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REVIEW article

Front. Phys., 23 October 2023
Sec. Mathematical Physics

The influence of rotation and viscosity on generalized conformable fractional micropolar thermoelasticity with two temperatures

  • 1Department of Mathematical Sciences, College of Science, Princess Nourah Bint Abdulrahman University, Riyadh, Saudi Arabia
  • 2Basic and Applied Science Institute, Arab Academy for Science, Technology and Maritime Transport, Alexandria, Egypt
  • 3National Committee for Mathematics, Academy of Scientific Research and Technology, Cairo, Egypt
  • 4Council of Future Studies and Risk Management, Academy of Scientific Research and Technology, Cairo, Egypt
  • 5Department of Mathematics, Faculty of Science, Damanhur University, Damanhur, Egypt

This research paper presents the generalized micropolar thermo-visco-elasticity model in an isotropic elastic medium that has two temperatures with conformable fractional order theory. The whole elastic medium rotates at a constant angular velocity. The generalized theory of thermoelasticity with one relaxation time is used to describe this model. We aim to study the effect of conformable fractional derivative, effect of rotation, and the two-temperature coefficients. The normal mode analysis is used to acquire the specific articulations for each component under consideration. Moreover, some specific cases are discussed with regarding to the problem. Numerical findings are gathered and displayed graphically for the variables under consideration. The outcomes were analyzed in terms of the presence or absence of rotation, viscosity, conformable fractional parameter and two temperatures for various values.

1 Introduction

The study of fractional calculus, a subject that has garnered significant attention from mathematicians, engineers, and physicians, involves the investigation of mathematical analysis utilizing differential operators of any order. The fractional calculus has extended the usual definitions of integer order integrals and derivatives in ordinary differential calculus by transforming them into real-order operators [16].

Over the past 40 years, there has been a lot of focus on Theories of thermoelasticity that permit for restricted heat wave speed. These theories, known as general thermo-elasticity theories, are hyperbolic and differ from the traditional combined thermo-elasticity (C-T) theory [7], This predicts an infinite pace of heat propagation and is based on a parabolic heat equation. Lord and Shulman (L-S) [8] were the first to alter the usual Fourier law by including a unique heat conduction law, resulting in a wave type heat equation, on the other hand Green and Lindsay (G-L) [9], introduced the temperature-rate hypothesis of thermoelasticity. Green and Naghdi (G-N) [10], proposed a theory of thermo-elasticity without energy dissipation, this, unlike earlier models, does not account for thermal energy loss. Chandrasekharaia proposed two theories of dual-phase lag thermo-elasticity [11, 12] and Tzou [13]. Eringen developed the general theory of micropolar elasticity [14, 15]. In this form of solid, the vector of displacement and micro-rotation is fully defined, whereas the displacement vector alone defines motion in the case of classical elasticity [16]. The essential equations of the theory of micropolar thermoelasticity linearly get by Tauchert et al. [17] and Boschi [18]. Ciarletta [19] proposed a thermoelasticity with micropolar energy dissipation. A Lord-Shulman model of micropolar thermoelasticity dependent linear theory was proposed by Sherief et al. [20]. Othman is to blame for various issues with thermoelastic spinning media [21].

Many authors have made significant contributions to resolving the boundary value problem for thermoelasticity [2227].

Chen and Gurtin discussed two types of temperatures: thermodynamic temperature and conductive temperature [28]. In time-independent settings, the connection between these two temperatures is linked to the heat supply. The two temperatures are similar in the absence of a heat supply and often differ in the presence of a heat supply. The two temperatures and strain are shown to have inputs in the form of a travelling wave and an instantaneous reaction that happens during the body. The waves in the two-temperature thermoelasticity theory were investigated by Warren [29], but no study in the sense of a generalised thermoelasticity theory has been carried out so far. So, along with two temperatures, the theory of two-temperature-generalized thermo-visco-elasticity will be constructed in this work.

Many authors have made significant contributions to resolving the boundary value problem for linear viscoelastic thermal materials [3033].

The current study seeks to determine the physical quantities, such as viscosity, rotation, conformable fractional parameter, and two-temperatures, in a homogeneous, isotropic, micropolar thermo-elastic material [1, 3440].

