We consider the Yang-Mills equations with a matrix gauge group $G$ on the de
Sitter dS$_4$, anti-de Sitter AdS$_4$ and Minkowski $R^{3,1}$ spaces. On all
these spaces one can introduce a doubly warped metric in the form $d s^2 =-d
u^2 + f^2 d v^2 +h^2 d s^2_{H^2}$, where $f$ and $h$ are the functions of $u$
and $d s^2_{H^2}$ is the metric on the two-dimensional hyperbolic space $H^2$.
We show that in the adiabatic limit, when the metric on $H^2$ is scaled down,
the Yang-Mills equations become the sigma-model equations describing harmonic
maps from a two-dimensional manifold (dS$_2$, AdS$_2$ or $R^{1,1}$,
respectively) into the based loop group $\Omega G=C^\infty (S^1, G)/G$ of
smooth maps from the boundary circle $S^1=\partial H^2$ of $H^2$ into the gauge
group $G$. From this correspondence and the implicit function theorem it
follows that the moduli space of Yang-Mills theory with a gauge group $G$ in
four dimensions is bijective to the moduli space of two-dimensional sigma model
with $\Omega G$ as the target space. The sigma-model field equations can be
reduced to equations of geodesics on $\Omega G$, solutions of which yield
magnetic-type configurations of Yang-Mills fields. The group $\Omega G$
naturally acts on their moduli space.Comment: 8 pages; v3: clarifying remarks and references adde

Popov, Alexander D.

Physics Letters B

English

arXiv

AbstractWe consider the Yang–Mills equations with a matrix gauge group G on the de Sitter dS4, anti-de Sitter AdS4 and Minkowski R3,1 spaces. On all these spaces one can introduce a doubly warped metric in the form ds2=−du2+f2dv2+h2dsH22, where f and h are the functions of u and dsH22 is the metric on the two-dimensional hyperbolic space H2. We show that in the adiabatic limit, when the metric on H2 is scaled down, the Yang–Mills equations become the sigma-model equations describing harmonic maps from a two-dimensional manifold (dS2, AdS2 or R1,1, respectively) into the based loop group ΩG=C∞(S1,G)/G of smooth maps from the boundary circle S1=∂H2 of H2 into the gauge group G. For compact groups G these harmonic map equations are reduced to equations of geodesics on ΩG, solutions of which yield magnetic-type configurations of Yang–Mills fields. The group ΩG naturally acts on their moduli space

Elsevier - Publisher Connector 

Loop groups in Yang–Mills theory 

We consider the Yang–Mills equations with a matrix gauge group G on the de Sitter dS4, anti-de Sitter AdS4 and Minkowski R3,1 spaces. On all these spaces one can introduce a doubly warped metric in the form ds2=−du2+f2dv2+h2dsH22, where f and h are the functions of u and dsH22 is the metric on the two-dimensional hyperbolic space H2. We show that in the adiabatic limit, when the metric on H2 is scaled down, the Yang–Mills equations become the sigma-model equations describing harmonic maps from a two-dimensional manifold (dS2, AdS2 or R1,1, respectively) into the based loop group ΩG=C∞(S1,G)/G of smooth maps from the boundary circle S1=∂H2 of H2 into the gauge group G. For compact groups G these harmonic map equations are reduced to equations of geodesics on ΩG, solutions of which yield magnetic-type configurations of Yang–Mills fields. The group ΩG naturally acts on their moduli space

Alexander D. Popov

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Loop groups in Yang–Mills theory

