On Identical Relations in Free Polynilpotent Lie Algebras

“…Burnside proved that B(m, 3) is finite for all m, and also proved that 5(2,4) is finite. In 1940 Sanov [37] proved that B(m, 4) is finite for all m, and in 1958 Hall [14] proved that B(m, 6) is finite for all m. To date, no other Burnside groups (apart from the cyclic Burnside groups) are known to be finite, although a great deal of work has been done in an attempt to determine whether or not B (2,5) is finite. In the other direction, Novikov and Adjan [33][34][35] proved that B(m, n) is infinite if m > 1 and n is odd and n > 4381.…”

Bounds in the restricted Burnside problem

“…Burnside proved that B(m, 3) is finite for all m, and also proved that 5(2,4) is finite. In 1940 Sanov [37] proved that B(m, 4) is finite for all m, and in 1958 Hall [14] proved that B(m, 6) is finite for all m. To date, no other Burnside groups (apart from the cyclic Burnside groups) are known to be finite, although a great deal of work has been done in an attempt to determine whether or not B (2,5) is finite. In the other direction, Novikov and Adjan [33][34][35] proved that B(m, n) is infinite if m > 1 and n is odd and n > 4381.…”

Bounds in the restricted Burnside problem

“…On the other hand, if U (L) is normal then it satisfies the standard polynomial identity of degree 4 [Herstein 1976, Section 5]. Therefore, in view of a theorem of Latysěv [Bahturin 1987, Section 6.7,…”

Normal enveloping algebras

“…If their conjecture is true, L is a PI-algebra [2,8], one which the identities which hold in the Lie algebra (such as Eq. (6)) are satisfied by all elements of the Lie algebra.…”

“…exp(a i τ A) exp(b i τ B) = exp(Z) (2) where Z ∈ L(A, B). Requiring Z = τ (A + B) + O(τ p+1 ) for some integer p > 1 gives a system of equations in the a i and b i which must be satisfied for the method to have order p. In the case of general A and B, then, at each order n = 1, .…”

The algebraic entropy of classical mechanics