2 Field equations and constitutive relations

We put a system in a generalized micropolar thermo-viscoelastic medium under five theories, two temperatures and rotation as [41, 42]:

(i) The constitutive relations

σij=2μe1+α1teij+λe1+α0teδijγeT01+γ0tTδij,(1)
mij=αϕr,rδij+εϕj,i+βϕi,j.(2)

(ii) Stress equation of motion

λe1+αot+μe1+α1tu¯+μe1+α1t+υ2u¯+υ×ϕ¯γe1+γotT=ρu¯¨+Ω¯×Ω¯×u¯+2Ω¯×u¯˙.(3)

(iii) Couple stress equation of motion [43, 44]

α+β+εϕ¯ε××ϕ¯+υ×u¯2υϕ¯=ρjϕ¯¨+Ω¯×ϕ¯˙.(4)

(iv) Heat conduction equation with five theories

kθ,ii=ρCE1+τ0αα!t1αtT˙+γeT01+γ0t1+τ0αα!t1αte˙,(5)

With,

T=θaθ,ii.(6)

3 Problem formulation

Take a homogenous, isotropic, micropolar-viscoelastic generalised medium with rotation and two temperatures with Cartesian rectangular system of coordinates x,y,z , getting half-space surface like the plane z=0. Two more terminology for the displacement equation in the rotating frame: the centripetal acceleration Ω¯×Ω¯×u¯ just because of the time change and the Coriolis acceleration 2Ω¯×u¯˙ because of the moving frame of reference.

Our study was restricted to xz plane. Then u¯, Ω¯ and ϕ¯ will have the components:

u¯=u,0,w,Ω¯=0,Ω,0 and ϕ¯=0,ϕ,0(7)

Combination of (3), (4) and (7) provides:

ρu¨+2Ωw˙Ω2u=μe1+α1t2u+1+α1tμe+1+α0tλee,xυϕ,zγe1+γ0tT,x,(8)
ρw¨Ω2w2Ωu˙=μe1+α1t+υ2w+μe1+α1t+λe1+α0te,z+υϕ,zγe1+γ0tT,z,(9)
ε2ϕ+υu,zw,x2υϕ=ρjϕ¨.(10)

From Eqs 1, 2, 7 the stresses can be formulated as follow:

σxx=2μe1+α1t+υu,x+λe1+α0teγe1+γ0tT,(11)
σzz=2μe1+α1t+υw,z+λe1+α0teγe1+γ0tT,(12)
σxz=μe1+α1t+υw,x+μe1+α1tu,z+υϕ,(13)
σzx=μe1+α1t+υu,z+μe1+α1tw,xυϕ,(14)
mxy=εϕ,x,(15)
mzy=εϕ,z.(16)

For simplification, we take the non-dimensional variables:

x,z=ϖcoxi,zi,t,τ0,α0,α1,γ0=ϖt,τ0,α0,α1,γ0,
T,θ=T,θT0,σij=σijγeT0,Ω=Ωc02η,u,w=ρcoϖγeTou,w,mij=ϖγeTocomij,ϕ=ρco2γeToϕ.(17)

Where, c02=λe+2μe+υρ,ϖ=ρco2CEk.

With regard to the non-dimensional quantities set out in (17), Eqs 810, Eqs 5, 6 take the form:

u¨Ω2u+2Ωw˙=a11+α1t+υ12u+a21+αot+a31+αote,xυ1ϕ,z1+γ0tT,x,(18)
w¨Ω2w2Ωu˙=a11+α1t+υ12w+a21+αot+a31+αote,z+υ1ϕ,x1+γ0t1+υ0tT,z,(19)
2ϕ+a4u,zw,x2a4ϕ=a5ϕ¨,(20)
2θ=1+τ0αα!t1αtT˙+εo1+γ0t1+τ0αα!t1αte˙,(21)
T=1a*2θ.(22)

Also, the constitutive relations (11)–(16) reduce to

σxx=2a11+α1t+υ1u,x+a21+α0te1+γ0tT,(23)
σzz=2a11+α1t+υ1w,z+a21+α0te1+γ0tT,(24)
σxz=a11+α1t+υ1w,x+a11+α1tu,z+υ1ϕ,(25)
σzx=a11+α1t+υ1u,z+a11+α1tw,xυ1ϕ,(26)
mxy=a6ϕ,x,(27)
mzy=a6ϕ,z,(28)

Where,

a1=μeρc02,a2=λeγeTo,a3=μeγeTo,a4=υco2εϖ2,a5=ρjco2ε,a6=εϖ2ρco4,εo=γeρCE,a*=aϖ2co2,υ1=υρco2 .(29)