Physics Letters B 748 (2015) 439–442Contents lists available at ScienceDirect
Physics Letters B
www.elsevier.com/locate/physletb
Loop groups in Yang–Mills theory
Alexander D. Popov
Institut für Theoretische Physik, Leibniz Universität Hannover, Appelstraße 2, 30167 Hannover, Germany
a r t i c l e i n f o a b s t r a c t
Article history:
Received 27 May 2015
Received in revised form 29 June 2015
Accepted 17 July 2015
Available online 22 July 2015
Editor: M. Cveticˇ
We consider the Yang–Mills equations with a matrix gauge group G on the de Sitter dS4, anti-de Sitter 
AdS4 and Minkowski R3,1 spaces. On all these spaces one can introduce a doubly warped metric in 
the form ds2 = −du2 + f 2dv2 + h2ds2
H2
, where f and h are the functions of u and ds2
H2
is the metric 
on the two-dimensional hyperbolic space H2. We show that in the adiabatic limit, when the metric on 
H2 is scaled down, the Yang–Mills equations become the sigma-model equations describing harmonic 
maps from a two-dimensional manifold (dS2, AdS2 or R1,1, respectively) into the based loop group G =
C∞(S1, G)/G of smooth maps from the boundary circle S1 = ∂H2 of H2 into the gauge group G . For 
compact groups G these harmonic map equations are reduced to equations of geodesics on G , solutions 
of which yield magnetic-type conﬁgurations of Yang–Mills ﬁelds. The group G naturally acts on their 
moduli space.
© 2015 The Author. Published by Elsevier B.V. This is an open access article under the CC BY license 
(http://creativecommons.org/licenses/by/4.0/). Funded by SCOAP3.1. Introduction
It is well known that the self-dual Yang–Mills equations in the 
Euclidean space R4,0 have an inﬁnite-dimensional algebra of “hid-
den symmetries” (see [1–6] for discovering, reviews and more ref-
erences). For the Yang–Mills potentials with value in a Lie algebra 
g = LieG , where G is a matrix gauge group, among these symme-
tries there is the Lie algebra of the loop group LG = C∞(S1, G). 
Here we shall show that the same group is a part of the moduli 
space of solutions to the Yang–Mills equations on the Lorentzian 
manifolds dS4, AdS4 and R3,1 of constant positive, negative and 
zero curvature.
We will use the adiabatic limit method which was applied to the 
ﬁrst-order self-dual Yang–Mills equations on the product 1 × 2
of two Riemann surfaces in [7]. It was shown that when the met-
ric on the Riemann surface 2 shrinks to a point, the Yang–Mills 
instantons converge to holomorphic maps from 1 to the moduli 
space of ﬂat connections on 2. In [8] this limit was discussed in 
the framework of topological Yang–Mills theories on 1 × 2. We 
will apply the adiabatic method to the second-order Yang–Mills 
equations on Lorentzian four-manifolds of constant curvature and 
describe how to construct approximate solutions of the Yang–Mills 
equations. It will be shown that these conﬁgurations become exact 
solutions in the adiabatic limit and their moduli space is the tan-
gent space TG of the based loop group G . Thus, G is a “hid-
E-mail address: popov@itp.uni-hannover.de.http://dx.doi.org/10.1016/j.physletb.2015.07.041
0370-2693/© 2015 The Author. Published by Elsevier B.V. This is an open access article 
SCOAP3.den symmetry group” not only of the ﬁrst-order self-dual Yang–
Mills equations but also of the second-order Yang–Mills equations 
on Lorentzian manifolds R3,1, AdS4 and dS4.
2. Metrics
It is known that on the de Sitter dS4 and anti-de Sitter AdS4
spaces one can introduce (local) coordinates such that the metrics 
on these spaces will be a double warped metrics of the form [10]
dS4 : ds2+1 = −du2 + cosh2 u dv2 + sinh2 u ds2H2 , (1)
AdS4 : ds2−1 = −du2 + sin2 u dv2 + cos2 u ds2H2 , (2)
where the ﬁrst two terms are metrics on the spaces dS2 and AdS2, 
respectively. Here,
ds2H2 = dχ2 + sinh2 χ dϕ2 , (3)
is the metric on the two-dimensional hyperbolic space H2. This 
