Half-integer

Rational number equal to an integer plus 1/2

In mathematics, a half-integer is a number of the form

n + 1 2 , {\displaystyle n+{\tfrac {1}{2}},}
where n {\displaystyle n} is an integer. For example,
4 1 2 , 7 / 2 , 13 2 , 8.5 {\displaystyle 4{\tfrac {1}{2}},\quad 7/2,\quad -{\tfrac {13}{2}},\quad 8.5}
are all half-integers. The name "half-integer" is perhaps misleading, as the set may be misunderstood to include numbers such as 1 (being half the integer 2). A name such as "integer-plus-half" may be more accurate, but while not literally true, "half integer" is the conventional term.[citation needed] Half-integers occur frequently enough in mathematics and in quantum mechanics that a distinct term is convenient.

Note that halving an integer does not always produce a half-integer; this is only true for odd integers. For this reason, half-integers are also sometimes called half-odd-integers. Half-integers are a subset of the dyadic rationals (numbers produced by dividing an integer by a power of two).[1]

Notation and algebraic structure

The set of all half-integers is often denoted

Z + 1 2 = ( 1 2 Z ) Z   . {\displaystyle \mathbb {Z} +{\tfrac {1}{2}}\quad =\quad \left({\tfrac {1}{2}}\mathbb {Z} \right)\smallsetminus \mathbb {Z} ~.}
The integers and half-integers together form a group under the addition operation, which may be denoted[2]
1 2 Z   . {\displaystyle {\tfrac {1}{2}}\mathbb {Z} ~.}
However, these numbers do not form a ring because the product of two half-integers is not a half-integer; e.g.   1 2 × 1 2   =   1 4     1 2 Z   . {\displaystyle ~{\tfrac {1}{2}}\times {\tfrac {1}{2}}~=~{\tfrac {1}{4}}~\notin ~{\tfrac {1}{2}}\mathbb {Z} ~.} [3] The smallest ring containing them is Z [ 1 2 ] {\displaystyle \mathbb {Z} \left[{\tfrac {1}{2}}\right]} , the ring of dyadic rationals.

Properties

  • The sum of n {\displaystyle n} half-integers is a half-integer if and only if n {\displaystyle n} is odd. This includes n = 0 {\displaystyle n=0} since the empty sum 0 is not half-integer.
  • The negative of a half-integer is a half-integer.
  • The cardinality of the set of half-integers is equal to that of the integers. This is due to the existence of a bijection from the integers to the half-integers: f : x x + 0.5 {\displaystyle f:x\to x+0.5} , where x {\displaystyle x} is an integer

Uses

Sphere packing

The densest lattice packing of unit spheres in four dimensions (called the D4 lattice) places a sphere at every point whose coordinates are either all integers or all half-integers. This packing is closely related to the Hurwitz integers: quaternions whose real coefficients are either all integers or all half-integers.[4]

Physics

In physics, the Pauli exclusion principle results from definition of fermions as particles which have spins that are half-integers.[5]

The energy levels of the quantum harmonic oscillator occur at half-integers and thus its lowest energy is not zero.[6]

Sphere volume

Although the factorial function is defined only for integer arguments, it can be extended to fractional arguments using the gamma function. The gamma function for half-integers is an important part of the formula for the volume of an n-dimensional ball of radius R {\displaystyle R} ,[7]

V n ( R ) = π n / 2 Γ ( n 2 + 1 ) R n   . {\displaystyle V_{n}(R)={\frac {\pi ^{n/2}}{\Gamma ({\frac {n}{2}}+1)}}R^{n}~.}
The values of the gamma function on half-integers are integer multiples of the square root of pi:
Γ ( 1 2 + n )   =   ( 2 n 1 ) ! ! 2 n π   =   ( 2 n ) ! 4 n n ! π   {\displaystyle \Gamma \left({\tfrac {1}{2}}+n\right)~=~{\frac {\,(2n-1)!!\,}{2^{n}}}\,{\sqrt {\pi \,}}~=~{\frac {(2n)!}{\,4^{n}\,n!\,}}{\sqrt {\pi \,}}~}
where n ! ! {\displaystyle n!!} denotes the double factorial.

References

  1. ^ Sabin, Malcolm (2010). Analysis and Design of Univariate Subdivision Schemes. Geometry and Computing. Vol. 6. Springer. p. 51. ISBN 9783642136481.
  2. ^ Turaev, Vladimir G. (2010). Quantum Invariants of Knots and 3-Manifolds. De Gruyter Studies in Mathematics. Vol. 18 (2nd ed.). Walter de Gruyter. p. 390. ISBN 9783110221848.
  3. ^ Boolos, George; Burgess, John P.; Jeffrey, Richard C. (2002). Computability and Logic. Cambridge University Press. p. 105. ISBN 9780521007580.
  4. ^ Baez, John C. (2005). "Review On Quaternions and Octonions: Their geometry, arithmetic, and symmetry by John H. Conway and Derek A. Smith". Bulletin of the American Mathematical Society (book review). 42: 229–243. doi:10.1090/S0273-0979-05-01043-8.
  5. ^ Mészáros, Péter (2010). The High Energy Universe: Ultra-high energy events in astrophysics and cosmology. Cambridge University Press. p. 13. ISBN 9781139490726.
  6. ^ Fox, Mark (2006). Quantum Optics: An introduction. Oxford Master Series in Physics. Vol. 6. Oxford University Press. p. 131. ISBN 9780191524257.
  7. ^ "Equation 5.19.4". NIST Digital Library of Mathematical Functions. U.S. National Institute of Standards and Technology. 6 May 2013. Release 1.0.6.