We define ex,z,t and ψx,z,t as the displacement potentials recount to u and w

e=u,x+w,z,ψ=u,zw,x.(30)

4 Normal mode analysis

In terms of normal modes, the solution of the considered variables can be written as:

u,w,e,ψ,T,θ,ϕ,mij,σijx,z,t=u¯,w¯,e¯,ψ¯,T¯,θ¯,ϕ¯,m¯ij,σ¯ijzexpωt+ibx.(31)

Where, u¯,w¯,e¯,ψ¯,T¯,θ¯,ϕ¯,m¯ij,σ¯ijz are the amplitudes of the variables, ω is the complex angular frequency, b is the wave number in the z-direction and =1 .

From Eqs 18, 19 we get

e¨Ω2e2Ωψ˙=a11+α1t+a21+αot+a31+αot+υ12e1+γ0t2T,(32)
ψ¨Ω2ψ+2Ωe˙=a11+α1t+υ12ψυ12ϕ.(33)

Using Eqs 22, 30, 31, Eqs 20, 21, 31 and 32 lead to

b1D2b2b2θ¯=b3e¯,(34)
b4b5D2b2e¯b6ψ¯=b7D2b21a*D2b2θ¯,(35)
b4b8D2b2ψ¯=b6e¯υ1D2b2ϕ¯,(36)
D2b2ϕ¯+a4ψ¯2a4ϕ¯=ω2a5ϕ¯.(37)

Also, the constitutive relations (18)–(21) become

σ¯xx=2a11+α1ω+υ1ibu¯+a21+αoωe¯1+γoωT¯,(38)
σ¯zz=2a11+α1ω+υ1Dw¯+a21+αoωe¯1+γoωT¯,(39)
σ¯xz=a11+α1ω+υ1ibw¯+a11+αoωDu¯+υ1ϕ¯,(40)
σ¯zx=a11+α1ω+υ1Du¯+a11+αoωibw¯υ1ϕ¯,(41)
m¯xy=iba6ϕ¯,(42)
m¯zy=a6Dϕ¯.(43)

Where,

D=ddz,b1=a*ω1+τ0αα!t1αω,b2=εoω1+γ0ω1+τ0αα!t1αω,
b3=εoω1+γ0ω1+τ0αα!t1αω,b4=ω2Ω2,b5=1+α1ωa1+1+α0ωa2+1+α1ωa3+υ1,b6=2Ωω,b7=1+γoω,b8=υ1+a11+α1ω,b9=ω2a5+2a4.

Eliminating ψ¯z, θ¯z and ϕ¯z between Eqs 3437, we get the following eighth order ordinary differential equation satisfied with e¯z

D8AD6+BD4CD2+Ee¯z=0.(44)

Where,

A=b1b5+a*b3b7a4υ1b4b8b92b2b8b8b1b4+2b2b1b5+b2b5+b3b7+2a*b2b3b7b1b5b8a*b3b7b8,
B=b1b5a*b3b7b4b9+b2b4+b2b8b9+b4b8b2a4υ1b8b2b1b4+b4b1b5+b2b4+b2b2b5+a4υ1b4b8b92b2b8b1b4+2b2b1b5+b2b5+b3b7+2a*b2b3b7a*b4b3b7b8b2b3b7b8b1b62b1b5b8a*b3b7b8,
C=b4b9+b2b4+b2b8b9+b4b8b2a4υ1b1b4+2b2b1b5+b2b5+b3b7+2a*b2b3b7+a4υ1b4b8b92b2b8a*b4b3b7+b2b3b7+b2b1b4+b4b1b5+b2b4+b2b2b5b62b1b9+2b2b1+b2b1b5b8a*b3b7b8,
E=b4b9+b2b4+b2b8b9+b4b8b2a4υ1a*b4b3b7+b2b3b7+b2b1b4+b4b1b5+b2b4+b2b2b5b62b2b1b9+b4b1+b2b9+b2b2b1b5b8a*b3b7b8.

By rewriting Eq. 44, we get

D2k12D2k22D2k32D2k42e¯z=0.(45)

Where, the roots of the characteristic Eq. 44

kn2 n=1,2,3,4.