space has two-sheets H2 = H2+ ∪ H2− with the common boundary 
S1 at χ → +∞ for H2+ and χ → −∞ for H2− .
We introduce on the Minkowski space–time a metric similar 
to (1) and (2). In the Cartesian coordinates xμ , μ = 0, 1, 2, 3, the 
metric has the form
ds20 = ημνdxμdxν with (ημν) = diag(−1,1,1,1) . (4)
Let us introduce coordinates u, χ and ϕ byunder the CC BY license (http://creativecommons.org/licenses/by/4.0/). Funded by 
440 A.D. Popov / Physics Letters B 748 (2015) 439–442x0 = u coshχ , x1 = u sinhχ cosϕ and x2 = u sinhχ sinϕ ,
(5)
and keep x3 untouched. The coordinates (5) have a range
u =
(
(x0)2 − (x1)2 − (x2)2
)1/2
> 0 , χ ∈ (−∞,+∞) and
ϕ ∈ [0,2π ] . (6)
They cover the interior of the light cone in R2,1 and we denote 
this subset of R2,1 by R2,1+ . The region R
2,1
− = R2,1 \ R2,1+ can be 
covered by other choice of pseudospherical coordinates. In these 
coordinates the metric (4) acquires the form
ds20 = −du2 + (dx3)2 + u2 ds2H2 . (7)
From (7) we recognize a cone over H2, i.e. R2,1+ = C(H2) and we 
restrict ourselves to the subset R3,1+ = R × R2,1+ ⊂ R3,1. For the 
metrics (1) and (2) we also consider u > 0, since for u = 0 they 
degenerate.
After denoting x3 = v , we see that the metrics (1), (2) and (7)
have the same form
ds2 = −du2 + f 2dv2 + h2ds2H2 , (8)
where
f = coshu and h = sinhu for dS4
f = sinu and h = cosu for AdS4 (9)
f = 1 and h = u for R3,1
Therefore, we will consider all three spaces together by using the 
metric (8), specifying f and h if necessary. Recall that we work in 
local coordinates which cover only part of any of the considered 
spaces. This is enough for our purposes. For further uniﬁcation 
we introduce the coordinates (yμ) = (ya, yi) = (u, v, χ, ϕ), where 
μ = (a, i) with a, b, . . . = 0, 1 and i, j, . . . = 2, 3. Then metric (8)
can be written as
ds2 = gμνdyμdyν = gabdyadyb + gijdyidy j , (10)
where g = (gab) is the metric on the two-dimensional space 
which is (a patch of) dS2, AdS2 or R1,1 and (gij) = h2(gH2i j ) where 
gH2 = (gH2i j ) is the metric on H2.
Finally, as H2 we will consider only the upper sheet of the two-
dimensional hyperbolic space with χ ≥ 0 for all three metrics (1), 
(2), (7) and consider only y0 = u > 0 in (8)–(10). All other regions 
of our spaces dS4, AdS4, and R3,1 can be considered similarly.
3. Yang–Mills equations
So, we consider Yang–Mills theory on a Lorentzian 4-manifold 
M with local coordinates yμ and the metric given by (8)–(10). We 
start with the potential A =Aμdyμ with values in the Lie algebra 
g = LieG having scalar product deﬁned by the trace Tr. Here G
is an arbitrary matrix gauge group. The ﬁeld strength F = dA +
A ∧A is the g-valued two-form:
F = 12Fμνdyμ ∧ dyν with Fμν = ∂μAν − ∂νAμ + [Aμ,Aν ] .
(11)
The Yang–Mills equations on M with the metric given by (8)–(10)
are
DμFμν := 1√|det g| ∂μ(
√|det g|Fμν) + [Aμ,Fμν ] = 0 , (12)where g = (gμν) and indices are raised by gμν . We have the obvi-
ous splitting
A=Aμdyμ =Aadya +Aidyi , (13)
F = 12Fabdya ∧ dyb +Faidya ∧ dyi + 12Fi jdyi ∧ dy j . (14)
4. Adiabatic limit
By using the adiabatic approach [7–9,11], which is based on the 
ideas of [12], we deform the metric (8) and introduce
ds2ε = −du2 + f 2dv2 + ε2h2ds2H2 , (15)
where ε is a real parameter. Then | det gε| = ε4| det(gab)| det(gij)
and
Fabε = gacε gbdε Fcd =Fab, Faiε = ε−2Fai and
F i jε = ε−4F i j , (16)
where indices of Fμν are raised by the metric gμν from (10).
To avoid the divergent term ε−2 Tr(Fi jF i j) in the Lagrangian, 
we impose the ﬂatness condition
Fi j = 0 (17)
on the Yang–Mills curvature along H2 in M . For the deformed met-
ric (15) the Yang–Mills equations have the form
ε2DaFab + DiF ib = 0 , (18)
DaFaj + ε−2DiF i j = 0 , (19)
and in the limit ε → 0 (after choosing Fi j = 0) we have
DiF ib = 0 , (20)
DaFaj = 0 . (21)
5. Flat connections
Flat connection AH2 =Aidyi on H2 (upper sheet) has a simple 
