Journal of Nonlinear Mathematical Physics

Volume 28, Issue 2, June 2021, Pages 242 - 253

Lie Symmetries of the Canonical Connection: Codimension One Abelian Nilradical Case

Authors
Hassan Almusawa1, *, Ryad Ghanam2, Gerard Thompson3
1Department of Mathematics, College of Sciences, Jazan University, Jazan 45142, Saudi Arabia
2Department of Liberal Arts & Sciences, Virginia Commonwealth University in Qatar, PO Box 8095, Doha, Qatar
3Department of Mathematics, University of Toledo, Toledo, OH 43606, U.S.A.
*Corresponding author: Email: haalmusawa@jazanu.edu.sa
Corresponding Author
Hassan Almusawa
Received 11 November 2020, Accepted 13 March 2021, Available Online 10 April 2021.
DOI
10.2991/jnmp.k.210401.001How to use a DOI?
Keywords
Lie group; canonical connection; geodesic system; Lie symmetry
Abstract

This paper studies the canonical symmetric connection βˆ‡ associated to any Lie group G. The salient properties of βˆ‡ are stated and proved. The Lie symmetries of the geodesic system of a general linear connection are formulated. The results are then applied to βˆ‡ in the special case where the Lie algebra 𝔀 of G, has a codimension one abelian nilradical. The conditions that determine a Lie symmetry in such a case are completely integrated. Finally the results obtained are compared with some four-dimensional Lie groups whose Lie algebras have three-dimensional abelian nilradicals, for which the calculations were performed by MAPLE.

Copyright
Β© 2021 The Authors. Published by Atlantis Press B.V.
Open Access
This is an open access article distributed under the CC BY-NC 4.0 license (http://creativecommons.org/licenses/by-nc/4.0/).

1. INTRODUCTION

This article concerns the canonical symmetric connection βˆ‡ associated to any Lie group G. It was introduced originally in 1926 as the β€œzero”- connection; see [3]. Some properties of βˆ‡ are considered in [6]. More recently βˆ‡ and its geodesic system have been investigated within the context of the inverse problem of Lagrangian dynamics; see [4,9,15]. See also [12] for related developments in dynamics. A different direction is taken in [11], which explores the role of βˆ‡ in statistics and information science.

In the first part of the paper in Section 2 we state and prove all the important geometric properties of βˆ‡. The second part of the paper is devoted to an examination of the Lie symmetries of the geodesic system determined by βˆ‡; more specifically, we consider βˆ‡ in the special case where the Lie algebra 𝔀 of G has a codimension one abelian nilradical. Within that class, we shall need to make further genericity assumptions, that we explain as we encounter them, in order to obtain some precise results.

The second part of the paper may be viewed as examination of the nature of Lie symmetries themselves. The cases considered possess a rich class of symmetries and it is of interest to compare them with, for example, a free particle system whose symmetries we review very briefly in Section 3. As basic references on Lie symmetries we cite [2,7,10]. We mention also [1,5] as concrete examples of Lie symmetries for several well known differential equations. The four-dimensional Lie algebras used in Section 6 are taken from [13].

One of the difficulties in executing a package such as MAPLE, that we use in Section 6, is that typically the differential equations involve parameters; such programs are not sensitive to special values that may break the symmetry of the system. Accordingly, it is necessary to integrate the conditions determining the symmetries. Along the way, the special values of the parameters should be revealed. In the case at hand, we are able to carry through this analysis completely in Section 6. The summation convention on repeated indices applies throughout the paper.

2. THE CANONICAL LIE GROUP CONNECTION

On left invariant vector fields X and Y the canonical symmetric connection βˆ‡ on a Lie group G is defined by

βˆ‡XY=12[X,Y] (2.1)
and then extended to arbitrary vector fields using linearity and the Leibnitz rule. Clearly βˆ‡ is left-invariant. One could just as well use right-invariant vector fields to define βˆ‡, but one must check that βˆ‡ is well defined, a fact that we will prove next.

Proposition 2.1.

In the definition of βˆ‡ we can equally assume that X and Y are right-invariant vector fields and hence βˆ‡ is also right-invariant and hence bi-invariant. Moreover βˆ‡ is symmetric, that is, its torsion is zero.

Proof. The fact that βˆ‡ is symmetric is obvious from eq. (2.1). Now we choose a fixed basis in the tangent space at the identity TIG. We shall denote its left and right invariant extensions by {X1, X2,..., Xn} and {Y1, Y2,..., Yn}, respectively. Then there must exist a non-singular matrix A of functions on G such that Yi=aijXj. We shall suppose that

[Xi,Xj]=CijkXk. (2.2)

Changing from the left-invariant basis to the right gives

Cijkakp=aikajmCkmp. (2.3)

Next, we use the fact that left and right vector fields commute to deduce that

ajkCikm+Xiajm=0, (2.4)
where the second term in eq. (2.4) denotes directional derivative. We note that necessarily
[Yi,Yj]=-CijkYk. (2.5)

Now we compute

βˆ‡YiYj+12CijkYk=12aikajmCkmp+aik(Xkaip)+12Cijkakp. (2.6)

Next we use eq. (2.4) to replace the second term on the right hand side of eq. (2.6) so as to obtain

βˆ‡YiYj+12CijkYk=12aikajmCkmp-aikajmCkmp+12Cijkakp. (2.7)

However, the right hand side of eq. (2.7) is seen to be zero by virtue of eq. (2.3). Thus

βˆ‡XY=12[X,Y] (2.8)
whenever X and Y are right invariant vector fields.

