On the thermomechanical consistency of the time differential dual-phase-lag models of heat conduction

International Journal of Heat and Mass Transfer 114 (2017) 277–285

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International Journal of Heat and Mass Transfer journal homepage: www.elsevier.com/locate/ijhmt

On the thermomechanical consistency of the time differential dual-phase-lag models of heat conduction Stan Chiriţa˘ a,b,⇑, Michele Ciarletta c, Vincenzo Tibullo c a

Faculty of Mathematics, Al. I. Cuza University of Ias
i, 700506 Ias
i, Romania Octav Mayer Mathematics Institute, Romanian Academy, 700505 Ias
i, Romania c University of Salerno, via Giovanni Paolo II n. 132, 84084 Fisciano, SA, Italy b

a r t i c l e

i n f o

a b s t r a c t

Article history: Received 1 March 2017 Received in revised form 6 June 2017 Accepted 15 June 2017

This paper deals with the time differential dual-phase-lag heat transfer models aiming, at first, to identify the eventually restrictions that make them thermodynamically consistent. At a first glance it can be observed that the capability of a time differential dual-phase-lag model of heat conduction to describe real phenomena depends on the properties of the differential operators involved in the related constitutive equation. In fact, the constitutive equation is viewed as an ordinary differential equation in terms of the heat flux components (or in terms of the temperature gradient) and it results that, for approximation orders greater than or equal to five, the corresponding characteristic equation has at least a complex root having a positive real part. That leads to a heat flux component (or temperature gradient) that grows to infinity when the time tends to infinity and so there occur some instabilities. Instead, when the approximation orders are lower than or equal to four, this is not the case and there is the need to study the compatibility with the Second Law of Thermodynamics. To this aim the related constitutive equation is reformulated within the system of the fading memory theory, and thus the heat flux vector is written in terms of the history of the temperature gradient and on this basis the compatibility of the model with the thermodynamical principles is analyzed. Ó 2017 Elsevier Ltd. All rights reserved.

2010 MSC: 74F05 80A20 Keywords: Time differential dual-phase-lag model Heat conduction Delay times Stability systems Thermodynamic compatibility

1. Introduction The dual-phase-lag model of heat conduction proposed in [1–3] distinguishes the time instant t þ sq , at which the heat flux flows through a material volume and the time instant t þ sT , at which the temperature gradient establishes across the same material volume:

qi ðx; t þ sq Þ ¼ kij ðxÞT ;j ðx; t þ sT Þ;

with

sq ; sT P 0:

ð1Þ

The above constitutive equation states, synthesizing its meaning, that the temperature gradient T ;j at a certain time t þ sT results in a heat flux vector qi at a different time t þ sq . In the above constitutive Eq. (1), besides the explicit dependence upon the spatial variable, we point out that qi are the components of the heat flux vector, T represents the temperature variation from the constant reference temperature T 0 > 0 and kij are the components of the conductivity tensor; moreover, t is the time variable while sq and sT are ⇑ Corresponding author. E-mail addresses: [email protected] (S. Chiriţa˘), [email protected] (M. Ciarletta), [email protected] (V. Tibullo). http://dx.doi.org/10.1016/j.ijheatmasstransfer.2017.06.071 0017-9310/Ó 2017 Elsevier Ltd. All rights reserved.

the phase lags (or delay times) of the heat flux and of the temperature gradient, respectively. In particular, sq is a relaxation time connected to the fast-transient effects of thermal inertia, while sT is caused by microstructural interactions, such as phonon scattering or phonon-electron interactions [4]. In addition to the thermal conductivity, the phase lags sT and sq are treated as two additional intrinsic thermal properties characterizing the energy-bearing capacity of the material. Eq. (1) describing the lagging behavior in heat transport, when coupled with the energy equation

qi;i ðx; tÞ þ .ðxÞrðx; tÞ ¼ aðxÞ

@T ðx; tÞ; @t

ð2Þ

displays two coupled differential equations of a delayed type. Due to the general time shifts at different scales, sT and sq , no general solution has been known yet. The refined structure of the lagging response depicted by equations (1) and (2), however, has been illustrated by Tzou [3] by expanding Eq. (1) in terms of the Taylor’s series with respect to time:

S. Chiriţa˘ et al. / International Journal of Heat and Mass Transfer 114 (2017) 277–285

278

qi ðx;tÞ þ

sq @qi 1! @t "

ðx;t Þ þ

¼ kij ðxÞ T ;j ðx;tÞ þ

s2q @ 2 qi 2! @t

2

sT @T ;j 1! @t

ðx;t Þ þ  þ

ðx;t Þ þ

snq @ n qi n! @t n

2

s @ T ;j 2 T

2! @t 2

dynamic consistency of the model in concern is established when

ðx;t Þ

ðx;t Þ þ  þ

m

s @ T ;j m T

m! @tm

# ðx;tÞ : ð3Þ

An interesting discussion concerning this expansion has been developed by Tzou [3] when n  m ¼ 0 or n  m ¼ 1, relating the progressive interchange between the diffusive and wave behaviors. We emphasize that the related time differential models obtained considering the Taylor series expansions of both sides of the Eq. (1) and retaining terms up to suitable orders in sq and sT (namely, first or second orders in sq and sT ) have been widely investigated with respect to their thermodynamic consistency as well as to interesting stability issues and wave propagation (see, for example, [5–9]). However, the general form of the time differential dual-phase-lag model as given by (3) wasn’t treated up to now, except for the paper by Quintanilla and Racke [10], where the spatial behavior is studied for solutions of the equation obtained by eliminating the heat flux vector between the constitutive Eq. (3) and the energy Eq. (2), provided n ¼ m or n ¼ m þ 1. The main purpose of this paper is to study the thermodynamical and mechanical consistency of the constitutive Eq. (3). We infer that the feasibility study of this constitutive equation greatly depends on the structure of the differential operators involved in its mathematical expression. In fact, if we consider the constitutive Eq. (3) as an ordinary linear differential equation in terms of the unknown function qi ðtÞ (or, equivalently, in terms of the unknown function T ;i ðtÞ) then we can observe that for n P 5 (or m P 5) it admits at least a complex root having a positive real part. That implies that qi ðtÞ (or T ;i ðtÞ) can tends to infinity when the time tends to infinity and so we are led to instability situations. On this way we conclude that the time differential dual-phase-lag model based on a constitutive equation of type (3) with n P 5 or m P 5 cannot be considered able to describe real mechanical situations. Instead, when n ¼ 0; 1; 2; 3; 4 and m ¼ 0; 1; 2; 3; 4 this is not the case and we have to study the thermodynamic consistency of the corresponding model. To this aim we follow [6,11] and we reformulate the constitutive Eq. (3) in such a way that the heat flux vector qi depends on the history of the temperature gradient. In this sense we rewrite the Eq. (3) in the framework of Gurtin and Pipkin [12] and Coleman and Gurtin [13] fading memory theory, and on this basis we analyze the compatibility of the model with the thermodynamical principles. Precisely, the thermo-