form
AH2 = g−1dˆg with dˆ= dyi
∂
∂ yi
, (22)
where g = g(ya, yi) is a smooth map from H2 (for any given ya) 
into the gauge group G . We consider smooth matrix-valued func-
tions g with smooth boundary value on S1 = ∂H2 and impose 
additional condition g = Id at 1 ∈ S1 (framing of ﬂat connection 
on H2 [9]). We denote by C∞0 (H2, G) the space of all such g in 
(22). On H2, as on a manifold with the boundary, the group of 
gauge transformations is deﬁned as [9]
GH2 =
{
g : H2 → G | g|∂H2 = Id
}
. (23)
Hence the solution space of the equation FH2 = 0 is the inﬁnite-
dimensional group N = C∞0 (H2, G) and the moduli space is the 
based loop group [13]
M= G = C∞0 (H2,G)/GH2 . (24)
Recall that g and AH2 depend on coordinates ya .
A.D. Popov / Physics Letters B 748 (2015) 439–442 4416. Moduli space
On the group manifold (24) we introduce local coordinates φα
with α = 1, 2, . . . and assume that Aμ ’s depend on u and v only 
via the moduli parameters φα = φα(u, v). Then moduli of ﬂat con-
nections on H2 deﬁne a map
φ :  →M with φ(u, v) = {φα(u, v)} , (25)
where by  we denote (a patch of) dS2, AdS2 or R1,1 depending 
on choice of M in (8)–(9). These maps are constrained by the equa-
tions (20) and (21). Since AH2 is a ﬂat connection for any ya ∈ , 
the derivatives ∂aAi have to satisfy the linearized around AH2 ﬂat-
ness condition, i.e. ∂aAi belong to the tangent space TAN of the 
space N = C∞0 (H2, G) of ﬂat connections on H2. Using the pro-
jection π on the moduli space, π :N →M, one can decompose 
∂aAi into the two parts
TAN = π∗TAM⊕ TAG ⇔ ∂aAi = (∂aφβ)ξβi + Dia , (26)
where G is the gauge group (restricted to H2 by ﬁxing ya ∈ , 
G|H2 = GH2 ), {ξα = ξαidyi} is a local basis of tangent vectors on 
TAM (they form the Lie algebra g) and a are g-valued gauge 
parameters (Dia are tangent vectors from TAG) which are deter-
mined by the gauge-ﬁxing equations
gij Diξα j = 0 ⇔ gij Di∂aA j = gij Di D ja . (27)
In fact, since φα depend on ya ∈ , we have N = N (ya), G =
GH2(ya) and M =N /G =M(ya).
Recall that Ai are ﬁxed by (22) and Aa are yet free. For the 
mixed components of the ﬁeld strength we have
Fai = ∂aAi − DiAa = (∂aφβ)ξβi − Di(Aa − a) . (28)
It is natural to choose Aa = a [12,14] and obtain
Fai = (∂aφβ)ξβi = π∗∂aAi ∈ TAM . (29)
On the other hand, since Ai(φα, y j) depends on ya only via φα , 
we have
∂aAi = ∂Ai
∂φβ
∂φβ
∂ ya
(27)⇒ a =Aa = (∂aφβ)β (30)
with the gauge parameters α deﬁned by (27) via the equations
gij Di D jα = gij Di ∂A j
∂φα
. (31)
Thus, if we know φα(u, v) then we can construct
(Aμ) = (Aa,Ai) =
(
(∂aφ
β)β , g
−1(φβ, y j)∂i g(φβ, yk)
)
(32)
which should solve the equations (20) and (21).
7. Harmonic maps
Substituting (29) into (20), one can see that these equations are 
resolved due to (27), (30) and (31). On the other hand, substitution 
of (29) and (30) into (21) gives us the equations
1√|det g | ∂a
(√|det g | gab∂bφβ
)
gij
H2
ξβ j
+ gab gi j
H2
(Daξβ j)∂bφ
β = 0 , (33)
where g = (gab) is the metric on  and gH2 = (gH2i j ) is the metric 
on H2. Before proceeding further we introduce a metric G = (Gαβ)
on the moduli space M = G of ﬂat connections on H2 asGαβ ≡ 〈ξα, ξβ〉 = −
∫
H2
d vol gij
H2
Tr(ξαiξβ j) , (34)
where the integral is taken over H2 = H2+ . Multiplying (33) by ξαi
and integrating over H2 (projection on the moduli space), we ob-
tain
1√|det g | ∂a
(√|det g | gab∂bφβ
)
〈ξα, ξβ〉 + gab〈ξα, Daξβ〉∂bφβ
= 1√|det g | ∂a
(√|det g | gab∂bφβ
)
Gαβ
+ 〈ξα,∇γ ξβ〉gab∂aφγ ∂bφβ
= Gασ
{
1√|det g | ∂a
(√|det g | gab∂bφσ
)
+ σβγ gab∂aφβ∂bφγ
}
= 0 , (35)
where
σβγ = 12 Gσλ
(
∂γ Gβλ + ∂βGγ λ − ∂λGβγ
)
with
∂γ := ∂
∂φγ
, (36)
are the Christoffel symbols and ∇γ are the corresponding covariant 
derivatives on the moduli space G of ﬂat connections on H2.
The equations
1√|det g | ∂a
(√|det g | gab∂bφα
)
+ αβγ gab∂aφβ∂bφγ = 0
(37)
are the Euler–Lagrange equations for the effective action
Seff =
∫