An alternative proof of Proposition 2.1 uses the inversion map ψ defined by, for S ∈ G,

ψ(S)=S-1. (2.9)

As such, one checks that ψ*I maps a left-invariant vector field evaluated at I to minus its right-invariant counterpart evaluated at I. Then ψ*I is an isomorphism and there is no change of sign in the structure constants, as compared with eq. (2.5). Since there are two minus signs in eq. (2.1) the same condition eq. (2.1) applies also to right-invariant vector fields.

Proposition 2.2.

  1. (i)

    An element in the center of 𝔀 engenders a bi-invariant vector field.

  2. (ii)

    A vector field in the center of 𝔀 is parallel.

  3. (iii)

    A bi-invariant differential k-form ΞΈ is closed and so defines an element of the cohomology group Hk(M, ℝ).

Proof.

  1. (i)

    Suppose that Z ∈ TIG is in the center of 𝔀 and let exp(tZ) be the associated one-parameter subgroup of G so that Z corresponds to the equivalence class of curves [exp(tZ)] based at I. Let S ∈ G; then LS* Z corresponds to the equivalence class of curves [S exp(tZ)] based at S. Since Z is in the center of 𝔀 then exp(tZ) will be in the center of G and hence [S exp(tZ)] = [exp(tZ)S]. It follows that any element in the center of 𝔀 engenders a bi-invariant vector field.

  2. (ii)

    Obvious from eq. (2.1).

  3. (iii)

    A proof can be found in [14]. Spivak shows that ψ*(ΞΈ) = (βˆ’1)kΞΈ, whereas dΞΈ, which is also bi-invariant, changes by Οˆβˆ—(dΞΈ) = (βˆ’1)k+1dΞΈ. It follows that dΞΈ = 0.

Proposition 2.3.

  1. (i)

    The curvature tensor, which is also bi-invariant, on vector fields X, Y, Z is given by

    R(X,Y)Z=14[[X,Y],Z]. (2.10)

  2. (ii)

    The connection βˆ‡ is flat if and only if the Lie algebra 𝔀 of G is two-step nilpotent.

  3. (iii)

    The tensor R is parallel in the sense that βˆ‡W R(X, Y)Z = 0, where W is a fourth right invariant vector field, so that G is in a sense a symmetric space.

  4. (iv)

    The Ricci tensor Rij of βˆ‡ is given by

    Rij=14CjmlCilm (2.11)
    and is symmetric and bi-invariant and is obtained by translating to the left or right one quarter of the Killing form. It engenders a bi-invariant pseudo-Riemannian metric if and only if the Lie algebra 𝔀 is semi-simple.

Proof.

  1. (i)

    Is obvious and applies to arbitrary vector fields since it is a tensorial object.

  2. (ii)

    Is obvious.

  3. (iii)

    This fact follows from a series of implications:

    4βˆ‡WR(X,Y)Z+4R(βˆ‡WX,Y)Z+4R(X,βˆ‡WY)Z+4R(X,Y)βˆ‡WZ=βˆ‡W[[X,Y],Z] (2.12)
    β‡’4βˆ‡WR(X,Y)Z+2R([W,X],Y)Z+2R(X,[W,Y])Z+2R(X,Y)[W,Z]-12[W,[[X,Y],Z]=0 (2.13)
    β‡’4βˆ‡WR(X,Y)Z+12[[W,X],Y],Z]+12[X,[W,Y]],Z]+12[[X,Y],[W,Z]]-12[W,[[X,Y],Z]=0 (2.14)
    β‡’4βˆ‡WR(X,Y)Z+12[[W,X],Y],Z]+12[X,[W,Y]],Z]-12[Z,[[X,Y],W]=0 (2.15)
    β‡’βˆ‡WR(X,Y)Z=0. (2.16)

  4. (iv)

    The formula eq. (2.11) is obvious from eqs. (2.1) and (2.10). The last remark follows from Cartan’s criterion.

Proposition 2.4.

  1. (i)

    Any left or right-invariant vector field is geodesic.

  2. (ii)

    Any geodesic curve emanating from the identity is a one-parameter subgroup.

  3. (iii)

    An arbitrary geodesic curve is a translation, to the left or right, of a one-parameter subgroup.

Proof.

  1. (i)

    Is obvious because of the skew-symmetry in eq. (2.1).

  2. (ii)

    By definition the curve t ↦ [S exp(tX)] integrates a geodesic field X.

  3. (iii)

    If the geodesic curve at t = 0 starts at S, translate the curve to I by multiplying on the left or right by Sβˆ’1 and apply (ii).

Proposition 2.5.

  1. (i)

    A left or right-invariant vector field is a symmetry, a.k.a. affine collineation, of βˆ‡.

  2. (ii)

    Any left or right-invariant one-form engenders a first integral of the geodesic system of βˆ‡.

Proof.

  1. (i)

    The following condition for vector fields X and Y says that vector field W is a symmetry or, affine collineation, of a symmetric linear connection:

    βˆ‡Xβˆ‡YW-βˆ‡βˆ‡XYW-R(W,X)Y=0. (2.17)
    In the case at hand of the canonical connection, this condition just reduces to the Jacobi identity when W, X and Y are all left or right- invariant.

  2. (ii)

    A one-form Ξ± is a Killing one-form, if the following condition holds:

    γ€ˆβˆ‡XΞ±,Y〉+γ€ˆX,βˆ‡Yα〉=0. (2.18)
    In the case of the canonical connection, if X and Y are right-invariant and Ξ± is right-invariant then eq. (2.1) gives
    γ€ˆX,βˆ‡Yα〉=12γ€ˆ[X,Y],α〉. (2.19)
    Clearly, (2.19) implies (2.18) so that every left or right-invariant one-form engenders a first integral of the geodesics: if the one-form is given in a coordinate system as Ξ±idxi on G, the first integral is Ξ±iui viewed as a function on the tangent bundle TG that is linear in the fibers.