The solution of Eq. 44, which bounded as x, is given by

e¯z=n=14Mneknz.(46)

In a similar manner,

θ¯x=n=14H1nMneknz,(47)
ψ¯z=n=14H3nMneknz.(48)

Substituting from Eqs 46 to Eq. 48 and (31) in Eqs 30, 22 and Eqs 3843, the thermodynamic temperature, micro-rotation, the displacement, force stresses and the couple stresses components take the form

T¯z=n=14H2nMneknz,(49)
ϕ¯z=n=14H4nMneknz,(50)
w¯z=n=14H5nMneknz,(51)
u¯z=n=14H6nMneknz,(52)
σ¯xxz=n=14H7nMneknz,(53)
σ¯zzz=n=14H8nMneknz,(54)
σ¯xzz=n=14H9nMneknz,(55)
σ¯zxz=n=14G1nMneknz,(56)
m¯xyz=n=14G2nMneknz,(57)
m¯zyx=n=14G3nMneknz.(58)

Where,

H1n=b3b1kn2b2b2,H2n=1a*kn2b2H1n,H3n=b4b5kn2b2+H2nb7kn2b2b6,H4n=a4H3nb9kn2b2,H5n=knibH3nkn2b2,H6n=i1+knH5nb,H7n=ibH6n2a11+α1ω+υ1+a21+αoωH2n1+γoωH8n=knH5n2a11+α1ω+υ1+a21+αoωH2n1+γoω,H9n=ibH5na11+α1ω+υ1+υ1H4na1knH6n1+α1ω,G1n=knH6na11+α1ω+υ1+iba1H5n1+α1ωυ1H4n,G2n=iba6H4n,G3n=a6knH4n.

Mnn=1,2,3,4, some coefficients can be calculated based on the boundary conditions

5 The boundary conditions

To obtain the coefficients Mnn=1,2,3,4, we use the surface’s boundary conditions on the surface z=0 as

Tx,0,t=fx,0,t=f*expωt+ibx,(59)
σzzx,0,t=0,(60)
σzxx,0,t=0,(61)
mzyx,0,t=0.(62)

Where, fx,t is an arbitrary function of x,t and f* is the magnitude of the constant temperature applied to the boundary.

Using Eqs 5962, the following equations satisfied by the coefficient Mnn=1,2,3,4 can be obtained

n=14H2nMn=f*,(63)
n=14H8nMn=0,(64)
n=14G1nMn=0,(65)
n=14G3nMn=0.(66)

We complete the solution of the problem by solving the system of Eqs 6366.

6 Numerical results and disccusion

To perform numerical calculations [45] the magnesium crystal value of the related parameters is taken at

To=23Co
λe=9.4×1010kg m1 s2,ε=0.779×109kg m s2,,k=2.510w.m1.k1,αt=2.36×105k1,ρ=1.74×103kg.m3,CE=9.623J.kg1.k1,υ=1010kg m1s2,μe=4×1010kg m1s2,j=0.2×1019m2.

The comparison was performed for

x=0.01,f*=1,ω=ω0+iξ,ω0=2,ξ=1,b=0.5,τ0=0.08,α=0.1a=0.5,Ω=0.1,α0=0.6,α1=0.9.

The numerical data given above were used to determine the real part distribution of the displacement component, force stress components, conductive temperature, thermo-dynamic temperature, micro-rotation, and couple stress components in relation to the problem under consideration. Figures 125 show the results.

FIGURE 1
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FIGURE 1. Thermodynamic temperature T for various values of rotation.

FIGURE 2
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FIGURE 2. Conductive temperature θ for various values of rotation.

FIGURE 3
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FIGURE 3. Horizontal displacement u for various values of rotation.

FIGURE 4
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FIGURE 4. Force stress components σzx for various values of rotation.

FIGURE 5
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FIGURE 5. Force stress components σzz for various values of rotation.

FIGURE 6
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FIGURE 6. Couple stress components mzy for various values of rotation.

FIGURE 7
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FIGURE 7. Micro-rotation φ for various values of rotation.

FIGURE 8
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FIGURE 8. Thermodynamic temperature T for two various values of two-temperature parameter.

FIGURE 9
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FIGURE 9. Conductive temperature θ for two various values of two - temperature parameter.

FIGURE 10
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FIGURE 10. Horizontal displacement u for two various values of two-temperature parameter.

FIGURE 11
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FIGURE 11. Force stress components σzx for two various values of two-temperature parameter.

FIGURE 12
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FIGURE 12. Force stress components σzz for two various values of two-temperature parameter.

FIGURE 13
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FIGURE 13. Couple stress components mzy for two various values of two-temperature parameter.