dy1dy2
√|det g | gabGαβ∂aφα∂bφβ (38)
of the Yang–Mills theory on M which appears from the term 
Tr(FajFaj) in the initial Yang–Mills Lagrangian in the adiabatic 
limit ε → 0. The equations (37) are the standard sigma-model 
equations deﬁning harmonic maps from  (= dS2, AdS2, or R1,1) 
into the based loop group G parameterized (locally) by coordi-
nates φα . Note that solutions φα(u, v) exist and depend on both 
coordinates u and v only if the gauge group G is noncompact. For 
compact groups G solutions of (37) exist only if φα do not depend 
on u. Then equations (37) reduce to the geodesic equations on the 
loop group G and gives static conﬁgurations of Yang–Mills ﬁelds. 
This result can be considered as supplementing the result of [15], 
where only electric components of adiabatic Yang–Mills ﬁelds were 
nonvanishing. Note that any geodesic on G is parametrized by 
the initial point φ0 ∈ G and by the velocity φ˙0 ∈ T0G . Therefore, 
the moduli space of solutions (32) (with ∂vφ = 0 and ∂uφ =: φ˙) 
can be identiﬁed with the tangent bundle TG of G . The based 
loop group G naturally acts on TG which can be identiﬁed 
with the semi-direct product G  g of G and its Lie algebra 
g = LieG
8. Concluding remarks
In conclusion we recall that in the Euclidean case Atiyah has 
shown [16] that the moduli space of instantons over R4,0 is bi-
jective to the moduli space of holomorphic maps from S2 to G . 
There is a conjecture (see e.g. [17]) that the moduli space of solu-
442 A.D. Popov / Physics Letters B 748 (2015) 439–442tions of the second-order Yang–Mills equations on R4,0 is bijective 
to the moduli space of harmonic maps from S2 to G . Our con-
sideration in this paper can be repeated for the Euclidean space. 
In [18] it was observed that R4 ∪ {∞} \ S1 = S4 \ S1 is confor-
mally diffeomorphic to the product manifold S2 × H2. Considering 
M = S2 × H2 and literally repeating our calculations for this Eu-
clidean manifold we will arrive to the equations (37) with  = S2. 
These equations will deﬁne harmonic maps from S2 into the based 
loop group G . Furthermore, from the implicit function theorem 
it follows that near every solution φ of (37) with  = S2 (and the 
corresponding solution Aε=0 of the Yang–Mills equations) there 
exists a solution Aε>0 of the Yang–Mills equations on M for ε suf-
ﬁciently small (cf. with the instanton case [7,9,18]). In other words, 
solutions of (37) with  = S2 approximate solutions of the Yang–
Mills equations on M = S2 × H2 (and on R4,0 after some maps [9,
18] from S2 × H2 to R4,0) and one can conjecture that the moduli 
spaces for Aε=0 and Aε>0 are bijective.
Acknowledgements
I would like to thank Olaf Lechtenfeld for valuable remarks. This 
work was partially supported by the Deutsche Forschungsgemein-
schaft grant LE 838/13.
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We consider the Yang-Mills equations with a matrix gauge group G on the de Sitter dS4, anti-de Sitter AdS4 and Minkowski R3,1R3,1 spaces. On all these spaces one can introduce a doubly warped metric in the form View the MathML sourceds2=−du2+f2dv2+h2dsH22, where f and h are the functions of u   and View the MathML sourcedsH22 is the metric on the two-dimensional hyperbolic space H2H2. We show that in the adiabatic limit, when the metric on H2H2 is scaled down, the Yang–Mills equations become the sigma-model equations describing harmonic maps from a two-dimensional manifold (dS2, AdS2 or R1,1R1,1, respectively) into the based loop group ΩG=C∞(S1,G)/GΩG=C∞(S1,G)/G of smooth maps from the boundary circle S1=∂H2S1=∂H2 of H2H2 into the gauge group G. For compact groups G these harmonic map equations are reduced to equations of geodesics on ΩG, solutions of which yield magnetic-type configurations of Yang–Mills fields. The group ΩG naturally acts on their moduli space.DFG/LE 838/1

