The total spin of the hadrons can be determined trivially by simply adding up the 1/2 spins of its valence quarks, with possible plus and minus values for each one. Each combination of plus or minus 1/2 spins adds up to a total spin, and each possible sum of spins for the valence quarks equals the possible total spins of hadrons with those valence quarks. Minimal values for a set of valence quarks are more stable, so protons and neutrons having a minimal possible combination of spins (i.e. they have spin 1/2 equal to 1/2 + 1/2 -1/2) since it is stable. All non-minimal spin sums are unstable hadrons
Surprisingly, however, this simple formula, however, doesn't reflect the actual spin of the full array of valence quarks, sea quarks, and gluons that add up to spin-1/2 in an actual proton. Reality gets to the same result, but in a much more complicated way.
A new PhD dissertation (250 pages) exhaustively examines this puzzle and uses a novel method to try to solve it with a formula (i.e. analytically) rather than with a numerical approximation, extrapolating down to the 3 color, 6 flavor reality, from more complex models with larger numbers of colors and flavors.
The proton spin puzzle denotes the challenge of describing the proton's spin in terms of the angular momenta of the quarks and gluons which comprise it. These quarks and gluons carry a fraction x of the proton's momentum. Contributions from small-x quarks and gluons, which only possess a little of the proton's momentum, are difficult to measure, since this requires very high energy experiments. Furthermore, early theoretical work in the 1990s predicted substantial contributions to the proton spin from these small-x particles. We need theoretical control over this corner of phase space in order to resolve the spin puzzle.In this dissertation, we build upon an existing framework for studying spin at small-x. Previously, several sets of small-x evolution equations were derived in this formalism -- one in the large-N(c) limit and one in the large-N(c) & N(f) limit. Here N(c) and N(f) are the numbers of quark colors and flavors [ed. there are three colors, three anti-colors, and six flavors in the Standard Model]. These equations were numerically solved but no analytic solutions had been found. In this dissertation we detail the construction of such analytic solutions, first in the large-N(c) limit and then in the large-N(c) & N(f) limit, after deriving an important correction to the existing large-N(c) & N(f) equations due to the contributions of quark-to-gluon transition operators.From the solutions constructed here, we can predict the behavior of the quark and gluon helicity distributions at asymptotically small-x (and large-N(c) or large- N(c) & N(f)), both as a general power law and further as explicit analytic expressions in the asymptotic limit. Our solutions also allow us to predict all four polarized DGLAP anomalous dimensions in the same limits, yielding expressions exact to all orders in the strong coupling. The expansions of our predictions agree completely with the full extent of existing finite-order calculations, to three loops.