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In quantum mechanics
Quantum mechanics

Quantum mechanics is a set of principles underlying the most fundamental known description of all physical systems at the microscopic scale . Notable amongst these principles are both a dual wave-like and particle-like behavior of matter and radiation, and prediction of probabilities in situations where classical physics predicts certaintie...
, the Hamiltonian H is the observable
Observable

In physics, particularly in quantum physics, a system observable is a property of the State that can be determined by some sequence of physical operational definition....
 corresponding to the total energy of the system. As with all observables, the spectrum
Spectrum (functional analysis)

In functional analysis, the concept of the spectrum of an operator is a generalisation of the concept of eigenvalues for matrices.Operators on infinite-dimensional spaces may have no eigenvalues....
 of the Hamiltonian
Hamiltonian

Hamiltonian may refer toIn mathematics:* Hamiltonian system* Hamiltonian path, in graph theory* Hamiltonian group, in group theory* Hamiltonian ...
 is the set of possible outcomes when one measures the total energy of a system. Like any other self-adjoint operator
Self-adjoint operator

In mathematics, on a finite-dimensional inner product space, a self-adjoint operator is one that is its own Adjoint of an operator, or, equivalently, one whose matrix is Hermitian matrix, where a Hermitian matrix is one which is equal to its own conjugate transpose....
, the spectrum of the Hamiltonian can be decomposed
Decomposition of spectrum (functional analysis)

In mathematics, especially functional analysis, the spectrum of an operator generalizes the notion of eigenvalues. Given an operator, it is sometimes useful to break up the spectrum into various parts....
, via its spectral measure
Projection-valued measure

In mathematics, particularly functional analysis a projection-valued measure is a function defined on certain subsets of a fixed set and whose values are self-adjoint projections on a Hilbert space....
s, into pure point, absolutely continuous, and singular parts. The pure point spectrum can be associated to eigenvectors, which in turn are the bound state
Bound state

In physics, a bound state is a composite of two or more building blocks that behaves as a single object. In quantum mechanics , a bound state is a state in the Hilbert space that corresponds to two or more particles whose interaction energy is negative, and therefore these particles cannot be separated unless energy is spent....
s of the system.






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In quantum mechanics
Quantum mechanics

Quantum mechanics is a set of principles underlying the most fundamental known description of all physical systems at the microscopic scale . Notable amongst these principles are both a dual wave-like and particle-like behavior of matter and radiation, and prediction of probabilities in situations where classical physics predicts certaintie...
, the Hamiltonian H is the observable
Observable

In physics, particularly in quantum physics, a system observable is a property of the State that can be determined by some sequence of physical operational definition....
 corresponding to the total energy of the system. As with all observables, the spectrum
Spectrum (functional analysis)

In functional analysis, the concept of the spectrum of an operator is a generalisation of the concept of eigenvalues for matrices.Operators on infinite-dimensional spaces may have no eigenvalues....
 of the Hamiltonian
Hamiltonian

Hamiltonian may refer toIn mathematics:* Hamiltonian system* Hamiltonian path, in graph theory* Hamiltonian group, in group theory* Hamiltonian ...
 is the set of possible outcomes when one measures the total energy of a system. Like any other self-adjoint operator
Self-adjoint operator

In mathematics, on a finite-dimensional inner product space, a self-adjoint operator is one that is its own Adjoint of an operator, or, equivalently, one whose matrix is Hermitian matrix, where a Hermitian matrix is one which is equal to its own conjugate transpose....
, the spectrum of the Hamiltonian can be decomposed
Decomposition of spectrum (functional analysis)

In mathematics, especially functional analysis, the spectrum of an operator generalizes the notion of eigenvalues. Given an operator, it is sometimes useful to break up the spectrum into various parts....
, via its spectral measure
Projection-valued measure

In mathematics, particularly functional analysis a projection-valued measure is a function defined on certain subsets of a fixed set and whose values are self-adjoint projections on a Hilbert space....
s, into pure point, absolutely continuous, and singular parts. The pure point spectrum can be associated to eigenvectors, which in turn are the bound state
Bound state

In physics, a bound state is a composite of two or more building blocks that behaves as a single object. In quantum mechanics , a bound state is a state in the Hilbert space that corresponds to two or more particles whose interaction energy is negative, and therefore these particles cannot be separated unless energy is spent....
s of the system. The absolutely continuous spectrum corresponds to the free states. The singular spectrum, interestingly enough, comprises physically impossible outcomes. For example, consider the finite potential well, which admits bound states with discrete negative energies and free states with continuous positive energies.