Proposition 2.6.

Any left or right-invariant one-form Ξ± is closed if and only if 〈[𝔀, 𝔀], Ξ±βŒͺ = 0, that is, Ξ± annihilates the derived algebra of 𝔀.

Proof. Consider the identity

dΞ±(X,Y)=Xγ€ˆY,α〉-Yγ€ˆX,α〉-γ€ˆ[X,Y],α〉. (2.20)

If Ξ± is left-invariant and we take X and Y left-invariant, then the first and second terms in eq. (2.20) are zero. Now the conclusion of the Proposition is obvious. The proof for right-invariant one-forms is similar.

Proposition 2.7.

Consider the following conditions for a one-form Ξ± on G:

  1. (i)

    Ξ± is bi-invariant.

  2. (ii)

    Ξ± is right-invariant and closed.

  3. (iii)

    Ξ± is left-invariant and closed.

  4. (iv)

    Ξ± is parallel.

Then we have the following implications: (i), (ii) and (iii) are equivalent and any one of them implies (iv).

Proof. The fact that (i) implies (ii) and (iii) follows from Proposition (2.2) part (iii). Now suppose that (iii) holds and let X and Y be right and left-invariant vector fields, respectively. Then consider again the identity

dΞ±(X,Y)=Xγ€ˆY,α〉-Yγ€ˆX,α〉-γ€ˆ[X,Y],α〉. (2.21)

Assuming that Ξ± is closed, then either because [X, Y] = 0 or by using Proposition 2.6, we find that eq. (2.21) reduces to

Xγ€ˆY,α〉=Yγ€ˆX,α〉. (2.22)

Now the left hand side of eq. (2.22) is zero, since Y and Ξ± are left-invariant. Hence 〈X, Ξ±βŒͺ is constant, which implies that Ξ± is right-invariant and hence bi-invariant. Thus (iii) implies (i). The proof that (ii) implies (i) is similar. Finally, supposing that (ii) or (iii) holds we show that (iv) holds. Then as with any symmetric connection, the closure condition may be written, for arbitrary vector fields X and Y, as

γ€ˆβˆ‡XΞ±,Y〉-γ€ˆX,βˆ‡Yα〉=0. (2.23)

Clearly eq. (2.18) and eq. (2.23) imply that Ξ± is parallel. So a closed, invariant one-form is parallel.

Of course, it may well be the case that there are no bi-invariant one-forms on G, for example if G is semi-simple so that [𝔀, 𝔀] = 𝔀. However, there must be at least one such one-form if G is solvable and at least two if G is nilpotent.

If we choose a basis of dimension dim 𝔀-dim [𝔀, 𝔀] for the bi-invariant one-forms on G, it may be used to obtain a partial coordinate system on G, since each such form is closed. Such a partial coordinate system is significant in terms of the geodesic system, in that it gives rise to second order differential equations that resemble the system in Euclidean space.

Proposition 2.8.

Each of the bi-invariant one-forms on G projects to a one-form on the quotient space G/[G, G], assuming that the commutator subgroup [G, G] is closed topologically in G. Furthermore the canonical connection βˆ‡ on G projects to a flat connection on G/[G, G] and the induced system of one-forms on G/[G, G] comprises a β€œflat” coordinate system.

Proof. The fact thata bi-invariant one-form on G projects to a one-form on G/[G, G] follows because each such form annihilates the vertical distribution of the principal right [G, G]-bundle G β†’ G/[G, G] and furthermore the equivariance, or Lie-derivative condition along the fibers, is trivially satisfied since the one-form is closed. The fact that βˆ‡ projects to G/[G, G] follows because [G, G]⊲G, as was noted in [8].

3. LIE SYMMETRIES OF A FREE PARTICLE

In this short Section we recall the Lie symmetry vector fields of a free particle system in dimension n. See also [1]. It may be regarded as the extreme case of the geodesic system of the canonical connection for an abelian Lie group. The geodesics are given by

x¨i=0 (3.1)
and the Lie symmetries by:
Dt,Dxi,tDt,xiDt,tDxi,xiDxj,tΞ”,xiΞ”, (3.2)
where Ξ” = tDt +xiDxi and gives 𝔰𝔩(n+2, ℝ) as symmetry Lie algebra. We note that 𝔰𝔩(n+2, ℝ) is of dimension (n+2)2 βˆ’1 = (n+3)(n+1).

4. CODIMENSION ONE ABELIAN NILRADICAL

4.1. Coordinate Normal Form

Rather than studying the canonical connection for general Lie groups, we will now examine a particular class, namely, those groups for which the associated Lie algebras are solvable and have a codimension one abelian nilradical. The following theorem gives a coordinate normal form for the canonical connection of a Lie algebra that has a codimension one abelian ideal. Such Lie algebras are characterized by a matrix ad(en+1) where en+1 is a fixed element of 𝔀, usually taken as the last element of a basis.

Theorem 4.1.

  1. (i)

    Suppose that 𝔀 is Lie algebra of dimension n + 1 such that there exists a basis {e1, e2,..., en, en+1} for which the only non-zero brackets in 𝔀 are given by [ei, en+1]=aijej, where, on the right hand side the summation over j extends from 1 to n. Then there exists a coordinate system (xi, w) on the local Lie group G associated to 𝔀, such that 𝔀 is faithfully represented by (Xi, W) where Xi=βˆ‚βˆ‚xi and W=βˆ‚βˆ‚w+ajkxjβˆ‚βˆ‚xk.

  2. (ii)

    In the coordinate system (xi, w) of (i) the geodesic equations of the canonical connection are given by

    xΒ¨i=ajixΛ™jwΛ™, wΒ¨=0. (4.1)

Part (i) of Theorem 4.1 gives an automatic implementation of Lie’s third theorem [6]. Part (ii) then gives a normal form for the geodesics of the canonical connection. In general, these geodesics can only be computed if a vector field representation of 𝔀 is known and only then by means of considerable calculation.

