Threshold Corrections to the MSSM Finite-Temperature Higgs Potential

doi:10.4236/jmp.2011.25039

Journal of Modern Physics, 2011, 2, 301-322

doi:10.4236/jmp.2011.25039 Published Online May 2011 (http://www.SciRP.org/journal/jmp)

Threshold Corrections to the MSSM Finite-Temperature

Higgs Potential

Mikhail Dolgopolov1, Mikhail Dubinin2, Elza Rykova1

1Samara State University, Samara, Russia

2Skobeltsyn Institute of Nuclear Physics, Moscow State University, Moscow, Russia

E-mail: {mikhaildolgopolov, elzarykova}@rambler.ru, dubinin@theory.sinp.msu.ru

Received January 18, 2011; revised February 23, 2011; accepted March 7, 2011

Abstract

In the minimal supersymmetric standard model (MSSM) the one-loop finite-temperature corrections from

the squark-Higgs bosons sector are calculated, the effective two-Higgs-doublet potential is reconstructed and

possibilities of the electroweak phase transition in full MSSM (

H

m



,tan



,,tb

A

,



,Q

m,U

m,

D

m) parameter

space are studied. At large values of ,tb

A

and



of around 1 TeV, favored indirectly by LEP2 and Teva-

tron data, the threshold finite-temperature corrections from triangle and box diagrams with intermediate third

generation squarks are very substantial. Four types of bifurcation sets are defined for the two-Higgs-doublet

potential. High sensitivity of the low-temperature evolution to the effective two-doublet and the MSSM

squark sector parameters is observed, but rather extensive regions of the full MSSM parameter space allow

the first-order electroweak phase transition respecting the phenomenological constraints at zero temperature.

As a rule, these regions of the MSSM parameter space are in line with the case of a light stop quark.

Keywords: Supersymmetry, Higgs Boson, Electroweak Phase Transition, Critical Temperature

1. Introduction

The absence of antimatter in the Universe (the baryon

asymmetry), a small ratio of the observed number of ba-

ryons to the observed number of photons 10

610

B

nn







and the absence of light (100

H

m GeV) CP-even Higgs

boson signal at LEP2 and Tevatron energies lay a spe-

cific claim to models of particle physics. The baryon

asymmetry and an extremely small B

nn



could be

understood on the basis of Sakharov conditions, which

are respected at the electroweak phase transition, expected

to take place at the temperature of the order of 102 GeV

[1]. Generation of nonzero vacuum expectation value v

of the scalar field breaks the electroweak symmetry

 

21

f

Y

SU U to the electromagnetic symmetry



1em

U. It is well-known [2] that in the simple isoscalar

model with the standard-like Higgs potential





U



22 4

11

24





 , describing a thermodynamically

equilibrium system of the scalar particles at the tempera-

ture T, the equation for the vacuum expectation value



vT has two solutions:



00v and



22

vT







24T, demonstrating the second order phase transition

at the critical temperature





220

c

Tv



, see

Figure 1(a) The thermal Higgs boson mass 2

h

m

22

4T



  vanishes at the critical temperature c

T

thus restoring the spontaneously broken symmetry.

However, in the cosmological evolution the stages

with thermodynamically non equilibrium plasma and the

first order phase transitions (see a typical



vT contour

in Figure 1(b)) are very important, so such simple pic-

ture in combination with the standard model CP-viola-

tion by means of the CKM mixing matrix turns out to be

not sufficient to justify the observed ratio of baryon

number to entropy. The situation becomes better in the

minimal supersymmetric model (MSSM) where sparti-

cles, extended two-doublet Higgs sector with the two

background fields and nonstandard sources of CP-viola-

tion provide a number of new possibilities. In a number

of approaches [3] the electroweak phase transition is

defined by evolution of the finite temperature effective

Higgs potential involving the cubic term in the back-

ground scalar fields 12

,vv.

The larger this term is, the stronger pronounced turns

out to be the first order phase transition, which is essen-

tial for consistency with the Higgs boson mass beyond

M. DOLGOPOLOV ET AL.

302

(a)

(b)

Figure 1. Contours on the (v, T) plane for (a) the second

order phase transition (fracture point) and (b) the first or-

der phase transition at the critical temperature Tc .

the LEP2 exclusion 115 GeV

H

m. Enhancement of

the cubic term in the MSSM at the one-loop level is sub-

stantial in the class of MSSM scenarios with a light right

stop [4]. Temperature loop corrections from the stop and

other additional scalar states could be large and lead to the

first order phase transition, the intensity of the latter de-

pends or



cc

vT T



, where

 

22

12ccc

vTvT vT

is the vacuum expectation value at the critical tempera-

ture c

T. The electroweak baryogenesis could be ex-

plained if



1

cc

vT T [5], the case of strong first order

phase transition.

In a number of analyses the MSSM finite-temperature

effective potential is taken in the representation

 



012 1

1

,,,0 ,0

()(),

eff

ring

VvT VvvVmv

VT VT



 (1)

where 0

V is the tree-level MSSM two-doublet potential

at the SUSY scale, 1

V is the (non-temperature) one-

loop resumed Coleman-Weinberg term, dominated by

stop and sbottom contributions,



1

VT is the one-loop

temperature term and ring

V is the correction of re-

summed leading infrared contribution from multi-loop

ring (or daisy) diagrams. The MSSM relations between

the









21

L

Y

SU U gauge couplings 2

g

and 1

g

, and

the quartic parameters 1, 2,3 ,4



of the potential 01 2

(, ,0)Vvv

are very restrictive. Only two additional parameters

21

tan vv





and

H

m



(charged scalar mass) determine

the zero-temperature two-doublet Higgs sector at tree-

level. The one-loop radiative corrections, both logarith-

mic and non-logarithmic generated at the threshold

SUSY

M, can change strongly the tree-level picture. They

depend on the parameters (,tb

A

,



,Q

m,U

m,

D

m) of the

scalar quarks-Higgs bosons interaction sector. In most

cases for the analysis in the representation (1) numerical

methods are used to find the critical temperature c

T, for

example, by solving the equation for the determinant of

second derivatives of the potential (1) at 1,2 0v



[6].

Then the two background fields



1,2 c

vT are found at

the minimum using the minimization conditions (i.e. the

absence of linear terms of the effective potential repre-

sentation in the “shifted” fields). The first order phase

transition strength is dependent on the cubic term 3

ETv

which appears from the infrared region.

Numerical high-precision Monte Carlo simulations on

the lattice [7] have been developed and applied to MSSM

in connection with the infrared problem [8] inherent to

all analyses based on the effective potentials. Infrared

divergences appear in the integration over bosonic static

(00





) Matsubara modes, which in the loop expansion

for the three-dimensional momentum space correspond

to the intermediate massless bosons. The non-perturbat-

ive investigations of the problem have been performed in

the framework of high-temperature dimensional reduc-

tion [9,10], when an effective three-dimensional MSSM

with the same Green’s functions as in the four-dimen-

sional MSSM for the light bosons is constructed [11-13]

by integrating out perturbatively the non-static modes.

Corrections from squarks and gauge bosons are intro-

duced after the reduction to the three-dimensional model.

In order to cover the temperature range from very low

temperatures to temperatures of the order of critical, the

following analysis uses an approach developed in [14,15]

for the general (non-temperature) two-Higgs doublet

potential with complex-valued parameters 2

12



, 5



, 6



and 7



, which violates the CP-invariance explicitly.

