In mathematics invariant theory, the bracket ring is the subring of the ring of polynomials k[x<sub>11</sub>,...,x<sub>dn</sub>] generated by the d-by-d minors of a generic d-by-n matrix (x<sub>ij</sub>).
The bracket ring may be regarded as the ring of polynomials on the image of a Grassmannian under the Plücker embedding.
For given d ⤠n we define as formal variables the brackets [û<sub>1</sub> û<sub>2</sub> ... û<sub>d</sub>] with the û taken from {1,...,n}, subject to [û<sub>1</sub> û<sub>2</sub> ... û<sub>d</sub>] = â [û<sub>2</sub> û<sub>1</sub> ... û<sub>d</sub>] and similarly for other transpositions. The set ÃÂ(n,d) of size generates a polynomial ring K[ÃÂ(n,d)] over a field K. There is a homomorphism æ(n,d) from K[ÃÂ(n,d)] to the polynomial ring K[x<sub>i,j</sub>] in nd indeterminates given by mapping [û<sub>1</sub> û<sub>2</sub> ... û<sub>d</sub>] to the determinant of the d by d matrix consisting of the columns of the x<sub>i,j</sub> indexed by the û. The bracket ring B(n,d) is the image of æ. The kernel I(n,d) of æ encodes the relations or syzygies that exist between the minors of a generic n by d matrix. The projective variety defined by the ideal I is the (nâÂÂd)d dimensional Grassmann variety whose points correspond to d-dimensional subspaces of an n-dimensional space.
To compute with brackets it is necessary to determine when an expression lies in the ideal I(n,d). This is achieved by a straightening law due to Young (1928).