Although we shall not need it, it is possible to obtain a matrix Lie group representation in GL(n + 1, ℝ) by exponentiating the matrix aji, assuming that it is upper triangular, and taking n arbitrary entries in the last column.

In fact (Xi, W) are the right-invariant vector fields and the dual one-forms are given by

dxi-ajixjdw,dw. (4.2)

Similarly, the left-invariant vector fields are given by

ewajiβˆ‚βˆ‚xi,βˆ‚βˆ‚w (4.3)
and the dual one-forms are given by
e-wajidxj,dw. (4.4)

We note also that dw is bi-invariant.

5. LIE SYMMETRIES OF THE CANONICAL CONNECTION

We encode the geodesic equations of a connection in terms of the vector field Ξ“=βˆ‚βˆ‚t+uiβˆ‚βˆ‚xi+fiβˆ‚βˆ‚ui. In order to be a Lie symmetry we need a vector field of the form X=ΞΎβˆ‚βˆ‚t+Ξ·iβˆ‚βˆ‚xi such that [X˜,Ξ“]=λΓ for some function Ξ», where X˜ denotes the first prolongation of X. It is apparent that βˆ‚βˆ‚t is a Lie symmetry. In the case of tβˆ‚βˆ‚t, its prolongation is given by tβˆ‚βˆ‚t-Ξ” where Ξ” is the dilation field uiβˆ‚βˆ‚ui. It follows that tβˆ‚βˆ‚t is a Lie symmetry, with Ξ» = βˆ’1, because [Ξ”,Ξ“]=Ξ“-βˆ‚βˆ‚t. Of course βˆ‚βˆ‚t and tβˆ‚βˆ‚t are symmetries for any linear connection. Thus, at the outset, we have the following Lie symmetries for the canonical connection:

  • β€’

    βˆ‚βˆ‚t

  • β€’

    tβˆ‚βˆ‚t

  • β€’

    any left-invariant vector field

  • β€’

    any right-invariant vector field

5.1. Lie Symmetries of a Symmetric Connection

Define

Pi=Ξ·Λ™i-uiΞΎΛ™ (5.1)
then
X˜=ΞΎβˆ‚βˆ‚t+Ξ·iβˆ‚βˆ‚xi+Piβˆ‚βˆ‚ui (5.2)
and
PΛ™i=Ξ·Β¨i-uiΞΎΒ¨-fiΞΎΛ™. (5.3)

The conditions for X to be Lie symmetry amount to

Ξ»=-ΞΎΛ™ (5.4)
ΞΎΛ™ui=Ξ·Λ™i-Pi (5.5)
ΞΎΛ™fi+Pjβˆ‚fiβˆ‚ui-PΛ™i+ΞΎβˆ‚fiβˆ‚t+Ξ·jβˆ‚fiβˆ‚xj=0 (5.6)
the second of which is an identity. Using the definition of Pi in eq. (5.6) gives
ΞΎΛ™fi=Ξ·Β¨i-uiΞΎΒ¨-fiΞΎΛ™-(Ξ·Λ™j-ujΞΎΛ™)βˆ‚fiβˆ‚uj-Ξ·iβˆ‚fjβˆ‚xi. (5.7)

Finally since the f i are are homogeneous quadratic ui, we find that eq. (5.7) reduces to

Ξ·Β¨i-uiΞΎΒ¨-Ξ·Λ™jβˆ‚fiβˆ‚uj-Ξ·iβˆ‚fjβˆ‚xi=0. (5.8)

Next we shall make use of the following identities:

ΞΎΒ¨=ΞΎtt+2ujΞΎtk+ujukΞΎjk+fiΞΎi (5.9)
Ξ·Β¨i=Ξ·tti+2ujΞ·tji+ujukΞ·jki+fjΞ·ji (5.10)
where we have used subscripts to denote derivatives. Eq. (5.8) contains terms of degree zero, one, two and three in the ui and we write down the coefficients of each term so as to obtain
βˆ‚2Ξ·iβˆ‚t2=0 (5.11)
2ujβˆ‚2Ξ·iβˆ‚xjβˆ‚t-uiβˆ‚2ΞΎβˆ‚t2-βˆ‚Ξ·jβˆ‚tβˆ‚fiβˆ‚uj=0 (5.12)
ujukβˆ‚2Ξ·iβˆ‚xjβˆ‚xk+fjΞ·ji-Ξ·jβˆ‚fiβˆ‚xj-2uiujβˆ‚2ΞΎβˆ‚tβˆ‚xj-ukβˆ‚Ξ·jβˆ‚xkβˆ‚fiβˆ‚uj=0 (5.13)
uiujukβˆ‚2ΞΎβˆ‚xjβˆ‚xk+uifkβˆ‚ΞΎβˆ‚xk=0. (5.14)

Now we shall write

fi=-Ξ“jkiujuk. (5.15)

Then eqs. (5.12, 5.13) and eq. (5.14) give, on equating powers of the ui to zero,

2βˆ‚2Ξ·iβˆ‚xkβˆ‚t-Ξ΄kiβˆ‚2ΞΎβˆ‚t2+2βˆ‚Ξ·jβˆ‚tΞ“jki=0 (5.16)
βˆ‚2ΞΎβˆ‚xjβˆ‚xk-Ξ“jkiΞΎi=0 (5.17)
βˆ‚2Ξ·iβˆ‚xkβˆ‚xm+βˆ‚Ξ·jβˆ‚xkΞ“jmi+βˆ‚Ξ·jβˆ‚xmΞ“jki+Ξ·jβˆ‚Ξ“kmiβˆ‚xj-Ξ΄kiβˆ‚2ΞΎβˆ‚tβˆ‚xm-Ξ΄miβˆ‚2ΞΎβˆ‚tβˆ‚xk-Ξ·jiΞ“kmj=0. (5.18)

5.2. More Lie Symmetries

In the case of the canonical connection, where the associated Lie algebra has a codimension one abelian nilradical, the connection components are constant and so each of the coordinate vector fields βˆ‚βˆ‚xi is a Lie symmetry for which Ξ» = 0 and of course they are right-invariant as noted in Theorem 4.1. It is apparent that wβˆ‚βˆ‚t is always a Lie symmetry with Ξ»=-wΛ™.

