Nakayama Automorphism of Some Skew PBW Extensions

Let R be an Artin-Schelter regular algebra and A = σ ( R ) (cid:104) x 1 , . . . , x n (cid:105) be a graded quasi-commutative skew PBW extension over R . In this paper we describe the Nakayama automorphism of A using the Nakayama automorphism of the ring of coeﬃcients R . We calculate explicitly the Nakayama automorphism of some skew PBW extensions.


Introduction
There are two notions of Nakayama automorphisms: one for skew Calabi-Yau algebras and another for Frobenius algebras. In this paper, we focus on skew Calabi-Yau algebras, or equivalently, Artin-Schelter regular algebras in the connected graded case (Proposition 2.7). The Nakayama automorphism is one of important homological invariants for Artin-Schelter regular algebras algebras. Nakayama automorphisms have been studied by several authors. Reyes, Rogalski and Zhang in [1] proved three homological identities about the Nakayama automorphism and gave several applications. Liu, Wang and Wu in [2] proved that if R is skew Calabi-Yau with Nakayama automorphism ν then the Ore extension A = R[x; σ, δ] has Nakayama automorphism ν such that ν | R = σ −1 ν and ν (x) = ux + b with u, b ∈ R and u invertible, the parameters u and b are still unknown. Zhu, Van Oystaeyen and Zhang computed the Nakayama automorphisms of trimmed double Ore extensions and skew polynomial extension R[x; σ], where σ is a graded algebra automorphism of R in terms of the homological determinant. Lü, Mao and Zhang in [3] and [4] used the Nakayama automorphism to study group actions and Hopf algebra actions on Artin-Schelter regular algebras of global dimension three and calculated explicitly the Nakayama automorphism of a class of connected graded Artin-Schelter regular algebras. Shen, Zhou and Lu in [5] described the Nakayama automorphisms of twisted tensor products of noetherian Artin-Schelter regular algebras. Liu and Ma in [6] gave an explicit formula to calculate the Nakayama automorphism of |158 Ingeniería y Ciencia ...
any Ore extension R[x; σ, δ] over a polynomial algebra R = K[t 1 , . . . , t m ] for an arbitrary m. In general, Nakayama automorphisms are known to be tough to compute.
Skew PBW extensions and quasi-commutative skew PBW extensions were defined in [7] and are non-commutative rings of polynomial type defined by a ring and a set of variables with relations between them. Skew PBW extensions include rings and algebras coming from mathematical physics such PBW extensions, group rings of polycyclic-by-finite groups, Ore algebras, operator algebras, diffusion algebras, some quantum algebras, quadratic algebras in three variables, some 3-dimensional skew polynomial algebras, some quantum groups, some types of Auslander-Gorenstein rings, some Koszul algebras, some Calabi-Yau algebras, some Artin-Schelter regular algebras, some quantum universal enveloping algebras, and others. There are some special subclasses of skew PBW extensions such as bijective, quasi-commutative, of derivation type and of endomorphism type (see Definition 2.2). Some noncommutative rings are skew PBW extensions but not Ore extensions (see [8], [9] and [10]).
The Nakayama automorphism has not been studied explicitly for skew PBW extensions. In this paper we focus on the Nakayama automorphism of quasi-commutative skew PBW extensions (Section 3) and non quasicommutative skew PBW extensions of the form σ(K[t 1 , . . . , t m ]) x (Section 4). Since every graded quasi-commutative skew PBW extension is isomorphic to a graded iterated Ore extension of endomorphism type (see [17,Proposition 2.7]), we have that if A is a graded quasi-commutative skew PBW extension of an Artin-Schelter regular algebra R, then A is Artin-Schelter regular (see Proposition 3.1). Now, for B a connected graded algebra, B is Artin-Schelter regular if and only if B is graded skew Calabi-Yau (see [1]), and hence the Nakayama automorphism of Artin-Schelter regular algebras exists. Therefore, if R is an Artin-Schelter regular algebra with Nakayama automorphism ν, then the Nakayama automorphism We establish the following notation: the symbol N is used to denote the set of natural numbers including zero. If α := (α 1 , . . . , α n ) ∈ N n then |α| := α 1 + · · · + α n . The letter K denotes a field. Every algebra is a K-algebra.

