quantum mechanics Quantum mechanics is a fundamental theory in physics that provides a description of the physical properties of nature at the scale of atoms and subatomic particles. It is the foundation of all quantum physics including quantum chemistry, ...

and its applications to quantum many-particle systems, notably

quantum chemistry Quantum chemistry, also called molecular quantum mechanics, is a branch of physical chemistry focused on the application of quantum mechanics to chemical systems, particularly towards the quantum-mechanical calculation of electronic contributions ...

, angular momentum diagrams, or more accurately from a mathematical viewpoint angular momentum graphs, are a diagrammatic method for representing

angular momentum In physics, angular momentum (rarely, moment of momentum or rotational momentum) is the rotational analog of linear momentum. It is an important physical quantity because it is a conserved quantity—the total angular momentum of a closed syst ...

quantum state In quantum physics, a quantum state is a mathematical entity that provides a probability distribution for the outcomes of each possible measurement on a system. Knowledge of the quantum state together with the rules for the system's evolution in ...

s of a quantum system allowing calculations to be done symbolically. More specifically, the arrows encode angular momentum states in

bra–ket notation In quantum mechanics, bra–ket notation, or Dirac notation, is used ubiquitously to denote quantum states. The notation uses angle brackets, and , and a vertical bar , to construct "bras" and "kets". A ket is of the form , v \rangle. Mathema ...

and include the abstract nature of the state, such as

tensor product In mathematics, the tensor product V \otimes W of two vector spaces and (over the same field) is a vector space to which is associated a bilinear map V\times W \to V\otimes W that maps a pair (v,w),\ v\in V, w\in W to an element of V \otimes W ...

s and transformation rules. The notation parallels the idea of

Penrose graphical notation In mathematics and physics, Penrose graphical notation or tensor diagram notation is a (usually handwritten) visual depiction of multilinear functions or tensors proposed by Roger Penrose in 1971. A diagram in the notation consists of several sha ...

and

Feynman diagram In theoretical physics, a Feynman diagram is a pictorial representation of the mathematical expressions describing the behavior and interaction of subatomic particles. The scheme is named after American physicist Richard Feynman, who introduc ...

s. The diagrams consist of arrows and vertices with

quantum number In quantum physics and chemistry, quantum numbers describe values of conserved quantities in the dynamics of a quantum system. Quantum numbers correspond to eigenvalues of operators that commute with the Hamiltonian—quantities that can be kno ...

s as labels, hence the alternative term "

graph Graph may refer to: Mathematics *Graph (discrete mathematics), a structure made of vertices and edges **Graph theory, the study of such graphs and their properties *Graph (topology), a topological space resembling a graph in the sense of discre ...

s". The sense of each arrow is related to

Hermitian conjugation In mathematics, specifically in operator theory, each linear operator A on a Euclidean vector space defines a Hermitian adjoint (or adjoint) operator A^* on that space according to the rule :\langle Ax,y \rangle = \langle x,A^*y \rangle, where ...

, which roughly corresponds to time reversal of the angular momentum states (c.f.

Schrödinger equation The Schrödinger equation is a linear partial differential equation that governs the wave function of a quantum-mechanical system. It is a key result in quantum mechanics, and its discovery was a significant landmark in the development of the ...

). The diagrammatic notation is a considerably large topic in its own right with a number of specialized features – this article introduces the very basics. They were developed primarily by Adolfas Jucys (sometimes translated as Yutsis) in the twentieth century.

Equivalence between Dirac notation and Jucys diagrams

Angular momentum states

The

vector of a single particle with total angular momentum quantum number ''j'' and total

magnetic quantum number In atomic physics, the magnetic quantum number () is one of the four quantum numbers (the other three being the principal, azimuthal, and spin) which describe the unique quantum state of an electron. The magnetic quantum number distinguishes th ...

''m'' = ''j'', ''j'' − 1, ..., −''j'' + 1, −''j'', is denoted as a ket . As a diagram this is a ''single''headed arrow. Symmetrically, the corresponding bra is . In diagram form this is a ''double''headed arrow, pointing in the opposite direction to the ket. In each case; *the quantum numbers ''j'', ''m'' are often labelled next to the arrows to refer to a specific angular momentum state, *arrowheads are almost always placed at the middle of the line, rather than at the tip, *equals signs "=" are placed between equivalent diagrams, exactly like for multiple algebraic expressions equal to each other. The most basic diagrams are for kets and bras: Arrows are directed to or from vertices, a state transforming according to: *a

standard representation In mathematics, the classical groups are defined as the special linear groups over the reals , the complex numbers and the quaternions together with special automorphism groups of symmetric or skew-symmetric bilinear forms and Hermitian or ske ...

is designated by an oriented line leaving a vertex, *a contrastandard representation is depicted as a line entering a vertex. As a general rule, the arrows follow each other in the same sense. In the contrastandard representation, the time reversal operator, denoted here by ''T'', is used. It is unitary, which means the

Hermitian conjugate In mathematics, specifically in operator theory, each linear operator A on a Euclidean vector space defines a Hermitian adjoint (or adjoint) operator A^* on that space according to the rule :\langle Ax,y \rangle = \langle x,A^*y \rangle, where ...

