The scattering amplitude of stringy hadrons I: Strings with opposite charges on their endpoints

In this note we describe hadrons: mesons and baryons as strings with electric charges on their endpoints. We consider here only the neutral system with opposite charges coupled to an external constant electric and magnetic fields. We derive certain classical solutions including rotating folded open strings. We write down the mode expansion and canonically quantize the system. The OPEs associated with such strings are determined. We re-derive the non-commutativity of the zero modes and the fact that the charges modify the spacetime metric. We show that the quantum worldsheet energy momentum tensor on the boundary is affected by the endpoint charges and differs from the corresponding Noether current. We determine the generalization of the Veneziano scattering amplitude for such strings in the critical dimension. Phenomenological implications are addressed and in particular we show that the external magnetic field can be tuned so that the amplitude vanishes for particular kinematic setups. We discuss the generalization of such strings to non-critical four dimensional spacetime. In particular we renormalize the divergence of the Polchinski-Strominger effective action associated with the rotating folded string.


Contents 1 Introduction
Open strings with electric charges on their ends have been investigated intensively starting from the early days of string theory and until these days. Many papers have been written about such open strings interacting with a constant electromagnetic background fields including several landmark papers [1][2][3][4]. Reviews of the topic containing more references include [5,6].
What is then the reason to revisit this well studied system? In the present paper we address this system from a different perspective. The basic idea here is that hadrons, both mesons and baryons, have the structure of an open bosonic string with particles on its ends. These particles are massive, charged and carry spin. Thus, the behavior of such strings in a constant electromagnetic field relates to that of, for instance, nucleons or π mesons, propagating in such a background. The stringy nature of hadrons has been described in recent years in the context of the HISH (holography inspired stringy hadron) model [7]. Unlike in the usual string theory, in which the modes of open strings correspond to fields of the standard model or other QFTs, here we associate them with the states of hadrons. The difference between these two points of view is manifested, for instance, in the fact that in nature the hadronic strings have massive endpoint particles and an intercept a ≤ 0 1 and hence the spin zero mode does not correspond to a tachyon but rather to a scalar meson of positive mass, and the spin one does not correspond to a massless gauge field but to a massive vector hadron.
The charges at the endpoints of strings interact with an external electromagnetic background field as well as interacting electromagnetically one with the other. In fact the latter interaction always takes place in a real world setting, but in the case where the external field is stronger one can approximate the behavior by ignoring the fields induced by the charges. Formally, this is done by not including the kinetic F µν F µν term for the EM field in the action.
It turns out that there is a substantial difference between the case of the interaction with an external EM background field of a string with opposite charges on its ends, such that the string as a whole is neutral, q 1 + q 2 = 0, and the case where the charges are general, q 1 = −q 2 , and the total charge is non-zero. In the present paper we analyze the neutral string case and the charged string will be discussed in a sequel paper [9]. Strings with charged endpoints 1 Here we mean the intercept of modified Regge trajectories expressed in terms of the mass squared as a function of the orbital rather than the total angular momentum. For a discussion of this property see section 3.3 in [8].
with mutual interaction but with no background electromagnetic field will be addressed in an additional publication.
The endpoint charges affect the behavior of the strings in several different aspects: (i) the solutions of the equations of motion, (ii) the classical Regge-like trajectories, (iii) the quantum spectrum and the intercept, (iv) the operator product expansions, (v) the form factors, and (vi) the string scattering amplitudes. In this paper we analyze each of these aspects for strings with opposite charges.
Let us briefly summarize the main results of this paper.
• In a constant magnetic field the classical solutions that take the form of a rotating open string with n folding points, starting from n = 1. There is no rotating solution without a fold. These strings admit classical linear Regge trajectories with a tension which is nT , where T is the basic string tension. The folding points rotate with the speed of light while the speed of the endpoint charges is β = | cos φ| where φ = arctan(qB).
• In previous investigations of this type of strings it has been realized [2] that the effect of the interaction with the external EM field is a modification of the spacetime metric, where q is the charge and F µν is the background EM field.
• It was further understood that the zero modes of the string, the center of mass coordinates, do not commute [x µ , x ν ] = iθ µν = i q T F µ ρ g ρν (1.2) so that the string coupled to an external field gives a realization of a non-commutative geometry [4].
• The modified spacetime metric enters Veneziano's scattering amplitude via Mandelstam variables that have to be computed using the modified metric. In addition each of the three beta functions is multiplied by a phase associated with the non-commutativity parameters (see eq. 9.21). The phases are a function of the momenta in the directions affected by the field.
• En route to the determination of the vertex operators and scattering amplitude we have found that the quantum energy-momentum tensor on the boundary of the worldsheet has a different form compared with the one derived as a Noether current associated with worldsheet translations or by variation with respect to the worldsheet metric. The modification which involves the metric of 1.1 takes the form T (y) = − 1 2α (g −1 ) µν :∂ y X µ ∂ y X ν (y): (1.3) where y is the coordinate on the boundary (the real axis when the worldsheet is the upper half-plane). It should be emphasized that the bulk energy momentum tensor is not modified and it is only the one on the boundary of the worldsheet.
• We show that for fixed target scattering there are kinematic parameters, namely momenta and scattering angles, for which by tuning the magnetic field the scattering amplitude vanishes.
• Since we are interested in the interaction of real neutral hadrons like neutrons or ρ 0 with electromagnetic background and their scattering amplitude we have to consider the strings in the non-critical four dimensions. We address this following [10] using the effective string theory approach of Polchinski and Strominger [11].
• In the effective string theory approach one expands around a classical solution that has a string length much larger than the string scale. We show how the long string expansion around the rotating string reproduces the same spectrum as the critical theory. To do so we show how one can deal with divergences at folding points, at least one of which is always present for the rotating string in a magnetic field.
Our results are in accordance with and complement several previous investigations of the system in particular: the dynamics of open strings in EM background [12], spacetime non-commutativity [13], non-commutative SYM [14], holographic description [15], a saddle point type of determination of the scattering amplitude [16] and others.
The paper is organized as follows: In the next subsection we describe hadrons, both mesons and baryons, as charged strings in holography and HISH. In section 2 we write down the various forms one can have for the action and the corresponding equations of motion. Section 3 is devoted to the symmetries of the system and the corresponding conserved currents and charges. In particular we spell out the reparametrization and Weyl invariance of the worldsheet, the invariance under target spacetime Poincaré transformation and the gauge invariance. In section 4 we present the general solutions of the equations of motion including certain specific examples. In the next section 5 we write down explicitly some classical solutions of the equations of motion, in particular a rotating folded string in magnetic field with or without massive endpoints and stretched strings in electric field. In section 6 we canonically quantize the system. We determine the non-commutative nature of the zero mode coordinates and we determine the spectrum and compute the intercept of the system. In section 7 we work out the operator product expansion of the target spacetime coordinates of the string both in the bulk and on the boundary of the worldsheet. Section 8 is devoted to the determination of the vertex operator. For that purpose we work out the quantum energy momentum tensor on the boundary. Using this vertex operator we compute in section 9 the scattering amplitude. We show that it takes the form of a modified Veneziano amplitude that incorporates the modified spacetime metric and the non-commutativity parameters. We also determine certain phenomenological implications of the scattering amplitude.
In section 10 we discuss the system in non-critical dimensions. We invoke the Polchinski-Strominger effective action to determine the intercept of the system and comment on the scattering amplitude in four dimensions. We summarize the results of this paper and present some open questions in section 11.

