Hot band

From formulasearchengine
Revision as of 16:07, 7 December 2012 by en>Petergans (not an orphan)
Jump to navigation Jump to search

In mathematical physics, spacetime algebra (STA) is a name for the Clifford algebra C1,3(R), or equivalently the geometric algebra G4 = G(M4), which can be particularly closely associated with the geometry of special relativity and relativistic spacetime.

It is a vector space allowing not just vectors, but also bivectors (directed quantities associated with particular planes, such as areas, or rotations) or multivectors (quantities associated with particular hyper-volumes) to be combined, as well as rotated, reflected, or Lorentz boosted. It is also the natural parent algebra of spinors in special relativity. These properties allow many of the most important equations in physics to be expressed in particularly simple forms, and can be very helpful towards a more geometric understanding of their meanings.

Structure

The spacetime algebra is built up from combinations of one time-like basis vector γ0 and three orthogonal space-like vectors, {γ1,γ2,γ3}, under the multiplication rule

γμγν+γνγμ=2ημν

where ημν is the Minkowski metric with signature (+ − − −)

Thus γ02=+1, γ12=γ22=γ32=1, otherwise γμγν=γνγμ.

The basis vectors γk share these properties with the Dirac matrices, but no explicit matrix representation is utilized in STA.

This generates a basis of one scalar {1}, four vectors {γ0,γ1,γ2,γ3}, six bivectors {γ0γ1,γ0γ2,γ0γ3,γ1γ2,γ2γ3,γ3γ1}, four pseudovectors {iγ0,iγ1,iγ2,iγ3} and one pseudoscalar {i}, where i=γ0γ1γ2γ3.

Reciprocal frame

Associated with the orthogonal basis {γμ} is the reciprocal basis {γμ=1γμ} for all μ =0,...,3, satisfying the relation

γμγν=δμν.

These reciprocal frame vectors differ only by a sign, with γ0=γ0, and γk=γk for k =1,...,3.

A vector may be represented in either upper or lower index coordinates a=aμγμ=aμγμ with summation over μ =0,...,3, according to the Einstein notation, where the coordinates may be extracted by taking dot products with the basis vectors or their reciprocals.

aγν=aνaγν=aν

Spacetime gradient

The spacetime gradient, like the gradient in a Euclidean space, is defined such that the directional derivative relationship is satisfied:

aF(x)=limτ0F(x+aτ)F(x)τ

This requires the definition of the gradient to be

=γμxμ=γμμ.

Written out explicitly with x=ctγ0+xkγk, these partials are

0=1ct,k=xk

Spacetime split

Spacetime split – examples:
xγ0=x0+x
pγ0=E+p[1]
vγ0=γ(1+v)[1]
with γ the Lorentz factor
γ0=t[2]

In spacetime algebra, a spacetime split is a projection from 4D space into (3+1)D space with a chosen reference frame by means of the following two operations:

  • a collapse of the chosen time axis, yielding a 3D space spanned by bivectors, and
  • a projection of the 4D space onto the chosen time axis, yielding a 1D space of scalars.[3]

This is achieved by pre or post multiplication by the timelike basis vector γ0, which serves to split a four vector into a scalar timelike and a bivector spacelike component. With x=xμγμ we have

xγ0=x0+xkγkγ0γ0x=x0xkγkγ0

As these bivectors γkγ0 square to unity, they serve as a spatial basis. Utilizing the Pauli matrix notation, these are written σk=γkγ0. Spatial vectors in STA are denoted in boldface; then with x=xkσk the γ0-spacetime split xγ0 and its reverse γ0x are:

xγ0=x0+xkσk=x0+xγ0x=x0xkσk=x0x

Multivector division

The spacetime algebra is not a division algebra, because it contains idempotent elements 12(1±γ0γi) and zero divisors: (1+γ0γi)(1γ0γi)=0. These can be interpreted as projectors onto the light-cone and orthogonality relations for such projectors, respectively. But in general it is possible to divide one multivector quantity by another, and make sense of the result: so, for example, a directed area divided by a vector in the same plane gives another vector, orthogonal to the first.

Spacetime algebra description of non-relativistic physics

Non-relativistic quantum mechanics

Spacetime algebra allows to describe the Pauli particle in terms of a real theory in place of a matrix theory. The matrix theory description of the Pauli particle is:[4]

itΨ=HSΨe2mcσ^BΨ

where i is the imaginary unit with no geometric interpretation, σ^i are the Pauli matrices (with the ‘hat’ notation indicating that σ^ is a matrix operator and not an element in the geometric algebra), and HS is the Schrödinger Hamiltonian. In the spacetime algebra the Pauli particle is described by the real Pauli–Schrödinger equation:[4]

tψiσ3=HSψe2mcBψσ3

where now i is the unit pseudoscalar i=σ1σ2σ3, and ψ and σ3 are elements of the geometric algebra, with ψ an even multi-vector; HS is again the Schrödinger Hamiltonian. Hestenes refers to this as the real Pauli–Schrödinger theory to emphasize that this theory reduces to the Schrödinger theory if the term that includes the magnetic field is dropped.

Spacetime algebra description of relativistic physics

Relativistic quantum mechanics

The relativistic quantum wavefunction is sometimes expressed as a spinor field, i.e.Potter or Ceramic Artist Truman Bedell from Rexton, has interests which include ceramics, best property developers in singapore developers in singapore and scrabble. Was especially enthused after visiting Alejandro de Humboldt National Park.

