In mathematics the spin group, denoted Spin(n),[1] [2] is a Lie group whose underlying manifold is the double cover of the special orthogonal group, such that there exists a short exact sequence of Lie groups (when)
1\toZ2\to\operatorname{Spin}(n)\to\operatorname{SO}(n)\to1.
The group multiplication law on the double cover is given by lifting the multiplication on
\operatorname{SO}(n)
As a Lie group, Spin(n) therefore shares its dimension,, and its Lie algebra with the special orthogonal group.
For, Spin(n) is simply connected and so coincides with the universal cover of SO(n).
The non-trivial element of the kernel is denoted −1, which should not be confused with the orthogonal transform of reflection through the origin, generally denoted −.
Spin(n) can be constructed as a subgroup of the invertible elements in the Clifford algebra Cl(n). A distinct article discusses the spin representations.
The spin group is used in physics to describe the symmetries of (electrically neutral, uncharged) fermions. Its complexification, Spinc, is used to describe electrically charged fermions, most notably the electron. Strictly speaking, the spin group describes a fermion in a zero-dimensional space; however, space is not zero-dimensional, and so the spin group is used to define spin structures on (pseudo-)Riemannian manifolds: the spin group is the structure group of a spinor bundle. The affine connection on a spinor bundle is the spin connection; the spin connection can simplify calculations in general relativity. The spin connection in turn enables the Dirac equation to be written in curved spacetime (effectively in the tetrad coordinates), which in turn provides a footing for quantum gravity, as well as a formalization of Hawking radiation (where one of a pair of entangled, virtual fermions falls past the event horizon, and the other does not).
Construction of the Spin group often starts with the construction of a Clifford algebra over a real vector space V with a definite quadratic form q.[3] The Clifford algebra is the quotient of the tensor algebra TV of V by a two-sided ideal. The tensor algebra (over the reals) may be written as
TV=R ⊕ V ⊕ (V ⊗ V) ⊕ …
The Clifford algebra Cl(V) is then the quotient algebra
\operatorname{Cl}(V)=TV/\left(v ⊗ v-q(v)\right),
q(v)
v\inV
\operatorname{Cl}(V)=\operatorname{Cl}0 ⊕ \operatorname{Cl}1 ⊕ \operatorname{Cl}2 ⊕ … ⊕ \operatorname{Cl}n
n
V
\operatorname{Cl}0=R
\operatorname{Cl}1=V
ak{spin}
\operatorname{Cl}2=ak{spin}(V)=ak{spin}(n),
ak{so}(n)
\operatorname{Pin}(V)
\operatorname{Cl}(V)
v1v2 … vk,
vi\inV
q(vi)=1.
The spin group is then defined as
\operatorname{Spin}(V)=\operatorname{Pin}(V)\cap\operatorname{Cl}even,
\operatorname{Cl}even=\operatorname{Cl}0 ⊕ \operatorname{Cl}2 ⊕ \operatorname{Cl}4 ⊕ …
If the set
\{ei\}
eiej=-ejei
i\nej,
v ⊗ v
v=ei+ej
The spin groups can be constructed less explicitly but without appealing to Clifford algebras. As a manifold,
\operatorname{Spin}(n)
\operatorname{SO}(n)
p:\operatorname{Spin}(n) → \operatorname{SO}(n)
p-1(\{e\})
\tildee
\operatorname{Spin}(n)
a,b\in\operatorname{Spin}(n)
\gammaa,\gammab
\gammaa(0)=\gammab(0)=\tildee
\gammaa(1)=a,\gammab(1)=b
\gamma
\operatorname{SO}(n)
\gamma(t)=p(\gammaa(t)) ⋅ p(\gammab(t))
\gamma(0)=e
\operatorname{Spin}(n)
\tilde\gamma
\gamma
\tilde\gamma(0)=\tildee
a ⋅ b=\tilde\gamma(1)
It can then be shown that this definition is independent of the paths
\gammaa,\gammab
\operatorname{Spin}(n)
For a quadratic space V, a double covering of SO(V) by Spin(V) can be given explicitly, as follows. Let
\{ei\}
t:\operatorname{Cl}(V)\to\operatorname{Cl}(V)
\left(eiej …
| t | |
| e | |
| k\right) |
=ek … ejei.
a,b\in\operatorname{Cl}(V)
(ab)t=btat.
Observe that Pin(V) can then be defined as all elements
a\in\operatorname{Cl}(V)
aat=1.