ðm; nÞ 2 fð0; 0Þ; ð1; 0Þ; ð0; 1Þ; ð2; 1Þ; ð1; 2Þ; ð2; 2Þ; ð3; 2Þ; ð2; 3Þ; ð3; 3Þ; ð3; 4Þ; ð4; 3Þ; ð4; 4Þg, provided appropriate restrictions are placed on the delay times.

2. Thermomechanical consistency of the model In this Section we consider the Eq. (3) as an ordinary linear nonhomogeneous differential (in time variable) equation in terms of the heat flux vector components and observe that its characteristic equation is

1 n n 1 1 1 s k þ sn1 kn1 þ    þ s2q k2 þ sq k þ 1 ¼ 0: n! q ðn  1Þ! q 2! 1!

ð4Þ

This equation is connected with the partial sums of the Maclaurin series for the exponential function e z and with the incomplete gamma function and its roots have been intensively studied in literature (see e. g. Eneström [14–17]). On the basis of the EneströmKakeya theorem it follows that all the roots of the Eq. (4) lie outside of the disk of radius s1q . Moreover, the Eq. (4) has no real root if n is even, while when n is odd, it has only one real root. However, here we are interested if this equation has at least a complex root with a positive real part. To this aim we outline the results obtained by Gábor Szegö [18] and Jean Dieudonné [19] who showed that the roots of the scaled exponential sum function approach the portion of the Szegö curve: jz expð1  zÞj ¼ 1 within the unit disk as n ! 1. Moreover, with the aim to visualize this result for n P 5 we recommend the simulation for the software package Wolfram Mathematica 11 presented in the Appendix (see also the Fig. 1).

Table 1 The values of x ¼ sq k with k solution of the characteristic Eq. (4) for n ¼ 1; 2; 3; 4. n

x ¼ sq k

1 2

1 1:0  1:0 i

3

1:5961 0:70196  1:8073 i

4

0:27056  2:5048 i 1:7294  0:88897 i

Fig. 1. Roots of the exponential sum for n ¼ 4 and for n ¼ 5.

S. Chiriţa˘ et al. / International Journal of Heat and Mass Transfer 114 (2017) 277–285

In view of the above discussion we can conclude that, for values of n greater than or equal to five, the characteristic Eq. (4) admits at least one complex root having a positive real part and this leads to a couple fT; qi g going to infinity as time tends to infinity, that is we are led to instability of the system. In conclusion, for n P 5 the corresponding models of dual-phase-lag of heat conduction are not suitable to describe the lagging behavior. Furthermore, we write the constitutive Eq. (3) in the following form

T ;i ðx;t Þ þ

sT @T ;i 1! @t "

ðx;t Þ þ

¼ K ij ðxÞ qj ðx;t Þ þ

s2T @ 2 T ;i 2! @t 2

sq @qj 1! @t

ðx;tÞ þ  þ

ðx;tÞ þ

m! @t m

2! @t 2

ðx;tÞ þ  þ

n

s @ qj n q

n! @t n

ðx;tÞ ;

where K ij are so that

ð6Þ

Following an argument similar to that in the above discussion, this time the unknown function being considered T ;i , we can conclude that, for values of m greater than or equal to five, the corresponding constitutive Eq. (3) leads to models of dual-phase-lag of heat conduction that are not suitable to describe the lagging behavior. On the other side, as it can be seen from the Table 1, it follows that for n ¼ 1; 2; 3; 4 all the solutions of the Eq. (4) have a negative real part and hence the corresponding contribution in the heat flux vector components can lead to an asymptotic stable behavior in time couple fT; qi g. In such cases we have to study further the consistency of the constitutive Eq. (3) with the Second Law of Thermodynamics. In conclusion, the constitutive Eq. (3) can be thermodynamically consistent only for n 2 f0; 1; 2; 3; 4g and m 2 f0; 1; 2; 3; 4g. Thus, in what follows we will study the thermodynamical consistency of the constitutive Eq. (3) for ðn; mÞ 2 f0; 1; 2; 3; 4g f0; 1; 2; 3; 4g. For future convenience, we will discuss separately each of the above cases. In order to study the cases involved in the Table 1, we consider the constitutive Eq. (3) as a memory constitutive equation of the type described in Gurtin and Pipkin [12] and Coleman and Gurtin [13]. 3. Case ðn; mÞ ¼ ð0; 0Þ This case yields the classical Fourier law of heat flux which is compatible with the Second Law of Thermodynamics.