Another Lie symmetry is given by X=xiβˆ‚βˆ‚xi. To see that it is so, note that the prolongation is given by X˜=xiβˆ‚βˆ‚xi+uiβˆ‚βˆ‚ui. Then

[X˜,Ξ“]=[xiβˆ‚βˆ‚xi+uiβˆ‚βˆ‚ui,βˆ‚βˆ‚t+uiβˆ‚βˆ‚xi+wΛ™βˆ‚βˆ‚w+fiβˆ‚βˆ‚ui]=[xiβˆ‚βˆ‚xi,uiβˆ‚βˆ‚xi]+[uiβˆ‚βˆ‚ui,ujβˆ‚βˆ‚xj]+[uiβˆ‚βˆ‚ui,akjukwΛ™βˆ‚βˆ‚uj]=-uiβˆ‚βˆ‚xi+uiβˆ‚βˆ‚xi=0. (5.19)

5.3. Codimension Abelian Nilradical Case

Next we shall adapt eqs. (5.11, 5.16, 5.17 and 5.18) to the codimension abelian nilradical case. Note that the Lie algebra is now of dimension n + 1. The first n coordinates are denoted by xi and the (n + 1)th by w. We shall denote a Lie symmetry now by

X=ΞΎβˆ‚βˆ‚t+Ξ·iβˆ‚βˆ‚xi+Ξ·βˆ‚βˆ‚w. (5.20)
and again we shall employ the summation convention in the range 1 to n. The connection components coming from eq. (4.1) are given by
Ξ“jki=0, Γjn+1i=Ξ“n+1ji=-12aji, Γn+1n+1i=0, Γijn+1=0, Γin+1n+1=Ξ“n+1in+1=0, Γn+1n+1n+1=0. (5.21)

We find the following conditions on ΞΎ, Ξ·i, Ξ· where in the interest of brevity, derivatives with respect to t and w are denoted by subscripts and derivatives with respect to xi is denoted by subscript i and

(i) ξjk=0 (ii) ξiw+12aijΞΎj=0 (iii) ξww=0 (iv)Ξ·tt=0 (v) ηtk=0 (vi) ηkm=0 (vii)Ξ·kw-ΞΎtk+12akjΞ·j=0 (viii) ηww-2ΞΎtw=0,(ix) 2Ξ·tw-ΞΎtt=0 (x) ηtti=0 (xi) ηtwi-12akiΞ·tk=0 (xii) ηwwi-ajiΞ·wj=0(xiii) 2Ξ·tki-Ξ΄kiΞΎtt-akiΞ·t=0 (xiv) ηkmi-12amiΞ·k-12akiΞ·m-Ξ΄kiΞΎtm-Ξ΄miΞΎtk=0 (xv) ηkwi-12ajiΞ·kj-12akiΞ·w+12akjΞ·ji-Ξ΄kiΞΎtw=0. (5.22)

5.4. Solving the PDE

Now we integrate (i)–(xv) above, to the extent possible. As such the solution to (iv), (v), (vi) is given by

Ξ·=Bk(w)xk+C(w)t+D(w). (5.23)

Turning now to (ii) and (iii), if we take the w-derivative of (ii) and use (ii) we conclude that

aijΞΎjw=0. (5.24)

Let us continue by assuming that the matrix A is non-singular. Then ΞΎjw = 0 and using (ii) again, we find that ΞΎj = 0. As such, from (iii) we conclude that

ΞΎ=E(t)w+F(t). (5.25)

Now from (viii) and (ix) we obtain ΞΎttw = 0 and Ξ·tww = 0. From the w-derivative of (vii) and the xk-derivative of (viii) we deduce that Ξ·jw = 0 and hence again from (vii) that Ξ·j = 0. Integrating (viii) and (ix) gives

ΞΎ=(Ft+G)w+K+Lt+Ut2, η=Ct+Fw2+Hw+J+Utw. (5.26)

Now we consider (x), (xi) and (xii). Take the w derivative of (xi) and the t derivative of (xii). We deduce that Ξ·twk=0 and hence from (xi) that Ξ·tk=0, since we are assuming that A is non-singular. Concerning (xii), we find that the solution is

Ξ·i=A-1ewAMi(x)+Ni(x). (5.27)

It remains to examine (xiii), (xiv) and (xv). However, we see that in view of the conditions that have already been solved, (xiii) gives C = U = 0. Furthermore (xiv) reduces to

Ξ·kmi=0. (5.28)

Hence we may write

Ξ·i=(a-1)jiewakj(Pmkxm+Qk)+Rjixj+Si. (5.29)

At this point, only (xv) remains to be satisfied and it is

ewajiPkj+akj((a-1)miewalmPjl+Rji)-aji((a-1)mjewalmPkl+Rkj)-aki(2Fw+H)-Ξ΄kiF=0. (5.30)
Eq. (5.30) splits into two conditions, the first of which may be written as
ewAPA+AewAP=0. (5.31)
Eq. (5.31) is equivalent to
AP+PA=0 (5.32)
that is, P anti-commutes with A, and for generic A, will possess only the zero matrix as solution.