Charged strings in holography and HISH
In nature mesons carry +1, 0, −1 electric charges and baryons +2, +1, 0, −1. In holography mesons are strings that end on flavor branes. From the point of view of the flavor branes the ends of the strings carry electric charges and since the string has a different orientation on its two endpoints, one can refer to one end as a "quark" and the other as an "antiquark". Baryons in holography are more complicated constructions of strings. They are built from N c strings that come out of a Dp brane that wraps a p-cycle and end on flavor branes.
The HISH model [7] maps the holographic stringy hadrons into string configurations in four flat spacetime dimensions and with N c = 3. Instead of strings in curved ten-dimensions, the main players in the HISH model are open strings with particles on their ends in flat four dimensional spacetime. These particles are massive and carry electric charge and spin. For mesons the particles represent both the "vertical segments" of the holographic strings and the charge and spin of their end on a flavor brane. This is also the case for one end of the baryonic string and on the other side the endpoint particle is constructed from a baryonic vertex combined with two short strings that connect the baryonic vertex to flavor branes, forming the holographic realization of a diquark. Both in the holographic picture and in the HISH model there is a force that is exerted on the endpoint particles and balances the tension. For hadrons with orbital angular momentum there is a classical centrifugal force that does this. In addition, there is always a repulsive Casimir force [8], which keeps also hadrons with vanishing orbital momentum from collapsing to a point.
We can assign a basic charge to the holographic flavor branes which is the electric charge of the corresponding flavored quark, namely, then we get for the holographic and HISH hadrons the charge setups depicted in figures 1 and 2. The diquarks used to construct the baryon in the HISH picture are endpoint particles like the quarks, and we can associate with them a mass, an electromagnetic charge, and spin. In figure 1 we drew the mesons associated with u and d quarks in the holographic picture (left) and in the HISH picture (right) and similarly in figure 2 the corresponding baryons. The vertical direction stands for the holographic radial dimension and the horizontal one for a coordinate in the four dimensional flat space. To describe the HISH string we write an action in the flat spacetime, taking for the string the Nambu-Goto action, plus correction terms from the non-critical theory for dimensions less than 26, as well as appropriate terms on the boundary of the worldsheet for the endpoint particles.
In the current paper we address only the case of neutral hadrons, namely the cases M 0 and B0 in the figures. In a similar manner to the stringy configurations depicted in the figures, there are stringy mesons and baryons that have ends on the s, c and b flavor branes and their charge setup in built in the same way.

Action and equations of motion
The most general action of the system we are interested in is given by where S st is the string worldsheet action given by the Nambu-Goto action, In the string action h αβ = η µν ∂ α X µ ∂ β X ν is the induced metric on the worldsheet and h is its determinant, the indices α, β being either τ or σ. The target space is D dimensional µ, ν = 0, ...D − 1. To keep track of units, we take the worldsheet coordinates τ and σ to have dimension of length, and our action is defined on the strip: −∞ < τ < ∞ and 0 ≤ σ ≤ .
The particles located at both endpoints of the string σ = 0 and σ = have an action that is built from two parts. First is a mass term S pm given by 2 The second term in the boundary action S pq respectively The parameters m i and q i are the mass and charge of the endpoint particles. We put a factor of T before the charged particle action, so that we work in a convention where q i F µν is a dimensionless quantity, or in other words the electromagnetic fields are given in units of the string tension. At this point we can consider two different cases. In one case we take the action 2.1 and we treat the gauge field A µ as a given background field A back µ (X). Another possibility is also to make the gauge field dynamical by turning on a kinetic term, namely taking In this case the gauge field in S pq takes the form of is the gauge field that one charge induces on the location of the other charge and vice versa, and A back denotes a background field. In this paper we consider only the former case where the gauge field is a background field. In a sequel paper we will consider the dynamical case.
For the case of interest in this paper, of a neutral string with q 1 = −q 2 = q, the action boundary terms S pq can be rewritten as a bulk term provided certain initial and final conditions are met.
Here αβ is the two dimensional antisymmetric tensor with τ σ = 1. The equivalence can be shown as follows (2.7) 2 We assume, as in preceding works, that the endpoint particle is spinless.
Thus, if the sum of the two last terms vanishes the bulk action indeed equals that of the action with the two boundary terms. The bulk action is recognizable as the action for a string in a background of a Kalb-Ramond B-field. From the full action 2.1 we derive the bulk equations of motion and at the boundaries the conditions In the most general case F µν is a function of X µ (τ, σ) which is evaluated at the boundary. As will be discussed in the next section, the action 2.1 is invariant under two dimensional reparametrization. We use the symmetry to fix the orthogonal gauge 3.1. In this gauge the bulk equations of motion read X µ −Ẍ µ = 0 (2.10) and the boundary conditions Apart from the analysis of classical solutions, in the rest of the paper we will consider only the case where the endpoints are massless, setting m 1 = m 2 = 0. For the neutral string case without masses the boundary equations at σ = 0 and σ = are the same X µ + qF µ νẊ ν = 0 σ = 0, (2.13)

Symmetries and conserved currents
The classical symmetries of ordinary open string theory are two dimensional diffeomorphism, local Weyl invariance and target space Poincare invariance. To study the symmetries of the combined action of an open string and endpoint charges 2.1 we need to examine how are these symmetries affected by the boundary terms 2.4 associated with the charges particles.