The case ðn; mÞ ¼ ð1; 0Þ yields the Cattaneo-Maxwell equation of the heat flux vector which is consistent with thermodynamics for all sq > 0 and it is equivalent to the constitutive equation with fading memory

qi ðx; tÞ ¼ 

sq

Z

1

s=sq

e 0

kij ðxÞT ;j ðx; t  sÞds:

ð7Þ

1

sT

Z 0

1

es=sT K ij ðxÞqj ðx; t  sÞds:

Z

1

sq

1

0

h i es=sq kij ðxÞ T ;j ðx; t  sÞ þ sT T_ ;j ðx; t  sÞ ds;

ð9Þ

which integrated by parts gives

sT k ðxÞT ;j ðx; tÞ sq ij  Z 1 1 sT 1 es=sq kij ðxÞT ;j ðx; t  sÞds:  sq sq 0

qi ðx; tÞ ¼ 

ð10Þ

To determine the restrictions imposed by thermodynamics on the constitutive equation in concern, we postulate the Second Law of Thermodynamics in terms of a Clausius-Duhem inequality formulated on cyclic histories of period p, that is (see, e.g. Amendola et al. [20], Chapter 8, Section 8.2: Thermodynamic Constraints for Rigid Heat Conductors, page 216):

I

qi ðtÞT ;i ðtÞdt 6 0;

or; equiv alently;

Z

0

p

qi ðtÞT ;i ðtÞdt 6 0;

ð11Þ

where the equality occurs only for the null cycle and having omitted everywhere the explicit dependence upon the space variable. Consequently, any cycle characterized by the history

T ;i ðt  sÞ ¼ f i cos xðt  sÞ þ g i sin xðt  sÞ; x > 0; f i f i þ g i g i > 0; ð12Þ has to fulfil (11) as an inequality. In view of the relations (10) and (12), we have   sT  qi ðtÞT ;i ðtÞ ¼  kij f i f j þ kij g i g j þ kij f i f j  kij g i g j cos2xt 2 sq  Z 1  1 sT þ2kij f i g j sin2xt  1 es=sq sq sq 0    1 1 kij f i f j þ kij g i g j cos xsþ kij f i f j  kij g i g j cos xð2t  sÞ  2 2  þkij f i g j sin xð2t  sÞ ds; ð13Þ so that, by replacing into the inequality (11) and recalling that now the period is p ¼ 2xp, we get

Z 2p=x 0



qi ðtÞT ;i ðtÞdt ¼ 



 p kij f i f j þ kij g i g j 

s T s q x2 þ 1 ; x 1 þ s2q x2

ð14Þ

which is negative for all x > 0. Concluding, the dual-phase-lag model of heat conduction for ðn; mÞ ¼ ð1; 1Þ is compatible with thermodynamics for all sq > 0 and sT > 0.

Let us first consider the case ðn; mÞ ¼ ð2; 0Þ, that is we study the constitutive equation

qi ðtÞ þ sq q_ i ðtÞ þ

ð8Þ

Hence we conclude that the corresponding model is thermodynamically consistent for all sT > 0.

1 2 s q€i ðtÞ ¼ kij T ;j ðtÞ; 2 q

ð15Þ

where a superposed dot denotes the time differentiation. Then it can be written in the fading memory theory as

qi ðtÞ ¼ 

The case ðn; mÞ ¼ ð0; 1Þ can be treated by a similar way in view of the form (5) of the constitutive equation and we will have

T ;i ðx; tÞ ¼ 

qi ðx; tÞ ¼ 

6. Case ðn; mÞ‰fð2; 0Þ; ð0; 2Þg

4. Case ðn; mÞ‰fð1; 0Þ; ð0; 1Þg

1

The constitutive Eq. (3), for ðn; mÞ ¼ ð1; 1Þ, is equivalent to the constitutive equation with fading memory

#

ð5Þ

K ij kjs ¼ kij K js ¼ dis :

5. Case ðn; mÞ ¼ ð1; 1Þ

ðx;t Þ

2

s @ qj 2 q

smT @ m T ;i

279

2

sq

Z

0

1

  s kij T ;j ðt  sÞds; es=sq sin

sq

ð16Þ

and hence, by taking into account the relation (12), we have   Z  1 1 s=sq s  qi ðtÞT ;i ðtÞ ¼  e sin kij f i f j þ kij g i g j cos xs sq 0 sq    þ kij f i f j  kij g i g j cos xð2t  sÞ þ 2kij f i g j sin xð2t  sÞ ds:

ð17Þ

S. Chiriţa˘ et al. / International Journal of Heat and Mass Transfer 114 (2017) 277–285

280

Therefore, we obtain

Z 2p=x 0

qi ðtÞT ;i ðtÞdt ¼ 

2p 

k f f þk g g



Z

1

  s cos xsds es=sq sin

sq x ij i j ij i j 0  

2p kij f i f j þkij g i g j

2 s2q x2 ; ¼ 4 4 x sq x þ4

sq

qi ðtÞ þ sq q_ i ðtÞ þ

  1 2 1 sq q€i ðtÞ ¼ kij T ;j ðtÞ þ sT T_ ;j ðtÞ þ s2T T€ ;j ðtÞ ; 2 2

ð26Þ

have been established by Fabrizio and Lazzari in [6] to be

pffiffiffi

pffiffiffi

2  3 sT < sq < 2 þ 3 sT ;

ð27Þ

which are equivalent with

ð18Þ which cannot conserve a constant sign for all x > 0. Thus, the Second Law of Thermodynamics cannot be satisfied and the corresponding dual-phase-lag model is inconsistently from thermodynamic point of view. In view of the form (5) of the constitutive equation and by using an argument similar with that into above we conclude that the corresponding model for ðn; mÞ ¼ ð0; 2Þ is incompatible with thermodynamics.

pffiffiffi

pffiffiffi

2  3 sq < sT < 2 þ 3 sq :

ð28Þ

9. Case ðn; mÞ‰fð3; 0Þ; ð0; 3Þg Let us first consider the constitutive equation

  1 1 v qi ðtÞ ¼ kij T ;j ðtÞ þ sT T_ ;j ðtÞ þ s2T T€ ;j ðtÞ þ s3T T ;j ðtÞ ; 2 6

ð29Þ

and note that for any cycle as described by (12) we have

Z 2p=x

7. Case ðn; mÞ‰fð2; 1Þ; ð1; 2Þg We outline here that the case ðn; mÞ ¼ ð2; 1Þ was studied by Fabrizio and Lazzari in [6] and it was shown that the corresponding model, based on the constitutive equation

qi ðtÞ þ sq q_ i ðtÞ þ



1 2 s q€i ðtÞ ¼ kij T ;j ðtÞ þ sT T_ ;j ðtÞ ; 2 q

ð19Þ

is compatible with the thermodynamics if and only if the delay times satisfy the inequality