Schrödinger equation

The Hamiltonian generates the time
Time

Time is a component of the measurement used to sequence events, to compare the durations of events and the intervals between them, and to quantify the motions of objects....
 evolution of quantum states. If is the state of the system at time t, then

.

where is the reduced Planck constant
Planck constant

The Planck constant , also called Planck's constant, is a physical constant used to describe the sizes of quantum in quantum mechanics. It is named after Max Planck, one of the founders of quantum theory....
 . This equation is known as the Schrödinger equation
Schrödinger equation

In physics, especially quantum mechanics, the Schr?dinger equation is an equation that describes how the quantum state of a physical system changes in time....
. (It takes the same form as the Hamilton-Jacobi equation, which is one of the reasons H is also called the Hamiltonian.) Given the state at some initial time (t = 0), we can integrate it to obtain the state at any subsequent time. In particular, if H is independent of time, then

.

Note: In introductory physics literature, the following is often taken as an assumption:

The eigenkets (eigenvectors) of H, denoted (using Dirac bra-ket notation
Bra-ket notation

Bra-ket notation is a standard notation for describing quantum states in the theory of quantum mechanics composed of bracket and vertical bars....
), provide an orthonormal basis
Orthonormal basis

In mathematics, an orthonormal basis of an inner product space V , is a set of mutually orthogonality vectors of magnitude 1 that span the space when infinite linear combinations are allowed....
 for the Hilbert space
Hilbert space

The mathematics concept of a Hilbert space, named after David Hilbert, generalizes the notion of Euclidean space. It extends the methods of vector algebra from the two-dimensional plane and three-dimensional space to infinite-dimensional spaces....
. The spectrum of allowed energy levels of the system is given by the set of eigenvalues, denoted , solving the equation:


.


Since H is a Hermitian operator, the energy is always a real number
Real number

In mathematics, the real numbers may be described informally in several different ways. The real numbers include both rational numbers, such as 42 and −23/129, and irrational numbers, such as pi and the square root of two; or, a real number can be given by an infinite decimal representation, such as 2.4871773339...., where the digits co...
.


From a mathematically rigorous point of view, care must be taken with the above assumption. Operators on infinite-dimensional Hilbert spaces need not have eigenvalues (the set of eigenvalues does not necessarily coincide with the spectrum of an operator). However, all routine quantum mechanical calculations can be done using the physical formulation.

Similarly, the exponential operator on the right hand side of the Schrödinger equation is sometimes defined by the power series
Exponential function

The exponential function is a function in mathematics. The application of this function to a value x is written as exp. Equivalently, this can be written in the form ex, where e is the mathematical constant that is the base of the natural logarithm and that is also known as Euler's number....
. One might notice that taking polynomials of unbounded and not everywhere defined operators may not make mathematical sense, much less power series. Rigorously, to take functions of unbounded operators, a functional calculus
Functional calculus

In mathematics, a functional calculus is a theory allowing one to apply mathematical functions to mathematical operators. The term was also used previously to refer to the calculus of variations....
 is required. In the case of the exponential function, the continuous
Continuous functional calculus

In mathematics, the continuous functional calculus of operator theory and C*-algebra theory allows applications of continuous functions to normal elements of a C*-algebra....
, or just the holomorphic functional calculus
Holomorphic functional calculus

In mathematics, holomorphic functional calculus is functional calculus with holomorphic functions. That is to say, given a holomorphic function ƒ of a complex number argument z and an operator T, the aim is to construct an operator...
 suffices. We note again, however, that for common calculations the physicist's formulation is quite sufficient.

By the *-homomorphism
Homomorphism

In abstract algebra, a homomorphism is a structure-preserving map between two algebraic structures . The word homomorphism comes from the Greek language: ???? meaning "same" and ???f? meaning "shape"....
 property of the functional calculus, the operator

is a unitary operator
Unitary operator

In functional analysis, a branch of mathematics, a unitary operator is a bounded linear operator U : H ? H on a Hilbert space H satisfying...
. It is the time evolution
Time evolution

Time evolution is the change of state brought about by the passage of time, applicable to systems with internal state . In this formulation, time is not required to be a continuous parameter, but may be discrete time or even wiktionary:finite....
 operator, or propagator, of a closed quantum system. If the Hamiltonian is time-independent, form a one parameter unitary group
Stone's theorem on one-parameter unitary groups

In mathematics, Stone's theorem on one-parameter group unitary groups is a basic theorem of functional analysis which establishes a one-to-one correspondence between self-adjoint operators on a Hilbert space H and one-parameter families of unitary operators...
 (more than a semigroup); this gives rise to the physical principle of detailed balance
Detailed balance

In mathematics and statistical mechanics, a Markov process is said to show detailed balance if the transition rates between each pair of states i and j in the state space obey...
.

