Lectures on Quantum Field Theory. Ashok Das

Lectures on Quantum Field Theory - Ashok Das


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with definite helicity, namely,

image

      so that the right-handed (four component) spinors in (3.155) are described by two component spinors with positive helicity while the left-handed (four component) spinors are described in terms of two component spinors of negative helicity. Explicitly, we see from (3.155) and (3.159) that we can identify

      We note here that the operators (see (3.159))

      can also be written in a covariant notation as

image

      with image defined in (2.121) and image It is straightforward to check that the operators P (±) satisfy the relations

image

      and, therefore, define projection operators into the space of positive and negative helicity two component spinors. They can be easily generalized to a reducible representation of operators acting on the four component spinors and have the form (see (2.71) or (3.119))

      and it is straightforward to check from (3.158) and (3.165) that

image

      which is the reason the spinors can be simultaneous eigenstates of chirality and helicity (when mass vanishes). In fact, from (3.161) as well as (3.165) we see that the right-handed spinors with chirality +1 are characterized by helicity +1 while the left-handed spinors with chirality −1 have helicity −1.

      For completeness as well as for later use, let us derive some properties of these spinors. We note from (3.159) that we can write the positive and the negative energy solutions as (we will do this in detail for the right-handed spinors and only quote the results for the left-handed spinors)

image

      Each of these spinors, image is one dimensional (namely, each of them has only one non-zero component) and together they span the two dimensional spinor space. We can choose image and image to be normalized so that we have

image

      For example, we can choose

      such that when p1 = p2 = 0, the helicity spinors simply reduce to eigenstates of σ3. Furthermore, we can also define normalized spinors u(+) and v(+). For example, with the choice of the basis in (3.169), the normalized spinors take the forms (here we are using the three dimensional notation so that pi = (p)i)

      105

      However, we do not need to use any particular representation for our discussions. In general, the positive helicity spinors satisfy

      which can be checked from the explicit forms of the spinors in (3.170). Here we note that the second relation follows from the fact that a positive helicity spinor changes into an orthogonal negative helicity spinor when the direction of the momentum is reversed (which is also manifest in the projection operators in (3.162)).

      Given the form of the right-handed spinors in (3.161), together with (3.171), it now follows in a straightforward manner that

      The completeness relation in (3.172) can be simplified by noting the following identity. We note that with p0 = |p|, we can write

image

      so that we can write the completeness relation in (3.172) as

image

      which can also be derived using the methods in section 3.4. We conclude this section by noting (without going into details) that similar relations can be derived for the left-handed spinors and take the forms

image

      Let us recall that the positive energy solutions of the Dirac equation have the form (see (2.49))

      while the negative energy solutions have the form

      In (3.176) we have defined

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