0 < sq 6 2sT :

ð20Þ

In what follows we consider the case ðn; mÞ ¼ ð1; 2Þ, that is we study the constitutive equation

  1 qi ðtÞ þ sq q_ i ðtÞ ¼ kij T ;j ðtÞ þ sT T_ ;j ðtÞ þ s2T T€ ;j ðtÞ : 2

ð21Þ

Considering (21) as a differential equation with the unknown function qi , we obtain the following equivalent representation

qi ðtÞ ¼ 

1

Z

sq

0

1



 1 es=sq kij T ;j ðt  sÞ þ sT T_ ;j ðt  sÞ þ s2T T€ ;j ðt  sÞ ds; 2

ð22Þ

qi ðtÞ ¼ 

s2T

2sq sq   1 sT  1 1

sq

sq

sT 2sq

sT

 kij T ;j ðtÞ

2sq  Z 1 0

es=sq kij T ;j ðt  sÞds:

ð23Þ

Thus, with the choice (12), from (23) we deduce

Z 2p=x 0











p kij f i f j þ kij g i g j s

s T s q 1  T x2 þ 1 ; qi ðtÞT ;i ðtÞdt ¼  2sq x 1 þ s2q x2 ð24Þ

and it will be negative for all x > 0 if and only if the following inequality

0 < sT 6 2sq ;

p  2x

  kij f i f j þ kij g i g j 2  s2T x2 ;

ð30Þ

which cannot conserve a constant sign for all x > 0. Thus, the Second Law of Thermodynamics cannot be satisfied and the corresponding dual-phase-lag model is inconsistently from thermodynamic point of view. Let us now consider the constitutive equation

qi ðtÞ þ sq q_ i ðtÞ þ

1 2 1 v s q€i ðtÞ þ s3q qi ðtÞ ¼ kij T ;j ðtÞ; 2 q 6

ð31Þ

which can be written as

  1 1 v €j ðtÞ þ s3q qj ðtÞ : T ;i ðtÞ ¼ K ij qj ðtÞ þ sq q_ j ðtÞ þ s2q q 2 6

ð32Þ

Thus, for any cycle characterized by

qi ðt  sÞ ¼ hi cos xðt  sÞ þ ‘i sin xðt  sÞ; x > 0; hi hi þ ‘i ‘i > 0; ð33Þ we have

Z 2p=x 0

qi ðtÞT ;i ðtÞdt ¼ 

 

p K ij hi hj þ K ij ‘i ‘j 2  s2q x2 ; 2x

ð34Þ

which cannot conserve a constant sign for all x > 0. Thus, the Second Law of Thermodynamics cannot be satisfied and the corresponding dual-phase-lag model is inconsistently from thermodynamic point of view.

and furthermore, by successive integration by parts, we have

 sT kij T_ ;j ðtÞ  1

0

qi ðtÞT ;i ðtÞdt ¼ 

ð25Þ

is fulfilled. Concluding, the dual-phase-lag models based upon the constitutive Eqs. (19) and (21) are compatible with the thermodynamics, provided the corresponding inequalities (20) and (25) are fulfilled. 8. Case ðn; mÞ ¼ ð2; 2Þ The restrictions upon the delay times which follow from Second Law of Thermodynamics for the constitutive equation

10. Case ðn; mÞ‰fð3; 1Þ; ð1; 3Þg We consider first the constitutive equation

  1 1 v qi ðtÞ þ sq q_ i ðtÞ ¼ kij T ;j ðtÞ þ sT T_ ;j ðtÞ þ s2T T€ ;j ðtÞ þ s3T T ;j ðtÞ ; ð35Þ 2 6 from which we deduce the following representation

 1 es=sq kij T ;j ðt  sÞ þ sT T_ ;j ðt  sÞ þ s2T T€ ;j ðt  sÞ 2 sq 0  1 3v ð36Þ þ sT T ;j ðt  sÞ ds: 6

qi ðtÞ ¼ 

1

Z

1

Further, for any cycle as described by (12), we obtain      Z 2p=x p kij f i f j þ kij g i g j 1 3 4 1 2

qi ðtÞT ;i ðtÞdt ¼ sq sT x þ sT  sq sT x2  1 ; 6 2 0 x 1 þ s2q x2 ð37Þ

an expression which cannot be negative for all positive values of x. Thus, the dual-phase-lag model based on the constitutive Eq. (35) cannot be compatible with thermodynamics.

S. Chiriţa˘ et al. / International Journal of Heat and Mass Transfer 114 (2017) 277–285

When the case ðn; mÞ ¼ ð3; 1Þ is addressed we write the constitutive equation in the form

T ;i ðtÞ þ sT T_ ;i ðtÞ ¼ K ij



 1 1 v €j ðtÞ þ s3q qj ðtÞ ; qj ðtÞ þ sq q_ j ðtÞ þ s2q q 2 6

ð38Þ

where, for convenience, we have set



0

ð40Þ

ð41Þ

ð42Þ

In the other case, that is for ðn; mÞ ¼ ð3; 2Þ, we write the constitutive equation in the following form

1 T ;i ðtÞ þ sT T_ ;i ðtÞ þ s2T T€ ;i ðtÞ 2   1 1 v €j ðtÞ þ s3q qj ðtÞ ; ¼ K ij qj ðtÞ þ sq q_ j ðtÞ þ s2q q 2 6

jðsÞ cos xsds; js ¼

0

js

6 ¼ s2q x4

ð43Þ

ð44Þ

12. Case ðn; mÞ ¼ ð3; 3Þ

s3q

sq

"



 12:1972

from which we deduce

i

Z 0

1

ð51Þ

sT 1 sq

2

sq

#

þ 0:0003

sq



sq



s2q x2 þ 24:3944 P 0;

