Irina Arefeva Steklov Mathematical Institute, RAS String Field Theory: from High Energy Physics to Cosmology
Quantization Classical Mechanics Classical Field Quantum Mechanics Second quantization Infinite # of the same particles n classical Fields Question: what happens with infinite # of types of classical fields? ….. How to arrange all these fields ? Looks like а rope, or a string Quantum Field 3 bodies problem, L.Faddeev if s<2 New problems: We have but do not have H, wave operators, but we have renormalized S-matrix Quantization
Experiments gave the Regge asymptotic behavior of the scattering amplitude of hadrons (1957) Veneziano amplitude Regge poles It was proposed by Numbu, Gato, Nielsen, Susskind (1970) to use string to describe infinite number of Regge states
First quantized approach, Polyakov's approach SFT
M. Kaku and K. Kikkawa, Phys. Rev. D 10 (1974) 1110,1823; E. Cremmer and J.L. Gervais, Nucl. Phys. B 76 (1974)209;B 90 (1974) 410. Action=functional of such that it reproduces the Veniziano amplitude Specific feature -- the string interaction by gluing strings by ends Green-Schwarz Light-Cone SSFT cancelation of anomalies for SO(32) heterotic string Light-Cone SFT
Wanted(1985): Gauge Invariant Principle behind String Field Interaction Many attempts: Various gauge covariant free string actions were given in: E. Witten, (1985), J.-L. Gervais (1985) L. Baulieu and S. Ouvry, Phys. Lett. B 171 (1986) 57. M. Kaku, Phys. Lett. B 162 (1985) 97; D. Friedan, Chicago University preprint EF (1985); T. Banks and M.E. Peskin, SLAC preprint 3740 (1985); A. Neveu, H. Nicolai and P.C. West, Phys. Lett. B 167 (1986) 307; W. Siegel and B. Zwiebach, Berkeley preprint UCBPTH (1985); A.Neveu and P.West have given the gauge-invariant interaction of a bosonic open string at the lowest levels, Phys. Lett. B 168 (1986) 192.
Recent developments began with Siegel’s formulation of a covariantly gauge-fixed bosonic string based on Kato and Ogawa’s BRST formalism of a first quantized string W. Siegel, Phys. Lett. B 151 (1985) 391,396 Kato and K. Ogawa, Nucl. Phys. B 212 (1983) 443 Hata, Itoh, Kugo, Kunitomo and Ogawa have constructed the gauge-fixed BRST invariant field theory for the interacting bosonic string based on the string-ends interaction. Problem with an extra parameter (string length), Phys. Lett. B 172 (1986) 186 The gauge-invariant formulation of the classical interacting bosonic open string related with HIKKO BRST invariant SFT was given in I.A., Volovich,TMF 67(1986) 320,460 = Phys.Lett.182 (1986) 159
Witten’s SFT, 1986 No extra-parameters, the gluing is different, now this is called Witten's gluing Gauge invariant Reproduces the Veneziano amplitudes
SuperSFT, 1990 Picture a=0 AMZ, 1990 I.A., Medvedev, Zubarev PTY and AMZ, 1990, Preitschopf, Thorn, Yost Non-polynomial action, Berkovits (1995)
SFT E.O.M This equation has the form similar to the Chern-Simons
Chern-Simons M is 3-manifold, principle G-bundle over M and A is one -form with values in G, action E.O.M.
Th. Flat connections of principal G-bundles over M entirely determined by holonomies around noncontractive cycles on the base M or Flat connections of principal G-bundles over M are in one to one correspondence with equivalence classes of homomorphism from the fundamental group of M to G up to conjugation, i.e.
Abelian case, QA=0, or dA=0 Poincare Lemma. On the contractive manifold, all closed forms are exact, i.e. Closed forms represent cohomology classes (de Rham cohomology). All solutions of dA=0 are given by the de Rham theory.
Tachyonic (Higgs-Like) Solutions to SFT This activity was initiated by the Sen conjectures Bosonic string has tachyon. There is tachyon in the Higgs model as well. In the Higgs model we start from finding the non-zero expectation value for the Higgs field Sen's 1-st conjecture:
Numerical Solutions to SFT( ) Bosonic case. Record calculations by Moeller, Rastelli, Zwiebach Fermionic case, B(+,-) theory; Berkovits,Sen, Zwiebach (2000) ABKM = IA, Belov,Koshelev, Medvedev (2001)
2005-now M.Schnabl and the following Schnabl; Okawa; Erler; I.A., Gorbachev, Medvedev, Fuchs,Kroyter; Takahashi Kishimoto and T. Takahashi; Erler;Ellwood Schnabl; Kiermaier, Zwiebach,….. Hashimoto, Itzhaki; Gaiotto, Rastelli, Sen, Zwiebach; Kawano, Kishimoto,Takahashi
Main intrigue T.Erler; R.Gorbachev; D.Grigoriev, P.Khromov; Ellwood
String in non-trivial background We do not have SFT in an arbitrary non-trivial background we do have in pp-waves, due to R.Metsaev study of the string spectrum in pp-waves we try to guess how can look level-truncated SFT in non-trivial background. (minimal interaction)
Rolling tachyon solutions in level truncated theories Rolling solutions in DBI theories,.... Rolling solutions in p-adic theories p=2 no-go theorems by Moeller and Zwiebach p=3 existence theorems by Vladimirov,Ya.Volovich Motivations I.A.,Joukovskaya, Koshelev;Ya.Volovich
Rolling tachyon solutions in level truncated theories in FRW metric Sen in 2003 proposed to use the bosonic string tachyon to describe pressure less Dark Matter. Tachyon related with nonBPS brane has been considers also as a model of the dynamical Dark Energy (IA,2005) Talks by L.Joukovskaya, A.Koshelev, S.Vernov
No Conclusion! M Ф