ψ=e12(μ+βi+ϕ)

where ϕ is a bivector, and[5][6]

ψ=R(ρeiβ)12

where according to its derivation by David Hestenes, ψ=ψ(x) is an even multivector-valued function on spacetime, R=R(x) is a unimodular spinor (or “rotor”[7]), and ρ=ρ(x) and β=β(x) are scalar-valued functions.[5]

This equation is interpreted as connecting spin with the imaginary pseudoscalar.Potter or Ceramic Artist Truman Bedell from Rexton, has interests which include ceramics, best property developers in singapore developers in singapore and scrabble. Was especially enthused after visiting Alejandro de Humboldt National Park. R is viewed as a Lorentz rotation which a frame of vectors γμinto another frame of vectors eμ by the operation eμ=RγμR~,[7] where the tilde symbol indicates the reverse (the reverse is often also denoted by the dagger symbol, see also Rotations in geometric algebra).

This has been extended to provide a framework for locally varying vector- and scalar-valued observables and support for the Zitterbewegung interpretation of quantum mechanics originally proposed by Schrödinger.

Hestenes has compared his expression for ψ with Feynman's expression for it in the path integral formulation:

ψ=eiΦλ/

where Φλ is the classical action along the λ-path.[5]

Spacetime algebra allows to describe the Dirac particle in terms of a real theory in place of a matrix theory. The matrix theory description of the Dirac particle is:[8]

γ^μ(jμeAμ)|ψ=m|ψ

where γ^ are the Dirac matrices. In the spacetime algebra the Dirac particle is described by the equation:[8]

ψiσ3Aψ=mψγ0

Here, ψ and σ3 are elements of the geometric algebra, and =γμμ is the spacetime vector derivative.

A new formulation of General Relativity

Lasenby, Doran, and Gull of Cambridge University have proposed a new formulation of gravity, termed gauge theory gravity (GTG), wherein spacetime algebra is used to induce curvature on Minkowski space while admitting a gauge symmetry under "arbitrary smooth remapping of events onto spacetime" (Lasenby, et al.); a nontrivial proof then leads to the geodesic equation,

ddτR=12(Ωω)R

and the covariant derivative

Dτ=τ+12ω,

where ω is the connexion associated with the gravitational potential, and Ω is an external interaction such as an electromagnetic field.

The theory shows some promise for the treatment of black holes, as its form of the Schwarzschild solution does not break down at singularities; most of the results of general relativity have been mathematically reproduced, and the relativistic formulation of classical electrodynamics has been extended to quantum mechanics and the Dirac equation.

See also

References

  • A. Lasenby, C. Doran, & S. Gull, “Gravity, gauge theories and geometric algebra,” Phil. Trans. R. Lond. A 356: 487–582 (1998).
  • Chris Doran and Anthony Lasenby (2003). Geometric Algebra for Physicists, Cambridge Univ. Press. ISBN 0-521-48022-1
  • David Hestenes (1966). Space-Time Algebra, Gordon & Breach.
  • David Hestenes and Sobczyk, G. (1984). Clifford Algebra to Geometric Calculus, Springer Verlag ISBN 90-277-1673-0
  • David Hestenes (1973). "Local observables in the Dirac theory", J. Math. Phys. Vol. 14, No. 7.
  • David Hestenes (1967). "Real Spinor Fields", Journal of Mathematical Physics, 8 No. 4, (1967), 798–808.

43 year old Petroleum Engineer Harry from Deep River, usually spends time with hobbies and interests like renting movies, property developers in singapore new condominium and vehicle racing. Constantly enjoys going to destinations like Camino Real de Tierra Adentro.

External links

  1. 1.0 1.1 A. N. Lasenby, C. J. L. Doran: Geometric algebra, Dirac wavefunctions and black holes. In: Peter Gabriel Bergmann, Venzo De Sabbata (eds.): Advances in the interplay between quantum and gravity physics, Springer, 2002, ISBN 978-1-4020-0593-0, pp. 256-283, p. 257
  2. A. N. Lasenby, C. J. L. Doran: Geometric algebra, Dirac wavefunctions and black holes. In: Peter Gabriel Bergmann, Venzo De Sabbata (eds.): Advances in the interplay between quantum and gravity physics, Springer, 2002, ISBN 978-1-4020-0593-0, pp. 256-283, p. 259
  3. John W. Arthur: Understanding Geometric Algebra for Electromagnetic Theory (IEEE Press Series on Electromagnetic Wave Theory), Wiley, 2011, ISBN 978-0-470-94163-8, p. 180
  4. 4.0 4.1 See eqs. (75) and (81) in: D. Hestenes: Oersted Medal Lecture
  5. 5.0 5.1 5.2 See eq. (3.1) and similarly eq. (4.1), and subsequent pages, in: D. Hestenes: On decoupling probability from kinematics in quantum mechanics, In: P.F. Fougère (ed.): Maximum Entropy and Bayesian Methods, Kluwer Academic Publishers, 1990, pp. 161–183 (PDF)
  6. See also eq. (5.13) of S. Gull, A. Lasenby, C. Doran: Imaginary numbers are not real – the geometric algebra of spacetime, 1993
  7. 7.0 7.1 See eq. (205) in: D. Hestenes: Spacetime physics with geometric algebra, American Journal of Physics, vol. 71, no. 6, June 2003, pp. 691 ff., DOI 10.1119/1.1571836 (abstract, full text)
  8. 8.0 8.1 See eqs. (3.43) and (3.44) in: Chris Doran, Anthony Lasenby, Stephen Gull, Shyamal Somaroo, Anthony Challinor: Spacetime algebra and electron physics, in: Peter W. Hawkes (ed.): Advances in Imaging and Electron Physics, Vol. 95, Academic Press, 1996, ISBN 0-12-014737-8, p. 272–386, p. 292