FIGURE 14
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FIGURE 14. Micro-rotation ϕ for two various values of two-temperature parameter.

FIGURE 15
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FIGURE 15. Thermodynamic temperature distribution T in the nonexistence and existence of viscosity.

FIGURE 16
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FIGURE 16. Conductive temperature distribution θ in the nonexistence and existence of viscosity.

FIGURE 17
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FIGURE 17. Horizontal displacement distribution u in the nonexistence and existence of viscosity.

FIGURE 18
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FIGURE 18. Distribution of force stress components σzx in the nonexistence and existence of viscosity.

FIGURE 19
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FIGURE 19. Distribution of force stress components σzz in the nonexistence and existence of viscosity.

FIGURE 20
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FIGURE 20. Distribution of couple stress components mzy in the nonexistence and existence of viscosity.

FIGURE 21
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FIGURE 21. Distribution of micro-rotation ϕ in the nonexistence and existence of viscosity.

FIGURE 22
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FIGURE 22. Distribution of the temperature T for various values of α.

FIGURE 23
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FIGURE 23. Distribution of the temperature θ for various values of α.

FIGURE 24
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FIGURE 24. Distribution of the horizontal displacement u for various values of α.

FIGURE 25
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FIGURE 25. Distribution of the stress component σzx for various values of α.

From an implementation standpoint, we divided the schematics into four components.

(i) For different values of rotation, the micropolar thermo-visco-elasticity theory with conformable fractional order theory and two-temperatures is concerned. Figures 17 i.e.., Ω=0.1,0.01.

(ii) For different values of aa=0,a=0.5, the micropolar thermo-visco-elasticity theory with rotation and conformable fractional order theory is concerned. Figures 814, where a=0 indicates one-type temperature and a=0.5 indicates two-types of temperature.

(iii) Concerned are micropolar thermoelasticity with rotation, conformable fractional order theory, and two temperatures. Figures 1521 show variable comparisons for various values of α0 and α1 where, α0=α1=0 indicates a generalized theory of micropolar thermo-elasticity (TE) and α0=0.6, α1=0.9 indicates generalized theory of micropolar thermo-visco-elasticity (TVE).

(v)The Figures 2225 clarified four curves predicted by the different theories of thermo-elasticity, such that

α=1, indicates the generalized micropolar thermoelastic theory with one relaxation time [8].

t=0, indicates the coupled theory of micropolar thermoelasticity [46].

0<α<1, indicates the generalized conformable fractional order theory of micropolar thermo-elasticity.

(i) (Effect of rotation)

Figures 1, 2 depict the distribution of θ and T with distance x with two-temperatures for varying rotational values. It is noticed that curves of θ and T begin from a positive value. Then, it then reduces to zero indefinitely.

Figure 3 shows the variations of u with distance x with two-temperatures for different values of rotation. The rotation has a decreasing influence.

Figures 4, 5 represent the profile of force stress components σzx,σzz based for various values of rotation with two-temperature. They start with a zero value that is completely compatible with the limits. The value of σzx,σzz for Ω=0.1 is less as compared to Ω=0.01, the values of σzx,σzz tending to zero.

Figure 6 displays the disparity of the couple stress component mzy with distance x for two-temperatures for varying rotational values. It begins with a zero value entirely consistent with the limit conditions. We notice that the value of mzy for Ω=0.1 is less as compared to Ω=0.01, the values of mzy tending to zero.

Figure 7 shows the variation of the micro-rotation ϕ with distance x, with two-temperatures for different values of rotation. The rotation has a decreasing influence.

(ii) Effect of two temperatures

Figure 8 illuminates the supply of the thermodynamic temperature T with distance x for different a=0,a=0.1. values under the influence of rotation. It begins with T=1 that fully complies with the limit conditions, subsequently decreases continually to zero value. We noticed that the parameter a has an increasing effect

Figure 9 shows the conductive temperature θ with distance x with the effect of rotation. We noticed that the curve of θ begins from a positive value. It then, reduces constantly to zero. We notice that the parameter a has an increasing effect.

Figure 10 displays the variations of u with distance z under the influence of rotation for different values of a=0,a=0.5. The parameter a is seen to have an increasing impact.

Figures 11, 12 denote the outline of the force stress component σzx,σzz under the effect of rotation for changed values of a=0,a=0.5. It begins with a zero value that is fully consistent with the limits. In this figure, we can see that the values of σzx,σzz for a=0 is greater than that at =0.5 .