Reparametrization invariance and the energy momentum tensor
The string action S st is classically invariant under two dimensional local reparametrization transformations {τ, σ} → {τ (τ, σ),σ(τ, σ)} and the boundary action terms S pq and S pm are invariant under one dimensional local reparametrization τ →τ (τ ). The bulk reparametrization symmetry can be fixed in the orthogonal gauge which takes the following form: The bulk action fixed in this gauge is invariant under worldsheet global translations σ α → σ α + a α where a α are constants independent of τ and σ. The corresponding Noether current is the well known energy momentum tensor which reads It is trivial to verify that the bulk equations of motion guarantee the conservation of T αβ . In terms of the complex worldsheet coordinates that will be introduced in section 7 the holomorphic and anti-holomorphic components of the energy momentum tensor are as usual Next we would like to examine the energy momentum tensor when charges are turned on at the endpoints and we add the S pq terms. For the case of vanishing total charge, q 2 = −q 1 , as we have seen above, the total action is a bulk action of the form of (2.6). It is easy to verify that due to the αβ factor the contribution to the energy momentum tensor from the term linear in the charge q vanishes. In fact this is also the result for the general case q 2 = −q 1 when the boundary terms cannot be translated to a bulk term. Since the S pq are integrals over dτ the issue is only the symmetry under the translation of τ . The corresponding world sheet Hamiltonian takes the form The boundary Hamiltonian at σ = 0 is given by and and similarly at σ = l. Since there is no contribution from the boundary the full Hamiltonian is Π µ is the canonical variable conjugate to X µ given by Another way to determine the energy momentum tensor is by varying the action with respect to the worldsheet metric. In general boundary terms depend on the worldline metric. For instance the mass term S pm 2.3 can be written as and thus its variation with respect to the einbein e(τ ) is non-trivial. However, for the boundary term associated with the coupling to a gauge field (2.4) the worldline metric drops out [1] which is another way to see that it does not affect the worldsheet result. Thus the conclusion is that classically the total Hamiltonian is not modified by the boundary terms S pq . We emphasize here that is the classical result. It will be shown later in section 8 that in fact quantum mechanically the energy momentum is modified by the boundary charge terms.

Weyl invariance
It is straightforward that the theory is classically scale invariant. The boundary action (2.4) and the bulk action (2.6) do not depend on the worldsheet metric and hence they are both trivially Weyl invariant classically. As was just mentioned the boundary mass term S pm does depend on worldline einbein e(τ ) but not S pq .
Quantum mechanically Weyl invariance requires the vanishing of the beta function associated with the coupling to the gauge field. It was shown in [2] that the condition for the vanishing of the beta function is given by which to the leading order in α is Maxwell's equation (for the derivation of the matrix factor see 4.16). Obviously constant F µν which will be assumed in the rest of the paper is a trivial solution of Maxwell's equation.

Space time translations
The bulk form of the coupling to external constant EM background field (2.6) is invariant under global spacetime translations since its dependence on X µ is only via its derivatives ∂ τ X µ and ∂ σ X µ . However, this is not the case for the action that includes boundary terms (2.4). In this case the variation of the action reads For a constant EM field, namely, A µ = − 1 2 F µν X ν and if we choose coordinates so that F µν is non-vanishing along a single pair of coordinates then obviously translations along the two other coordinates do not modify the boundary terms. However, translations along the directions of F µν do modify the boundary terms. The variation of these terms takes the form When the square bracket vanishes the action is invariant also under spacetime translations along the direction of the EM field. This condition is related to the condition of the equivalence of the bulk and boundary terms formulations.
For the action which is invariant under spacetime translations, either the bulk action or the the one that includes boundary terms and the condition of above is fulfilled, the corresponding Noether charge P µ is given be Obviously for translations not along the directions of F µν only the term which is an integral over σ survives.

Lorentz transformations
For infinitesimal Lorentz transformations parametrize as where ε is an infinitesimal parameter and µ ν is the two dimensional Levi-Civita antisymmetric tensor, the situation is as follows. Transformations which are not along the EM field directions obviously leave the action in both formulations invariant. For transformation which are along both coordinates of the EM field, the variation of the bulk action (2.6) takes the form Note that the last two terms have indexes µ and ν which are the directions of the EM field and of the Lorentz transformation. Also the boundary terms (2.4) are invariant under such transformations.
For a Lorentz transformation that involves only one coordinate along the direction of the EM field let's take with no loss of generality the case of F µν = F 12 and the transformations δX 1 = εX 3 , δX 3 = −εX 1 . For such a case we get that the variation of the bulk action (2.6) reads where in the last step we have made integration by part over τ and over σ. The later includes a surface term that vanishes upon using the boundary equations of motion and the former requires that lim T →∞ ( The Noether charge associated with Lorentz transformation that are not along the directions of the EM field are as usual For Lorentz transformations along theX 1 , X 2 with F 12 If a Lorentz transformation along one coordinate of EM field as stated above is a symmetry the corresponding Noether charge is given by

Gauge invariance
The worldsheet action in its bulk formulation (2.6) is obviously gauge invariant. Under the gauge transformation A µ (X) → A µ (X) + ∂ µ Λ(X) , the variation of the boundary term at σ = 0 takes the form and similarly for the boundary at σ = l. Thus, the action with boundary terms is invariant under gauge transformations only provided that the transformation parameter is periodic or vanishes on the boundary of the τ direction. So far we have discussed the invariance of the classical action. As was discussed in details in [4] in the quantum picture the system has to be regularized. Using point splitting regularization and taking into account the noncommutative nature of the zero model ( see (6.17) ) it was shown that in the quantum action is in fact invariant under a modified gauge transformation, involving the Moyal star product defined using the non-commutativity phase. In (3.12) it was pointed out that invariance under space time translation requires fulfilling certain boundary conditions. Similarly (3.21) sets the condition for invariance under gauge transformation. It is easy to check that the action is invariant under combined spacetime translation and gauge invariance if the transformation parameters obey a ν ∂ ν A µ − ∂ µ Λ(x) = 0 at both σ = 0 and σ = l where a ν and Λ are the parameters associated with the spacetime translation and gauge transformation respectively.

Mode expansion
The most general solution of the bulk equations of motion (2.10) is a sum of left and right moving modes, for which can we write the mode expansions The two boundary conditions at σ = 0 and determine the spectrum of allowed eigenfrequencies ω n and the relation between the left and right moving oscillators, α n andα n . We will write the equations for the general case of any q 1 and q 2 before specializing to the neutral string with q 1 = −q 2 = q. The boundary conditions we have to satisfy are The first difference between the neutral and charged strings is that the zero modes linear in τ and σ cannot satisfy both conditions simultaneously, unless q 1 = −q 2 and the boundary condition is the same on both endpoints. For the oscillating modes, the two boundary conditions translate into the requirements We define the two matrices Such that the first boundary condition can be written in matrix notation 3 asα n = M 1 α n , and then the second boundary condition is For q 1 = −q 2 then the matrices M 1 and M 2 are the inverse of one another, and we simply get that the solution is ω n = n. For the general case the possible solutions are ω n = n + δ, where δ is independent of n and is a simple function of the eigenvalues of the matrix M 2 M 1 . The charged string case will be discussed fully in the sequel paper [9]. Returning to the neutral string case then, denoting q = q 1 = −q 2 , we have seen from the above that the left and right moving modes are related bỹ 3 Throughout this paper we use matrix notation to denote tensors where the first index is an upper index and the second is a lower index. When we define, for instance, C = (1 − qF ) −1 we mean the tensor C µ ν that obeys C µ where the matrix M is defined as The full mode expansion that solves the equations of motion and the boundary conditions in the neutral case is In the above expression we have written the zero mode such that the parameter x µ is the center of mass coordinate (at τ = 0), while α µ 0 is related to the total momentum of the string by Or We will see that the matrix that we have denoted g becomes important later on, where we see how it can be interpreted as an effective metric seen by the open string. Furthermore, the matrix M relating the left and right moving oscillators α n andα n can be seen to be a Lorentz transformation. One can verify that for any choice of F µν it obeys