ð52Þ

ð53Þ

where



s3T sT s2 sT ; b1 ¼ 4:06574 T2  6:09877 þ 4:06582 s3q sq sq sq sT 1 sq

2

þ 0:0003;

! ð54Þ

d1 ¼ 24:3944:

Furthermore, we see that the derivative

df ¼ 3a1 z2  2b1 z  c1 ; dz

ð55Þ

b1 

qffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffi 2 b1 þ 3a1 c1 3a1

< 0;

z2 ¼

b1 þ

qffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffi 2 b1 þ 3a1 c1 3a1

> 0:

ð56Þ

Thus, f ðzÞ P 0 for all z > 0 if we have f ðz2 Þ > 0, that is

ð45Þ

h

jðsÞkij T ;j ðt  sÞ þ sT T_ ;j ðt  sÞ 

s2T € s3 v T ;j ðt  sÞ þ T T ;j ðt  sÞ ds; 6

q

for all x P 0. We associate with this inequality the function

z1 ¼

v

€i ðtÞ þ qi ðtÞ qi ðtÞ þ sq q_ i ðtÞ þ q 2 6   s2 s3 v ¼ kij T ;j ðtÞ þ sT T_ ;j ðtÞ þ T T€ ;j ðtÞ þ T T ;j ðtÞ ; 2 6

2

3



admits the roots

We consider here the constitutive equation

þ

ð50Þ

f ðzÞ  a1 z3  b1 z2  c1 z þ d1 ;

Thus, we can conclude that the restrictions to be fulfilled by the delay times in order to have the thermodynamic consistency are described by the relations (42) and (44), respectively.

sq ða  cÞ2 þ d2

jðsÞ sin xsds:

In view of the values for a; c and d given in (48), it follows that the constitutive Eq. (45) is compatible with thermodynamics if the following condition is fulfilled !

3 s

2 s3 s2 sT T 0:677637 T3 s2q x2  4:0657 T2  6:09877 þ 4:06582 s2q x2

0:28441 sT < sq 6 1:4902 sT :

6

0

3 d2  3c2 þ 2ca  s2q x2 1 7 þ 5: a2 þ s2q x2 c2 þ d2 þ s2 x2 2  4d2 s2 x2 q q

c1 ¼ 12:1972

h

ð48Þ

q

and use the same procedure like that in the above to obtain the following restriction

qi ðtÞ ¼ 

1



a1 ¼ 0:677637

s2q

ð47Þ

ða  2cÞ c2 þ d2  as2q x2 7 a jc ¼ sq 6 þ 4 2 5;

2 a þ s2q x2 c2 þ d2 þ s2 x2  4d2 s2 x2 2

which is negative for all positive x if the delay times satisfy the inequality

0:28441 sq < sT 6 1:4902 sq :

Z

1

2

 "   2p kij f i f j þ kij g i g j 1 s2T 2 sT 4 4 qi ðtÞT ;i ðtÞdt ¼  1 sx 4 4 2 2 sq 3 sq q xðsq x þ 4Þ # !

sT s2  1  T2 s2q x2 þ 2 ; sq sq

sq

 ;

Furthermore, from the relations (47) and (50), we have

1

þ 2

ds

  6p kij f i f j þ kij g i g j h i sq x ða  cÞ2 þ d2      1 1 1  s2T x2 jc þ sT x  s3T x3 js ; ð49Þ 2 6

Z

jc ¼

and therefore, for any cycle as described by (12), we obtain

Z 2p=x

sq

 cos

qi ðtÞT ;i ðtÞdt ¼ 

where

It is equivalent with the following representation

  h s k T ðt  sÞ þ sT T_ ;j ðt  sÞ es=sq sin sq 0 sq ij ;j  1 1 v þ s2T T€ ;j ðt  sÞ þ s3T T ;j ðt  sÞ ds; 2 6

ds

Then, for any cycle characterized by (12), we have

0

Let us first consider the case ðn; mÞ ¼ ð2; 3Þ, that is we study the constitutive equation   1 1 1 v €i ðtÞ ¼ kij T ;j ðtÞ þ sT T_ ;j ðtÞ þ s2T T€ ;j ðtÞ þ s3T T ;j ðtÞ : qi ðtÞ þ sq q_ i ðtÞ þ s2q q 2 2 6 ð39Þ

Z

d

sin

a ¼ 1:5961; c ¼ 0:70196; d ¼ 1:8073: Z 2p=x

11. Case ðn; mÞ‰fð3; 2Þ; ð2; 3Þg

2

ac

jðsÞ ¼ eas=sq þ ecs=sq and

and use the above procedure to establish the incompatibility with thermodynamics of the corresponding dual-phase-lag model of heat conduction.

qi ðtÞ ¼ 

281

ð46Þ

rffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffi

3 1

2 3 b1 þ 3a1 c1 6 27a21 d1  2b1  9a1 b1 c1 : 2

ð57Þ

Thus, the constitutive Eq. (45) is compatible with the thermodynamics if the delay times satisfy the inequality (57). It can be verified that the set of delay times fulfilling (57) is non-empty (in fact it contains the case when sT ¼ sq ). Moreover, we have to outline that the inequality (52) has an approximately character and it depends on the approximation order of the roots a; c and d as defined in (48) and obtained in the Table 1.

