- •1. Introduction
- •2. Supersymmetry essentials
- •2.1. A new spacetime symmetry
- •2.2. Supersymmetry and the weak scale
- •2.3. The neutral supersymmetric spectrum
- •2.4. R-Parity
- •2.5. Supersymmetry breaking and dark energy
- •2.6. Minimal supergravity
- •2.7. Summary
- •3. Neutralino cosmology
- •3.1. Freeze out and wimPs
- •3.2. Thermal relic density
- •3.2.1. Bulk region
- •1. Introduction
- •2. Construction of trial functions
- •2.1. A new formulation of perturbative expansion
- •2.2. Trial function for the quantum double-well potential
- •3. Hierarchy theorem and its generalization
- •4. Asymmetric quartic double-well problem
- •4.1. Construction of the first trial function
- •4.2. Construction of the second trial function
- •4.3. Symmetric vs asymmetric potential
- •5. The n-dimensional problem
- •1. Introduction
- •2. The star product formalism
- •3. Geometric algebra and the Clifford star product
- •4. Geometric algebra and classical mechanics
- •5. Non-relativistic quantum mechanics
- •6. Spacetime algebra and Dirac theory
- •7. Conclusions
- •1. Introduction
- •1.1. Historical overview
- •1.2. Aims of this article
- •2. Random curves and lattice models
- •2.1. The Ising and percolation models
- •2.1.1. Exploration process
- •2.2. O (n) model
- •2.3. Potts model
- •2.4. Coulomb gas methods
- •2.4.1. Winding angle distribution
- •2.4.2. N-leg exponent
- •3.1. The postulates of sle
- •3.2. Loewner’s equation
- •3.3. Schramm–Loewner evolution
- •3.4. Simple properties of sle
- •3.4.1. Phases of sle
- •3.4.2. Sle duality
- •3.5. Special values of κ
- •3.5.1. Locality
- •3.5.2. Restriction
- •3.6. Radial sle and the winding angle
- •3.6.1. Identification with lattice models
- •4. Calculating with sle
- •4.1. Schramm’s formula
- •4.2. Crossing probability
- •4.3. Critical exponents from sle
- •4.3.1. The fractal dimension of sle
- •4.3.2. Crossing exponent
- •4.3.3. The one-arm exponent
- •5. Relation to conformal field theory
- •5.1. Basics of cft
- •5.2. Radial quantisation
- •5.3. Curves and states
- •5.4. Differential equations
- •5.4.1. Calogero–Sutherland model
- •6. Related ideas
- •6.1. Multiple slEs
- •6.2. Other variants of sle
- •6.3. Other growth models
- •1. Introduction
- •1.1. Acoustic force field
- •1.2. Primary axial acoustic force
- •1.3. Primary and secondary acoustic force
- •2. Application of Newton’s second law
- •3. Mathematical model
- •3.1. Preliminary analysis
- •4. Equation for particle trajectories
- •5. Concentration equation
- •6. Experimental procedure and results
- •6.1. SiC particle trajectories in an acoustic field
- •7. Comparison between experimental results and mathematical model
- •8. Summary and conclusions
7. Conclusions
There are two formal and conceptual barriers that separate quantum theory from classical theory. The first barrier is that classical theory is described on the phase space while quantum theory is described on the Hilbert space. This conceptual barrier is overcome by the program of deformation quantization that describes quantum theory on the phase space. The second barrier is that one uses in classical mechanics the Gibbs–Heaviside formalism, which cannot take spin into account. In quantum theory where spin is a physical observable it is described in the non-relativistic case by the “Feynman trick”, which substitutes by and in the relativistic case it is introduced by writing pμγμ. Both notations clearly indicate that the σi and the γμ are basis vectors, but this is obscured by representing them by matrices. The work of Hestenes has clarified this point by formulating classical and quantum theory in the same formalism of geometric algebra. The surprising thing is now that also this second barrier can be overcome in terms of the star product formalism, so that classical and quantum theory can be unified on a formal level. Both can be described by the formalism of deformed superanalysis, where classical mechanics is a “half-deformed” formalism, that means the deformation only takes place in the Grassmann sector of superanalysis, while quantum mechanics leads to a “totally deformed” formalism, where also the product of the scalar coefficients are deformed. This shows on a formal level that quantum theory is more fundamental than classical theory.
The star product formalism has also advantages in the context of geometric calculus, because it gives an explicit expression for the geometric product. Geometric algebra, in the way Hestenes constructed it, is formulated with respect to the scalar and the wedge product, which represent the lowest and the highest order terms of the geometric product. All other terms of the geometric product are then formulated with the help of these two products. This approach is very practical, especially if one has only terms that are at most bivectors. But in the general case the highest and the lowest terms of an expansion have on a formal level the same status as all other terms. The star product gives now all these terms of different grade as terms of an expansion, that can be calculated in a straightforward fashion.
SLE for theoretical physicists
John Cardy, Rudolf Peierls Centre for Theoretical Physics, 1 Keble Road, Oxford OX1 3NP, UK All Souls College, Oxford, UK Received 14 March 2005; accepted 4 April 2005. Available online 12 May 2005.
Abstract
This article provides an introduction to Schramm (stochastic)–Loewner evolution (SLE) and to its connection with conformal field theory, from the point of view of its application to two-dimensional critical behaviour. The emphasis is on the conceptual ideas rather than rigorous proofs.
Article Outline
1. Introduction
1.1. Historical overview
1.2. Aims of this article
2. Random curves and lattice models
2.1. The Ising and percolation models
2.1.1. Exploration process
2.2. O (n) model
2.3. Potts model
2.4. Coulomb gas methods
2.4.1. Winding angle distribution
2.4.2. N-leg exponent
3. SLE
3.1. The postulates of SLE
3.2. Loewner’s equation
3.3. Schramm–Loewner evolution
3.4. Simple properties of SLE
3.4.1. Phases of SLE
3.4.2. SLE duality
3.5. Special values of κ
3.5.1. Locality
3.5.2. Restriction
3.6. Radial SLE and the winding angle
3.6.1. Identification with lattice models
4. Calculating with SLE
4.1. Schramm’s formula
4.2. Crossing probability
4.3. Critical exponents from SLE
4.3.1. The fractal dimension of SLE
4.3.2. Crossing exponent
4.3.3. The one-arm exponent
5. Relation to conformal field theory
5.1. Basics of CFT
5.2. Radial quantisation
5.3. Curves and states
5.4. Differential equations
5.4.1. Calogero–Sutherland model
6. Related ideas
6.1. Multiple SLEs
6.2. Other variants of SLE
6.3. Other growth models
Acknowledgements
References