PBW theory for Bosonic extensions of quantum groups

Abstract

In this paper, we develop the PBW theory for the bosonic extension of a quantum group Uq() of any finite type. When belongs to the class of simply-laced type, the algebra arises from the quantum Grothendieck ring of the Hernandez-Leclerc category over quantum affine algebras of untwisted affine types. We introduce and investigate a symmetric bilinear form \ , \ on which is invariant under the braid group actions i on , and study the adjoint operators i,p and i,p with respect to \ , \ . It turns out that the adjoint operators i,p and i,p are analogues of the q-derivations ei' and i on the negative half q-() of q(). Following this, we introduce a new family of subalgebras denoted as g() in g. These subalgebras are defined for any elements in the positive submonoid + of the (generalized) braid group of . We prove that g() exhibits PBW root vectors and PBW bases defined by for any sequence of . The PBW root vectors satisfy a Levendorskii-Soibelman formula and the PBW bases are orthogonal with respect to \ , \ . The algebras () can be understood as a natural extension of quantum unipotent coordinate rings.