Preliminaries
In this section, we fix basic notations and recall definitions and properties for this paper.
Definition 2.1. Let R and A be rings. We say that A is a skew PBW extension over R, if the following conditions hold: (ii) there exist elements x 1 , . . . , x n ∈ A such that A is a left free Rmodule, with basis the basic elements In this case, it is said also that A is a left polynomial ring over R with respect to {x 1 , · · · , x n } and Mon(A) is the set of standard monomials of A. Moreover, x 0 1 · · · x 0 n := 1 ∈ Mon(A).
The notation σ(R) x 1 , . . . , x n and the name of the skew PBW extensions are due to the next proposition.
In the following definition we recall some sub-classes of skew PBW extensions. Examples of these sub-classes of algebras can be found in [15]. such that (iv') for any 1 ≤ i, j ≤ n, there exists c i,j ∈ R \ {0} such that (b) A is called bijective, if σ i is bijective for each σ i ∈ Σ, and c i,j is invertible for any 1 ≤ i < j ≤ n.
(c) If σ i = id R for every σ i ∈ Σ, we say that A is a skew PBW extension of derivation type.
(d) If δ i = 0 for every δ i ∈ ∆, we say that A is a skew PBW extension of endomorphism type.
The next proposition was proved in [9].
Proposition 2.2. Let R = m≥0 R m be a N-graded algebra and let A = σ(R) x 1 , . . . , x n be a bijective skew PBW extension of R satisfying the following two conditions: (i) σ i is a graded ring homomorphism and δ i : R(−1) → R is a graded σ i -derivation for all 1 ≤ i ≤ n, where σ i and δ i are as in Proposition 2.1. (2) and c i,j ∈ R 0 .
For p ≥ 0, let A p the K-space generated by the set Then A is a N-graded algebra with graduation Note that the family of graded iterated Ore extensions is strictly contained in the family of graded skew PBW extensions (see [9,Remark 2.11]). Examples of graded skew PBW extensions can be found in [9] and [10]. Proposition 2.3. Quasi-commutative skew PBW extensions with the trivial graduation of R are graded skew PBW extensions. If we assume that R has a different graduation to the trivial graduation, then A is graded skew PBW extension if and only if σ i is graded and Therefore σ i is a graded ring homomorphism and δ i : 1 x n and c i,j ∈ R = R 0 . If R has a nontrivial graduation, then the result is obtained from the relations (4), (5) and Definition 2.3.
In [18,Definition 1.4] finitely graded algebra was presented. B is finitely graded if the following conditions hold: (iii) B is finitely generated as algebra, i.e., there is a finite set of elements Note that a finitely graded algebra B is finitely generated as K-algebra if and only if B = K x 1 , . . . , x m /I, where I is a proper homogeneous two-sided ideal of K x 1 , . . . , x m . A finitely graded algebra B is finitely presented if the two-sided ideal I is finitely generated.
The following properties of graded skew PBW extensions were proved in [9].
Remark 2.1 ([9], Remark 2.10). Let A = σ(R) x 1 , . . . , x n be a graded skew P BW extension. Then we have the following properties: (iii) If R is finitely generated then A is finitely generated.
(iv) For (i), (ii) and (iii) above, we have that if R is a finitely graded algebra then A is a finitely graded algebra.
(v) If R is locally finite, then A as K-algebra is a locally finite.
(vi) A as R-module is locally finite.
(vii) If R is finitely presented then A is finitely presented.
The following proposition establishes the relation between graded skew PBW extensions and graded iterated Ore extensions.
be a finitely presented graded algebra over K. The algebra B will be called Artin-Schelter regular, if B has the following properties: (i) B has finite global dimension d: every graded B−module has projective dimension ≤ d.
The enveloping algebra of a ring B is defined as B e := B ⊗ B op . We characterize the enveloping algebra of a skew PBW extension in [12]. If M is an B-bimodule, then M is an B e module with the action given by When one or the other of ν, τ is the identity map, we shall simply omit it, writing for example M ν for 1 M ν .
In particular, An algebra B is said to be homologically smooth, if as a B e -module, B has a finitely generated projective resolution of finite length.
as B e -modules. If ν is the identity, then B is said to be Calabi-Yau.
A graded algebra B is called graded skew Calabi-Yau of dimension d, if (i) B is homologically smooth.
(ii) There exists a graded automorphism ν of B such that as B e -graded modules, for some integer l. If ν is the identity, then B is said to be graded Calabi-Yau.
The automorphism ν is called the Nakayama automorphism of B. As a consequence of Proposition 2.5, we have that a skew Calabi-Yau algebra is Calabi-Yau if and only if its Nakayama automorphism is inner. If B is a Calabi-Yau algebra of dimension d, then the Hochschild dimension of B (that is, the projective dimension of A as an A-bimodule) is d (see [ Proposition 2.6. Let B be a skew Calabi-Yau algebra with Nakayama automorphism ν. Then ν is unique up to an inner automorphism, i.e, the Nakayama automorphism is determined up to multiplication by an inner automorphism of B.
Proof. Let B be a skew Calabi-Yau algebra with Nakayama automorphism ν and let µ be another Nakayama automorphism, i.e., Reyes, Rogalski and Zhang in [1], proved that Artin-Schelter regular algebras and graded skew Calabi-Yau algebras coincide for the connected case. 3 Nakayama automorphism of quasi-commutative skew PBW extensions Since graded quasi-commutative skew PBW extensions are isomorphic to graded iterated Ore extensions of endomorphism type, it follows that graded quasi-commutative skew PBW extensions with coefficients in Artin-Schelter regular algebras are skew Calabi-Yau, and the Nakayama automorphism exists for these extensions. With this in mind, in this section we give a description of Nakayama automorphism for these non-commutative algebras using the Nakayama automorphism of the ring of the coefficients.
The following properties of graded quasi-commutative skew PBW extensions were proved in [17, Theorem 3.6 and Theorem 4.5].  (ii) If R is a finitely presented graded skew Calabi-Yau algebra of global dimension d, then A is graded skew Calabi-Yau of global dimension d + n.
As a consequence of Proposition 2.7 and Proposition 3.1 we have the following property.