Now define the automorphism
\alpha\colon\operatorname{Cl}(V)\to\operatorname{Cl}(V)
\alpha(v)=-v, v\inV,
a*
\alpha(a)t
\operatorname{Pin}(V)\to\operatornameO(V)
\rho(a)v=ava*,
v\inV
a\inV
\rho(a)
This gives a double covering of both O(V) by Pin(V) and of SO(V) by Spin(V) because
a
-a
It is worth reviewing how spinor space and Weyl spinors are constructed, given this formalism. Given a real vector space V of dimension an even number, its complexification is
V ⊗ C
W
\overline{W}
V ⊗ C=W ⊕ \overline{W}
The space
W
ηk=\left(e2k-1-ie2k\right)/\sqrt2
1\lek\lem
\overline{W}
style{wedge}W
W
1\toZ2\to\operatorname{Spin}C(n)\to\operatorname{SO}(n) x \operatorname{U}(1)\to1.
\operatorname{Cl}(V) ⊗ C
\operatorname{Spin}C(V)=\left(\operatorname{Spin}(V) x S1\right)/\sim
\sim
This has important applications in 4-manifold theory and Seiberg–Witten theory. In physics, the Spin group is appropriate for describing uncharged fermions, while the SpinC group is used to describe electrically charged fermions. In this case, the U(1) symmetry is specifically the gauge group of electromagnetism.
In low dimensions, there are isomorphisms among the classical Lie groups called exceptional isomorphisms. For instance, there are isomorphisms between low-dimensional spin groups and certain classical Lie groups, owing to low-dimensional isomorphisms between the root systems (and corresponding isomorphisms of Dynkin diagrams) of the different families of simple Lie algebras. Writing R for the reals, C for the complex numbers, H for the quaternions and the general understanding that Cl(n) is a short-hand for Cl(Rn) and that Spin(n) is a short-hand for Spin(Rn) and so on, one then has that[3]
Cleven(1) = R the real numbers
Pin(1) =
Spin(1) = O(1) = the orthogonal group of dimension zero.--
Cleven(2) = C the complex numbers
Spin(2) = U(1) = SO(2), which acts on z in R2 by double phase rotation . Corresponds to the abelian
D1
Cleven(3) = H the quaternions
Spin(3) = Sp(1) = SU(2), corresponding to
B1\congC1\congA1
Cleven(4) = H ⊕ H
Spin(4) = SU(2) × SU(2), corresponding to
D2\congA1 x A1
Cleven(5)= M(2, H) the two-by-two matrices with quaternionic coefficients
Spin(5) = Sp(2), corresponding to
B2\congC2
Cleven(6)= M(4, C) the four-by-four matrices with complex coefficients
Spin(6) = SU(4), corresponding to
D3\congA3
There are certain vestiges of these isomorphisms left over for (see Spin(8) for more details). For higher n, these isomorphisms disappear entirely.
In indefinite signature, the spin group is constructed through Clifford algebras in a similar way to standard spin groups. It is a double cover of, the connected component of the identity of the indefinite orthogonal group . For, is connected; for there are two connected components.[4] As in definite signature, there are some accidental isomorphisms in low dimensions:
Spin(1, 1) = GL(1, R)
Spin(2, 1) = SL(2, R)
Spin(3, 1) = SL(2, C)
Spin(2, 2) = SL(2, R) × SL(2, R)
Spin(4, 1) = Sp(1, 1)
Spin(3, 2) = Sp(4, R)
Spin(5, 1) = SL(2, H)
Spin(4, 2) = SU(2, 2)
Spin(3, 3) = SL(4, R)
Spin(6, 2) = SU(2, 2, H)
Note that .
Connected and simply connected Lie groups are classified by their Lie algebra. So if G is a connected Lie group with a simple Lie algebra, with G′ the universal cover of G, there is an inclusion
\pi1(G)\subset\operatorname{Z}(G'),
with Z(G′) the center of G′. This inclusion and the Lie algebra
ak{g}
ak{g}
The definite signature Spin(n) are all simply connected for n > 2, so they are the universal coverings of SO(n).
In indefinite signature, Spin(p, q) is not necessarily connected, and in general the identity component, Spin0(p, q), is not simply connected, thus it is not a universal cover. The fundamental group is most easily understood by considering the maximal compact subgroup of SO(p, q), which is SO(p) × SO(q), and noting that rather than being the product of the 2-fold covers (hence a 4-fold cover), Spin(p, q) is the "diagonal" 2-fold cover – it is a 2-fold quotient of the 4-fold cover. Explicitly, the maximal compact connected subgroup of Spin(p, q) is
Spin(p) × Spin(q)/.