Examples
We write the explicit forms the solutions take for some specific cases next. We use the metric with the signature (−, +, +, +, . . .). In this sign convention the electromagnetic tensor F µν in four dimensions is For a pure magnetic field, F 12 = B, the matrix M relating the left and right moving modes of the open string is in simply a rotation matrix in the 12 plane affected by the magnetic field with the rotation angle The effective metric is For an electric field we have a pure boost in the direction of the electric field with the boost parameter and with the effective metric (for E = −F 01 ) Here we see clearly the a critical value of the field |qE| = 1, where the metric is singular [3]. Another interesting particular case is when we combine an electric with a transverse magnetic field. We take F 01 = −E and F 12 = B = αE. If |α| < 1 we can boost the system to a frame with only an electric field, while for |α| > 1 we have a frame with only a magnetic field, so the return to one of the two cases described above. In the special case of α = 1, while the effective metric takes the special form Here there is no apparent singularity when we reach the critical field |qE| = 1.
-15 -Before quantizing the modes, we will write explicitly some classical solutions of the equations of motion that are of special interest.

Rotating string in magnetic field
For a string in a constant magnetic field F 12 = B, then is a solution to the equations of motion and boundary conditions provided The solution also obeys the Virasoro constraintsẊ 2 + X 2 = 0 andẊ · X = 0. Solutions with n > 1 describe strings that are folded on themselves n times. Under the magnetic field, the solution with n = 1 also develops a fold at σ = (1 − φ/π) (we will assume w.l.o.g. that qB > 0 and hence φ > 0). The energy of the rotating string is given by which in the orthogonal gauge becomes The angular momentum in terms of the polar coordinates similarly becomes Note that the endpoints do not contribute to E and J. The endpoint contribution to P µ is proportional to F µν X ν at the endpoint which is zero for the energy component, while for J the contributions from the endpoints cancel for the rotating solution at hand We can already see that For n = 1 this is the usual open string trajectory, while larger n gives the result for a folded string, where the effective tension is n times the basic tension T . The length of the string is So that E and J are given by the familiar expressions E = π 2 T L, J = 1 n π 8 T L 2 . Note that L is the total length of the folded string, which is n times the extent of the string in space time, plus the additional folded segment whose length depends on the magnetic field.
Points along the string move at a velocity given by Contrary to the rotating open string with Neumann boundary conditions, here the endpoints move at a finite velocity given by while the folding point in the string moves at the speed of light.

Rotating solution with endpoint masses
The classical solutions may be easier to understand when we add mass terms on the endpoints of the string in addition to charges. Then, the boundary condition of the string is actually the force equation on the endpoint particles, and we can see under what conditions the fold develops. The boundary conditions with masses were already stated in eqs. 2.11-2.12.
For the ansatz of a rotating solution as in eq. 5.1, the boundary conditions are When m = 0 we find the solution from before with ω = nπ and φ = arctan(qB). We want to see now the directions of the forces acting on the particle, and why the fold has to appear. At time τ = 0, what we wrote above is the force equation on the particle in the X 1 direction.
In the first equation, if φ = φ 0 is a solution then so is φ 0 + π. We pick the solution between −π/2 and π/2 so cos φ is positive. We can also choose qB > 0 and ω > 0 so that sin φ is also positive. The first equation can be written in terms of the velocity of the first endpoint as For the other endpoint, we take the first solution, in which 0 < ω < π. Now there are two possibilities, either the solution requires ω + φ > π (as we have seen it is in the massless case), or not. If it is larger than π then a fold develops. With the fold, then the pull of string is added to the centrifugal force, rather than subtracted from it: If there is no fold, then the sign of the tension force is reversed, while the others remain the same − γ 2 m 2 ωβ 2 + T e γ 2 + T eqBβ 2 = 0 (5.14) The two options are drawn in figure 4. Solving the boundary equations 5.11 numerically shows that, for a given value of qB there is a value of the mass below which there must be a fold in order to obey the force equations.

Stretched string in electric field
The solution for a string stretched by an electric field F 01 = −E is Where X t is some direction transverse to X 0 and X 1 . The transverse momentum is needed to make the solution obey the Virasoro constraintẊ 2 + X 2 = 0 (or the full Nambu-Goto equations of motion), and it is We can understand this condition again by introducing an endpoint mass so that the boundary condition is the force equation on the endpoint particle. For the solution above, the boundary condition in the presence of an endpoint mass in the X 1 direction is The LHS is zero since the solution is not accelerating. The condition then that the forces be balanced can be met for a specific value of p 2 t , as the tension is rescaled by a factor of 1 − p 2 t = γ −1 in the force equation. Alternatively, one could have a rotating solution in a plane transverse to the electric field for the same effect 6 Canonical quantization

Quantizing the modes
Now we take the mode expansion of section 4.1 and perform the quantization of the modes. We quantize by imposing the canonical equal time commutation relations The canonical [x µ , p ν ] commutator implies that for the mode α 0 , where g = (1 − q 2 F 2 ) −1 as defined above. We will also show that we need to leave a non-zero commutator of the center of mass coordinates By plugging in the mode expansion, and using the above together with the property η ρσ M µ ρ M ν σ = η µν of the M matrices: In the case of F = 0 then the sum becomes n =0 1 n cos(n(σ ±σ )) which vanishes because each term in the sum is odd under n → −n. In our case we are left with 1 n sin( π n(σ + σ )) (6.6) The infinite sum is in general given by Here x = π (σ + σ ) is between 0 and 2π, where the sum simplifies to One can show that qF µ ρ g ρν + N πT (M µν − M νµ ) = 0 (6.10) holds for any choice of F when the normalization constant is N = α 2 = 1 4πT (which is what it would have been also in the usual Neumann case with no charges). This can be readily seen when using the explicit forms of M and g, and noting that M νµ = (M −1 ) µν . This leaves us with Since we need this commutator to be zero we find that the center of mass coordinates must satisfy the non-trivial commutation relation Now we want the commutator of X µ with its conjugate momentum, For constant F µν we can pick the gauge A µ = − 1 2 F µν X ν . We have already shown that the equal time [X µ , X ν ] commutator vanishes, so we need to show only that In a similar calculation to the one above where we have dropped the part proportional to δ(σ + σ ). The constant second term in the last line vanishes, and we find that the usual commutator holds. To summarize, we have shown how imposing the commutation relations leads to the canonical equal time commutation relations of X µ and Π µ . The non-trivial commutation relations between the center of mass coordinates is necessary for the vanishing of the equal time commutator [X µ (τ, σ), X ν (τ, σ )]. For the specific case of a constant electric field it is a time-space non-commutativity while in the constant magnetic field F 12 = B the non-trivial commutation relation is In the example of a combined electric and transverse magnetic field of equal magnitude F 01 = −F 12 = −E, the result is