Liu, Wang and Wu in [2, Theorem 3.3] proved that if R is a skew
Calabi-Yau algebra with Nakayama automorphism ν then the Ore extension A = R[x; σ, δ] has Nakayama automorphism ν such that ν | R = σ −1 ν and ν (x) = ux + b with u, b ∈ R and u invertible. If δ = 0 then they deduced the following result. In the next theorem we show a way to calculate the Nakayama automorphism for a graded quasi-commutative skew PBW extension A of an Artin-Schelter regular algebra R.

Proof. Note that
is such that θ j (x i ) = c i,j x i (c i,j ∈ K as in Definition 2.1), 1 ≤ i < j ≤ n and θ i (r) = σ i (r), for r ∈ R. Note that Now, since R is connected then by Remark 2.1, A is connected. So, the multiplicative group of R and also the multiplicative group of A is K \ {0}, therefore the identity map is the only inner automorphism of A. Let µ i the Nakayama automorphism of R[ By Proposition 3.2 we have that the Nakayama automorphism µ 1 of R[x 1 ; θ 1 ] is given by µ 1 (r) = σ −1 1 ν(r) for r ∈ R, and µ 1 ( Continuing with the procedure we have that the Nakayama automorphism of A is given by for r ∈ R, and In general, for 1 ≤ i ≤ n, we have that Note that c i,i = 1.

From Theorem 3.1 the following corollary is immediately obtained.
Corollary 3.2. Let A = σ(R) x 1 , . . . , x n be a graded quasicommutative skew PBW extension of an Artin-Schelter regular algebra R with Nakayama automorphism ν. Then A is graded Calabi-Yau if and only if σ 1 · · · σ n = ν and u i = n j=i c i,j , for all 1 ≤ i ≤ n, where u i is as in Theorem 3.1.
Let K[t 1 , . . . , t m ] be the polynomial algebra and σ : K[t 1 , . . . , t m ] → K[t 1 , . . . , t m ] an algebra automorphism. We define Let h ∈ K \ {0}. The algebra of shift operators is defined by S h := Proof. Since x h t = (t − h)x h , then σ h (t) := t − h, then det(M ) = ∂t−h ∂t = 1. By Remark 3.1 we have that the Nakayama automorphism ν of S h is given by ν(t) = t and ν(x h ) = det(M )x = 1, i.e., the Nakayama automorphism of S h is the identity map. Therefore S h is Calabi-Yau. Proof. Note that A = K[t 1 , . . . , t m ][x; σ] is a quasi-commutative skew PBW extension of the graded Calabi-Yau algebra K[t 1 , . . . , t m ]. Since σ is graded then A is a graded quasi-commutative skew PBW extension. By Theorem 3.1 we have that the Nakayama automorphism µ of A is given by By Remark 3.1 we have that the Nakayama automorphism of A is given by Since K[t 1 , . . . , t m ] is connected, then by Remark 2.1 A is connected, so the multiplicative group of A is K \ {0}. Therefore the identity map is the only inner automorphism of A. As by Proposition 2.6 we have that the Nakayama automorphism is unique up to inner automorphisms, then ν must be equal to µ. So u = det(M ). be an iterated skew polynomial ring (see [21,Page 23]), with σ i graded. A is a skew PBW extension of R with relations x i r = σ i (r)x i and x j x i = x i x j , for r ∈ R and 1 ≤ i, j ≤ n. As R is graded and c i,j = 1 ∈ R 0 , then by Proposition 2.3 we have that A is a graded quasi-commutative skew PBW extension of R. Therefore, A is a graded skew Calabi-Yau algebra (Corollary 3.1). By Proposition 2.4, R[x 1 , . . . , x n ; σ 1 , . . . , σ n ] ∼ = R[x 1 ; θ 1 ] · · · [x n ; θ n ], where θ j (r) = σ j (r) and θ j (x i ) = x i for i < j. Applying Theorem 3.1 we have that the Nakayama automorphism µ of A is given by µ(r) = (σ 1 · · · σ n ) −1 ν(r), if r ∈ R and µ( The algebra H is a graded quasi-commutative skew PBW extension of K[t 1 , . . . , t n ], where K[t 1 , . . . , t n ] is endowed with usual graduation. According to Proposition 2.1, we have that By Proposition 2.4, H is isomorphic to a graded iterated Ore extension of endomorphism type Since K[t 1 , . . . , t n ] is a graded Calabi-Yau algebra, then its Nakayama automorphism ν is the identity map. Applying Theorem 3.1, we have that the Nakayama automorphism µ of H is given by So, det(M ) = q. By Corollary 3.3 we have that the Nakayama automorphism µ of H is given by Therefore, the Nakayama automorphism of H is completely determined by the parameter q.