The second condition coming from Eq. (5.30) is

akjRji-ajiRkj-(2Fw+H)aki-FΞ΄ki=0. (5.33)

Note that there are no conditions on Qk and Sk and that necessarily F = 0. After putting F = 0, eq. (5.33) may be written in matrix form as

[R,A]=HA (5.34)
where the left hand side is a commutator. From eq. (5.34) we conclude that either H = 0 or tr(A) = 0. If tr(A) = 0 then the Lie algebra is unimodular; if tr(A) β‰  0 then R commutes with A.

To summarize, the solution for ΞΎ, Ξ·i, Ξ· is given by eq. (5.26) with C = F = U = 0 and

Ξ·i=Rjixj+Si+ewakj(Pjkxj+Tk) (5.35)
where H and R satisfy condition eq. (5.34) and P satisfies eq. (5.32).

5.5. Analyzing the Solutions of the Algebraic Condition (5.34)

From the preceding analysis we see that the only ambiguity that arises in the determination of the possible Lie symmetries depends on the solution of the algebraic eq. (5.34). We are already assuming that the matrix A is non-singular. If furthermore, the codimension one Lie algebra is not unimodular, that is traces of all ad-matrices are not zero, so in our case trA β‰  0, then necessarily H = 0 and R must commute with A. The centralizer of A in 𝔀𝔩(n, ℝ) certainly contains all polynomials in A and equality holds if and only if A is non-derogatory. In fact A is non-derogatory if and only if its minimum polynomial coincides with its characteristic polynomial if and only if each eigenvalue is of geometric multiplicity one. The set of non-derogatory matrices is Zariski open and dense and contains the set of all matrices with distinct eigenvalues. For such matrices the centralizer of A is of dimension n; otherwise, the dimension of the centralizer of A becomes more problematic to estimate. The algebra of polynomials can have quite a small dimension. The extreme case of all is when A is a non- zero multiple of the identity, in which case all matrices in 𝔀𝔩(n, ℝ) commute with A. This case corresponds to algebras A3.3, A4.5(a=b=1), A5.7(a=b=c=1) in [13].

5.6. Analyzing the Solutions of the PDE

It is apparent that the coefficients of Si and ewakjTk in 5.35 correspond to right and left-invariant vector fields. If we take R = A and H = 0 in eq. (5.34) we obtain ajixjβˆ‚βˆ‚xi as a symmetry vector field. If we add to it βˆ‚βˆ‚w coming from J in eq. (5.26) we obtain the n + 1st right-invariant vector field. Note also that βˆ‚βˆ‚w is the n + 1st left-invariant vector field.

One more symmetry vector field may be obtained by taking R as the identity and again H = 0 in eq. (5.34). This vector field was already found in Section 5.2. Similarly from ΞΎ appearing in eq. (5.26) we reproduce βˆ‚βˆ‚t,tβˆ‚βˆ‚t and wβˆ‚βˆ‚t.

Finally we count the minimal number symmetry vector fields. We have n + 1 right-invariant and n + 1 left-invariant vector fields. We have also βˆ‚βˆ‚t,tβˆ‚βˆ‚t and wβˆ‚βˆ‚t. In the generic case, where A is non-singular, has trace non-zero is non-derogatory and the only solution to eq. (5.32) is trivial, we obtain an extra n βˆ’ 1 independent symmetries coming from eq. (5.34) and also H = 0. At the other extreme, where A is a non-zero multiple of the identity, we obtain n2 + 2n + 4 independent symmetries.

Theorem 5.1.

In case the matrix A is non-singular and has trace non-zero, the dimension of the Lie symmetry algebra of the geodesic system eq. (4.1) is at least 3n + 4 and at most n2 + 2n + 4; moreover, 3n + 4 occurs only if A is non-derogatory and n2 + 2n + 4 if and only ifA isa non-zero multiple of the identity.

6. FOUR-DIMENSIONAL CANONICAL GEODESIC SYSTEMS AND THEIR SYMMETRY ALGEBRAS

In this final Section we illustrate our results by considering Lie symmetries of the canonical connection with codimension one abelian nilradical case in dimension four. The calculations here have been performed using MAPLE. The algebras correspond to cases A4.2a, A4.3, A4.4, A4.5ab, A4.6ab in [13]. Our analysis is extensive although not exhaustive for these five cases. The matrix A that played the key role in Sections 4 and 5 here is 3 Γ— 3. In case A4.3 the matrix A is singular, so our results are not applicable; nonetheless, it is included as it suggests that the symmetry algebra will be of greater dimension when A is singular. In all the other cases, the symmetry algebra is of dimension at least 13 in accordance with Theorem 5.1; in several cases extra symmetries occur because there are non-trivial solutions to eq. (5.32).

6.1. A4.2a

Lie Brackets: [e1, e4]= ae1, [e2, e4]= e2 + e3, [e3, e4]= e3, (a β‰  0).

Geodesics:

x¨=ax˙w˙y¨=(y˙+z˙)w˙z¨=z˙w˙w¨=0. (6.1)

Lie symmetries a β‰  Β±1:

e1=-zDy, e2=Dz, e3=ew(Dz+wDy), e4=Dy, e5=ewDy, e6=wDt, e7=Dt,  e8=Dx, e9=eawDx, e10=yDy+zDz, e11=-Dw, e12=tDt, e13=xDx.

The Lie algebra ℝ4 β‹Š (H5 βŠ• ℝ4) is 13-dimensional solvable. It has a 9-dimensional non-abelian nilradical H5 βŠ• ℝ4. Here H5 denotes the 5-dimensional Heisenberg algebra and is spanned by e1, e2, e3, e4, e5 and the ℝ4 summand is spanned by e6, e7, e8, e9. The 4-dimensional abelian complement to H5 βŠ• ℝ4 is spanned by e10, e11, e12, e13.