However, in this publication a simplified situation of the

Higgs potential in the CP conserving limit is considered

(the imaginary parts of the effective parameters 5,6,7



and 2

12



are taken to be zero). Full MSSM effective

potential in the generic 1



,2

 basis has the form

M. DOLGOPOLOV ET AL.

303







22

121 112 22

2*2

1212122 1

22

1112 22

311 2241221

55

12 1221 21

*

61112611 21

*

722 1272221

,

22

eff

U







 



 

 



 

 

 

 

(2)

where the background fields (vev’s) are

1





1

0, 2v and



22

0, 2v . The tem-

perature corrections from squarks, both logarithmic and

non- logarithmic (at the SUSY threshold) are incorpo-

rated to 17

,,



. In [14,15] (see also [16]) a nonlinear

transformation for masses and mixing angles i







67

,, ,,,,

ihHA

H

mm mm









, 1,, 5i to the Higgs

bosons mass basis can be found for a general case (h,

H

and

A

are the neutral and

H

,

H

 are the charged

Higgs bosons,



is the h-

H

mixing angle, tan



21

vv)

 



2

22

12

2

,()

22

2

,,, interaction terms

hH

eff

A

H

mm

UhhHH

mAAmH H

hH AH







 





(3)

which allows to work with symbolic expressions for the

temperature-dependent Higgs boson mass eigenstates.

In Section 2 various one-loop temperature corrections

to the potential are calculated. Section 3 contains some

examples of the electroweak phase transition for finite-

temperature effective potential reconstructed in the full

MSSM parameter space. The potential of scalar quarks -

Higgs bosons interaction and some technical details of

evaluation can be found in the Appendix.

2. Finite Temperature Corrections of

Squarks

In the finite temperature field theory Feynman diagrams

with boson propagators, containing Matsubara frequen-

cies 2π

nnT



 (0, 1,2,n), lead to structures of

the form





12 3222

1

d

,,,,

2π

b

ni

nj

ImmmTm





 







k

k

 (4)

Here k is the three-dimensional momentum in a system

with the temperature T. In the following calculations first

we perform integration with respect to k and then take

the sum, using the reduction to three-dimensional theory

in the high-temperature limit for zero frequencies. At

0n



, the result is [17,18]







12

32

3

,,,

1π32

22π

2π

,32,

b

Imm m

b

TT b

SMb









(5)

where





32

22

1

2

1

(, 32)d,

.

2π

b

n

SMb x

nM

m

MT







 











(6)

For 1b the parameter 2

m is a linear function de-

pendent on 2

i

m and the variables





d

x

of Feynman

parametrization, which are the integration variables in

(6). At the integer values of b the integrand in (3) is a

generalized Hurwitz zeta-function [19]. Note that for the

leading threshold corrections to effective parameters of

the two-doublet potential 2b, so the wave-function

renormalization appears in connection with the diver-

gence at 2b



(which is suppressed by vertex factors,

see [14]).

A number of integrals can be easily calculated. The

integral J0 is calculated









012 32222

12

d1

,

2π

1,

4π

Jaa aa

aa





k

kk

(7)

taking a residue in the spherical coordinate system. Here

2

1;2

a are the sums of squared frequency and squared

mass, see (7). Derivatives of 0

J

with respect to 1

a

and 2

a can be used for calculation of integrals







11 232

22 22

12

0

2

11 11 2

d1

[,]

2π

11

28π

Jaa

aa

J

aa aaa





 



k

kk

(8)









212 322

22 22

12

2

0

3

121 212 12

d1

,

2π

11

.

48π

Jaa

aa

J

aaa aaa aa







 

k

kk

(9)

and1

1The same results for 3

J

and 4

J

can be found in [11] and [12],

where they appear in the context of high temperature dimensional re-

duction.

M. DOLGOPOLOV ET AL.

304











31233222222

123

121323

d1

,,

2π

1,

4π

Jaaa aaa

aaaaaa



k

kkk

(10)









41 2 332

22 2222

123

2

11 21323

d1

[, , ]

2π

2,

8π

Jaaa

aaa

aa aa aaa







k

kkk

(11)

Thus, the procedure of Feynman parametrization is not

used. Substitution of 22222

11

4πanTm and 2

2

a



22 22

2

4πnT m to (7) and summation over Matsubara

frequencies after the integration gives

 



0120 12

,0

22 2222 22

,0 12

,,

1.

4π4π4π

n

nn

Imm Jmm

nT mnT m



 



 



 



 (12)

or, after redefinition of mass parameters 1;2

M



1; 22πmT the temperature corrections to effective po-

tential are expressed by summed integrals





112 42

2

22 2222

,0

11 2

1

,64π

1,

nn

IMM T

Mn MnMn



 







 (13)



21 254

3

22 222222

,0

12 12

1

[,]

256π

1.

nn

IMM T

MnMn MnMn



 





 



(14)

Note that the series (12) are divergent, but the deriva-

tives (13) and (14) are convergent for all 1;2

M

. In the

following it will be convenient to keep separately terms

for zero and nonzero modes in the sum. Both terms will

be temperature-dependent since the zero-mode integrals

coincide with (7) - (9), where 22

ii

am and the factor

T should be accounted for. Numerical check of the zero

temperature limiting case 0T demonstrates that the

non-temperature field theory results are successfully re-

produced. In the high-temperature limit the zero mode

gives dominant contribution in agreement with a known

suppression of quantum effects at increasing tempera-

tures.

The sum of integrals (13) and (14) can be expressed

by means of the generalized zeta-function. Such forms

can be derived if Feynman parameters are introduced in

the integrand of (7)



2222

1

2

022 22

1

d,

1

ab

mm

x

mxm x











 





kk

(15)

Redefinition of 2πTkpk and denomination









2222

,,

aba bb

M

MMxMMxM  gives



1

42

2222 0222

11d

.

2π

ab

x

mmTnM





 

 

kk p

(6)

and divergent series for (7) (



3

d2πdTkp)







0

1

32

0222

,0

,

1d1

d,

2π2π

ab

nn

IMM

x

TnM



 

 





p

(17)

With the help of dimensional regularization or differ-

entiating the integral



2

32

22

d1

4π

2

MM

OT

M

e



 



p

p (18)

over the parameter

M

, equation (17) can be reduced to



12

020

11

,d 2,,,

2

16π

ab

IMMx M

T









 (19)

where





,,ust



is the generalized Hurwitz zeta-func-

tion [19]:2



1

,,.

s

u

n

ust

nt









 (20)

So in the case under consideration sums of integrals

(13) and (14) can be calculated by differentiation of (19)

with respect to mass parameters participating in

M







,,

ab

M

MMx. Differentiation increases the power

s

in the denominator of (19) giving convergent integrals





10

12

42 0

,2

13

d 2,,,

2

64 π

ab

aa

T

IMM I

MM

x

xMx

T









 





(21)





 

21

12

64 0

1

,2

35

d 1 2,,.

2

256π

ab

bb

IMM I

MM

x

xx Mx

T





 













(22)

The integrals (21) and (22) are equal to the series (13)

2Note that (non-generalized) Hurwitz zeta-function is defined by





1

0

,

s

nt

n

st











.

M. DOLGOPOLOV ET AL.

305

and (14), respectively.