The spectrum and the intercept
If we insert the mode expansion for X (eq. 4.13) into the expression for the worldsheet Hamiltonian of eq. 3.7, we find the result Quantum mechanically, the only correction that H will take will be the addition of the normal ordering constant, which is the same as for the Neumann string since the eigenfrequencies are the same, For the last equation we assume D = 26, and we discuss the non-critical case in section 10. The mass-shell condition for a physical state (L 0 − a)|Φ = 0 now includes the effective metric, and it is On the other hand, the string is still propagating in a flat background metric, so one might define its mass squared as The explicit expressions for the magnetic (F 12 = B) and electric (F 10 = E) fields are, respectively It is not clear what the correct definition of the mass is, whether it is to be defined with the effective metric g µν or with the background metric η µν . The Lorentz symmetry is broken by the external field, and both possible definitions of the mass are invariant under the remaining unbroken part of the symmetry.
Some authors addressing this issue in the past have defined it the former way (for instance [2]), declaring the spectrum of the string is unchanged by the electromagnetic field, while others used the definition with η µν , noting the negative sign contribution to the mass squared as we have here [12]. Most references do not relate p µ with the Noether charge associated with as done in [12] and here.
A similar though different shift of the mass spectrum was discussed in [17] in the context of non-neutral strings in a magnetic field. Since the effect starts at the order (qF ) 2 (recall that the field is given in units of the string tension), then experiments to detect a shift in the mass of hadrons in the presence of magnetic fields are are clearly not practical. Instead, one may consider processes involving also closed strings, and use closed strings to probe the open strings. Since our open strings have total charge zero, there must be processes where both open and closed strings are involved. The closed strings propagate in the flat background and do not interact (directly) with the external field, and for them one can unambiguously declare that η µν p µ p ν is the mass squared, and they have the usual spectrum of M 2 = 2 α (N +Ñ − 2), and with N =Ñ for all states. An examination of interactions between closed and neutral open strings in the presence of the EM field might give a preference to one of the definitions of the mass of the open string over the other.

The operator product expansion
We compute the propagator as the singular part of where T denotes time ordering and : : normal ordering. We define the normal ordering of operators in the usual way, by putting annihilation operators to the right of creation operators, such that This is because p µ is also an annihilation operator in the sense that p µ |0 = 0, which ensures the vacuum is translation invariant. We also have to define :x µ x ν :, since they do not commute. There an ambiguity in how we define it, although the choice only affects the constant part of the two point function. To make a choice, we use the symmetric option of Inserting the mode expansion for X and using the above definitions, we find that [α α m , α β n ] mn δ µ α e −im π (τ −σ) + M µ α e −im π (τ +σ) δ ν β e −in π (τ −σ ) + M ν β e −in π (τ +σ ) In terms of z ≡ e i π (τ −σ) andz ≡ e i π (τ +σ)4 , and substituting the commutators from the previous section, Using the relations between the matrices M and g, namely that (1 − qF )g = (1 + qF ) −1 = 1 2 (1 + M ), we can combine the log terms and get X µ (z,z)X ν (w,w) − :X µ (z,z)X ν (w,w): = (7.7) This is equivalent to the form presented in [4], which in our notation is On the boundary, the real axis, we write z = y 1 , w = y 2 . Approaching the boundary from the upper half plane z = y 1 + i , the last term introduces a branch cut as In total we can write the boundary propagator G µν (y 1 , y 2 ) = −α g µν log(y 1 − y 2 ) 2 + 1 2 iθ µν (sign(y 1 − y 2 ) + 1) (7.10) where In this expression we see how g µν , which we first defined in our mode expansion of the solution to relate α µ 0 to the momentum can now be interpreted as an effective metric seen by the open string in the presence of an external field.

Energy momentum tensor on the boundary and the vertex operator
The question we want to answer in this section is what form the energy-momentum tensor takes, as a local operator defined on the boundary, and then how a vertex operator of the correct dimension can be constructed. Classically, and in the bulk, the energy-momentum tensor is unaffected by the charges, and we have the holomorphic and anti-holomorphic currents On the boundary, z =z = y we suggest that the form of T (y) =T (y) should be where g −1 is defined as the inverse of the tensor g µν that appears in the boundary propagator. 5 In other words, g enters the boundary energy-momentum tensor as would a background metric. In addition, T (y) is defined with respect to the boundary normal ordering defined using the boundary propagator, namely through in accordance with eq. 7.10 for the boundary propagator. The extra factor of 1 2 in the definition is necessary even in the usual Neumann open string case, because of the doubling in the boundary normal ordering. Note that in this section we ignore the θ µν part of 7.10 since it does not affect the OPEs of operators that involve derivatives.
The motivation behind the above definition of T (y) is to yield the correct OPEs with itself and other operators when computed directly on the boundary, that is for a primary operator O, the OPE when both T and O are placed on the boundary should read [18,19] T where h y is the dimension of the operator under rescaling of y.
In addition to T (y) we would like to examine if the open string vertex operator for the tachyon (with momentum k µ ) also requires a change to reflect the presence of the effective metric. We write the two operators in a more general form V k (y) = :e ivµν k µ X ν (y): (8.6) and write the different OPEs while keeping track of the different tensor contractions. Then the boundary propagator with the "effective metric" derived from g µν implies the following forms for OPEs involving T (y), denoting y 12 ≡ y 1 − y 2 , All the OPEs involving T imply that we have to take t αβ g βµ = δ µ α , or t µν = (g −1 ) µν . This ensures, for example that ∂X µ is a primary operator on the boundary with dimension one, and also that the T T OPE is of the same form as in the bulk.
Specifically we want that the coefficient of the y −4 12 term will remain η µ µ = D, which is the central charge of the bosons, so it can be canceled by the ghost contribution of −26 on the boundary as well as in the bulk. The OPE of the ghost part of the energy momentum tensor with itself on the boundary is assumed to be unchanged by the presence of the external field. This should be a reasonable assumption as the derivation of the Faddeev-Popov ghosts for the open string does not depend on the details of the boundary condition for the bosons X µ , only on the fact that there is a boundary.
Explicitly, the ghost OPE implies the doubling in the boundary OPEs b(y 1 )c(y 2 ) ∼ 2 y 12 (8.12) In the ghost boundary energy-momentum tensor we will include a factor of 1 2 relative to the bulk definition and replace ∂ → ∂ y , T (y 2 ) + 2 y 12 ∂ y T (y 2 ) (8.14) as can be verified by explicit calculations using the boundary OPEs of X and the ghosts. Similarly we have the expected OPEs of T with X and ∂X, With the choice t µν = (g −1 ) µν we can also read the dimension of the tachyon vertex operator V k as h y (V k ) = α g µν v µα v νβ k α k β (8.16) As discussed in section 6.2 the spectrum includes states with α g µν k µ k ν = 1−N . In particular the ground state has α g µν k µ k ν = 1. To have the correct dimension for V k the only possibility is v µν = η µν . Then all operators of the form (∂X) J V k will have dimension J + 1 as it is for the Neumann string.
To summarize, we define the boundary energy momentum tensor as T (y) = − 1 2α (g −1 ) µν :∂ y X µ ∂ y X ν (y): (8.17) and the tachyon vertex operator is defined as V k (y) = :e ik·X (y): (8.18) using the normal dot product with the flat background metric. The latter definition also ensures that the vertex operator transforms correctly under the translation symmetry X µ → X µ + a µ , by picking up a phase e ik·a . The open string vertex operator does not change its form relative to the string without endpoint charges. It is still the exponential operator for a string propagating in a flat background. The difference is that it is now defined w.r.t. the boundary normal ordering, which does include g µν . This choice of V k is also what leads to a consistent scattering amplitude, as we will see in the next section.