Institutionelles Repositorium der Leibniz Universität Hannover

Physics Letters B 748 (2015) 439–442Contents lists available at ScienceDirectPhysics Letters Bwww.elsevier.com/locate/physletbLoop groups in Yang–Mills theoryAlexander D. PopovInstitut für Theoretische Physik, Leibniz Universität Hannover, Appelstraße 2, 30167 Hannover, Germanya r t i c l e i n f o a b s t r a c tArticle history:Received 27 May 2015Received in revised form 29 June 2015Accepted 17 July 2015Available online 22 July 2015Editor: M. CveticˇWe consider the Yang–Mills equations with a matrix gauge group G on the de Sitter dS4, anti-de Sitter AdS4 and Minkowski R3,1 spaces. On all these spaces one can introduce a doubly warped metric in the form ds2 = −du2 + f 2dv2 + h2ds2H2, where f and h are the functions of u and ds2H2is the metric on the two-dimensional hyperbolic space H2. We show that in the adiabatic limit, when the metric on H2 is scaled down, the Yang–Mills equations become the sigma-model equations describing harmonic maps from a two-dimensional manifold (dS2, AdS2 or R1,1, respectively) into the based loop group G =C∞(S1, G)/G of smooth maps from the boundary circle S1 = ∂H2 of H2 into the gauge group G . For compact groups G these harmonic map equations are reduced to equations of geodesics on G , solutions of which yield magnetic-type conﬁgurations of Yang–Mills ﬁelds. The group G naturally acts on their moduli space.© 2015 The Author. Published by Elsevier B.V. This is an open access article under the CC BY license (http://creativecommons.org/licenses/by/4.0/). Funded by SCOAP3.1. IntroductionIt is well known that the self-dual Yang–Mills equations in the Euclidean space R4,0 have an inﬁnite-dimensional algebra of “hid-den symmetries” (see [1–6] for discovering, reviews and more ref-erences). For the Yang–Mills potentials with value in a Lie algebra g = LieG , where G is a matrix gauge group, among these symme-tries there is the Lie algebra of the loop group LG = C∞(S1, G). Here we shall show that the same group is a part of the moduli space of solutions to the Yang–Mills equations on the Lorentzian manifolds dS4, AdS4 and R3,1 of constant positive, negative and zero curvature.We will use the adiabatic limit method which was applied to the ﬁrst-order self-dual Yang–Mills equations on the product 1 × 2of two Riemann surfaces in [7]. It was shown that when the met-ric on the Riemann surface 2 shrinks to a point, the Yang–Mills instantons converge to holomorphic maps from 1 to the moduli space of ﬂat connections on 2. In [8] this limit was discussed in the framework of topological Yang–Mills theories on 1 × 2. We will apply the adiabatic method to the second-order Yang–Mills equations on Lorentzian four-manifolds of constant curvature and describe how to construct approximate solutions of the Yang–Mills equations. It will be shown that these conﬁgurations become exact solutions in the adiabatic limit and their moduli space is the tan-gent space TG of the based loop group G . Thus, G is a “hid-E-mail address: popov@itp.uni-hannover.de.http://dx.doi.org/10.1016/j.physletb.2015.07.0410370-2693/© 2015 The Author. Published by Elsevier B.V. This is an open access article SCOAP3.den symmetry group” not only of the ﬁrst-order self-dual Yang–Mills equations but also of the second-order Yang–Mills equations on Lorentzian manifolds R3,1, AdS4 and dS4.2. MetricsIt is known that on the de Sitter dS4 and anti-de Sitter AdS4spaces one can introduce (local) coordinates such that the metrics on these spaces will be a double warped metrics of the form [10]dS4 : ds2+1 = −du2 + cosh2 u dv2 + sinh2 u ds2H2 , (1)AdS4 : ds2−1 = −du2 + sin2 u dv2 + cos2 u ds2H2 , (2)where the ﬁrst two terms are metrics on the spaces dS2 and AdS2, respectively. Here,ds2H2 = dχ2 + sinh2 χ dϕ2 , (3)is the metric on the two-dimensional hyperbolic space H2. This space has two-sheets H2 = H2+ ∪ H2− with the common boundary S1 at χ → +∞ for H2+ and χ → −∞ for H2− .We introduce on the Minkowski space–time a metric similar to (1) and (2). In the Cartesian coordinates xμ , μ = 0, 1, 2, 3, the metric has the formds20 = ημνdxμdxν with (ημν) = diag(−1,1,1,1) . (4)Let us introduce coordinates u, χ and ϕ byunder the CC BY license (http://creativecommons.org/licenses/by/4.0/). Funded by 440 A.D. Popov / Physics Letters B 748 (2015) 439–442x0 = u coshχ , x1 = u sinhχ cosϕ and x2 = u sinhχ sinϕ ,(5)and keep x3 untouched. The coordinates (5) have a rangeu =((x0)2 − (x1)2 − (x2)2)1/2> 0 , χ ∈ (−∞,+∞) andϕ ∈ [0,2π ] . (6)They cover the interior of the light cone in R2,1 and we denote this subset of R2,1 by R2,1+ . The region R2,1− = R2,1 \ R2,1+ can be covered by other choice of pseudospherical coordinates. In these coordinates the metric (4) acquires the formds20 = −du2 + (dx3)2 + u2 ds2H2 . (7)From (7) we recognize a cone