Let \(\mathbb K\) be a field of characteristic zero and \(A\) an associative commutative \(\mathbb K\)-algebra that is an integral domain. Denote by \(R\) the quotient field of \(A\) and by \(W(A)=R\operatorname{Der} A\) the Lie algebra of derivations on \(R\) that are products of elements of \(R\) and derivations on \(A\). Nilpotent Lie subalgebras of the Lie algebra \(W(A)\) of rank \(n\) over \(R\) with the center of rank \(n-1\) are studied. It is proved that such a Lie algebra \(L\) is isomorphic to a subalgebra of the Lie algebra \(u_n(F)\) of triangular polynomial derivations where \(F\) is the field of constants for \(L\).

Yu. A. Bahturin, Identical Relations in Lie Algebras (in Russian), Nauka, Moscow

(1985).

V.V. Bavula, Lie algebras of triangular polynomial derivations and an isomorphism

criterion for their Lie factor algebras Izv. RAN. Ser. Mat., 77 (2013), Issue 6, 3-44.

V. V. Bavula, The groups of automorphisms of the Lie algebras of triangular polynomial derivations, J. Pure Appl. Algebra, 218 (2014), Issue 5, 829-851.

J. Draisma, Transitive Lie algebras of vector fields: an overview, Qual. Theory Dyn. Syst., 11 (2012), no. 1, 39-60.

A. Gonza ́lez-Lo ́pez, N. Kamran and P.J. Olver, Lie algebras of differential operators in two complex variables, Amer. J. Math., 114 (1992), 1163-1185.

S. Lie, Theorie der Transformationsgruppen, Vol. 3 Unter Mitwirkung von F. Engel, Leipzig (1893).

Ie. O. Makedonskyi and A.P. Petravchuk, On nilpotent and solvable Lie algebras of derivations, Journal of Algebra, 401 (2014), 245-257.

Ie. O. Makedonskyi and A.P. Petravchuk, On finite dimensional Lie algebras of planar vector fields with rational coefficients, Methods Func. Analysis Topology, 19 (2013), no.4, 376-388.