dS [O(2,2)O(2,2)-AdS] group, and HH is the Hubble constant. We find \alpha'm^2_{\mbox{dS}}\approx 5.9n,\;(n\in N_0), and a {\it finite} number of states N_{\mbox{dS}}\approx 0.17/(H^2\alpha') in de Sitter spacetime; m^2_{\mbox{AdS}}\approx 4H^2n^2 (large nN0n\in N_0) and N_{\mbox{AdS}}=\infty in anti de Sitter spacetime. The level spacing grows with nn in AdS spacetime, while is approximately constant (although larger than in Minkowski spacetime) in dS spacetime. The massive states in dS spacetime decay through tunnel effect and the semi-classical decay probability is computed. The semi-classical quantization of {\it exact} (circular) strings and the canonical quantization of generic string perturbations around the string center of mass strongly agree.Comment: Latex, 26 pages + 2 tables and 5 figures that can be obtained from the authors on request. DEMIRM-Obs de Paris-9404

    Mass Spectrum of Strings in Anti de Sitter Spacetime

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    We perform string quantization in anti de Sitter (AdS) spacetime. The string motion is stable, oscillatory in time with real frequencies ωn=n2+m2α2H2\omega_n= \sqrt{n^2+m^2\alpha'^2H^2} and the string size and energy are bounded. The string fluctuations around the center of mass are well behaved. We find the mass formula which is also well behaved in all regimes. There is an {\it infinite} number of states with arbitrarily high mass in AdS (in de Sitter (dS) there is a {\it finite} number of states only). The critical dimension at which the graviton appears is D=25,D=25, as in de Sitter space. A cosmological constant Λ0\Lambda\neq 0 (whatever its sign) introduces a {\it fine structure} effect (splitting of levels) in the mass spectrum at all states beyond the graviton. The high mass spectrum changes drastically with respect to flat Minkowski spacetime. For ΛΛN2,\Lambda\sim \mid\Lambda\mid N^2, {\it independent} of α,\alpha', and the level spacing {\it grows} with the eigenvalue of the number operator, N.N. The density of states ρ(m)\rho(m) grows like \mbox{Exp}[(m/\sqrt{\mid\Lambda\mid}\;)^{1/2}] (instead of \rho(m)\sim\mbox{Exp}[m\sqrt{\alpha'}] as in Minkowski space), thus {\it discarding} the existence of a critical string temperature. For the sake of completeness, we also study the quantum strings in the black string background, where strings behave, in many respects, as in the ordinary black hole backgrounds. The mass spectrum is equal to the mass spectrum in flat Minkowski space.Comment: 31 pages, Latex, DEMIRM-Paris-9404

    Yang--Baxter symmetry in integrable models: new light from the Bethe Ansatz solution

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    We show how any integrable 2D QFT enjoys the existence of infinitely many non--abelian {\it conserved} charges satisfying a Yang--Baxter symmetry algebra. These charges are generated by quantum monodromy operators and provide a representation of qq-deformed affine Lie algebras. We review and generalize the work of de Vega, Eichenherr and Maillet on the bootstrap construction of the quantum monodromy operators to the sine--Gordon (or massive Thirring) model, where such operators do not possess a classical analogue. Within the light--cone approach to the mT model, we explicitly compute the eigenvalues of the six--vertex alternating transfer matrix \tau(\l) on a generic physical state, through algebraic Bethe ansatz. In the thermodynamic limit \tau(\l) turns out to be a two--valued periodic function. One determination generates the local abelian charges, including energy and momentum, while the other yields the abelian subalgebra of the (non--local) YB algebra. In particular, the bootstrap results coincide with the ratio between the two determinations of the lattice transfer matrix.Comment: 30 page

    Exact solution of the SUq(n)SU_{q}(n) invariant quantum spin chains

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    The Nested Bethe Ansatz is generalized to open boundary conditions. This is used to find the exact eigenvectors and eigenvalues of the An1A_{n-1} vertex model with fixed open boundary conditions and the corresponding SUq(n)SU_{q}(n) invariant hamiltonian. The Bethe Ansatz equations obtained are solved in the thermodynamic limit giving the vertex model free energy and the hamiltonian ground state energy including the corresponding boundary contributions.Comment: 29 page