S. Chiriţa˘ et al. / International Journal of Heat and Mass Transfer 114 (2017) 277–285

282

13. Case ðn; mÞ‰fð4; 0Þ; ð0; 4Þg Let us first consider the constitutive equation

"

qi ðtÞ ¼ kij T ;j ðtÞ þ sT T_ ;j ðtÞ þ

# @4T 1 2€ 1 v 1 sT T ;j ðtÞ þ s3T T ;j ðtÞ þ s4T 4;j ðtÞ ; 2 6 24 @t ð58Þ

and note that for any cycle as described by (12) we have

Z 2p=x 0

qi ðtÞT ;i ðtÞdt ¼ 

  i p kij f i f j þ kij g i g j h 2 2 2 sT x  6  12 ; ð59Þ 24x

which cannot conserve a constant sign for all x > 0. Thus, the Second Law of Thermodynamics cannot be satisfied and the corresponding dual-phase-lag model is inconsistently from thermodynamic point of view. Let us now consider the constitutive equation

qi ðtÞ þ sq q_ i ðtÞ þ

4

1 2 1 v 1 @ q s q€i ðtÞ þ s3q qi ðtÞ þ s4q 4i ðtÞ ¼ kij T ;j ðtÞ; 2 q 6 24 @t ð60Þ

4

T ;i ðtÞ ¼ K ij qj ðtÞ þ sq q_ j ðtÞ þ

@ q 1 2 1 v 1 s q€j ðtÞ þ s3q qj ðtÞ þ s4q 4j ðtÞ : 2 q 6 24 @t

Thus, for any cycle characterized by (33), we obtain

0

qi ðtÞT ;i ðtÞdt ¼ 

"

T ;i ðtÞ þ sT T_ ;i ðtÞ ¼ K ij qj ðtÞ þ sq q_ j ðtÞ þ

# 4 1 2 1 v 1 @ q sq q€j ðtÞ þ s3q qj ðtÞ þ s4q 4j ðtÞ ; 2 6 24 @t

and we obtain   Z 2p=x p K ij hi hj þ K ij ‘i ‘j   qi ðtÞT ;i ðtÞdt ¼  x 1 þ s2T x2 0 " #    s3q  sq sq sq 2 2 4 4  1 s x þ 1  s x þ 1 ;  T sT 2sT T 6s3T 4sT

ð67Þ

ð68Þ

which cannot conserve a constant sign for all x > 0. Concluding this section, we see that the dual-phase-lag models based on the constitutive Eqs. (63) and (66) are not compatible with the thermodynamics.

#

ð61Þ Z 2p=x

we write it as

ð66Þ

15. Case ðn; mÞ‰fð4; 2Þ; ð2; 4Þg

which can be written as

"

1 1 v 1 4 @ 4 qi €i ðtÞ þ s3q qi ðtÞ þ qi ðtÞ þ sq q_ i ðtÞ þ s2q q s ðtÞ 2 6 24 q @t4 h i ¼ kij T ;j ðtÞ þ sT T_ ;j ðtÞ ;

   p K ij hi hj þ K ij ‘i ‘j 2 2 2 sq x  6  12 ; 24x

Let us first consider the constitutive equation

1 €i ðtÞ qi ðtÞ þ sq q_ i ðtÞ þ s2q q 2 #  1 1 v 1 4 @ 4 T ;j sT 4 ðtÞ ; ¼ kij T ;j ðtÞ þ sT T_ ;j ðtÞ þ s2T T€ ;j ðtÞþ s3T T ;j ðtÞ þ 2 6 24 @t ð69Þ

ð62Þ which cannot conserve a constant sign for all x > 0. Thus, the Second Law of Thermodynamics cannot be satisfied and the corresponding dual-phase-lag model is inconsistently from thermodynamic point of view.

which gives

qi ðtÞ ¼ 

2

sq

Z

1

es=sq sin

0

s

sq

h kij T ;j ðt  sÞ þ sT T_ ;j ðt  sÞ

# 1 2€ 1 3v 1 4 @ 4 T ;j þ sT T ;j ðt  sÞþ sT T ;j ðt  sÞ þ s ðt  sÞ ds: 2 6 24 T @t 4

14. Case ðn; mÞ‰fð4; 1Þ; ð1; 4Þg

ð70Þ

Further, for any cycle characterized by (12), we obtain We consider now the constitutive equation " # 1 1 v 1 @4T qi ðtÞ þ sq q_ i ðtÞ ¼ kij T ;j ðtÞ þ sT T_ ;j ðtÞ þ s2T T€ ;j ðtÞ þ s3T T ;j ðtÞ þ s4T 4 ðtÞ ; 2 6 24 @t

Z 2p=x 0



qi ðtÞT ;i ðtÞdt ¼ 

1

! s4T 6 6 s4T 2s3T s2T 4 4

sx þ  þ sq x   12s4q q 6s4q 3s3q s2q

sq

! # s2T 2 2

þ sq x þ 4 ; 2 1  sq s2q



1 es=sq kij T ;j ðt  sÞ þ sT T_ ;j ðt  sÞ þ s2T T€ ;j ðt  sÞ 2 # 4 1 v 1 4@ T s ðt  sÞ ds: ð64Þ þ s3T T ;j ðt  sÞ þ 6 24 T @t 4

qi ðtÞ ¼ 

1

Z

2sT

0

Therefore, for any cycle characterized by (12), we get   Z 2p=x p kij f i f j þ kij g i g j

qi ðtÞT ;i ðtÞdt ¼  0 x 1 þ s2q x2 " #     s3T sT sT sT 2 2 4 4  1 s x þ 1  s x þ 1 ;  q 6s3q 4sq sq 2sq q

ð65Þ which cannot conserve a constant sign for all x > 0. Thus, the Second Law of Thermodynamics cannot be satisfied and the corresponding dual-phase-lag model is inconsistently from thermodynamic point of view. When it is considered the constitutive equation



"

ð63Þ

which furnishes

p kij f i f j þ kij g i g j xðs4q x4 þ 4Þ

ð71Þ

which cannot conserve a negative sign for all x > 0. Thus, the Second Law of Thermodynamics cannot be satisfied and the corresponding dual-phase-lag model is inconsistently from thermodynamic point of view. The same conclusion can be obtained for the case ðn; mÞ ¼ ð4; 2Þ. 16. Case ðn; mÞ‰fð4; 3Þ; ð3; 4Þg Let us first consider the constitutive equation

qi ðtÞ þ sq q_ i ðtÞ þ

1 2 1 v s q€i ðtÞ þ s3q qi ðtÞ 2 q 6

# 1 2€ 1 3v 1 4 @ 4 T ;j _ ¼ kij T ;j ðtÞ þ sT T ;j ðtÞ þ sT T ;j ðtÞþ sT T ;j ðtÞ þ s ðtÞ ; 2 6 24 T @t 4 

ð72Þ

S. Chiriţa˘ et al. / International Journal of Heat and Mass Transfer 114 (2017) 277–285

which gives

qi ðtÞ ¼ 

6

h

sq ðc  aÞ2 þ d2

i

Z 0

1

h

jðsÞkij T ;j ðt  sÞ þ sT T_ ;j ðt  sÞ

# 1 2€ 1 3v 1 4 @ 4 T ;j þ sT T ;j ðt  sÞ þ sT T ;j ðt  sÞ þ s ðt  sÞ ds; 2 6 24 T @t4

ð73Þ

where jðsÞ is given by relation (47) and the values of a; d and c are given by (48). For any cycle characterized by (12), we have

