August 6, 2007 基研研究会@近畿大学 1 Comments on Solutions for Nonsingular Currents in Open String Field Theories Isao Kishimoto I. K., Y. Michishita, arXiv:0706.0409.

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August 6, 2007 基研研究会@近畿大学 1 Comments on Solutions for Nonsingular Currents in Open String Field Theories Isao Kishimoto I. K., Y. Michishita, arXiv: [hep-th], to be published in PTP

2 Introduction Witten’s bosonic open string field theory (d=26): There were various attempts to prove Sen’s conjecture since around 1999 using the above. Numerically, it has been checked with “level truncation approximation.” [ c.f. … Gaiotto-Ratelli “Experimental string field theory”(2002) ] Analytically, some solutions have been constructed. Here, we generalize “Schnabl’s analytical solutions” (2005, 2007) which include “tachyon vacuum solution” in Sen’s conjecture and “marginal solutions.”

3 In Berkovits’ WZW-type superstring field theory (d=10) the action in the NS sector is given by There were some attempts to solve the equation of motion. Numerically, tachyon condensation was examined using level truncation. [Berkovits(-Sen-Zwiebach)(2000),…] Analytically, some solutions have been constructed. Recently [April (2007)], Erler / Okawa constructed some solutions, which are generalization of Schnabl / Kiermaier- Okawa-Rastelli-Zwiebach’s marginal solution (2007) in bosonic SFT. We consider generalization of their solutions and examine gauge transformations.

4 Main claim Then, gives a solution to the EOM: Suppose that is BRST invariant and nilpotent : where In the case : wedge state, we have : Schnabl / Kiermaier-Okawa-Rastelli-Zwiebach’s marginal solution for nonsingular current is reproduced. : Schnabl’s tachyon vacuum solution is reproduced. bosonic SFT

5 Suppose that satisfies following conditions: Then, give solutions to the EOM: where In the case : wedge state, we find : Erler / Okawa’s marginal solutions for nonsingular supercurrents are reproduced. super SFT

6 Witten’s bosonic open string field theory BRST operator: String field: Action: Witten star product: Equation of motion: Gauge transformation:

7 Preliminary “sliver frame”: ( :UHP) For a primary field of dim=h, In particular, we often use and

8 For the wedge state:, we have. Using we have a * product formula: star product

9 Associated with the wedge states, we have such as. With BRST invariant and nilpotent : we have a solution to the equation of motion [Ellwood-Schnabl]

10 ∵ 0 Note 1. is also BRST invariant and nilpotent. can naturally include 1-parameter.

11 We can regard as a map from a solution to another solution: Note 2. Composition of maps forms a commutative monoid: In general, for we have

12 Example of BRST invariant and nilpotent where is “nonsingular” matter primary of dimension 1: marginal solution tachyon solution In particular, Due to the nonsingular condition for the current, we find nilpotency :

13 From a BRST invariant, nilpotent which satisfies, we can generate a solution Marginal solution

14 Tachyon solution From a BRST invariant, nilpotent which satisfies, we can generate a solution: Each term is computed as Then, we can re-sum the above as Here, expansion parameter is redefined as

15 The solution can be rewritten as whereare BPZ odd and derivations w.r.t., and is the Schnabl’s solution for tachyon condensation at By regularizing it as the new BRST operator around the solution satisfies which implies vanishing cohomology and This result is -independent.

16 Note perturbative vacuum Non-perturbative vacuum In fact, the solution can be rewritten as pure gauge form by evaluating the infinite summation formally We can evaluate the action as

17 Berkovits’ WZW-type super SFT The action for the NS sector is String field Φ : ghost number 0, picture number 0, Grassmann even, expressed by matter and ghosts : Equation of motion: Gauge transformation: Using the wedge states as in bosonic SFT, we have

18 map solutions to other solutions because Corresponding to the wedge states, we have constructed : such as are defined in the same way as. Then, we find that

19 If satisfies Example of using nonsingular matter supercurrent: where we suppose More explicitly, on the flat background, we can take is a solution: are also solutions.

20 Using path-ordering, we found for bosonic SFT. (In the case, this form coincides with Ellwood’s one.) Based on the identity state, BRST inv. and nilpotent Without the identity state, including Schnabl’s marginal and scalar solutions In this sense, Gauge transformations

21 Similarly, in super SFT, we have found

22 Based on the identity state, Without the identity state, including Erler / Okawa’s marginal solutions In this sense, Note: The above gauge equivalence relations seem to be formal and might not be well-defined. The gauge parameter string fields might become “singular,” as well as Schnabl or Takahashi-Tanimoto’s tachyon solution.

23 In [Takahashi-Tanimoto, Kishimoto-Takahashi] some solutions based on the identity state for general (super)current were already constructed. At least formally, and with give solutions which are not based on the identity state! Zeze’s talk! Future problems How about general (super)currents? Namely, C.f. [KORZ], [Fuchs-Kroyter-Potting], [Fuchs-Kroyter], [Kiermaier-Okawa] So far, various computations seem to be rather formal. Definition of the “regularity” of string fields? It is very important in order to investigate “regular solutions,” gauge transformations among them and cohomology around them.

24 弦の場の理論 07 理研シンポジウム 弦の場の理論 月 6 日(土), 7 日(日) 埼玉県和光市理化学研究所 大河内記念ホール