The scattering amplitude
Next we consider the scattering amplitude of strings with charges on their endpoints. As in ordinary string scattering the computation of the level amplitude translates to calculation of expectations values of vertex operators on a geometry of a disk. The tree level amplitude of strings with the charges (q, −q) on their endpoints is depicted in figure 5. Note that for charge conservation all the strings should have the same charges on their endpoints. The amplitude is defined as in the ordinary bosonic string theory. We compute it by looking at the expectation value of vertex operators on the disk. The vertex operator was defined in the previous section, V k (y) = :e ik·X (y): (9.1) and it represents an asymptotic tachyon state with incoming momentum k µ . We can use our boundary propagator (we use the result of eq. 7.10, minus the constant part) to compute the OPE of two exponential operators on the boundary, :e ik 1 ·X (y 1 ): :e ik 2 ·X (y 2 ): ∼ e − i 2 θµν k µ 1 k ν 2 sign(y 1 −y 2 ) |y 1 − y 2 | 2α k 1 k 2 :e i(k 1 +k 2 )·X (y 2 ): where we have defined the scalar product w.r.t. to g µν a b ≡ g µν a µ b ν (9.4) Since we will write the scattering amplitude for tachyons, all our momenta will obey α k i k i = 1 (9.5) Figure 5. The tree level amplitude of a 2 → 2 scattering of strings with (q, −q) charges on their ends. This worldsheet can be mapped to a disk with a charge q running along its boundary.
as seen in section 6.2. The modifications from the Neumann string case are then a phase from the non-commutativity part, and the modified scalar product in the exponent of |y 12 |.
We can now follow the textbook derivation (see for instance chapter 6 in [20]) of the three and four point functions using our modified propagator. The expectation value of a product of n exponents on the boundary of the disk will be If momentum is conserved i k i = 0, then the phase factor depends only on the cyclic ordering of the y i , as observed in [4]. For example, for n = 3, and using the shorthand notation s ij = sign(y i − y j ) the phase can be written as where we have used momentum conservation in the first part, and antisymmetry of θ µν in the second part. The cyclic form of the phase is manifest. Up to various constants and a delta function for momentum conservation which are the same as in the chargeless case and will be left out of all the following, the amplitude for three tachyons on the disk is S D 2 (k 1 , k 2 , k 3 ) = :c 1 e ik 1 ·X (y 1 ): :c 1 e ik 2 ·X (y 2 ): :c 1 e ik 3 ·X (y 3 ): + (k 2 ↔ k 3 ) (9.8) The points y i have been fixed and integration on each of them has been replaced with the corresponding Faddeev-Popov ghost. We sum over both ways to arrange the three points on the disk by exchanging k 2 and k 3 for the second term. We assume that the expectation values of the c-ghosts in the above expression are unaffected by the change of boundary condition and are the same as in the Neumann string case, and we can write the next step as We can use momentum conservation k 1 + k 2 + k 3 = 0 and α k k = 1 for each of the three states to replace and likewise for other pairs of k i k j . The exponent of each |y ij | vanishes, but we are left with the phases, which combine to give For the last part we again used the antisymmetry of θ µν and momentum conservation to get We will use this type of manipulation often in the following. The three point function is independent of the three positions of the points on the disk, which is the first consistency condition. We see that it is a function of the momenta in the plane affected by the external field.
If we proceed to write the four tachyon amplitude on the disk in the same way, again not writing any additional constants, we find that :c 1 e ik i ·X (y i ): :e ik 4 ·X (y 4 ): + (k 2 ↔ k 3 ) (9.12) At this point we fix y 1 = 0, y 2 = 1, y 3 → ∞. We can see again how the mass shell condition α k k = 1 removes the dependence on y 3 as we have the factor in the amplitude We still have to keep track of the phase factors in the integral. As before, the phase depends on the cyclic ordering of the points. We can write the phase explicitly as (9.15) After choosing y 1 = 0, y 2 = 1, and y 3 = ∞, the phase reduces to iΘ(y 4 ) = − i 2 θ µν (k µ 1 k ν 2 (−1 + sign(1 − y 4 ) + sign(y 4 )) + k µ 1 k ν 3 sign(y 4 ) + k µ 2 k ν 3 sign(y 4 − 1)) (9.16) By integrating y 4 from −∞ to ∞ and adding the term with k 2 and k 3 exchanged we sum over the six different cyclic orderings of the four vertex operators on the disk, The integral breaks up into three domains y 4 < 0, 0 < y 4 < 1, and y 4 > 1. In each part we will have a different Θ(y 4 ), and each will give a different Beta function multiplied by that phase. The Beta function can be written in one of the two equivalent ways We use as before 2α and define the modified Mandelstam variables, such thats +t +ũ = −4/α in the usual way. In terms ofs,t andũ the amplitude is given by The st part comes from the domain y 4 > 1, while su comes from y 4 < 0 and tu from 0 < y 4 < 1. From the general expression 9.16 one finds that the phases are An alternative form for the phases is The exchange of k 2 and k 3 switchess andt while the phases transform as Θ st → −Θ st , Θ su → −Θ tu , and Θ tu → −Θ su . This leads us to the final answer for the amplitude S D 2 (k 1 , k 2 , k 3 , k 4 ) = cos(Θ st )I(s,t) + cos(Θ su )I(s,ũ) + cos(Θ tu )I(t,ũ) (9.29) One can verify that the amplitude is fully crossing symmetric. The amplitude is also invariant under q → −q, as expected.

