It had been naively believed that the quark sea in the proton was formed by
quantum chromodynamics (QCD) processes that did not discriminate between up and down quarks. However, results of deep inelastic scattering of high energy
muons on a proton and a
deuteron targets by CERN-NMC showed that there are more 's than 's in the proton. The Gottfried sum measured by NMC was 0.235±0.026, which is significantly smaller than the
expected value of 1/3. This means that (
x)-(
x) integrated over Bjorken
x from 0 to 1.0 is 0.147±0.039, indicating a flavor asymmetry in the proton sea. Recent measurements using Drell–Yan scattering probed the flavor asymmetry of the proton. To
leading order in the strong interaction coupling constant, αs, the Drell-Yan cross section is given by \frac{d^2 \sigma}{dx_1 dx_2} = \frac{4\pi \alpha}{9sx_1 x_2}\sum_{i\in u,d,s,\cdots} e_i^2 \left[q_i^A(x_1)\bar{q}^B_i(x_2) + \bar{q}_i^A(x_1)q^B_i(x_2) \right] where \alpha is the
fine-structure constant, s is the center-of-mass energy squared, e_i is the charge of quark with flavor i, and q_i^{A,B} (x_{1,2} ) denote the
parton distribution function of in hadron A and hadron B, with momentum x_1 and x_2, respectively. Similarly \bar{q}_i^{A,B} (x_{1,2} ) denotes the antiquark distributions. Using the
isospin symmetry, the parton distribution functions for proton and neutron are related as follows: \begin{align} u(x) &\equiv u^p(x) = d^n (x) \\ d(x) &\equiv d^p(x) = u^n (x) \\ \bar{u}(x) &\equiv \bar{u}^p(x) = \bar{d}^n(x) \\ \bar{d}(x) &\equiv d^p(x) = \bar{u}^n(x) \\ \end{align} Therefore, the proton on deuterium over proton on hydrogen Drell-Yan cross section can be written as \begin{align} \frac{\sigma^{pd}}{2\sigma^{pp}} &= \frac{\sigma^{pn}+\sigma^{pp}}{2\sigma^{pp}}\\ & =\frac{1}{2} \left[1+ \frac{4u(x_1)\bar{d}(x_2) + d(x_1)\bar{u}(x_2)}{4u(x_1)\bar{u}(x_2) + d(x_1)\bar{d}(x_2)}\right] \end{align} Using the fact that there are more u quarks in proton, this ratio can be approximated as : \frac{\sigma^{pd}}{2\sigma^{pp}} \approx \frac{1}{2}\left[1+ \frac{\bar{d}(x_2)}{\bar{u}(x_2)}\right] where \bar{d}(x) and \bar{u}(x) are the anti-down and anti-up quark distributions in the
proton sea and x is the Bjorken-x scaling variable (the momentum fraction of the target quark in the
parton model). ==Z boson production ==