    Renormalization Group Flow and Fragmentation in the Self-Gravitating Thermal Gas

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    The self-gravitating thermal gas (non-relativistic particles of mass m at temperature T) is exactly equivalent to a field theory with a single scalar field phi(x) and exponential self-interaction. We build up perturbation theory around a space dependent stationary point phi_0(r) in a finite size domain delta \leq r \leq R ,(delta << R), which is relevant for astrophysical applica- tions (interstellar medium,galaxy distributions).We compute the correlations of the gravitational potential (phi) and of the density and find that they scale; the latter scales as 1/r^2. A rich structure emerges in the two-point correl- tors from the phi fluctuations around phi_0(r). The n-point correlators are explicitly computed to the one-loop level.The relevant effective coupling turns out to be lambda=4 pi G m^2 / (T R). The renormalization group equations (RGE) for the n-point correlator are derived and the RG flow for the effective coupling lambda(tau) [tau = ln(R/delta), explicitly obtained.A novel dependence on tau emerges here.lambda(tau) vanishes each time tau approaches discrete values tau=tau_n = 2 pi n/sqrt7-0, n=0,1,2, ...Such RG infrared stable behavior [lambda(tau) decreasing with increasing tau] is here connected with low density self-similar fractal structures fitting one into another.For scales smaller than the points tau_n, ultraviolet unstable behaviour appears which we connect to Jeans' unstable behaviour, growing density and fragmentation. Remarkably, we get a hierarchy of scales and Jeans lengths following the geometric progression R_n=R_0 e^{2 pi n /sqrt7} = R_0 [10.749087...]^n . A hierarchy of this type is expected for non-spherical geometries,with a rate different from e^{2 n/sqrt7}.Comment: LaTex, 31 pages, 11 .ps figure

    The excitation of a charged string passing through a shock wave in a charged Aichelburg-Sexl spacetime

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    We investigate how much a first-quantized charged bosonic test string gets excited after crossing a shock wave generated by a charged particle with mass M~\tilde{M} and charge Q~\tilde{Q}. On the basis of Kaluza-Klein theory, we pay attention to a closed string model where charge is given by a momentum along a compactified extra-dimension. The shock wave is given by a charged Aichelburg-Sexl (CAS) spacetime where Q~=0\tilde{Q}=0 corresponds to the ordinary Aichelburg-Sexl one. We first show that the CAS spacetime is a solution to the equations of motion for the metric, the gauge field, and the axion field in the low-energy limit. Secondly, we compute the mass expectation value of the charged test string after passing through the shock wave in the CAS spacetime. In the case of small Q~\tilde{Q}, gravitational and Coulomb forces are canceled out each other and hence the excitation of the string remains very small. This is independent of the particle mass M~\tilde{M} or the strength of the shock wave. In the case of large Q~\tilde{Q}, however, every charged string gets highly excited by quantum fluctuation in the extra-dimension caused by both the gauge and the axion fields. This is quite different from classical "molecule", which consists of two electrically charged particles connected by a classical spring.Comment: Latex, 20 pages, no figures, accepted for Nucl. Phys.

    Exact String Solutions in 2+1-Dimensional De Sitter Spacetime

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    Exact and explicit string solutions in de Sitter spacetime are found. (Here, the string equations reduce to a sinh-Gordon model). A new feature without flat spacetime analogy appears: starting with a single world-sheet, several (here two) strings emerge. One string is stable and the other (unstable) grows as the universe grows. Their invariant size and energy either grow as the expansion factor or tend to constant. Moreover, strings can expand (contract) for large (small) universe radius with a different rate than the universe.Comment: 11 pages, Phyzzx macropackage used, PAR-LPTHE 92/32. Revised version with a new understanding of the previous result
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