Nakayama automorphism of some specific skew PBW extensions
Liu and Ma in [6] computed the Nakayama automorphism for Ore extensions over a polynomial algebra in n variables. Since Ore extensions of bijective type are skew PBW extensions, in this section we use these results to calculate explicitly the Nakayama automorphism of some skew PBW extensions of the form A = σ(K[t 1 , . . . , t m ]) x , which are not quasicommutative.
Next we present [6, Theorem 4.2], but using the notation of skew PBW extensions.
Theorem 4.1. Let A = σ(K[t 1 , . . . , t m ]) x be a skew PBW extension of derivation type. The Nakayama automorphism ν of A is then given by ν(r) = r for all r ∈ R and ν( Next we calculate the Nakayama automorphism of a skew PBW extension of derivation type using Theorem 4.1. This automorphism had already been calculated by other authors using other techniques (see for example [2] or [22]).

automorphism of A is given by
If the Nakayama automorphism of a skew Calabi-Yau algebra A is the identity then A is Calabi-Yau. Thus, from Theorem 4.1 the following are obtained immediately.
Example 4.2. The first Weyl algebra A 1 (K) = K[t][x; ∂/∂t] is a skew PBW extension of derivation type which is not graded. Note that xt = tx + 1, then δ(t) = 1 and ∂δ(t) ∂t = ∂1 ∂t = 0. By Corollary 4.1 we have that A 1 (K) is a Calabi-Yau algebra, which was already known but using other techniques (see for example [23] Next we present [6, Theorem 4.5], but using the notation of skew PBW extensions. Theorem 4.2. Let A = σ(K[t 1 , . . . , t m ]) x be a graded skew PBW extension with σ = id. Then the Nakayama automorphism ν of A is given by where M is as in (8), k is as in (9) and σ q is the extension of σ to K[t 1 , . . . , t m ] q .
where K is an algebraically closed field of characteristic zero and p 12 , p 13 , p 23 , p, q ∈ K \ {0}. Notice that these algebras are graded skew PBW extensions. In the following proposition we calculate the Nakayama automorphism of A(2) using Theorem 4.2.

Conclusions
There are some special subclasses of skew PBW extensions such as bijective, quasi-commutative, of derivation type and of endomorphism type (see Definition 2.2). Some noncommutative rings are skew PBW extensions but not Ore extensions (see [8], [9] and [10]). We illustrate each one of the properties studied here with some of these examples of skew PBW extensions.

From Proposition 3.1, if
A is a graded quasi-commutative skew PBW extension of an Artin-Schelter regular algebra R, then A is Artin-Schelter regular. Now, for connected graded algebras, an algebra is Artin-Schelter regular if and only if this is graded skew Calabi-Yau (see 2.7). Therefore, if R is an Artin-Schelter regular algebra with Nakayama automorphism ν, then the Nakayama automorphism µ of a graded quasi-commutative skew PBW extension A exists, and we compute it using the Nakayama automorphism ν together some especial automorphisms of R and A (see Theorem 3.1). As a consequence of Theorem 3.1, we have that if A = σ(R) x 1 , . . . , x n is a graded quasi-commutative skew PBW extension of an Artin-Schelter regular algebra R with Nakayama automorphism ν, then A is graded Calabi-Yau if and only if σ 1 · · · σ n = ν and u i = n j=i c i,j , for all 1 ≤ i ≤ n (see Corollary 3.2). Another consequence of Theorem 3.1 is the fact that for A = K[t 1 , . . . , t m ][x; σ] with σ be a graded algebra automorphism, u = det(M ), i.e., the element u is calculable (see Corollary 3.3).
Most authors give a description of the Nakayama automorphism of some specific Artin-Schelter regular algebras in terms of some parameters that can not be calculated explicitly (see for example [2], [5] and [24]). Since Ore extensions of bijective type are skew PBW extensions, in Section 4 is calculated explicitly the Nakayama automorphism of some skew PBW extensions (Examples 4.1, 4.2 and Proposition 4.1).