Electric charge Quarks have
fractional electric charge values, either −, or + times the
elementary charge (
e), depending on flavor. Up, charm, and top quarks (collectively referred to as
up-type quarks) have a charge of +
e; down, strange, and bottom quarks (
down-type quarks) have a charge of −
e. Antiquarks have the opposite charge to their corresponding quarks; up-type antiquarks have charges of −
e and down-type antiquarks have charges of +
e. Since the electric charge of a
hadron is the sum of the charges of the constituent quarks, all hadrons have integer charges: the combination of three quarks (baryons), three antiquarks (antibaryons), or a quark and an antiquark (mesons) always results in integer charges. For example, the hadron constituents of atomic nuclei, neutrons and protons, have charges of 0
e and +1
e, respectively; the neutron is composed of two down quarks and one up quark, and the proton of two up quarks and one down quark. Spin can be represented by a
vector whose length is measured in units of the
reduced Planck constant ħ (pronounced "h bar"). For quarks, a measurement of the spin vector
component along any axis can only yield the values + or −; for this reason quarks are classified as
spin- particles. The component of spin along a given axis—by convention the
z axis—is often denoted by an up arrow ↑ for the value + and a down arrow ↓ for the value −, placed after the symbol for flavor. For example, an up quark with a spin of + along the
z axis is denoted by u↑.
Weak interaction of
beta decay of a
neutron into
proton,
electron, and
electron antineutrino via a virtual
boson. Time is flowing upwards. The CKM matrix (discussed below) encodes the probability of this and other quark decays.|alt=A tree diagram consisting mostly of straight arrows. A down quark forks into an up quark and a wavy-arrow W[superscript minus] boson, the latter forking into an electron and reversed-arrow electron antineutrino. A quark of one flavor can transform into a quark of another flavor only through the weak interaction, one of the four
fundamental interactions in particle physics. By absorbing or emitting a
W boson, any up-type quark (up, charm, and top quarks) can change into any down-type quark (down, strange, and bottom quarks) and vice versa. This flavor transformation mechanism causes the
radioactive process of
beta decay, in which a neutron () "splits" into a proton (), an
electron () and an
electron antineutrino () (see picture). This occurs when one of the down quarks in the neutron () decays into an up quark by emitting a
virtual boson, transforming the neutron into a proton (). The boson then decays into an electron and an electron antineutrino. Both beta decay and the inverse process of
inverse beta decay are routinely used in medical applications such as
positron emission tomography (PET) and in experiments involving
neutrino detection. of the weak interactions between the six quarks. The "intensities" of the lines are determined by the elements of the
CKM matrix.|alt=Three balls "u", "c", and "t" noted "up-type quarks" stand above three balls "d", "s", "b" noted "down-type quark". The "u", "c", and "t" balls are vertically aligned with the "d", "s", and b" balls, respectively. Colored lines connect the "up-type" and "down-type" quarks, with the darkness of the color indicating the strength of the weak interaction between the two; The lines "d" to "u", "c" to "s", and "t" to "b" are dark; The lines "c" to "d" and "s" to "u" are grayish; and the lines "b" to "u", "b" to "c", "t" to "d", and "t" to "s" are almost white. While the process of flavor transformation is the same for all quarks, each quark has a preference to transform into the quark of its own generation. The relative tendencies of all flavor transformations are described by a
mathematical table, called the
Cabibbo–Kobayashi–Maskawa matrix (CKM matrix). Enforcing
unitarity, the approximate
magnitudes of the entries of the CKM matrix are: : \begin{bmatrix} |V_\mathrm {ud}| & |V_\mathrm {us}| & |V_\mathrm {ub}| \\ |V_\mathrm {cd}| & |V_\mathrm {cs}| & |V_\mathrm {cb}| \\ |V_\mathrm {td}| & |V_\mathrm {ts}| & |V_\mathrm {tb}| \end{bmatrix} \approx \begin{bmatrix} 0.974 & 0.225 & 0.003 \\ 0.225 & 0.973 & 0.041 \\ 0.009 & 0.040 & 0.999 \end{bmatrix}, where
Vij represents the tendency of a quark of flavor
i to change into a quark of flavor
j (or vice versa). There exists an equivalent weak interaction matrix for leptons (right side of the W boson on the above beta decay diagram), called the
Pontecorvo–Maki–Nakagawa–Sakata matrix (PMNS matrix). Together, the CKM and PMNS matrices describe all flavor transformations, but the links between the two are not yet clear.
