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THE ANNIHILATOR OF TENSOR SPACE IN THE $q$-ROOK MONOID ALGEBRA
Part of:
Semigroups
Algebraic combinatorics
Linear algebraic groups and related topics
Representation theory of groups
Published online by Cambridge University Press: 02 March 2017
Abstract
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In this paper, we give an explicit construction of a quasi-idempotent in the $q$-rook monoid algebra $R_{n}(q)$ and show that it generates the whole annihilator of the tensor space $U^{\otimes n}$ in $R_{n}(q)$.
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- © 2017 Australian Mathematical Publishing Association Inc.
References
Dieng, M., Halverson, T. and Poladian, V., ‘Character formulas for q-rook monoid algebras’, J. Algebraic Combin.
17 (2003), 99–123.Google Scholar
Grood, C., ‘A Specht module analog for the rook monoid’, Electron. J. Combin.
9 (2002), Article ID #R2, 10 pages.Google Scholar
Halverson, T., ‘Representations of the q-rook monoid’, J. Algebra
273 (2004), 227–251.CrossRefGoogle Scholar
Halverson, T. and Ram, A., ‘
q-rook monoid algebras, Hecke algebras, and Schur–Weyl duality’, J. Math. Sci.
121 (2004), 2419–2436; translated from Zap. Nauch. Sem. POMI
283 (2001), 224–250.Google Scholar
Hu, J., ‘Schur–Weyl reciprocity between quantum groups and Hecke algebras of type G (r, 1, n)’, Math. Z.
238 (2001), 505–521.Google Scholar
Hu, J. and Xiao, Z.-K., ‘On tensor spaces for Birman–Murakami–Wenzl algebras’, J. Algebra
324 (2010), 2893–2922.CrossRefGoogle Scholar
Lehrer, G. I. and Zhang, R. B., ‘Strongly multiplicity free modules for Lie algebras and quantized groups’, J. Algebra
306 (2006), 138–174.CrossRefGoogle Scholar
Lehrer, G. I. and Zhang, R. B., ‘The second fundamental theorem of invariant theory for the orthogonal group’, Ann. of Math. (2)
176 (2012), 2031–2054.Google Scholar
Lehrer, G. I. and Zhang, R. B., ‘The Brauer category and invariant theory’, J. Eur. Math. Soc. (JEMS)
17 (2015), 2311–2351.CrossRefGoogle Scholar
Mathas, A., Iwahori–Hecke algebras and Schur algebras of the symmetric group, University Lecture Series, 15 (Amreican Mathematical Society, Providence, RI, 1999).Google Scholar
Paget, R., ‘Representation theory of q-rook monoid algebras’, J. Algebraic Combin.
24 (2006), 239–252.Google Scholar
Sakamoto, S. and Shoji, T., ‘Schur–Weyl reciprocity for Ariki–Koike algebras’, J. Algebra
221 (1999), 293–314.Google Scholar
Solomon, L., ‘The Bruhat decomposition, Tits system and Iwahori ring for the monoid of matrices over a finite field’, Geom. Dedicata
36 (1990), 15–49.Google Scholar
Solomon, L., ‘Representations of the rook monoid’, J. Algebra
256 (2002), 309–342.CrossRefGoogle Scholar
Solomon, L., ‘The Iwahori algebra of M
n
(F
q
), a presentation and a representation on tensor space’, J. Algebra
273 (2004), 206–226.Google Scholar
Xiao, Z.-K., ‘On tensor spaces for rook monoid algebras’, Acta Math. Sinica, English Series
32 (2016), 607–620.Google Scholar
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