Threshold corrections from the triangle and box dia-

grams, shown in Figure 2, are denoted by th

i





,

1,, 7i. They contribute additively to the parameters

SUSY th

iii





. In the following normalization con-

ventions from [14] are used. Calculation of the finite-

temperature diagrams for the general case of complex-

valued



and ,tb

A

gives the result (see some details

in the Appendix)



44

12 2

22

2

22

12

111

22 2

2

212

1

22

11

3,3 ,

3,2 ,

2

12 3 ,

2

6,

thr

tQUbbQD

tQUUQ

b

bbQ D

bDQ

hImm hAImm

gg

hImmgImm

hg g

hA Imm

hgImm





 

 

 



 

 



 



 









 





(23)



44

22 2

22

2

22

12

111

222

2

212

1

22

11

3,3,

3,,

2

12 3 ,

2

62 ,

thr

ttQU bQD

bQDDQ

t

tt QU

tUQ

hA ImmhImm

gg

hImmgImm

hg g

hAI mm

hgImm





 

 

 













 









 





(24)

22

2

221

3

22 2

212

1

22 2

2

211

1

22

2

221

22 2

212

1

22 2

2

211

1

3

12

12 3,

12

3,

33

3

12

12 3,

4

6,

66

thr

t

tQU

t

tUQ

b

t

bQD

b

bDQ

t

gg

h

hg g

AImm

hg g

AImm

gg

h

hg g

AImm

hg g

AImm

h















 











 





















 











 















2

22

2

22

3

2242

4

,

2,,

tQU

bb QD

tbtbQ UD

tb tbQUD

AImm

hAImm

hhAAImm m

A

AAAImmm





















 

(25)

φ

i

φ

i

φ

i

φ

i

φ

i

φ

i

φ

i

φ

i

φ

i

φ

i

φ

i

φ

i

q



q



q



q



q



q



q

q



φ

i

Figure 2. Threshold corrections (left and central diagram)

and diagram contributing to the wavefunction renormali-

zation (right).



22

4

42

2

4

2

22 2

2

212

22

212

1

22

222

11 1

22 2

2

212

22

212

1

2

6,

12 3

4

3,

4

3,

12 3

4

3,

4

1

2

thr

tt QU

bb QD

t

tQU

ttUQ

t

b

bQD

b

hAImm

hgg

h

gg

AImm

Aggh Imm

hgg

h

gg

AImm

Ag







 



























 



























2

222

11 13

6, th

bUQ

ghImm



















(26)

422 422

52 2

3,3,

thr

ttQUbb QD

hAImm hAImm

 





 





(27)

2

4

62

2

4

2

22

12

111

22 2

212

1

22

1

3,

3

,,

4

12 3

,

4

6

,

2

thr

tt QU

bbb QD

ttQUUQ

b

bb QD

b

DQ

hA Imm

hAAImm

gg

h AImmgImm

hgg

hA Imm

hg

Imm







 











 









 





 















(28)



2

4

72

2

4

2

22 2

212 1

11

222

212

1

22

11

3,

3,,

42

12 3 ,

4

3,

thr

ttt QU

bb QD

bbQD DQ

t

tt QU

tUQ

hAAImm

hA Imm

gg g

hAImm Imm

hgg

hA Imm

hgImm









 













 









 









 





(29)

M. DOLGOPOLOV ET AL.

306

where 1

g

, 2

g

are U(1) and SU(2) gauge couplings,



is the Higgs superfield mass parameter, t

A

, b

A

are

the trilinear squarks-Higgs bosons parameters, ,

tb

hh are

the Yukawa couplings and ,,

QUD

mmm denote the sca-

lar quark mass parameters, in terms of which the physi-

cal masses are expressed.

Corrections of “fish” diagrams, see Figure 3, give

the following contributions to the effective parameters



2

24

211

1,

69

f

bQDU

gg

hImImIm





 



 (30)



2

21

2

24

211

6

,

336

f

tQ

tUD

g

hIm

gg

hImIm





 







 





(31)











4222

34 11

4222

22

2222

22

11 11

1

() 6

72

92

,

3366

f

bt

btQ

tUbD

ghhg

ghhgIm

gg gg

hIm hIm







 

 

 

 

(32)











4222

311

422222

22

22 22

22

1111

22

16

72

928

3366

,.

f

bt

btbt Q

tUbD

tbUD

ghhg

ghhghhIm

gg gg

hIm hIm

hhI mm





 

 

 

 

 



(33)



22

4

22

,.

f

btQ

tbU D

gg

hhIm

hhI mm





 







(34)

The three-dimensional integrals in (30)-(34) are



1,

8π

1

,.

4π

I

UD

Jm m

Jm mmm





(35)

φ

i

φ

i

φ

i

φ

i

φ

i

φ

i

φ

i

φ

i

φ

i

φ

i

φ

i

q



q



q



q



q



q



φ

i

Figure 3. “Fish” diagrams.

see (7), leading to series analogously to (12) and (17).

The logarithmic corrections for non-degenerate

squark masses can be defined following [20] and [21]

Schematically, in the results of [15])



2

ln SUSY

t

M

m

should

be replaced by





2

ln QU

t

mm

m:







log42 2

111

2

4224

22 2

111 36

384 π

94 16ln,

b

QU

bb

t

ghg

mm

ghg hm







 





(36)





log42 24

2112

2

422

22

144 14436

1536 π

576 144ln,

t

QU

tt

t

g

hg g

mm

hghm



 



 





(37)









log4222

311

2

422222

22 2

111 18

384 π

9216ln,

bt

QU

bt bt

t

ghhg

mm

ghhghh m







 



(38)







log422 2

42 2

2

22

2

32

64 π

8ln .

bt

QU

bt

t

g

hhg

mm

hh m



 







(39)

Large logarithms not connected with the renormaliza-

tion group appear also in the wave-function renormaliza-

tion yield, see below.

It is known that in order to renormalize the 4





the-

ory, one needs to renormalize the self-coupling and the

mass of the scalar field. If the 4





theory is supple-

mented by fermions with interactions defined by the

Yukawa term, an additional wave-function renormaliza-

tion is necessary. Similar situation takes place in the

two-doublet model. Expanding the self-energy diagram

(see the insertion to the leg in Figure 2, right) calculated

with non-degenerate masses at finite temperature, we get

at 20p



the wave-function renormalization (w.f.r.)

correction, which is defined by a factor in front of 2

p.

At zero temperature two ways of w.f.r. calculation can be

used [22]. The following calculation is based on the in-

tegration of convergent w.f.r. contribution over the mo-

mentum squared, previously which has been used in dif-

ferentiation. The standard subtraction scheme at zero

momentum (BPSZ-scheme) in the divergent expression

for the self-energy contribution, when the divergent pole

part is subtracted, turns out to be not convenient at finite

temperatures, because in summation over Matsubara

frequencies not divergent integrals, but divergent series

M. DOLGOPOLOV ET AL.

307

must be subtracted. Following [14] we can write





 

22 22

1121121222

22 2

31211224211225

22 22

61 2122171 22112

11

(),,

22

11

,,0,

42

11

()( )0,0.

88

wfr wfr

wfrwfr wfr

wfr wfr

ggA ggA

ggAA gAA

ggAA ggAA











 



 

 

 

(40)

where A matrices 2 × 2 are3



2

22

2

23 1

,,,1 ,

24 π2

U

ijQ U

UU

A

h

A

FmmTUDl

AA

 





































A (41)

include the series (compare with equation (113) in [9], tak- ing into account differentiation to get the finite w.f.r. yield)







  



22

12 3

22

12

33

22

122

12 12

1

,,

2π2π

1

2.

2π2π

n

Fmm TT

mnTmnT

TT

mm mnTmnT



















(42)

The sum of all w.f.r. corrections to 5,6,7



vanishes.