Strong interaction and color charge According to
quantum chromodynamics (QCD), quarks possess a property called
color charge. There are three types of color charge, arbitrarily labeled
blue,
green, and
red. Each of them is complemented by an anticolor—
antiblue,
antigreen, and
antired. Every quark carries a color, while every antiquark carries an anticolor. The system of attraction and repulsion between quarks charged with different combinations of the three colors is called
strong interaction, which is mediated by
force carrying particles known as
gluons; this is discussed at length below. The theory that describes strong interactions is called
quantum chromodynamics (QCD). A quark, which will have a single color value, can form a
bound system with an antiquark carrying the corresponding anticolor. The result of two attracting quarks will be color neutrality: a quark with color charge
ξ plus an antiquark with color charge −
ξ will result in a color charge of 0 (or "white" color) and the formation of a
meson. This is analogous to the
additive color model in basic
optics. Similarly, the combination of three quarks, each with different color charges, or three antiquarks, each with different anticolor charges, will result in the same "white" color charge and the formation of a
baryon or
antibaryon. In modern particle physics,
gauge symmetries—a kind of
symmetry group—relate interactions between particles (see
gauge theories). Color
SU(3) (commonly abbreviated to SU(3)c) is the gauge symmetry that relates the color charge in quarks and is the defining symmetry for quantum chromodynamics. Just as the laws of physics are independent of which directions in space are designated
x,
y, and
z, and remain unchanged if the coordinate axes are rotated to a new orientation, the physics of quantum chromodynamics is independent of which directions in three-dimensional color space are identified as blue, red, and green. SU(3)c color transformations correspond to "rotations" in color space (which, mathematically speaking, is a
complex space). Every quark flavor
f, each with subtypes
fB,
fG,
fR corresponding to the quark colors, forms a triplet: a three-component
quantum field that transforms under the fundamental
representation of SU(3)c. The requirement that SU(3)c should be
local—that is, that its transformations be allowed to vary with space and time—determines the properties of the strong interaction. In particular, it implies the existence of
eight gluon types to act as its force carriers.
Mass of proportional volumes.
Proton (gray) and
electron (red) are shown in bottom left corner for scale. Two terms are used in referring to a quark's mass:
current quark mass refers to the mass of a quark by itself, while
constituent quark mass refers to the current quark mass plus the mass of the
gluon particle field surrounding the quark. These masses typically have very different values. Most of a hadron's mass comes from the gluons that bind the constituent quarks together, rather than from the quarks themselves. While gluons are inherently massless, they possess energy—more specifically,
quantum chromodynamics binding energy (QCBE)—and it is this that contributes so greatly to the overall mass of the hadron (see
mass in special relativity). For example, a proton has a mass of approximately , of which the rest mass of its three valence quarks only contributes about ; much of the remainder can be attributed to the field energy of the gluons (see
chiral symmetry breaking). The Standard Model posits that elementary particles derive their masses from the
Higgs mechanism, which is associated to the
Higgs boson. It is hoped that further research into the reasons for the top quark's large mass of ~, almost the mass of a gold atom, might reveal more about the origin of the mass of quarks and other elementary particles.
Size In QCD, quarks are considered to be point-like entities, with no structure. As of 2014, experimental evidence indicates they have no structure greater than 10−4 times the size of a proton, i.e. less than .
Table of properties The following table summarizes the key properties of the six quarks.
Flavor quantum numbers (
isospin (
I3),
charm (
C),
strangeness (
S, not to be confused with spin),
topness (
T), and
bottomness (
B′)) are assigned to certain quark flavors, and denote qualities of quark-based systems and hadrons. The
baryon number (
B) is + for all quarks, as baryons are made of three quarks. For antiquarks, the electric charge (
Q) and all flavor quantum numbers (
B,
I3,
C,
S,
T, and
B′) are of opposite sign. Mass and
total angular momentum (
J; equal to spin for point particles) do not change sign for the antiquarks. == Interacting quarks ==