Lie symmetries a = Β±1:

e1=Dx, e2=eawDx, e3=zDy, e4=Dz, e5=ew(Dz+wDy), e6=Dy, e7=ewDy, e8=xe(1-a)w2Dy, e9=ze(a-1)w2Dx, e10=wDt, e11=Dt, e12=yDy+zDz, e13=Dw,e14=tDt, e15=xDx.

In each case the Lie algebra ℝ4 β‹Š (N9 βŠ• ℝ2) is 15-dimensional solvable. It has an 11-dimensional decomposable nilradical, N9 βŠ• ℝ2, where N9 is 9-dimensional indecomposable nilpotent spanned by e1, e2, e3, e4, e5, e6, e7, e8, e9 and ℝ2 by e10, e11 and a 4-dimensional abelian complement spanned by e12, e13, e14, e15. The β€œextra” symmetry for a = 1 is explained by the fact that only for that value is the matrix A not non-derogatory; meanwhile a = βˆ’1 is the unique value for which eq. (5.32) has a non-trivial solution.

6.2. A4.3

Lie brackets: [e1, e4]= e1, [e3, e4]= e2.

Geodesics:

x¨=x˙w˙y¨=z˙w˙z¨=0w¨=0. (6.2)

Lie symmetries:

e1=wDt, e2=w22Dy+wDz, e3=ewDx, e4=Dy, e5=Dx, e6=Dz, e7=Dt, e8=wDy, e9=tDt+yDy+zDz, e10=Dw+z2Dy, e11=xDx, e12=(wz-y)Dy+zDze13=13(2tDt-yDy-zDz), e14=tDy, e15=zDt, e16=tw2Dy+tDz, e17=(wz-2y)Dt,e18=zDy, e19=(zw22-yw)Dy+(wz-2y)Dz.

The symmetry algebra is 𝔰𝔩(3, ℝ) β‹Š (ℝ3 β‹Š ℝ8) where 𝔰𝔩(3, ℝ) is spanned by e12, e13, e14, e15, e16, e17, e18, e19, the ℝ3 factor is spanned by e9, e10, e11 and the nilradical ℝ8 is spanned by e1, e2, e3, e4, e5, e6, e7, e8.

6.3. A4.4

Lie brackets: [e1, e4]= e1, [e2, e4]= e1 + e2, [e3, e4]= e2 + e3.

Geodesics:

x¨=(x˙+y˙)w˙y¨=(y˙+z˙)w˙z¨=z˙w˙w¨=0. (6.3)

Lie symmetries:

e1=Dx, e2=Dy, e3=Dz, e4=zDx, e5=yDx+zDy, e6=ewDx,  e7=ew(wDx+Dy), e8=ew(w22Dx+wDy+Dz),e9=Dt, e10=wDt, e11=tDt, e12=Dw, e13=xDx+yDy+zDz.

The symmetry algebra is a 13-dimensional indecomposable solvable algebra ℝ3 β‹Š (N8 βŠ• ℝ2). Its nilradical is 10-dimensional decomposable, a direct sum of an 8-dimensional nilpotent N8 spanned by e1, e2, e3, e4, e5, e6, e7, e8 and ℝ2 spanned by e9, e10. The complement to the nilradical is abelian spanned by e11, e12, e13.

6.4. A4.5ab

Lie brackets: [e1, e4]= e1, [e2, e4]= ae2, [e3, e4]= be3, (ab β‰  0, βˆ’1 ≀ a ≀ b ≀ 1).

Geodesics:

x¨=x˙w˙y¨=ay˙w˙z¨=bz˙w˙w¨=0. (6.4)

Generic case Lie symmetries:

e1=Dx, e2=Dy, e3=Dz, e4=ewDx, e5=eawDy, e6=ebwDz, e7=Dt,  e8=wDt, e9=xDx, e10=yDy, e11=zDz,  D12=tDt, e13=Dw.

It is a 13-dimensional indecomposable solvable Lie algebra ℝ5 β‹Š ℝ8. It has an 8-dimensional abelian nilradical spanned by e1, e2, e3, e4, e5, e6, e7, e8 and 5-dimensional abelian complement spanned by e9, e10, e11, e12, e13.

A4.5ab (a = 1, b = 1)

Lie symmetries:

e1=Dx, e2=Dy, e3=Dz, e4=ewDx, e5=ewDy, e6=ewDz, e7=Dt, e8=wDt,e9=xDx+yDy+zDz, e10=tDt, e11=Dw, e12=yDx, e13=xDy, e14=zDye15=yDz, e16=xDz, e17=zDx, e18=xDx-zDz, e19=yDy-zDz.

It is a 19-dimensional indecomposable Lie algebra with a non-trivial Levi decomposition. The semi-simple part is 𝔰𝔩(3, ℝ) and is spanned by e12, e13, e14, e15, e16, e17, e18, e19. The radical is a semi-direct product ℝ8 β‹Š ℝ3 with abelian nilradical spanned by e1, e2, e3, e4, e5, e6, e7, e8 and 3-dimensional abelian complement spanned by e9, e10, e11. This finding is in agreement with Theorem 5.1.

A4.5ab (a = 1, b = βˆ’1)

Lie symmetries:

e1=Dx, e2=Dy, e3=Dz, e4=ewDx, e5=ewDy, e6=e-wDz, e7=Dt, e8=wDt, e9=tDt,e10=3Dw+xDx+yDy-2zDz, e11=xDx+yDy+zDz, e12=zewDx, e13=zewDy,e14=xe-wDz, e15=ye-wDy, e16=yDx, e17=xDy, e18=xDx-zDz, e19=yDy-zDz.