It is useful to check that the finite temperature correc-

tions are reduced to the structures of zero-temperature

MSSM, which play a role of boundary condition at

0T. Indeed in the limiting case of 0T and degen-

erate squark mass parameters all equal to SUSY

M the

threshold corrections given by equations (23)-(29) are

reduced to previous zero-temperature results [14,23]. For

example, 1



 for abSUSY

mmM



 







44

122

22

2

22

12

111

22 2

2

212

1

22

11

33

32

2

12 3

2

6,

tSUSY bSUSY

tSUSYSUSY

b

bSUSY

hIM hAIM

gg

hIMgIM

hg g

hA IM

hgIM





 





















 



(43)

where the integrals are





4

143

22

d1

2π

11

,

16 π2

SUSY

k

IM

kM

M

 





(44)





4

24424

22

d1 11

16 π6

2π

SUSY

k

IM M

kM





(45)

Transformation to Minkowski space leads to the change

of sign in (44). The equality of the temperature series for

1,2

I

to the symbolic expressions for the integrals can be

numerically verified.

In the limiting case of 0T



and different squark mass

parameters the reduction of (13) and (14) to the four-

dimensional 1

I

and 2

I

can be achieved using

2

22 22

2222

1

11

,

2

ab

aa ab

pm pm

mmpm pm









 











(46)

Differentiating (46) with respect to b

m

22

22 22

2

22 22

1

11

.

2

ab

bb ab

pm pm

mmpm pm









 



 





 

(47)

then using Feynman parametrization (15), differentiation

in the same way as in (46) and (47), and dimensional

regularization to integrate over the four-momentum

p

with the following integration over the Feynman pa-

rameter, we arrive at

3The equations in [14] are given for the general case of complex-valued



, ,tb

A

.

M. DOLGOPOLOV ET AL.

308



4

142

22 22

22

2

222

d1

2π

12ln

,

16 π

ab

a

ab

b

ab

p

I

pm pm

m

mm m

mm

 













 



(48)



4

2422

22 22

3

222

d1

2π

ln

.

8π

ab

a

ab ab

b

ab

p

I

pm pm

m

mm mmm

mm













(49)

In the limit ab

mm these formulas coincide with the

expressions for degenerate squark masses (44) and (45).

In calculations of the temperature dependent parame-

ters





iT



of the effective MSSM potential at moderate

temperatures truncated series with fifty terms (50 Ma-

tsubara frequencies) were used. Relative contributions of

the remaining terms are less than 10–2 percent at T = 50

GeV, decreasing with an increasing T. At small tem-

peratures of the order of a few GeV an acceptable accu-

racy is achieved with 1000 terms. The effective parame-

ters



iT



are less than one, justifying the perturbative

approach, as a rule, at the squark mass parameters around

several hundred GeV. However, strong parametric de-

pendence is observed here, for example, at the squark

mass parameters 200, 500 and 800 GeV the criteria



1

iT



 is valid up to T



860 GeV, while taking

degenerate squark masses at 600 GeV it turns out that at

600T GeV the perturbative regime cannot be used.

3. Thermal Evolution and the Critical

Temperature

In view of the effective two-doublet potential structure

defined by (2) one could assume that the two-dimen-

sional picture of a broken symmetry of



12

,

eff

Uvv with

a local minima at 0T, 1,2 0v



appears in the sum of

the potential terms with 2

1



, 2

2



and 2

12



of dimen-

sion 2 in the fields, which form a ‘saddle’ (a hyperboloid

in the



12

,vv space), and of the dimension 4 terms

1, ,7



 which are increasing quartically, being unbounded

from above. However, the situation is more involved

because 2

1



, 2

2



, 2

12



and i



respect a number of

constraints. In this section we are going to describe

roughly some possible scenarios of temperature evolu-

tion in the effective two-doublet MSSM Higgs sector

with threshold, logarithmic and wave-function renor-

malization one-loop corrections. Two sets of the squark

mass parameters in the following numerical calculations

are used

(A) 500 GeV, 200 GeV, 800 GeV,

QU D

mmm





(B) 500 GeV, 800 GeV, 200 GeV.

QU D

mmm





Masses of the third generation squarks are



22222

1,2

22222

1, 2

222

1

222

2

14,

2

14,

2

LR LR

top

ttttt

b

bbbbb

mmmmmAm



 







 









where

2

22 22

222 2

22 22

222 2

12

cos 2sin,

23

2

cos 2sin,

3

11

cos 2sin,

23

1

cos 2sin

3

L

R

L

R

Qtop Zw

t

UtopZ w

t

Qb Zw

b

DbZ w

b

mmm m





 







 





 















and

22 22

1, ,

22 22

2, ,

cot2cot ,

tan2tan .

tb tb

AAA

AA A











 

With these parameters the third generation squark ei-

genstates 1, 2

t

m and 1,2

b

m which masses are positively

defined exist, as a rule, in an extensive regions of the

(tan



,

A

,



) parameter space, see Figure 5. Set (A)

favors the light stop, while the light sbottom is a feature

of the parameter set (B). Fixed parameters for the plots in

Figure 5 are tan 5





, ,1

tb

A TeV, 1.5



 TeV,

180

H

m GeV. Squark masses vary in the range from

200 GeV to 800 GeV at the values of ,tb

A

and



up

to the order of 1 TeV. Large difference of the stop

masses is necessary to respect constraints following from

the LEP2 experimental limit 11 5

h

m GeV. The values

of tan



above 5 and large soft supersymmetry break-

ing parameters ,tb

A

and



of the order of Q

m also

lead to an acceptable Higgs boson mass h

m (but weaken

the strength of the electroweak phase transition if taken

too large). At the same time substantial threshold correc-

tions appear in the MSSM scenarios with large ,tb

A

and



, like the BGX scenario [24] and the CPX scenario

[25], or the regions of MSSM parameter space close to

BGX and CPX.

In the following the equilibrium states of effective po-

tential (2) as a function of the two variables of state 1

v

and 2

v and six temperature-dependent control parame-

ters









17

,,TT



are going to be analysed. Local pro-

M. DOLGOPOLOV ET AL.

309

perties of



12 17

,,, ,

eff

Uvv



 are defined by a number

of well-known theorems in the framework of the catas-

trophe theory (Morse and Thom theorems for the reduc-

tion of a potential function to the canonical form by a

nonlinear transformation [26]). They describe properties

bility matrix (also called the Hessian) 2

ijeffij

UUvv .

Simplest two-dimensional example of the Hessian is

given by the MSSM Higgs potential at the SUSY scale,

where





22

1212

8gg



 ,



22

321

4gg



 ,

2

42

2g



 and 567

0







 are independent of

the temperature. The equilibrium matrix at the stationary

points has the form

 

2

2222222

212

1211212

22 22

12 12

2

2222222

12 1

1212 122

22 22

12 12

11

4

11

44

AA

vvv

ggvm ggvvm

vv vv

vv v

ggvvmggvm

vv vv

 



 



(50)

(A

m is the CP-odd scalar mass) and the nonisolated (or

degenerate) critical points defined by the condition

det 0

ij

U lead to the equation



2

22222 22

1212 12

0

A

ggmvv vv,

so the MSSM surface of minima





2

2222

0121212

,32Uvvggv v  is unbounded

from below and the bifurcation set looks as the two ‘flat

directions’ 12

vv



, see Figure 4. Threshold corrections

at zero temperature can be found in [23]. As a rule they

transform the decreasing function in Figure 4 to a saddle

configuration, slowly increasing along one of the ‘flat

directions’ and more rapidly decreasing along the other.