Z 2p=x 0



ð74Þ



2 sT s3 s2 sT 1:01643 T3  4:06574 T2 þ6:09877  4:06582 s2q x2 sq sq sq sq "



sT 1 sq

2

#

þ 0:0003



s2q x2 þ 24:3944 P 0;

ð75Þ

for all x P 0. Thus, the constitutive Eq. (72) is compatible with the thermodynamics if the delay times satisfy the inequalities

sT

0< < 1:33332; sq rffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffi

3 1

2 3 b2 þ 3a2 c2 6 27a22 d2  2b2  9a2 b2 c2 ; 2

ð76Þ

where

s3T s4  0:508231 T4 3 sq sq

a2 ¼ 0:677637 b2 ¼

sT s3 s2 sT 1:01643 T3 þ 4:06574 T2  6:09877 þ 4:06582 sq sq sq sq 

c2 ¼ 12:1972

sT 1 sq

which can be written as

qi ðtÞ ¼ 

! s3T s4T 2 2 3 0:677637 3  0:508231 4 sq x sq sq

 12:1972

ð79Þ

!

where

"

1

bs

ð81Þ

1 D ¼ 3ab2  3cd2 þ c3  a3  2ðc  aÞ h    ðc  aÞ2 3a2 þ 3c2  b2  d2    þ b2  d2 3c2  3a2 þ b2  d2 ¼ 22:165;

ð82Þ

and now we have set

a ¼ 0:27056; b ¼ 2:5048; c ¼ 1:7294; d ¼ 0:88897:

ð83Þ

Then, for any cycle characterized by (12), we have     Z 2p=x 24p kij f i f j þ kij g i g j 1 1 qi ðtÞT ;i ðtÞdt ¼  1  s2T x2 þ s4T x4 K c 2 24 sq x D 0    1 3 3 þ sT x  sT x K s ; 6 ð84Þ

Z 0

d2 ¼ 24:3944:

ð80Þ

# ða  cÞ2 þ d2  b2 bs KðsÞ ¼ e cos  sin sq 2bðc  aÞ sq " # ds ða  cÞ2 þ b2  d2 ds ;  ecs=sq cos þ sin sq 2dðc  aÞ sq as=sq

Kc ¼

þ 0:0003;

Z

1

Ks ¼

KðsÞ cos xsds;

1

ð85Þ

KðsÞ sin xsds:

0

Further, with the aid of (81), we have

ð77Þ It can be verified that it is non-empty the set of values for the delay times as defined by the relation (76), (in fact it contains at least the case when the delay times are equally, sT ¼ sq ). When the case ðn; mÞ ¼ ð4; 3Þ is considered, the constitutive equation is written in the equivalent form

1 1 v T ;i ðtÞ þ sT T_ ;i ðtÞ þ s2T T€ ;i ðtÞ þ s3T T ;i ðtÞ 2 6 #  4 1 1 v 1 4 @ qj €j ðtÞþ s3q qj ðtÞ þ ¼ K ij qj ðtÞ þ sq q_ j ðtÞ þ s2q q sq 4 ðtÞ ; 2 6 24 @t

2







q





c2 þ d2  a2  b2 s2q x2 þ c2 þ d2

2 K s ¼ s x4 2 q

h

s2q x2 þ a2  b2  caa ðc  aÞ2 þ d2  b2 





s4q x4 þ 2 a2  b2 s2q x2 þ a2 þ b2 h



s2q x2 þ c2  d2 þ cc a ðc  aÞ2 þ b2  d2 





q



3 3c2  d2 þ a2 þ b2  4ac 7 5

2 s4q x4 þ 2ðc2  d2 Þs2q x2 þ c2 þ d2



and

and then the thermodynamic restrictions can be obtained easily by using the relation (76).



2 2 2 2 2 2 2 2 2 2 2 2 sq 6 c þ d  a  b sq x  a þ b 3a  b þ c þ d  4ac Kc ¼ 4

2 2ðc  aÞ s4 x4 þ 2ða2  b2 Þs2 x2 þ a2 þ b2

ð78Þ

Let us now consider the constitutive equation

24 sq D

where

2

17. Case ðn; mÞ ¼ ð4; 4Þ

Z

h s2 KðsÞkij T ;j ðt  sÞ þ sT T_ ;j ðt  sÞþ T T€ ;j ðt  sÞ 2 0 # 4 3 v s 1 4 @ T ;j þ T T ;j ðt  sÞ þ s ðt  sÞ ds; 24 T @t4 6

qi ðtÞT ;i ðtÞdt ¼ 

where jc and js are defined by the relation (51). In view of relations (48), (51) and (74) it follows that the Second Law of Thermodynamics can be satisfied if the following inequality is fulfilled

þ

1 1 v 1 4 @ 4 qi €i ðtÞ þ s3q qi ðtÞ þ qi ðtÞ þ sq q_ i ðtÞ þ s2q q s ðtÞ 2 6 24 q @t 4 " # 1 1 v 1 4 @ 4 T ;j sT 4 ðtÞ ; ¼ kij T ;j ðtÞ þ sT T_ ;j ðtÞ þ s2T T€ ;j ðtÞ þ s3T T ;j ðtÞ þ 2 6 24 @t



6p kij f i f j þ kij g i g j h i sq x ðc  aÞ2 þ d2   1 1 4 4  1  s2T x2 þ sT x jc 2 24    1 3 3 þ sT x  sT x js ; 6

283



s4q x4 þ 2 c2  d2 s2q x2 þ c2 þ d2

2

ð86Þ

i

2

i3 5:

ð87Þ

In view of relations (83), (86) and (87) it follows that the Second Law of Thermodynamics can be satisfied if the following inequality is fulfilled

S. Chiriţa˘ et al. / International Journal of Heat and Mass Transfer 114 (2017) 277–285

284

2:69456

!

