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In particle physics, the hypercharge (a portmanteau of hyperonic and charge) Y of a particle is a quantum number conserved under the strong interaction. The concept of hypercharge provides a single charge operator that accounts for properties of isospin, electric charge, and flavour. The hypercharge is useful to classify hadrons; the similarly named weak hypercharge has an analogous role in the electroweak interaction.


Hypercharge is one of two quantum numbers of the SU(3) model of hadrons, alongside isospin I3. The isospin alone is sufficient for two quark flavours--namely,
--whereas presently six flavours of quarks are known.

SU(3) weight diagrams (see below) are 2-dimensional with the coordinates referring to two quantum numbers, I3 (also known as Iz), which is the z-component of isospin and Y, which is the hypercharge (the sum of strangeness S, charm C, bottomness B′, topness T, and baryon number B). Mathematically, hypercharge is

Strong interactions conserve hypercharge, but weak interactions do not.

Relation with electric charge and isospin

The Gell-Mann-Nishijima formula relates isospin and electric charge

where I3 is the third component of isospin and Q is the particle's charge.

Isospin creates multiplets of particles whose average charge is related to the hypercharge by:

since the hypercharge is the same for all members of a multiplet, and the average of the I3 values is 0.

SU(3) model in relation to hypercharge

The SU(2) model has multiplets characterized by a quantum number J, which is the total angular momentum. Each multiplet consists of substates with equally-spaced values of Jz, forming a symmetric arrangement seen in atomic spectra and isospin. This formalizes the observation that certain strong baryon decays were not observed, leading to the prediction of the mass, strangeness and charge of the

The SU(3) has supermultiplets containing SU(2) multiplets. SU(3) now needs two numbers to specify all its sub-states which are denoted by ?1 and ?2.

specifies the number of points in the topmost side of the hexagon while specifies the number of points on the bottom side.


  • The nucleon group (protons with Q = +1 and neutrons with Q = 0) have an average charge of +, so they both have hypercharge Y = 1 (baryon number B = +1, S = C = B′ = T = 0). From the Gell-Mann-Nishijima formula we know that proton has isospin I3 = +, while neutron has I3 = -.
  • This also works for quarks: for the up quark, with a charge of +, and an I3 of +, we deduce a hypercharge of , due to its baryon number (since three quarks make a baryon, a quark has a baryon number of ).
  • For a strange quark, with charge -, a baryon number of and strangeness of -1 we get a hypercharge Y = -, so we deduce an I3 = 0. That means that a strange quark makes an isospin singlet of its own (same happens with charm, bottom and top quarks), while up and down constitute an isospin doublet.

Practical obsolescence

Hypercharge was a concept developed in the 1960s, to organize groups of particles in the "particle zoo" and to develop ad hoc conservation laws based on their observed transformations. With the advent of the quark model, it is now obvious that hypercharge Y is the following combination of the numbers of up (nu), down (nd), strange (ns), charm (nc), top (nt) and bottom (nb):

In modern descriptions of hadron interaction, it has become more obvious to draw Feynman diagrams that trace through individual quarks composing the interacting baryons and mesons, rather than counting hypercharge quantum numbers. Weak hypercharge, however, remains of practical use in various theories of the electroweak interaction.


  • Semat, Henry; Albright, John R. (1984). Introduction to Atomic and Nuclear Physics. Chapman and Hall. ISBN 978-0-412-15670-0.

  This article uses material from the Wikipedia page available here. It is released under the Creative Commons Attribution-Share-Alike License 3.0.



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