In the general case the potential (2) as a function of the

vacuum expectation values



22

222442233

3456 7

12 12

12121212121 21 212

,2244422

Uvvvvvv vvvvvvvv



 



  (51)

includes temperature-dependent parameters





iT



,

1,, 7,i and





1, 2

vT

, see equations (23)-(29), which

define the thermal evolution from some high temperature

T of the order of several hundred GeV down to zero.

We denote 3453 45

Re



 

. Conditions of the ex-

tremum





12

,0Uvv



 distinguishing an isolated (or

nondegenerate) critical points

 

222

23 2

2

111 3451267

sin

ReRetan3Re cotRe tan,

22

vv

v

















  (52)

 

222

23 2

1

222 3451267

cos

ReRecotRe cot3Retan,

22

vv

v





 

 (53)

where

Figure 4. The zero-temperature surface of extrema for the

two-doublet Higgs potential





012

,Uvv, see (2), at the scale

SUSY

M

.



2

12

2

56 7

Resincos

2ReRecotRe tan,

2

A

v

m





















(54)

are also mentioned as the minimization conditions which

set to zero the linear terms in the physical fields h,

H

and

A

and ensure a local extremum at any point of the

surface





12

,

eff

Uvv

in the background fields space (see

e.g. [14])4 Important input parameters of the two-doublet

potential are 21

tan vv





and the charged Higgs bo-

son mass



2

22

54

Re

2

WA

H

v

mmm



 

where the effective temperature-dependent mass of the

4Although only the CP-conserving limit is considered, we keep the

notation of real parts for the variables where a phase factor could ap-

p

ear in the general case.

M. DOLGOPOLOV ET AL.

310

2t

m

2b

m

1b

m

1t

m

2t

m

2b

m

1b

m

1t

m

2t

m

2b

m

1b

m

1t

m

2t

m

2b

m

1b

m

1t

m

2t

m

2b

m

1b

m

1t

m

2t

m

2b

m

1b

m

1t

m

(1) (2) (5) (6)

(3)

(7)

(4)

Figure 5. Third generation squark masses as a function of tan β (first row of plots), A (second row) and μ (third row of plots).

For the left column of plots the squark sector parameter values are 500 GeV

Q

m



, 200 GeV

U

m



, 800 GeV

D

m, set (A).

For the right column of plots the squark sector parameter values are Q

m =500 GeV, U

m =800 GeV, D

m =200 GeV, set

(B). The fourth row of plots demonstrates the regions of “light stop” 120 GeV < 1

~

t

m< 180 GeV (left panel) and “light sbot-

tom” 120 GeV <

1

~

b

m< 180 GeV (right panel) in the (A, μ) plane. In the regions (1), tgβ =40 and (2), tgβ =5, squark parameters

are given by set (A), in the region (3), where tgβ =5, and (4), where tgβ =30, squark parameters given by set (B). For regions

(5) and (6) single parameter U

m of the set (A) is shifted to 400 GeV, for region (7) single parameter D

m of the set (B) is

shifted to 400 GeV, other kept fixed.

M. DOLGOPOLOV ET AL.

311

longitudinal W-boson is









22

2

,

52

LL

L

WWW

W

mvT mvT

TgT





(with the one-loop Standard Model and third-generation

squarks contributions included in the polarization opera-

tor; 222

22

W

mvg). If in the process of thermal evolu-

tion, when the system moves along some trajectory in the









12

,vT vT plane, we require the minimization of U

with respect to the scalar fields oscillation in the extre-

mum









12

,vT vT and continuously admit the inter-

pretation of the system in terms of scalar states ,hH

and

A

, then 2

1



, 2

2



and 4

12



can be expressed by

means of the effective parameters 1, ,7



 [14]4. Only

2

1



, 2

2



and 2

12



are dependent on the direction in the





12

,vv plane, while 1, ,7



 are not.

First it is useful to consider the simplified case

67

0



. The two-doublet Higgs potential without

6



and 7



terms has been considered in the context of

discrete Peccei-Quinn symmetry [27]. Nonisolated (or

degenerate) critical points in the 12

,vv plane, defined by

the condition 2

det 0

ij

Uvv, or

2

1

2

222

1 1121234512

222

12345 1 22212

2

det 0

2

v

vvv

vv v

 

 



 (55)

where the minimization conditions (52) and (53) (or,

equivalently, the conditions for isolated points of





12

,Uvv ) have been substituted. The system of two

nonlinear equations for 12

,vv

3222

345

11121112 2

3222

345

221 22 2121

0,

2

0.

2

vvvvv











(56)

can be factorized by the rotation in the 12

,vv plane

11 2

21 2

cossin,

sincos ,

vv v





 (57)

where



22

12

2

22 2

12 12

22

12

2

22 2

12 12

1

sin ,

224

1

cos ,

224





 























(58)

Then the factorized equations (56) are

222

345

1112 1

222

345

2221 2

0

2

0

2

vv v





























(59)

where



2

222224

1,2121 212

14

2











(60)

and the four types of bifurcation sets defined by the sta-

bility matrices





12

,

ij

Uvv can be easily found

1) 222

345

11210

2

vv







 and 222

345

2212 0

2

vv





,



2

1 134512

12 2

345 1 222

2

,2

ij

vvv

Uvv vv v





2) 22

111 0v





 and 20v,



2

11

12 22

345

21

20

,02

ij

v

Uvv v







3) 10v



and 22

222 0v





,



22

345

12

2

22

0

,2

02

ij

v

Uvv

v











4) 10v



and 20v



,



2

1

12 2

2

0

,0

ij

Uvv





Bifurcation set in the case (1) which is defined by

2

det 0

ij

Uvv



 can be understood in the elementary

language. The surface of stationary points





12

,

eff

Uvv







44 22

1 122345124vv vv



 is positively defined and

unbounded from above if the Sylvester’s criteria for the

quadratic form







22

121 2

,,

eff eff

Uvv Uvv is respected

2

345

1212

0, 0,0

4







 (61)

At the critical temperature defined by equation

2

1 2345 40

 



 the positively defined potential surface

of stationary points starts to develop the saddle configu-

ration which is unbounded from below, see Figure 6.

The “flat direction” at the critical temperature which is

developed at the angle



22

345 12

tan2





, or



2

2345

2

22

1 21 2345

tan





 



 

(62)

is defined by the control parameters



1T



,





2T



and





345 T



not depending on the 1

v and 2

v. The

regions of positively and negatively defined 1



and 2



and the contour for Sylvester’s criteria (61) are shown in

4 The normalization of 1,2



in [14] is different from [15] by a factor o

f

2.

M. DOLGOPOLOV ET AL.

312

Figures 7 and 8 at the temperature 150 GeVT in the

(,

tb

AA A



 ) plane. The squark mass parameters Q

m,

U

m and

D

m are fixed as mentioned in the beginning

of the section, set (A), the (

A

,



) parameters are cho-

sen in the vicinity of the contours which separate posi-

tively and negatively defined



-parameters in (61). The

critical temperature in this case is slightly above 120

GeV, insignificantly dependent on the values of (,tb

A

,



)

if they are changing along the contours in Figure 7-8,

separating the light grey and the dark grey areas. The

strength of the electroweak phase transition along the

direction (62) can be roughly estimated using the equa-

tion







22

c

vT E

T





 (63)

where E is a temperature-independent factor in front

of the cubic term 3

ETv in the effective potential

rewritten in the polar coordinates (22

12

vvv

,





21

arctg vv



), and









is a factor in front of the

quartic term 44v. The cubic term is given by correc-

tions coming from the resummation of the multiloop

Figure 6. Development of the saddle configuration for the surface of stationary points of the potential





12

,

eff

Uvv

, see (2), at

the critical temperature Tc = 120 GeV. The squark sector parameter values are 500

Q

m



GeV, 200

U

m GeV, 800

D

m

GeV, 1200

tb

AA GeV, 500





GeV, the charged Higgs boson mass 150

H

m



GeV. Horizontal plane corresponds to

0

eff

U.

