Difference between revisions of "Super-space"
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A [[Vector space|vector space]] $ V $ | A [[Vector space|vector space]] $ V $ | ||
over a field $ k $ | over a field $ k $ | ||
− | endowed with a $ \mathbf Z / 2 $- | + | endowed with a $ \mathbf Z / 2 $-grading $ V = V _ {\overline{0} } \oplus V _ {\overline{1} } $. |
− | grading $ V = V _ {\overline{0} | + | The elements of the spaces $ V _ {\overline{0} } $ |
− | The elements of the spaces $ V _ {\overline{0} | + | and $ V _ {\overline{1} } $ |
− | and $ V _ {\overline{1} | ||
are said to be even and odd, respectively; for $ x \in V _ {i} $, | are said to be even and odd, respectively; for $ x \in V _ {i} $, | ||
the parity $ p( x) $ | the parity $ p( x) $ | ||
is defined to be $ i $ | is defined to be $ i $ | ||
− | $ ( i \in \mathbf Z / 2 = \{ \overline{0} | + | $ ( i \in \mathbf Z / 2 = \{ \overline{0} , \overline{1} \} ) $. |
Each super-space $ V $ | Each super-space $ V $ | ||
has associated to it another super-space $ \Pi ( V) $ | has associated to it another super-space $ \Pi ( V) $ | ||
− | such that $ \Pi ( V) _ {i} = V _ {i+ \overline{1} | + | such that $ \Pi ( V) _ {i} = V _ {i+ \overline{1} } $ |
$ ( i \in \mathbf Z / 2 ) $. | $ ( i \in \mathbf Z / 2 ) $. | ||
The pair $ ( m, n) $, | The pair $ ( m, n) $, | ||
− | where $ m = \mathop{\rm dim} V _ {\overline{0} | + | where $ m = \mathop{\rm dim} V _ {\overline{0} } $, |
− | $ n = \mathop{\rm dim} V _ {\overline{1} | + | $ n = \mathop{\rm dim} V _ {\overline{1} } $, |
is called the dimension of the super-space $ V $. | is called the dimension of the super-space $ V $. | ||
The field $ k $ | The field $ k $ | ||
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etc., is defined naturally. In particular, a linear mapping $ \phi : V \rightarrow W $ | etc., is defined naturally. In particular, a linear mapping $ \phi : V \rightarrow W $ | ||
is even if $ \phi ( V _ {i} ) \subset W _ {i} $, | is even if $ \phi ( V _ {i} ) \subset W _ {i} $, | ||
− | and odd if $ \phi ( V _ {i} ) \subset W _ {i+ \overline{1} | + | and odd if $ \phi ( V _ {i} ) \subset W _ {i+ \overline{1} } $. |
A homogeneous bilinear form $ \beta : V \otimes V \mapsto k $ | A homogeneous bilinear form $ \beta : V \otimes V \mapsto k $ | ||
is said to be symmetric if | is said to be symmetric if | ||
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$$ | $$ | ||
− | All these concepts apply equally to $ \mathbf Z / 2 $- | + | All these concepts apply equally to $ \mathbf Z / 2 $-graded free modules $ V $ |
− | graded free modules $ V $ | ||
over an arbitrary commutative [[Superalgebra|superalgebra]] $ C $. | over an arbitrary commutative [[Superalgebra|superalgebra]] $ C $. | ||
The basis in $ V $ | The basis in $ V $ |
Latest revision as of 08:37, 16 June 2022
A vector space $ V $
over a field $ k $
endowed with a $ \mathbf Z / 2 $-grading $ V = V _ {\overline{0} } \oplus V _ {\overline{1} } $.
The elements of the spaces $ V _ {\overline{0} } $
and $ V _ {\overline{1} } $
are said to be even and odd, respectively; for $ x \in V _ {i} $,
the parity $ p( x) $
is defined to be $ i $
$ ( i \in \mathbf Z / 2 = \{ \overline{0} , \overline{1} \} ) $.
Each super-space $ V $
has associated to it another super-space $ \Pi ( V) $
such that $ \Pi ( V) _ {i} = V _ {i+ \overline{1} } $
$ ( i \in \mathbf Z / 2 ) $.
The pair $ ( m, n) $,
where $ m = \mathop{\rm dim} V _ {\overline{0} } $,
$ n = \mathop{\rm dim} V _ {\overline{1} } $,
is called the dimension of the super-space $ V $.
The field $ k $
is usually considered as a super-space of dimension $ ( 1, 0) $.
For two super-spaces $ V $ and $ W $, the structure of a super-space on the spaces $ V \oplus W $, $ \mathop{\rm Hom} _ {k} ( V, W) $, $ V ^ \star $, etc., is defined naturally. In particular, a linear mapping $ \phi : V \rightarrow W $ is even if $ \phi ( V _ {i} ) \subset W _ {i} $, and odd if $ \phi ( V _ {i} ) \subset W _ {i+ \overline{1} } $. A homogeneous bilinear form $ \beta : V \otimes V \mapsto k $ is said to be symmetric if
$$ \beta ( y, x) = (- 1) ^ {p( x) p( y)+ p( \beta )( p( x)+ p( y)) } \beta ( x, y), $$
and skew-symmetric if
$$ \beta ( y, x) = -(- 1) ^ {p( x) p( y)+ p( \beta )( p( x)+ p( y)) } \beta ( x, y). $$
All these concepts apply equally to $ \mathbf Z / 2 $-graded free modules $ V $ over an arbitrary commutative superalgebra $ C $. The basis in $ V $ is usually selected so that its first vectors are even and its last ones odd. Any endomorphism $ \phi $ of the module $ V $ is denoted in this basis by a block matrix
$$ \alpha = \left ( \begin{array}{cc} X & Y \\ Z & T \\ \end{array} \right ) , $$
where $ X \in M _ {n} ( C) $, $ T \in M _ {m} ( C) $, such that if $ \phi $ is even, then $ X $ and $ T $ consist of even elements and $ Y $ and $ Z $ consist of odd elements, whereas if $ \phi $ is odd, then $ X $ and $ T $ consist of odd elements and $ Y $ and $ Z $ consist of even elements (in the former case the matrix $ \alpha $ is even, in the latter, odd).
References
[1] | F.A. Berezin, "Introduction to superanalysis" , Reidel (1987) (Translated from Russian) |
[2] | D.A. Leites (ed.) , Seminar on super-manifolds , Kluwer (1990) |
Comments
References
[a1] | F.A. Berezin, M.A. Shubin, "The Schrödinger equation" , Kluwer (1991) (Translated from Russian) (Supplement 3: D.A. Leites, Quantization and supermanifolds) |
Super-space. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Super-space&oldid=52453