over H2, i.e. R2,1+ = C(H2) and we restrict ourselves to the subset R3,1+ = R × R2,1+ ⊂ R3,1. For the metrics (1) and (2) we also consider u > 0, since for u = 0 they degenerate.After denoting x3 = v , we see that the metrics (1), (2) and (7)have the same formds2 = −du2 + f 2dv2 + h2ds2H2 , (8)wheref = coshu and h = sinhu for dS4f = sinu and h = cosu for AdS4 (9)f = 1 and h = u for R3,1Therefore, we will consider all three spaces together by using the metric (8), specifying f and h if necessary. Recall that we work in local coordinates which cover only part of any of the considered spaces. This is enough for our purposes. For further uniﬁcation we introduce the coordinates (yμ) = (ya, yi) = (u, v, χ, ϕ), where μ = (a, i) with a, b, . . . = 0, 1 and i, j, . . . = 2, 3. Then metric (8)can be written asds2 = gμνdyμdyν = gabdyadyb + gijdyidy j , (10)where g = (gab) is the metric on the two-dimensional space which is (a patch of) dS2, AdS2 or R1,1 and (gij) = h2(gH2i j ) where gH2 = (gH2i j ) is the metric on H2.Finally, as H2 we will consider only the upper sheet of the two-dimensional hyperbolic space with χ ≥ 0 for all three metrics (1), (2), (7) and consider only y0 = u > 0 in (8)–(10). All other regions of our spaces dS4, AdS4, and R3,1 can be considered similarly.3. Yang–Mills equationsSo, we consider Yang–Mills theory on a Lorentzian 4-manifold M with local coordinates yμ and the metric given by (8)–(10). We start with the potential A =Aμdyμ with values in the Lie algebra g = LieG having scalar product deﬁned by the trace Tr. Here Gis an arbitrary matrix gauge group. The ﬁeld strength F = dA +A ∧A is the g-valued two-form:F = 12Fμνdyμ ∧ dyν with Fμν = ∂μAν − ∂νAμ + [Aμ,Aν ] .(11)The Yang–Mills equations on M with the metric given by (8)–(10)areDμFμν := 1√|det g| ∂μ(√|det g|Fμν) + [Aμ,Fμν ] = 0 , (12)where g = (gμν) and indices are raised by gμν . We have the obvi-ous splittingA=Aμdyμ =Aadya +Aidyi , (13)F = 12Fabdya ∧ dyb +Faidya ∧ dyi + 12Fi jdyi ∧ dy j . (14)4. Adiabatic limitBy using the adiabatic approach [7–9,11], which is based on the ideas of [12], we deform the metric (8) and introduceds2ε = −du2 + f 2dv2 + ε2h2ds2H2 , (15)where ε is a real parameter. Then | det gε| = ε4| det(gab)| det(gij)andFabε = gacε gbdε Fcd =Fab, Faiε = ε−2Fai andF i jε = ε−4F i j , (16)where indices of Fμν are raised by the metric gμν from (10).To avoid the divergent term ε−2 Tr(Fi jF i j) in the Lagrangian, we impose the ﬂatness conditionFi j = 0 (17)on the Yang–Mills curvature along H2 in M . For the deformed met-ric (15) the Yang–Mills equations have the formε2DaFab + DiF ib = 0 , (18)DaFaj + ε−2DiF i j = 0 , (19)and in the limit ε → 0 (after choosing Fi j = 0) we haveDiF ib = 0 , (20)DaFaj = 0 . (21)5. Flat connectionsFlat connection AH2 =Aidyi on H2 (upper sheet) has a simple formAH2 = g−1dˆg with dˆ= dyi∂∂ yi, (22)where g = g(ya, yi) is a smooth map from H2 (for any given ya) into the gauge group G . We consider smooth matrix-valued func-tions g with smooth boundary value on S1 = ∂H2 and impose additional condition g = Id at 1 ∈ S1 (framing of ﬂat connection on H2 [9]). We denote by C∞0 (H2, G) the space of all such g in (22). On H2, as on a manifold with the boundary, the group of gauge transformations is deﬁned as [9]GH2 ={g : H2 → G | g|∂H2 = Id}. (23)Hence the solution space of the equation FH2 = 0 is the inﬁnite-dimensional group N = C∞0 (H2, G) and the moduli space is the based loop group [13]M= G = C∞0 (H2,G)/GH2 . (24)Recall that g and AH2 depend on coordinates ya .A.D. Popov / Physics Letters B 748 (2015) 439–442 4416. Moduli spaceOn the group manifold (24) we introduce local coordinates φαwith α = 1, 2, . . . and assume that Aμ ’s depend on u and v only via the moduli parameters φα = φα(u, v). Then moduli of ﬂat con-nections on H2 deﬁne a mapφ :  →M with φ(u, v) = {φα(u, v)} , (25)where by  we denote (a patch of) dS2, AdS2 or R1,1 depending on choice of M in (8)–(9). These maps are constrained by the equa-tions (20) and (21). Since AH2 is a ﬂat connection for any ya ∈ , the derivatives ∂aAi have to satisfy the linearized around AH2 ﬂat-ness condition, i.e. ∂aAi belong to the tangent space TAN of the space N = C∞0 (H2, G) of ﬂat connections on H2. Using the pro-jection π on the moduli space, π :N →M, one can decompose ∂aAi into the two partsTAN = π∗TAM⊕ TAG ⇔ ∂aAi = (∂aφβ)ξβi + Dia , (26)where G is the gauge group (restricted to H2 by ﬁxing ya ∈ , G|H2 = GH2 ), {ξα = ξαidyi} is a local basis of tangent vectors on TAM (they form the Lie algebra g) and a are g-valued gauge parameters (Dia are tangent vectors from TAG) which are deter-mined by the gauge-ﬁxing equationsgij Diξα j = 0 ⇔ gij Di∂aA j = gij Di D ja . (27)In fact, since φα depend on ya ∈ , we have N = N (ya), G =GH2(ya) and M =N /G =M(ya).Recall that Ai are ﬁxed by (22) and Aa are yet