Figure 7. Contours of negatively defined 1



(left, dark grey area) and 2



(right, dark grey area) in the (,

tb

AA



) plane at

the temperature 150 GeV, 150

H

m



GeV. Set (A), the case of light stop, is used for the squark sector parameter values

(500

Q

m GeV, 200

U

m GeV, 800

D

m GeV).

M. DOLGOPOLOV ET AL.

313

Figure 8. Contour of negatively defined determinant

2

12 3454

 

 (dark grey area) in the (,

tb

AA



) plane at

the temperature 150 GeV. Set (A), the case of light stop, is

used for the squark sector parameter values (500

Q

m



GeV, 200

U

m GeV, 800

D

m GeV).

diagrams in the infrared region. In the case of a heavy

stop which decouples [6], the effective potential is similar

to Standard Model potential and

 

33

32

322

212 3

2

22 2

2.

48π3π

WZ

SM

mm

Eggg v









 (64)

In the case of a light stop one can use an approxima-

tion SM MSSM

EE E , where an additional term [4]

3

2

3

32

22 1,

3π

t

MSSM t

Q

A

Em

vm











(65)

stop mixing parameter here tan

tt

AA







. The quar-

tic term along the direction (62) can be written in the

form







24 3

1 345267

2

tantan2 tan2 tan.

1tan















(66)

The condition /1

cc

vT [5], necessary to avoid

sphaleron transitions which erase the baryon asymmetry

initially generated at the electroweak phase transition,

can be respected in a rather extensive regions of the (

A

,



) plane. The contours of /1

cc

vT in the (

A

,



)

plane (see Figure 9) separate the regions not only around

the origin (

A

,



) = (0,0), but also the areas with (

A

,



)

of the order of 1 TeV, where the quartic term









changes sign crossing zero along the flat direction (62).

If we the set (B) is chosen for the squark mass pa-

rameters Q

m, U

m and

D

m, corresponding to the case

of light sbottom and relatively heavy stop, then the factor

Figure 9. Contours for the criteria 1

cc

vT in the (,

tb

AA





) plane. In the light grey regions 1

cc

vT. In order to include

qualitatively the effect of

M

SSM

E, for the left plot 2SM

EE



and for the right plot 4SM

EE



. 67

0



, charged Higgs

boson mass 150

H

m GeV. Set (A), the case of light stop, is used for the squark sector parameter values (500

Q

m



GeV,

200

U

m GeV, 800

D

m GeV ).

M. DOLGOPOLOV ET AL.

314

2



is always positive in the broad range of temperatures

from a few to a several thousands of GeV, the surface of

stationary points is always a saddle, so the potential does

not have a stable minimum at the origin 12

0vv.

For the general case of nonzero 6



and 7



defined

by equations (28) and (29) the effective potential







44 22

121 12234512

33

61 2712

,

224

eff

Uvvv vvv

vv vv





 



always demonstrates a saddle configuration for the sur-

face of stationary points, which slopes become steeper

with an increase of the temperature. Typical shape of



12

,

eff

Uvv

is shown in Figure 10.

Bifurcation set in the cases (2) and (3) is different

from the bifurcation set in the case (1). The condition

10v is equivalent to



22 222

12121212

vvv v

 

  (67)

so it follows from (58) that 22

1

sin vv



 and cos





22

2

vv (where 222

12

vvv), so22

2

vv. Then 2

1







2222

121212

2vvv



 . The factor 345



in the poten-

tial with rotated vacuum expectation values





12

,Uvv

can be found substituting (57) to (51)









22 22

345 12

4224

345

224 422

121 212

1 2345

44

166

4

34

24

cs cs

sscc

vvv vvv

vv







 







 

(68)

Using these equations one can rewrite the conditions for

the case (2) 10v and 22

1345 22v



 in the form







44

134512345 2

22

3451212

4(4)

6220

vv

 







 

(69)

The regions of positively and negatively defined 1



and

2



and the contour for Sylvester’s criteria for the form

(69) are shown in Figures 11 and 12 at the temperature



T

150 GeV in the (bt AAA ,



) plane. The

squark mass parameters Q

m, U

m and D

m are fixed

as mentioned in the beginning of the section, set (A), the

(A,



) parameters are chosen in the vicinity of the

contours which separate positively and negatively defined



-parameters in (69). As for the analysis of bifurcation

set (1), set (B) again does not demonstrate a stable

minimum at the origin for a broad range of temperatures.

The phase transition for the case (2) is developed in the

Figure 10. The surface of extrema for the potential Ueff (v1,

v2), see (2), with nonzero λ6 and λ7 at the temperature T =120

GeV. The squark sector parameter values Q

m



500 GeV,

U

m



200 GeV, D

m800



GeV, At = Ab = 1500 GeV, μ =

1000 GeV, charged Higgs boson mass

H

m = 150 GeV.

Horizontal plane corresponds to Ueff =0.

Figure 11. Contours of negatively defined 4λ1 + λ345 (left, dark grey area) and 4λ2 + λ345 (right, dark grey area) in the (At = Ab, μ)

plane at the temperature 150 GeV,

H

m = 150 GeV. Set (A), the case of light stop, is used for the squark sector parameter

values (Q

m = 500 GeV, U

m = 200 GeV,

D

m = 800 GeV).

M. DOLGOPOLOV ET AL.

315

Figure 12. Contour of negatively defined determinant (4λ1 +

λ345)(4λ2 + λ345) − (3λ345 − λ1 − λ2)2 (dark grey area) in the (At

= Ab, μ) plane at the temperature 150 GeV. Set (A), the case

of light stop, is used for the squark sector parameter values

(mQ =500 GeV, mU =200 GeV, mD = 800 GeV).

direction



of the





12

,vv plane







345 1 2

22

1 3452 345

33

tan 244



 



 (70)

Bifurcation set in the case (4) 10v and 20v



de-

fined by the equation 22

12 0



 can also be understood

on the elementary level as a result of the diagonalization

of the effective potential

22

22222

12

121212

22

eff

Uvvvv



   by the rotation (57),

giving the form 2222

11 22

eff

Uvv



 . This case is inter-

esting not only in the case of an effective field theory

under consideration but also in a more general physical

framework. So far it has been assumed that we are in the

framework of an effective field theory at the top

m en-

ergy scale, when the contributions from squarks decouple

or a contribution of the potential terms with squarks (see

the Appendix) is practically constant. However, if it is

not the case and the Higgs bosons-squarks quartic term is

positive definite with the global minimum at the origin

12

0vv, the phase transition may occur due to the

development of a saddle configuration by the 2

1



, 2

2



and 2

12



terms.