Energy eigenket degeneracy, symmetry, and conservation laws


In many systems, two or more energy eigenstates have the same energy. A simple example of this is a free particle, whose energy eigenstates have wavefunctions that are propagating plane waves. The energy of each of these plane waves is inversely proportional to the square of its wavelength
Wavelength

In physics, wavelength is the distance between repeating units of a propagating wave of a given frequency. It is commonly designated by the Greek language letter lambda ....
. A wave propagating in the x direction is a different state from one propagating in the y direction, but if they have the same wavelength, then their energies will be the same. When this happens, the states are said to be degenerate.

It turns out that degeneracy occurs whenever a nontrivial unitary operator
Unitary matrix

In mathematics, a unitary matrix is an n by n complex number matrix U satisfying the condition where is the identity matrix and is the conjugate transpose of U....
 U commutes with the Hamiltonian. To see this, suppose that |a> is an energy eigenket. Then U|a> is an energy eigenket with the same eigenvalue, since

Since U is nontrivial, at least one pair of and must represent distinct states. Therefore, H has at least one pair of degenerate energy eigenkets. In the case of the free particle, the unitary operator which produces the symmetry is the rotation operator
Rotation operator

This article concerns the rotation operator, as it appears in quantum mechanics....
, which rotates the wavefunctions by some angle while otherwise preserving their shape.

The existence of a symmetry operator implies the existence of a conserved
Conservation law

In physics, a conservation law states that a particular measurable property of an isolated physical system does not change as the system evolves....
 observable. Let G be the Hermitian generator of U:

It is straightforward to show that if U commutes with H, then so does G:

Therefore,

In obtaining this result, we have used the Schrödinger equation, as well as its dual
Bra-ket notation

Bra-ket notation is a standard notation for describing quantum states in the theory of quantum mechanics composed of bracket and vertical bars....
,

Thus, the expected value
Expected value

In probability theory and statistics, the expected value of a random variable is the Lebesgue integral of the random variable with respect to its probability measure....
 of the observable G is conserved for any state of the system. In the case of the free particle, the conserved quantity is the angular momentum
Angular momentum

In physics, the angular momentum of a particle about an origin is a vector quantity related to rotation, equal to the mass of the particle multiplied by the cross product of the position vector of the particle with its velocity vector....
.

Hamilton's equations


Hamilton's equations in classical Hamiltonian mechanics
Hamiltonian mechanics

Hamiltonian mechanics is a reformulation of classical mechanics that was introduced in 1833 by Irish mathematician William Rowan Hamilton. It arose from Lagrangian mechanics, a previous reformulation of classical mechanics introduced by Joseph Louis Lagrange in 1788, but can be formulated without recourse to Lagrangian mechanics using sym...
 have a direct analogy in quantum mechanics. Suppose we have a set of basis states , which need not necessarily be eigenstates of the energy. For simplicity, we assume that they are discrete, and that they are orthonormal, i.e.,

Note that these basis states are assumed to be independent of time. We will assume that the Hamiltonian is also independent of time.

The instantaneous state of the system at time t, , can be expanded in terms of these basis states:

where

The coefficients an(t) are complex
Complex number

In mathematics, the complex numbers are an extension of the real numbers obtained by adjoining an imaginary unit, denoted i, which satisfies:...
 variables. We can treat them as coordinates which specify the state of the system, like the position and momentum coordinates which specify a classical system. Like classical coordinates, they are generally not constant in time, and their time dependence gives rise to the time dependence of the system as a whole.

The expectation value of the Hamiltonian of this state, which is also the mean energy, is

where the last step was obtained by expanding in terms of the basis states.

Each of the an(t)s actually corresponds to two independent degrees of freedom, since the variable has a real part and an imaginary part. We now perform the following trick: instead of using the real and imaginary parts as the independent variables, we use an(t) and its complex conjugate
Complex conjugate

In mathematics, the complex conjugate of a complex number is given by changing the sign of the imaginary part. Thus, the conjugate of the complex number...
 an*(t). With this choice of independent variables, we can calculate the partial derivative
Partial derivative

In mathematics, a partial derivative of a function of several variables is its derivative with respect to one of those variables with the others held constant ....


By applying Schrödinger's equation and using the orthonormality of the basis states, this further reduces to

Similarly, one can show that

If we define "conjugate momentum" variables pn by

then the above equations become

which is precisely the form of Hamilton's equations, with the s as the generalized coordinates, the s as the conjugate momenta, and taking the place of the classical Hamiltonian.

See also

  • Hamiltonian mechanics
    Hamiltonian mechanics

    Hamiltonian mechanics is a reformulation of classical mechanics that was introduced in 1833 by Irish mathematician William Rowan Hamilton. It arose from Lagrangian mechanics, a previous reformulation of classical mechanics introduced by Joseph Louis Lagrange in 1788, but can be formulated without recourse to Lagrangian mechanics using sym...