We review the description of inclusive single unpolarized light hadron production using fragmentation functions in the framework of the factorization theorem. We summarize the factorization of quantities into perturbatively calculable quantities and these universal fragmentation functions, and then discuss some improvements beyond the standard fixed order approach. We discuss the extraction of fragmentation functions for light charged (π ± , K ± and p/p) and neutral (K 0 S and Λ/Λ) hadrons using these theoretical tools through global fits to experimental data from reactions at various colliders, in particular from accurate e + e − reactions at LEP, and the subsequent successful predictions of other experimental data, such as data gathered at HERA, the Tevatron and RHIC from these fitted fragmentation functions as allowed by factorization universality. These global fits also impose competitive constraints on αs(MZ). Emphasis is placed on the need for accurate data from ep and pp(p) reactions in which the hadron species is identified in order to constrain the separate fragmentation functions of each quark flavour and hadron species. 65 A.1. Twist expansion 66 A.2. The modern approach to factorization 68 A.3. Connection with the older approach to factorization 70 A.4. Treatment of non partonic quarks 71 A.5. Matching conditions 72 3 A.6. Open issues 73 B. Leading order splitting functions 73 C. Mellin space 74 D. Summary of inclusive single hadron production measurements 76 D.1. e + e − reactions 76 D.2. pp(p) reactions 79References 79up to higher twist terms, which are suppressed relative to the overall cross section by a factor O(Λ QCD /E s ) or more. The parton label i = 0 for the gluon, while i = (−)I for (anti)quarks, where I = 1, . . . , 6 corresponds respectively to the flavours d, u, s, c, b and t. The fact that n f = 6 necessarily will be explained below. m i is a renormalization scheme-dependent mass associated with parton i, which will be taken to be its pole mass, and a s = α s /(2π) is the expansion parameter in perturbative series. The dσ i are the equivalent partonic cross sections obtained by replacing the detected hadron h with a real on-shell parton i moving in the same direction but with momentum p h /z, and the sum over unobserved hadrons replaced with a sum over unobserved partons. In e.g. e + e − → h + X, dσ i is completely calculable in perturbation theory, while for processes involving initial state hadrons, such as ep → e + h + X at HERA and pp(p) → h + X at the LHC (RHIC), dσ i will be convolutions of perturbatively calculable quantities with PDFs for each initial state hadron, a result which also follows from the factorization theorem. The dσ i are otherwise perturbatively calculable if all subprocesses with energy scale below some arbitrary factorization scale M f ≫ Λ QCD are factored out of them and into the FFs D h i (and PDFs if applicable) according to the factorization theorem. While the dσ i differ from process to process, the FFs are universal and therefore, through them, measureme...