Phenomenological implications
To relate the scattering amplitude 9.29 to scattering processes of real neutral stringy hadrons like the neutrons or π 0 one has to derive the analogous result in four dimensions rather than the critical dimensions. This will be discussed in the next section. Meanwhile we would like to examine the amplitude associated with various different kinematic setups and look for ways to confront it with experimental data. The reference amplitude is the Veneziano formula with no electric or magnetic background turned on A 0 . Next is the amplitude in the presence of electric field. In that case we distinguish between the case where the direction of the scattering strings is parallel or perpendicular to the electric field A E || and A E ⊥ respectively. Similarly, there are two amplitudes when the magnetic field is turned on A B || and A B ⊥ . In the case of A 0 g µν = η µν , θ µν = 0 and the Beta functions are expressed in terms of s, t and u. is given in terms ofs The other amplitudes are determined in a similar manner. Note that the effect on the Mandelstam variables starts at quadratic order in the field strength for small values of qE, while the phases are linear in the field. This is true for a general EM field.
The most efficient way to confront the theoretical result for the amplitude of scattering in the presence of constant EM field (9.29) is to look for zeros of the amplitude which are not zeros of the amplitude without EM background. From (9.29) it is evident that this can happen if cos(Θ st ) = 0, cos(Θ su ) = 0, cos(Θ tu ) = 0 (9.33) If instead only cos(Θ st ) = 0 holds than the st channel of the amplitude vanishes and similarly for su and tu. For the st amplitude to vanish we need that For the case of a magnetic field B = F 12 this condition reads This condition can be obeyed only provided that the expression inside the square brackets does not vanish. If the scattering takes place in a plane perpendicular to eitherx 1 orx 2 obviously it does vanish. This is also the case for a center of mass scattering in thex 1 ,x 2 plane with the momenta 36) On the other hand for a scattering in the lab frame of a projectile on a fixed target with k 1 = (k, 0, 0), k 2 = (0, 0, 0), we find that the condition is q Tk k y B 1 + q 2 B 2 = π (9.38) and for non-relativistic scattering we havekk y =kk 1 − k k . This equation determines the value of k for which givek the channel st vanishes. In fact it is easy to check that for this kinematic setup this condition leads also to the vanishing of cos(Θ su ) and cos(Θ tu ) and hence of the full scattering amplitude.
Since we write the magnetic field in units of the string tension, then the effect is always very small for realistic values of the magnetic field. The typical string tension for hadrons is T ≈ 0.18 GeV 2 , while the strongest magnetic fields producible in a lab are of the order 10 1 Tesla, which is ≈ 2×10 −15 GeV 2 . The effect of the magnetic field is also proportional to kk/T and can be increased by going to higher and higher transverse momenta, but overcoming a factor of 10 −14 to reach the point where the amplitude vanishes is unrealistic.
As an aside, we note that the strongest magnetic fields in nature are in magnetars, a type of neutron star, where fields as large as 10 11 Tesla ∼ 10 −5 GeV 2 can exist [21,22]. Since neutrons are strings with charged particles on their endpoints, one can hope to find some way of making the string model applicable there. Of course this would require a lot of work beyond the scope of this paper. Very strong magnetic fields are also found in heavy ion collisions, in experiments such as RHIC, but there the interaction is with quark-gluon plasma, rather than hadrons [23].
10 The non-critical string with endpoint charges To relate the scattering amplitude 9.29 or any other of the calculated values in the previous sections to the physics of real world hadrons one has to consider strings in four spacetime dimensions, rather than the critical D = 26.
A framework in which this can be done is that of effective string theory [11,[24][25][26][27]. The effective string theory description requires us to expand around a long string, a classical solution of length L. We can then write an effective action for the transverse fluctuations around the long string, where successive terms in the action are of increasing order of the expansion parameter s /L, with the intrinsic length scale being s = √ α . The effective string action gives a consistent description for the string action in any dimension D ≤ 26.
We use the prescription of Polchinski and Strominger (PS) [11], where the action is written in the orthogonal gauge. The leading order term is the Nambu-Goto action, and the first added term is The coefficient is chosen is such a way that the conformal anomaly is canceled (to the relevant order in the 1/L expansion) for any D. We do not add any new terms to the boundary. Since the expansion requires us to start from a solution with finite length, we will examine the expansion around the rotating solution that we had for the string in a constant magnetic field (section 5.1).

Spectrum of fluctuations around a rotating solution
In this section we examine the quantization of the fluctuations around a rotating string in a magnetic field and compare it to the quantization presented in previous sections, where no such expansion was carried out. The analysis of fluctuations around rotating strings without the background magnetic field was addressed in [28][29][30][31][32][33]. Our computation for the string in a magnetic field differs from those in the above references by the addition of the phase φ in the solution, implying the presence of a folding point as discussed in section 5.
We insert into our action X µ = X µ rot + δX µ where X µ rot is the rotating solution of eq. 5.1. Instead of making the orthogonal gauge choice, we gauge away the time component for the fluctuations, meaning δX 0 = 0, or X 0 = eτ . This is the static gauge which fixes τ , while σ is essentially fixed by the choice of the function R(σ) = 1 ω cos(ωσ + φ) used to define the solution.
The full bulk action is the Nambu-Goto action plus PS term as discussed above. To get the leading order terms in the 1/L expansion in the effective action for the fluctuations we take only the terms quadratic in the fluctuations from the NG part of the action. The PS term need only be evaluated on the classical solution in the leading order.
All the fluctuations transverse to the plane of rotation are just free fields. There is no difference for them between the rotating and the non-rotating string, and they are unaffected by the magnetic field. The modes in the plane of rotation are different.
In polar coordinates X 1 = ρ cos θ, X 2 = ρ sin θ, we have The mode δρ is longitudinal to the string, and contributes only boundary terms to the action, while the mode δθ needs to be redefined to give a canonically normalized kinetic term. This is a mode transverse to the string which we call the planar mode. In terms of in the propagator without rotation (eq. 7.10), which is a more physical manifestation of the non-commutativity. We leave that as an open question, and turn to the computation of the intercept in the non-critical rotating string.

The intercept
Next we would like to determine the intercept associated with the folded rotating string solution in non-critical dimensions, in the presence of the magnetic field. A more general and complete analysis of rotating strings with folds, which includes both the open string in electromagnetic background and folded closed strings will appear in [34]. Here we summarize the results for the former case. The intercept has a contribution of 1 24 from each of the D − 2 modes transverse to the string, including the planar mode discussed in the previous subsection.
For the non-critical string, in the leading order we have in addition to the result of eq. 10.14 a constant term in the Hamiltonian that we get by inserting the classical solution into the Polchinski-Strominger term in the action, This term will contribute a correction to the intercept for D = 26. The integral diverges, with the source of the divergence being the folding point x + φ = π that moves at the speed of light. For the string with no charges the divergence can be regularized by adding endpoint masses as counterterms, as was done in [31,33]. For the rotating solution in a magnetic field, it is the folding point, rather than the endpoints of the string, that moves at the speed of light, and consequently we cannot regularize the divergence by adding boundary terms. On the other hand, one can write a classical rotating solution for the system that has a mass at the point where the string is folded. If the fold is at the point σ = s and we insert the usual massive particle worldline term into the action, fixed at that point, then in addition to the boundary condition at the endpoints we have the condition at the folding point We can solve the equations by taking a solution of the same form as before, with a phase jump at the folding point. That is, we will have ρ(σ) = e ω cos(ωσ + φ 1 ) for σ ≤ s, and the same solution with φ 1 → φ 2 = −φ 1 − 2ωs for σ ≥ s. The parameters φ 1 and ω are determined from the two boundary conditions and the equation at the folding point.
The physical effect of the mass is to slow down the folding point to a finite velocity as given by the force equation at the fold Evaluating the PS Lagrangian on this solution, we find the same form as for the string with massive endpoints, As explained in [33], we can write the energy in terms of the effective length of the rotating string,L = L arcsin β β (10.19) and the relativistic massm = γm, since that is the form that appears in the classical energy of the rotating string solution For the string with massive endpoints it was argued that we can redefine the mass at the endpoint of the rotating string to eliminate the first term in E P S that diverges in the massless limit, and that we get the correct finite result for the intercept by considering only the 1/L term. If we do this here, we find that the subtraction can be done without reference to the value of the magnetic field, so that as in [31,33] in the massless limit even when the string is in a magnetic field. This means that the total intercept, considering all transverse fluctuations as well the PS contribution remains a = D − 2 24 + 26 − D 24 = 1 (10.22) for any D and any value of the magnetic field B.