This allows us to calculate the fundamental groups of SO(p, q), taking p ≥ q:
\pi1(SO(p,q))=\begin{cases} 0&(p,q)=(1,1)or(1,0)\\ Z2&p>2,q=0,1\\ Z&(p,q)=(2,0)or(2,1)\\ Z x Z&(p,q)=(2,2)\\ Z&p>2,q=2\\ Z2&p,q>2\\ \end{cases}
Thus once the fundamental group is Z2, as it is a 2-fold quotient of a product of two universal covers.
The maps on fundamental groups are given as follows. For, this implies that the map is given by going to . For, this map is given by . And finally, for, is sent to and is sent to .
The fundamental groups
\pi1(\operatorname{SO}(n))
\pi1(\operatorname{SO}(n))
n>3
SO(1)
SO(2)\congS1
SO(3)\congRP3
The proof uses known results in algebraic topology.[5]
The same argument can be used to show\pi(SO(1,n)\uparrow)\cong\pi(SO(n))
Hn
SO(1,n)\uparrow
The center of the spin groups, for, (complex and real) are given as follows:
\begin{align} \operatorname{Z}(\operatorname{Spin}(n,C))&=\begin{cases} Z2&n=2k+1\\ Z4&n=4k+2\\ Z2 ⊕ Z2&n=4k\\ \end{cases}\\ \operatorname{Z}(\operatorname{Spin}(p,q))&=\begin{cases} Z2&porqodd\\ Z4&n=4k+2,andp,qeven\\ Z2 ⊕ Z2&n=4k,andp,qeven\\ \end{cases} \end{align}
Quotient groups can be obtained from a spin group by quotienting out by a subgroup of the center, with the spin group then being a covering group of the resulting quotient, and both groups having the same Lie algebra.
Quotienting out by the entire center yields the minimal such group, the projective special orthogonal group, which is centerless, while quotienting out by yields the special orthogonal group – if the center equals (namely in odd dimension), these two quotient groups agree. If the spin group is simply connected (as Spin(n) is for), then Spin is the maximal group in the sequence, and one has a sequence of three groups,
Spin(n) → SO(n) → PSO(n),splitting by parity yields:
Spin(2n) → SO(2n) → PSO(2n),
ak{so}(n,R).
The homotopy groups of the cover and the quotient are related by the long exact sequence of a fibration, with discrete fiber (the fiber being the kernel) – thus all homotopy groups for are equal, but π0 and π1 may differ.
For, Spin(n) is simply connected (is trivial), so SO(n) is connected and has fundamental group Z2 while PSO(n) is connected and has fundamental group equal to the center of Spin(n).
In indefinite signature the covers and homotopy groups are more complicated – Spin(p, q) is not simply connected, and quotienting also affects connected components. The analysis is simpler if one considers the maximal (connected) compact and the component group of .
The spin group appears in a Whitehead tower anchored by the orthogonal group:
\ldots → Fivebrane(n) → String(n) → Spin(n) → SO(n) → O(n)
The tower is obtained by successively removing (killing) homotopy groups of increasing order. This is done by constructing short exact sequences starting with an Eilenberg - MacLane space for the homotopy group to be removed. Killing the 3 homotopy group in Spin(n), one obtains the infinite-dimensional string group String(n).
Discrete subgroups of the spin group can be understood by relating them to discrete subgroups of the special orthogonal group (rotational point groups).
Given the double cover, by the lattice theorem, there is a Galois connection between subgroups of Spin(n) and subgroups of SO(n) (rotational point groups): the image of a subgroup of Spin(n) is a rotational point group, and the preimage of a point group is a subgroup of Spin(n), and the closure operator on subgroups of Spin(n) is multiplication by . These may be called "binary point groups"; most familiar is the 3-dimensional case, known as binary polyhedral groups.
Concretely, every binary point group is either the preimage of a point group (hence denoted 2G, for the point group G), or is an index 2 subgroup of the preimage of a point group which maps (isomorphically) onto the point group; in the latter case the full binary group is abstractly
C2 x G
Z2k+1
C4k+2\congZ2k+1 x Z2,
Of particular note are two series:
For point groups that reverse orientation, the situation is more complicated, as there are two pin groups, so there are two possible binary groups corresponding to a given point group.