''T''^† equals the inverse operator ''T''⁻¹, that is ''T''^† = ''T''⁻¹. Its action on the

position operator In quantum mechanics, the position operator is the operator that corresponds to the position observable of a particle. When the position operator is considered with a wide enough domain (e.g. the space of tempered distributions), its eigenvalues ...

leaves it invariant: :

T \hat T^\dagger = \hat

but the linear

momentum operator In quantum mechanics, the momentum operator is the operator (physics), operator associated with the momentum (physics), linear momentum. The momentum operator is, in the position representation, an example of a differential operator. For the case o ...

becomes negative: :

T \hat T^\dagger = - \hat

and the

spin Spin or spinning most often refers to: * Spinning (textiles), the creation of yarn or thread by twisting fibers together, traditionally by hand spinning * Spin, the rotation of an object around a central axis * Spin (propaganda), an intentionally b ...

operator becomes negative: :

T \hat T^\dagger  = - \hat

Since the orbital

angular momentum operator In quantum mechanics, the angular momentum operator is one of several related operators analogous to classical angular momentum. The angular momentum operator plays a central role in the theory of atomic and molecular physics and other quantum prob ...

is L = x × p, this must also become negative: :

T \hat T^\dagger  = - \hat

and therefore the total angular momentum operator J = L + S becomes negative: :

T \hat T^\dagger  = - \hat

Acting on an eigenstate of angular momentum , it can be shown that: These authors use the theta variant ' for the time reversal operator, here we use ''T''. :

T \left, j,m\right\rangle \equiv \left, T (j,m)\right\rangle  = ^ \left, j,-m\right\rangle

The time-reversed diagrams for kets and bras are: It is important to position the vertex correctly, as forward-time and reversed-time operators would become mixed up.

Inner product

The inner product of two states and is: :

\langle j_2 , m_2 ,  j_1 , m_1 \rangle = \delta_ \delta_

and the diagrams are: For summations over the inner product, also known in this context as a contraction (c.f.

tensor contraction In multilinear algebra, a tensor contraction is an operation on a tensor that arises from the natural pairing of a finite-dimensional vector space and its dual. In components, it is expressed as a sum of products of scalar components of the tens ...

): :

\sum_m \langle j,m ,  j,m \rangle = 2j + 1

it is conventional to denote the result as a closed circle labelled only by ''j'', not ''m'': : AM diagrams inner product contraction

Outer products

The outer product of two states and is an operator: :

\left,  j_2 , m_2 \right\rangle \left\langle j_1 , m_1 \

and the diagrams are: For summations over the outer product, also known in this context as a contraction (c.f.

): :

\begin
\sum_m ,  j,m \rangle \langle j,m ,  & = \sum_m ,  j, -m \rangle \langle j, -m ,  \\
 & = \sum_m ^,  j, -m \rangle \langle j, -m ,  \\
 & = \sum_m ^,  j, -m \rangle \langle j, -m , ^ \\
 & = \sum_m T,  j, m \rangle \langle j, m , T^\dagger 
\end

where the result for ''T'' was used, and the fact that ''m'' takes the set of values given above. There is no difference between the forward-time and reversed-time states for the outer product contraction, so here they share the same diagram, represented as one line without direction, again labelled by ''j'' only and not ''m'': AM diagrams outer product contraction

Tensor products

The tensor product ⊗ of ''n'' states , , ... is written :

\begin
\left, j_1 , m_1 , j_2 , m_2 , ... j_n , m_n \right\rangle & \equiv \left, j_1,m_1\right\rangle\otimes\left, j_2,m_2\right\rangle\otimes\cdots\otimes\left, j_n,m_n\right\rangle \\
 & \equiv \left, j_1,m_1\right\rangle \left, j_2,m_2\right\rangle \cdots \left, j_n,m_n\right\rangle
\end

and in diagram form, each separate state leaves or enters a common vertex creating a "fan" of arrows - ''n'' lines attached to a single vertex. Vertices in tensor products have signs (sometimes called "node signs"), to indicate the ordering of the tensor-multiplied states: *a ''minus'' sign (−) indicates the ordering is ''clockwise'',

\circlearrowright

, and *a ''plus'' sign (+) for ''anticlockwise'',

\circlearrowleft

. Signs are of course not required for just one state, diagrammatically one arrow at a vertex. Sometimes curved arrows with the signs are included to show explicitly the sense of tensor multiplication, but usually just the sign is shown with the arrows left out. For the inner product of two tensor product states: :

\begin
 & \left\langle j'_n , m'_n , ... , j'_2 , m'_2 , j'_1 , m'_1 , j_1 , m_1 , j_2 , m_2 , ... j_n , m_n \right\rangle \\ 
= & \langle j'_n , m'_n ,  ... \langle j'_2 , m'_2,   \langle j'_1 , m'_1 ,  ,  j_1 , m_1 \rangle ,  j_2 , m_2 \rangle ... ,  j_n , m_n \rangle \\
= & \prod_^n \left\langle j'_k , m'_k ,  j_k , m_k \right\rangle 
\end

there are ''n'' lots of inner product arrows:

Examples and applications

*The diagrams are well-suited for

Clebsch–Gordan coefficients In physics, the Clebsch–Gordan (CG) coefficients are numbers that arise in angular momentum coupling in quantum mechanics. They appear as the expansion coefficients of total angular momentum eigenstates in an uncoupled tensor product basis. In ...

. *Calculations with real quantum systems, such as

multielectron atom Every atom is composed of a nucleus and one or more electrons bound to the nucleus. The nucleus is made of one or more protons and a number of neutrons. Only the most common variety of hydrogen has no neutrons. Every solid, liquid, gas, a ...

s and

molecular A molecule is a group of two or more atoms held together by attractive forces known as chemical bonds; depending on context, the term may or may not include ions which satisfy this criterion. In quantum physics, organic chemistry, and bioche ...

systems.

References

* * Wormer and Paldus (2006) provides an in-depth tutorial in angular momentum diagrams. *

Notes

{{Quantum mechanics topics Angular momentum Quantum mechanics