Comments on the scattering amplitude for non-critical strings
In the previous section we discussed the spectrum and the intercept at non-critical dimensions. We would like next to address the same issue about the scattering amplitude, namely, the vertex operators and the expectation values of their products.
In [10] off-shell vertex operators in effective string theory in non-critical dimension were written down. It is emphasized there that these vertex operators correspond to external background fields rather than states of the string theory itself. For our purposes this is not what is needed. Instead we need the on-shell vertex operator for the scalar state of the open string. 7 Nevertheless, we would like to examine the proposal of [10]. The boundary vertex operator of a scalar state in non-critical dimensions is expected to take the form V k = :e iηµν k µ X ν e γϕ (y): (10.23) 7 In the ordinary string theory this is obviously a tachyonic state but in the string theory of hadrons it is not since there are such hadronic states like π 0 . This can achieved if in that theory the intercept is negative [8].
where ϕ is the Liouville field and β should be determined from the requirement that the operator have dimension one. It was shown in [11,27] that the Liouville field can be expressed as a composite operator of the following form ϕ = − 1 2 log (∂ α X µ ∂ α X µ ) (10.24) Following the discussion of section (8) the space time metric in this expression should be η µν . Thus, the vertex operator takes the form V k = :e iηµν k µ X ν (∂ α X µ ∂ α X µ ) −γ/2 (y): (10.25) However, the world sheet energy momentum tensor that determines β should have the modified metric as in (8.2). In addition there is a contribution of the Liouville term so the boundary energy momentum tensor reads T (y) = − 1 α (g −1 ) µν :∂ y X µ ∂ y X ν (y): + D − 26 24 (g −1 ) µν :∂ y X µ ∂ 3 y X ν (y): (g −1 ) µν :∂ y X µ ∂ y X ν (y): (10.26) In [10] it was found out that to determine γ to leading order one has to use only the first term in the energy momentum tensor and at that order the vertex operator reads V k = :e iηµν k µ X ν (∂ α X µ ∂ α X µ ) −α k k+1 (y): (10.27) The conclusion is thus that to leading order since on shell α k k = 1 the Liouville dressing is dropped off and the vertex operator is the one of the critical dimensions. In fact also the first order correction to the vertex operator found in [10] vanishes on shell. Hence it seems that to leading order in the string length the scattering amplitude of the non-critical string is the same as that of the critical string.

Summary
In this paper we have determined the scattering amplitude of an open string with two opposite charges on its endpoints in a constant electromagnetic background field. As part of the introduction we have already summarized the results of this work. These include: (i) Classical solutions of rotating strings requiring folds. (ii) The modification of the spacetime metric along the directions of the EM field. (iii) The non-commutativity of the center of mass coordinates along those directions. (iv) The determination of the scattering amplitude for this type of strings, including the Mandelstam variables that are changed due to the modified metric and certain phases that follow from the non-commutativity parameters. (v) The fact that the quantum energy momentum on the boundary of the string worldsheet is affected by the boundary charges and is different from the Noether procedure result. (vi) Phenomenological implications including the observation that by tuning the magnetic field or the kinematic parameters the scattering amplitude can be set to zero. (vii) Mapping the scattering amplitude of strings in the critical dimensions to the case of non-critical four dimensions.
There are several open questions that follow from the results of the current paper. Among them are: • The second part of this project is the determination of the scattering amplitude of a string with charges at the endpoints of an open string for the general case where the total charge of the string is non-zero, q 1 + q 2 = Q = 0. This generalization is highly non-trivial, in part due to the fact that the general charges now implies different boundary conditions for the two endpoints of the string. In 4 here we showed how that implies a constant shift in the spectrum. The charged string case raises several other questions, for instance if there is a quantization condition on the endpoint charges, and the question of how one expands around an accelerating string if there is an electric field. All these questions will be addressed in a sequel publication [9].
• As we have already mentioned part of the motivation for this analysis is to determine physical experiments that will verify the stringy nature of hadrons. Here in this note we took a constant electromagnetic field to couple to the open strings. In a similar manner one see how the string is affected by non-constant fields, like for instance electromagnetic plane waves or other types of radiation fields.
• Hadronic strings in the form of open strings with massive and charged endpoints differ from the ordinary string not only when coupled to an external electromagnetic fields but also due to the mutual electromagnetic interaction between the two endpoints. An analysis of the corresponding quantum spectra of such strings and scattering amplitudes will be presented in future work.
• Part of the motivation for the present paper has been to develop new ways to be sensitive to the stringy nature of hadrons. In addition to the spectrum we would like to have more measurable quantities that will enable us to reveal the stringy nature of hadrons. Form factors like magnetic moments and structure functions are different for hadrons as composite particles and hadrons as strings.
• The generalization of Veneziano's amplitude to the scattering amplitude of strings in four or any other non-critical dimensions has not been investigated thoroughly. Certain issues have been worked out in [10] when considering the ordinary open string. We have made several basic comments about the case of strings with charges on their endpoints. Further exploration of this issue in both the ordinary and charged strings is an obvious open question.
• For the hadronic strings which have massive endpoints, or the string in the magnetic field, it is natural to expand around a rotating solution. We have shown that quantizing the fluctuations around the rotating strings gives the same spectrum that we get without the expansions. However, the structure of zero modes is different and this needs further exploration. Another important question is seeing how such a semi-classical expansion can be used to compute scattering amplitudes for long non-critical strings.
• Another interesting feature of the rotating strings is that they can develop folds, and the rotating solution in a magnetic field requires at least one fold. These folds introduce certain divergences, and we have given a short explanation here of how they can be regularized by introducing a mass at the fold. This treatment can be generalized to other solutions with folds, specifically to rotating closed strings.