Such situation may take place when the vacuum ex-

pectation values of charged and colored superpartners

participate in the full MSSM scalar potential, possibly

giving charge and color breaking minima [28]. For illus-

trative purposes it is convenient to use the polar coordi-

nates

  





12

cos ,sinvT vTTvT vTT



 for

the vacuum expectation values. The mass term of the

two-doublet potential has the form



22

22 222

12 12

,cossinsin 2

22

mass

vv

Uv





 

(71)

By definition at the critical temperature the gradient of





,

mass

Uv



is zero along some direction in the (1

v,2

v)

plane, then 0

mass

Uv



 and 10

mass

vU



; it

follows from these two equations



2

12

22

12

2

22 42 24

1 2121212

2

tan 2,

40





  







 





(72)

The first of these equations is equivalent to (58). The

phase transition is characterized by the critical angle





T



which defines the flat direction4 for the mass

term at the temperature c

T in the background fields

plane





12

,vv , and at the real-valued 1



, 2



and 12



the critical temperature is defined by the equation

224

12 12





 (73)

which is equivalent to 2

10



 or 2

20



. For a fixed

set of the squark sector parameters5 the thermodynamical

evolution of the effective potential is described by a

0

eff

nU



 trajectory in the three-dimensional (v, T,

tan



) space, which is defined by the intersection of the

two surfaces, corresponding to the equation (72) for the

critical angle (“



-surface”), and the equation (73) for

the 1



, 2



and 12



(“



-surface”). The cross sections

of



-surface (calculated without any approximations

numerically) by the plane at fixed 0T, giving the (v,

tan



) contour, and the cross section at tan

1





giving

the (v,T) contour is shown in Figure 13. The presence

of nonzero effective parameters 6



and 7



is essential

to get the critical temperature of the order of 100 GeV.

Useful analytical approximation can be obtained using

the minimization conditions (52)-(53), then the critical

angle





T



defined by (72) can be expressed as7

5Flat directions may exist also in the quartic term separately taken, see

e.g. [29].

6Mathematica package [30] with encoded representations of





iT



by means of series with n = 50 was used to scan the MSSM parame-

ter space. At low temperatures the convergence of Matsubara series

becomes worse, so the number of terms up to n = 1000 is needed to

reach an acceptable accuracy.

7In different context analogous relation between tan



and tan



can be found in [6], where the mass term of the form





2,vf T



with













2

,fTaTb







was analyzed for a special case of degener-

ate squark masses, 0

A





 and within the high-temperature expan-

sion. Our quartic potential is very different from the tree-level





22 42

12

8cos 2

T

ggv





 plus a logarithmic term [6], so the expression

3/1

T

E



 of Bochkarev-Shaposhnikov criteria



1

cc

vT Tfor the

absence of sphaleron in the broken phase gives different results with

nonzero threshold corrections.

M. DOLGOPOLOV ET AL.

316

Figure 13. Cross sections of the μ-surface, see (72), at the temperature close to zero (right panel) and tan β = 1 (left panel, see

also Figure 1). White area in the right plot corresponds to the parameter values when the effective mass term (71) has a saddle

configuration, At,b = 1800 GeV, μ = 2000 GeV. The β-surface is very close to the μ-surface. The squark sector parameter values

are mQ =500 GeV, mU =200 GeV, mD =800 GeV, the charged Higgs boson mass

H

m



= 150 GeV.

22 2

2

12

345 2

2

1

2

11

tan 2tan22cos2sin2

cos 2

2

A

m

v

m

 











  







(74)

where





5

167 267

1tantan, tan2tantantan2.

24





 

 (75)

The assumption

 

0T



, i.e. only the modulo of



vT but not the direction in



12

,vv plane are

changed in the process of thermal evolution, gives for the

critical angle (74)







23

22

12 67

56 7345

22 2

22 tan3tancottan3tan

2cottan 0.

1tan

A

mv

vm

  

 









 







(76)

This approximation may be too rough at small 

H

m,

as pointed out in [6]. The saddle configuration changes

not only the shape, but also the horizontal orientation in

the process of thermal evolution. For the case 56





70



 (76) is reduced to

21345

2 345

2

tan 2









 (77)

Combining (53) and (76), where only the leading power

terms in i



and omit 22

5A

mv



 are kept, the equa-

tion (73) can be written in the form



22

1234521 3453451 3452345

22 220



  (78)

The vacuum expectation value v and mass A

m do

not explicitly participate in this equation, only the di-

mensionless effective parameters i



of the quartic po-

tential terms. The left-hand side of (78) approaches zero

from below as v increases, demonstrating however no

solution for the saddle configuration. This can be under-

stood qualitatively if we rewrite (78) in the form

22

1 2345

cot tan0

 



 where the numerical val-

M. DOLGOPOLOV ET AL.

317

ues calculated in the BGX scenario are 10



, 20





and 3450



, so in (77) tan 1





.

Turning back to the case of effective field theory when

the squarks decouple at the top

m energy scale, the eva-

luation of thermal masses of Higgs bosons, mixing an-

gles and couplings can be done using results of [14]. For

example, the thermal evolution of the CP-even Higgs

bosons h and

H

is expressed by (compact notations

sins





, cosc





, etc. are used











 

2222222222 22

12 34567

222Re2Re Re ,

hA

mcmvsccsccsssscccsccs

 

 

 

  (79)











 

222 2222222 22

12 34567

222Re2 ReRe,

HA

msmvccssccsscsscsccss

 

 

 

 (80)

where the mixing angle



of the CP-even states h and

H

is











2222

234267

22 22

21252672

2Re2Re

tan 2.

22ReRe Re

A

sm vscs

cm vcscs





 

 

 

 (81)

We show the regions of the (v,T) plane where the

CP-even Higgs boson masses h

m and

H

m are posi-

tively defined in Figure 14-16 (shaded areas).” Tachyo-

nic” areas (shown in white colour) correspond to the

negative squared masses of h

m or

H

m, see (3), when

the fluctuations of physical fields h and

H

near the

unstable local extremum (



1

vT,





2

vT

) grow exponen-

tially with time.

Configuration of the effective potential



,,

eff

UhH



,

A

T expressed in the physical fields h,

H

in these

areas is a saddle or a function with negative or indefinite

sign values unbounded from below. The ‘saddle’ tem-

perature 120

c

T GeV (see Figure 6) is close to the

temperature, when the thermal mass





h

mT

vanishes,

only at the low tan



values. The heavy scalar mass





H

mT

vanishes at the temperatures substantially higher

than c

T. In the scenario under consideration at higher

tan



one should increase the charged scalar mass to

respect the zero-temperature condition



0 246v GeV.

4. Summary

The analysis of effective MSSM finite-temperature po-

tential is based on a calculation of various one-loop tem-

perature corrections from the squark-Higgs boson sector

for the case of nonzero trilinear parameters t

A

, b

A

and

Higgs superfield parameter



. Quantum corrections are

incorporated in the parameters





1, ,7T



 of the effec-

tive two-doublet potential (2), which is then explicitly

rewritten in terms of Higgs boson mass eigenstates, using

the approach developed in [14,15]. The effective para-

meters









17

,,TT



 include the threshold corrections

Figure 14. In the shaded areas mh (left panel) and mH (right panel) are positively defined at the parameter values tanβ = 5,

H

m= 180 GeV, At,b = 1200 GeV, μ = 500 GeV. Isocontours of constant mh and mH masses are indicated. The squark sector

parameter values are mQ = 500 GeV, mU = 200 GeV, mD = 800 GeV.

M. DOLGOPOLOV ET AL.

318

Figure 15. The same contours as in Figure 14 at tanβ = 15,

H

m



= 230 GeV.

Figure 16. The same contours as in Figure 14 at tanβ = 40,

H

m



= 260 GeV.

from triangle, box and “fish” diagrams together with the

logarithmic and the wave-function renormalization terms.

Dominant contribution comes from the triangle and box

graphs (Figure 2, left and central) and can be written in a

compact form by means of the generalized Hurwitz

zeta-function.