3 s4T 2 2 4 s2T s2T sT s x  32:3346  43:1121 þ 32:3348 s2q x2 q 4 2 2 sq sq sq sq

þ 64:668

!

2 s4T s3T s2T sT  258:676 þ 388:015  258:673 þ 64:6695 s2q x2 s4q s3q s2q sq

 776:016

!

s2T sT  1552:06 þ 776:031 s2q x2 þ 1552:03 P 0; 2 sq sq

ð88Þ

for all x P 0. It is not difficult to see that the above inequality is fulfilled when sT ¼ sq and so we can conclude that it is non-empty the set of couples ðsT ; sq Þ for which the constitutive Eq. (79) is compatible with the thermodynamics. Unfortunately, there seems to be unavailable to get an explicit expression defining this set. 18. Conclusions

ð0; 0Þ ð0; 1Þ ð0; 2Þ ð0; 3Þ

ð0; 4Þ

1

C B B ð1; 0Þ ð1; 1Þ ð1; 2Þ ð1; 3Þ ð1; 4Þ C C B B m  n ¼ B ð2; 0Þ ð2; 1Þ ð2; 2Þ ð2; 3Þ ð2; 4Þ C C; C B @ ð3; 0Þ ð3; 1Þ ð3; 2Þ ð3; 3Þ ð3; 4Þ A ð4; 0Þ ð4; 1Þ ð4; 2Þ ð4; 3Þ ð4; 4Þ provided appropriate restrictions are placed upon the delay times. In fact, from a mathematical point of view, the lagging behavior can be equally described by the following equation equivalent with the constitutive Eq. (3)

qi ðx; tÞ ¼ qhi ðx; tÞ þ qpi ðx; tÞ;

ð89Þ

where qhi ðx; tÞ represents the general integral of the homogeneous differential equation

qi ðx; tÞ þ

sq @qi 1! @t

ðx; tÞ þ

Conflict of interest None declared.

We inferred here an opinion about the time differential dualphase-lag models that is based on the information that we have upon the differential operators involved into the related constitutive equations. It is shown that, when the approximation orders are greater than or equal to five, the corresponding models lead to some instable mechanical systems. Instead, when the approximation orders are lower than or equal to four, then the corresponding models can be compatible with the thermodynamics, provided some appropriate restrictions are assumed upon the delay times. More precisely, the thermodynamical consistency of the model in concern is established when ðm; nÞ take the values in boldface of the matrix

0

ables. The extension of this analysis to nonlinear models (when, for example, the thermophysical properties of substances depend strongly on the temperature), there seems to be a complex task and for this it remains an open problem to be subject in a future research. On the other side, the present paper furnishes a new perspective upon the relationship between the thermodynamic aspects and the stability properties, with reference to the time differential dual-phase-lag models of heat conduction. We believe that this research provides useful information to clarify the applicability of these models.

s2q @ 2 qi 2! @t

2

ðx; t Þ þ    þ

snq @ n qi n! @t n

ðx; t Þ ¼ 0;

ð90Þ

Acknowledgments The authors are very grateful to the reviewers for their valuable comments, which have led to an improvement of the present work. Appendix A. Szegö’s curve In this appendix we provide the source code that has been created to generate an animation with the software package Wolfram Mathematica 11. The generated animation shows the complex roots of the scaled exponential sum of order n in the complex plane, with n increasing from 1 to 50, and it shows that the roots approach the Szegö curve as n increases. The following code could be entered in a Mathematica session and, once executed, the animation window is shown. e[n_, z_] :¼ Sum[z^k/k!, {k, 0, n}] axes = Graphics[{Line[{{-1, 0}, {1, 0}}], Line[{{0, 1}, {0, 1}}]}]; szegoeCurve = ContourPlot[Evaluate[Abs[z E^(1 z)] == 1/. z -> x + I y], {x, 1, 1}, {y, 1, 1}, PlotPoints -> 50]; rootsGraph[m_] :¼ Module[{roots, n = IntegerPart [m], points,} roots = NSolve[e[n, n z] == 0, z][[All, 1, 2]]; points = Transpose[{Re[roots], Im[roots]}]; Show[{axes, szegoeCurve, ListPlot[points, PlotRange -> {{-1, 1}, {-1, 1}}, AspectRatio -> 1]}]] Animate[rootsGraph[m], {m, 1, 50}, DefaultDuration > 50]

and qpi ðx; tÞ is a particular solution of the differential Eq. (3). The explicit expression of qhi ðx; tÞ represents a concrete combination of the number of time exponentials relating the roots of the characteristic Eq. (4), while the expression of the particular solution qpi ðx; tÞ represents a convolution (memory) term. In view of the results established by Szegö [18], if follows that, for n P 5, the expression of qhi ðx; tÞ involves some exponentials growing in time at infinity and this proves an asymptotic instable mechanical system. Thus, the situation with ðn; mÞ ¼ ð1; 0Þ, which corresponds to rather widely used model with an only delay time of the heat flux relative to the temperature gradient, appears to lead to an instable mechanical system. Instead, when n < 5 this is not the case and we have searched the memory term described by qpi ðx; tÞ by means of the techniques developed for materials with memory by Gurtin and Pipkin [12] and Coleman and Gurtin [13] and Amendola et al. [20]. Our analysis is limited to the constitutive Eq. (3), where the delay times are assumed to be positive constant parameters. It is worth to mention that our analysis remains valid when the delay times are not constant, but they can depend on the spatial vari-

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