free. For the mixed components of the ﬁeld strength we haveFai = ∂aAi − DiAa = (∂aφβ)ξβi − Di(Aa − a) . (28)It is natural to choose Aa = a [12,14] and obtainFai = (∂aφβ)ξβi = π∗∂aAi ∈ TAM . (29)On the other hand, since Ai(φα, y j) depends on ya only via φα , we have∂aAi = ∂Ai∂φβ∂φβ∂ ya(27)⇒ a =Aa = (∂aφβ)β (30)with the gauge parameters α deﬁned by (27) via the equationsgij Di D jα = gij Di ∂A j∂φα. (31)Thus, if we know φα(u, v) then we can construct(Aμ) = (Aa,Ai) =((∂aφβ)β , g−1(φβ, y j)∂i g(φβ, yk))(32)which should solve the equations (20) and (21).7. Harmonic mapsSubstituting (29) into (20), one can see that these equations are resolved due to (27), (30) and (31). On the other hand, substitution of (29) and (30) into (21) gives us the equations1√|det g | ∂a(√|det g | gab∂bφβ)gijH2ξβ j+ gab gi jH2(Daξβ j)∂bφβ = 0 , (33)where g = (gab) is the metric on  and gH2 = (gH2i j ) is the metric on H2. Before proceeding further we introduce a metric G = (Gαβ)on the moduli space M = G of ﬂat connections on H2 asGαβ ≡ 〈ξα, ξβ〉 = −∫H2d vol gijH2Tr(ξαiξβ j) , (34)where the integral is taken over H2 = H2+ . Multiplying (33) by ξαiand integrating over H2 (projection on the moduli space), we ob-tain1√|det g | ∂a(√|det g | gab∂bφβ)〈ξα, ξβ〉 + gab〈ξα, Daξβ〉∂bφβ= 1√|det g | ∂a(√|det g | gab∂bφβ)Gαβ+ 〈ξα,∇γ ξβ〉gab∂aφγ ∂bφβ= Gασ{1√|det g | ∂a(√|det g | gab∂bφσ)+ σβγ gab∂aφβ∂bφγ}= 0 , (35)whereσβγ = 12 Gσλ(∂γ Gβλ + ∂βGγ λ − ∂λGβγ)with∂γ := ∂∂φγ, (36)are the Christoffel symbols and ∇γ are the corresponding covariant derivatives on the moduli space G of ﬂat connections on H2.The equations1√|det g | ∂a(√|det g | gab∂bφα)+ αβγ gab∂aφβ∂bφγ = 0(37)are the Euler–Lagrange equations for the effective actionSeff =∫dy1dy2√|det g | gabGαβ∂aφα∂bφβ (38)of the Yang–Mills theory on M which appears from the term Tr(FajFaj) in the initial Yang–Mills Lagrangian in the adiabatic limit ε → 0. The equations (37) are the standard sigma-model equations deﬁning harmonic maps from  (= dS2, AdS2, or R1,1) into the based loop group G parameterized (locally) by coordi-nates φα . Note that solutions φα(u, v) exist and depend on both coordinates u and v only if the gauge group G is noncompact. For compact groups G solutions of (37) exist only if φα do not depend on u. Then equations (37) reduce to the geodesic equations on the loop group G and gives static conﬁgurations of Yang–Mills ﬁelds. This result can be considered as supplementing the result of [15], where only electric components of adiabatic Yang–Mills ﬁelds were nonvanishing. Note that any geodesic on G is parametrized by the initial point φ0 ∈ G and by the velocity φ˙0 ∈ T0G . Therefore, the moduli space of solutions (32) (with ∂vφ = 0 and ∂uφ =: φ˙) can be identiﬁed with the tangent bundle TG of G . The based loop group G naturally acts on TG which can be identiﬁed with the semi-direct product G  g of G and its Lie algebra g = LieG8. Concluding remarksIn conclusion we recall that in the Euclidean case Atiyah has shown [16] that the moduli space of instantons over R4,0 is bi-jective to the moduli space of holomorphic maps from S2 to G . There is a conjecture (see e.g. [17]) that the moduli space of solu-442 A.D. Popov / Physics Letters B 748 (2015) 439–442tions of the second-order Yang–Mills equations on R4,0 is bijective to the moduli space of harmonic maps from S2 to G . Our con-sideration in this paper can be repeated for the Euclidean space. In [18] it was observed that R4 ∪ {∞} \ S1 = S4 \ S1 is confor-mally diffeomorphic to the product manifold S2 × H2. Considering M = S2 × H2 and literally repeating our calculations for this Eu-clidean manifold we will arrive to the equations (37) with  = S2. These equations will deﬁne harmonic maps from S2 into the based loop group G . Furthermore, from the implicit function theorem it follows that near every solution φ of (37) with  = S2 (and the corresponding solution Aε=0 of the Yang–Mills equations) there exists a solution Aε>0 of the Yang–Mills equations on M for ε suf-ﬁciently small (cf. with the instanton case [7,9,18]). In other words, solutions of (37) with  = S2 approximate solutions of the Yang–Mills equations on M = S2 × H2 (and on R4,0 after some maps [9,18] from S2 × H2 to R4,0) and one can conjecture that the moduli spaces for Aε=0 and Aε>0 are bijective.AcknowledgementsI would like to thank Olaf Lechtenfeld for valuable remarks. This work was partially supported by the Deutsche Forschungsgemein-schaft grant LE 838/13.References[1] L. Dolan, A new symmetry group of real self-dual Yang–Mills, Phys. Lett. B 113 (1982) 387.[2] L. Dolan, Kac–Moody algebras and exact solvability in hadronic physics, Phys. Rep. 109 (1984) 1.[3] L.-L. Chau, M.-L. Ge, Y.-S. 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Loop groups in Yang-Mills theory

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