Temperature evolution of the potential





12

,

eff

Uvv

expressed in terms of the background fields (





1

vT,





2

vT) is very sensitive to the MSSM scenario under

consideration. We are using the scenarios with large

,tb

A

and



(about/of the order of 1 TeV), favored by

the available experimental data. Two characteristic sets,

(A) and (B) (see Section 3), are used for the

squark-Higgs boson sector parameters Q

m, U

m and

D

m. A relatively light stop quark is inherent for the set

(A), while with the set (B) sbottom quark is the lightest

scalar quark eigenstate for an extensive regions of the

MSSM parameter space. Our analysis is essentially

two-dimensional, i.e. the electroweak symmetry breaking

is considered for the two-dimensional potential surface









12

,UvTvT, the shape of which is defined by nine

parameters 1

1



, 2

2



, 2

12



and 17

,,



 in the general

(nonsupersymmetric) two-Higgs-doublet model. For the

case of discrete Peccei-Quinn symmetry two parameters

are equal to zero: 67

0





. Using the terminology of

the theory of catastrophes [26], we analyse the local be-

havior of the two-dimensional potential function, de-

pendent on the several (less than five) control parameters.

The surface of equilibrium points defined by the zero

gradient





12

,0Uvv



 looks like either a paraboloid

function unbounded from above with the global mini-

mum at the origin or a saddle configuration. Two types

of surfaces are separated by the critical condition





2

12

det ,0

effi j

Uvvvv



 which defines the bifurca-

M. DOLGOPOLOV ET AL.

319

tion set in the MSSM parameter space. The electroweak

phase transition along some direction in the 1

v, 2

v

plane occurs when the temperature evolution of 1, ,5





from the TeV temperature scale down to zero tempera-

ture transforms a surface unbounded from above to a

saddle configuration.

In Section 3 four types of bifurcation sets for the two-

Higgs-doublet potential





12

,

eff

Uvv are found. The bi-

furcation set (1) defined by equation (61) develops a

phase transition in the direction which is fixed by Equa-

tion (62) in the (12

,vv) plane. In the MSSM only the pa-

rameter set (A) of the squark-Higgs bosons sector, char-

acterized by the light stop quark, shows the necessary

configuration of the surface for stationary points

(paraboloid with a global minimum at the origin at high

temperatures and a saddle at low temperatures). The bi-

furcation contour (also called the separatrix in the catas-

trophe theory terminology) in the (

A

,



) plane for the

set (1) is shown in Figure conditionlambdas. The pa-

rameter set (B) with the light sbottom always gives a

saddle configuration because 10



 and 20



 in the

parameter space. The bifurcation sets (2) and (3) are

similar, demonstrating a phase transition in the direction

defined by Equation (70) in the (12

,vv) plane. The bifur-

cation contours in the (

A

,



) plane for the set (2) are

shown in Figure 12. Again, only the parameter set (A)

with the light stop demonstrates the necessary configura-

tion of the equilibrium surfaces. The bifurcation set (4)

includes a phase transition in the direction of equation

(72) at the temperature defined by equation (73). This

case was analyzed earlier in the literature in the context

of the one-dimensional effective potential. The bifurca-

tion contours for the case of parameter set (A) are shown

in Figure 13. Summarizing, in all four cases the global

minimum at the origin 12

0vv



,



0, 00

eff

U



at

high temperatures is transformed to a local minimum

with





12

,0

eff

Uvv at a lower temperature for the pa-

rameter set (A), but the directions of transition to this

minimum in the (12

,vv) plane are different.

Oscillations of Higgs fields in the vicinity of an ex-

tremum

 



12

,vTv T give the effective potential with

a minimum moving along the surface of stationary points.

The potential



,,

eff

UhHA written in terms of physical

Higgs fields (i.e. Higgs mass eigenstates h,

H

and

A

)

demonstrates the spectrum of scalars with positively de-

fined masses which are reaching zero at different tem-

peratures. These temperatures are, as a rule, not close to

the ‘critical’ temperature c

T, when the potential



12

,

eff

Uvv forms a horizontal ‘narrow gully’, so not

only the first, but also the second derivatives are zero in

some direction.

The isocontours for CP-even scalar masses h

m and

H

m fall down in an extremely narrow temperature re-

gion near 0T



, see Figures 14-16, so during the ‘over-

turn’ of the potential a nearly step-like decrease of





vT must happen to keep constant masses.

Although the evaluation is performed at the one-loop

only and not all possible corrections are considered, usu-

ally it is possible to adjust



, ,tb

A

(or ,tb

X

), Q

m,

U

m and

D

m of the MSSM parameter space in such a

way that the boundary condition for zero temperature





0 246v GeV is respected, the lightest Higgs boson

mass is large enough, the critical temperature is of the

order of 100 GeV or higher, and the phase transition is of

the first order. Threshold corrections with



, ,tb

A

of

the order of 1 TeV can increase the strength the elec-

troweak phase transition. Independently on the tempera-

ture evolution scenarios, one should not forget that the

value of tan



at zero temperature must be consistent

with the range from 5 to 50-60, provided by phenome-

nological restrictions from LEP2 and Tevatron data for

the reactions ee hZ



, hbb, and pp tt,

tHb



. In the nearest future useful information about

the allowed regions of the MSSM parameter space could

be provided by the LHC Higgs physics program [31].

Availability of the criteria



1

cc

vT T for the absence

of sphaleron in the broken phase deserves a more careful

study with more precise evaluation of radiative correc-

tions from other sources, especially the infrared ones.

Only the case of real-valued MSSM parameters ,tb

A

and



was considered. Generalization to the com-

plex-valued parameters (the case of explicit CP violation

in the squark-Higgs and the two-doublet Higgs sectors)

is straightforward with radiation corrections defined by

Eqs.(27)-(29), where phases of ,tb

A

and



can be

introduced. Complex 5,6,7



lead to the mixing of CP-

even h,

H

and CP-odd

A

scalars resulting in the

Higgs bosons without a definite CP-parity 1

h, 2

h and

3

h with specific properties, modifying the qualitative

picture described above.

5. Acknowledgements

M.D. (MSU) is grateful to Mikhail Shaposhnikov for

useful discussion. Work was partially supported by

grants ADTP 3341, 10854, RFBR 10-02-00525-a, NS

1456. 2008.2 and FAP contract 5163. E. R. thanks the

“Dynasty” Foundation and ICPPM for partial financial

support.

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Appendix

Supersymmetric potential of the Higgs bosons - third

generation of scalar quarks interaction has the form [32]

0,

MQ

VV VVV





 (82)

where





22

2*2* ,

Mijij

Q

UD

VMQQ

MUUM DD

















(83)







 

2

** **

2,

DUT

iiii

DU

ii ii

VQDiQU

QD iQU







 

 





(84)





 



**

*

2

(

1.., ,,,1,2,

2

jl

ikijk l

QUD

i jijijij

Q

ij ij

T

ij ij

V

QQUU DD

QQ

iDUhcijkl

















 



 















(85)

Q

V denotes the four scalar quarks interaction terms,

2

0

i











, and

I



are defined by the tree-level

equalities



22222

2121

2222

22

22 2

11

diag ,,

44

11

diag,,

22

11

diag ,,

44

Q

QUQ

Q

DU

U

UUU

ggYh ggY

hggh

gYhgY















 







 







22 2

11

diag,,

44

.

D

DDD

UD

hgYgY

hh

















Here the squark hypercharges are





131

i

Q

Y, i

D

Y





232, 43

i

U

Y , and the Yukawa couplings for

the third generation squarks 22

,.

sin cos

tb

mm

hh

vv





In the general case of complex-valued parameters









1;2 1;2

;, ;,

UD

UU DD

hA hA





  (86)

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