It is a 19-dimensional indecomposable Lie algebra with a non-trivial Levi decomposition. The semi-simple part is 𝔰𝔩(3, ℝ) and is spanned by e12, e13, e14, e15, e16, e17, e18, e19. The radical isa semi-direct product ℝ8 β‹Š ℝ3 with abelian nilradical spanned by e1, e2, e3, e4, e5, e6, e7, e8 and 3-dimensional abelian complement spanned by e9, e10, e11.

A4.5ab (a = 1)

Lie symmetries:

e1=Dx, e2=Dy, e3=z, e4=ewDx, e5=ewDy, e6=ebwDz, e7=Dt, e8=wDt, e9=Dw,  e10=xDx+yDy, e11=zDz, e12=tDt, e13=xDx-yDy, e14=yDx, e15=xDy.

It is a 15-dimensional indecomposable Lie algebra with a non-trivial Levi decomposition. The semi-simple part is 𝔰𝔩(2, ℝ) and is spanned by e13, e14, e15. The radical isa semi-direct product ℝ4 β‹Š ℝ8 with abelian nilradical spanned by e1, e2, e3, e4, e5, e6, e7, e8 and 4-dimensional abelian complement spanned by e9, e10, e11, e12.

A4.5ab (a = βˆ’1)

Lie symmetries:

e1=Dx, e2=Dy, e3=Dz, e4=ewDx, e5=e-wDy, e6=ebwDz,e7=Dt, e8=tDt, e9=wDt, e10=2Dw+xDx-yDy, e11=xDx+yDy, e12=zDze13=xDx-yDy, e14=yewDx, e15=xe-wDy.

It is a 15-dimensional indecomposable Lie algebra with a non-trivial Levi decomposition. The semi-simple part is 𝔰𝔩(2, ℝ) and is spanned by e13, e14, e15. The radical is a semi direct product ℝ4 β‹Š ℝ8 with abelian nilradical spanned by e1, e2, e3, e4, e5, e6, e7, e8 and 4-dimensional abelian complement spanned by e9, e10, e11, e12.

6.5. A4.6ab

Lie brackets: [e1, e4]= ae1, [e2, e4]= be2 βˆ’ e3, [e3, e4]= e2 + be3 (a β‰  0, b β‰₯ 0).

Geodesics:

x¨=(bx˙+y˙)w˙y¨=(by˙-x˙)w˙z¨=az˙w˙w¨=0. (6.5)

Lie symmetries:

e1=Dt, e2=Dx, e3=Dy, e4=Dz, e5=eawDz, e6=ebw(sinw Dx+cosw Dy),e7=ebw(-cosw Dx+sinw Dy), e8=wDt, e9=zDz, e10=-yDx+xDy,  e11=xDx+yDy, e12=tDt, e13=Dw.

The symmetry algebra is a 13-dimensional indecomposable solvable algebra ℝ5 β‹Š ℝ8. Its nilradical is 8-dimensional abelian and spanned by e1, e2, e3, e4, e5, e6, e7, e8. The complement to the nilradical is abelian and spanned by e9, e10, e11, e12, e13.

A4.6ab, (b = 0)

Lie symmetries:

e1=Dy, e2=Dx, e3=Dz, e4=Dw, e5=tDt, e6=Dt,e7=zDz, e8=wDt, e9=xDx+yDy, e10=-yDx+xDy,  e11=eawDz, e12=sinw Dx+cosw Dy, e13=-cosw Dx+sinw Dy,e14=(ycosw +xsinw )Dx+(xcosw -ysinw)Dy,e15=-(xcosw -ysinw)Dx+(ycosw +xsinw)Dy.

The symmetry algebra is a 15-dimensional indecomposable algebra that has a non-trivial Levi decomposition.

The semi-simple part is 𝔰𝔩(2, ℝ) and is spanned by e13, e14, e15. The nilradical is abelian and is spanned by e1, e2, e3, e4, e5, e6, e7, e8 and the complement to the nilradical is abelian and spanned by e9, e10, e11, e12. Again the β€œextra” symmetry for b = 0 is explained by the fact that, for such a value, eq. (5.32) has a non-trivial solution.

CONFLICTS OF INTEREST

The authors declare they have no conflicts of interest.

AUTHORS’ CONTRIBUTION

All authors have equally contributed to this work.

FUNDING

This work received no external funding.

Footnotes

Data availability statement: The data that support the findings of this study are available from the corresponding author [HA], upon reasonable request.

REFERENCES

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Journal
Journal of Nonlinear Mathematical Physics
Volume-Issue
28 - 2
Pages
242 - 253
Publication Date
2021/04/10
ISSN (Online)
1776-0852
ISSN (Print)
1402-9251
DOI
10.2991/jnmp.k.210401.001How to use a DOI?
Copyright
Β© 2021 The Authors. Published by Atlantis Press B.V.
Open Access
This is an open access article distributed under the CC BY-NC 4.0 license (http://creativecommons.org/licenses/by-nc/4.0/).

Cite this article

TY  - JOUR
AU  - Hassan Almusawa
AU  - Ryad Ghanam
AU  - Gerard Thompson
PY  - 2021
DA  - 2021/04/10
TI  - Lie Symmetries of the Canonical Connection: Codimension One Abelian Nilradical Case
JO  - Journal of Nonlinear Mathematical Physics
SP  - 242
EP  - 253
VL  - 28
IS  - 2
SN  - 1776-0852
UR  - https://doi.org/10.2991/jnmp.k.210401.001
DO  - 10.2991/jnmp.k.210401.001
ID  - Almusawa2021
ER  -