Figure 13 shows the profile of the couple stress component mzy under the influence of rotation for the values of a=0,a=0.5. This begins with a zero value that is totally compatible with the limits. In this figure, we can see that the value of mzy for a=0.5 is greater than that at as a=0 It is observed that the influence is rising in parameter.

Figure 14 represents the variation of the micro-rotation with distance under the influence of rotation for different values of =0, a=0.5. In the figure the value of ϕ for a=0.5 is greater than that at a=0. The a parameter is seen to have a growing effect.

(iii) Effect of viscosity

Figures 15, 16 depict θ and T in two-temperature under the influence of rotation with and without of viscosity. It has been observed that the curves of θ and T begin from a positive value, Then it decreases constantly to zero.

Figure 17 shows the deviation of the horizontal displacement distribution u with distance x under the influence of rotation and two-temperatures with and without viscosity. It can be seen that TE>TVE

Figures 18, 19 represent the profile of stress components σzx, σzz under the influence of rotation and two-temperature for TE and TVE.They begin with a zero value that is fully in line with the limit conditions. The value of σzx for TVE is greater than that for TE. the value of σzz for TE is greater than that for TVE.

Figure 20 depicts the disparity of the couple stress mzy with distance x under the influence of rotation and two-temperatures for TE and TVE.We observe that the value of mzy for TVE is greater than that for TE.

Figure 21 depicts the variation of the micro-rotation ϕ with distance x under the influence of rotation and two-temperature for TE and TVE. We observe that the value of ϕ for TVE is greater than that for TE.

(v) Effect of Conformable fractional parameter

The figures [2224] clarified four curves predicted by the different theories of thermo-elasticity, such that

α=1, indicates the generalized thermoelastic theory with one relaxation time [10].

t=0, indicates the coupled theory of thermoelasticity [9].

0<α<1, indicates the generalized conformable fractional order theory of thermo-elasticity.

Figures 22, 23 depict the distribution of the thermo-dynamic temperature T and conductive temperature θ with distance x, under the influence of rotation and two-temperature for various values of α and for t=0. It is observed that the variation of θ starts from a positive value, then decreases continually to zero. It is also visible that for α=1, the result coincides with all results of applications that are taken in the context of the generalized thermoelasticity with one relaxation time, for t=0, the result coincides with all results of applications that are taken in the case of the coupled theory, for α=0.1 and α=0.5 gives new results for the generalized conformable fractional order theory of thermoelasticity From this figure it is spotted that as fractional parameter α increase the measure of the temperature θ rise.

Figure 24 shows the variations of u via distance x under the influence of rotation and two-temperature for various values of α and t=0. For α=1, the result to agree with all results of applications that are taken in the context of the generalized thermoelasticity with one relaxation time, for t=0, the result agree with all results of applications that are taken in the context of the coupled theory, for α=1 and α=0.5 gives new results for the generalized conformable fractional order theory of thermoelasticity.

Figure 25 explains the variations of stress components σzx with distance x under the influence of rotation and two-temperature for various values of α and for t=0. It can be visible that they beginning with zero value that fully agrees with the boundary conditions.

7 Conclusion

Normal mode analysis was employed to investigate the behavior of the conductive temperature, the thermodynamic temperature, the component of horizontal displacement, the component of force stress, the couple stresses, and the micro-rotation under the effect of rotation, conformable fractional order theory, viscosity, and two-temperatures in a homogeneous, isotropic, generalized micropolar thermo-viscoelastic medium. We aim to study the effect of conformable fractional derivative, effect of rotation, and the two-temperature coefficients. The above analysis leads us to the following conclusions:

• Variations in various fields are clearly constrained to a certain zone in all of the data, and the values vanish outside of the region, which is consistent with the perspective of generalized micropolar thermo-visco- elasticity theory.

• All of the physical values fulfill the boundary criteria.

• The thermodynamic and conductive temperature nature of all models TE and TVE is same.

• The angular velocity and two-temperature parameters have a significant impact on the horizontal displacement component, the force stress components, the couple stresses components, and the micro-rotation. However, there are minor impacts on the conductive temperature and the thermodynamic temperature.

• For two temperature parameter values, θ and T show a virtually identical pattern, and increasing the value of the two-temperature parameter leads the values of those functions to grow. While increasing the two-temperature parameter value leads the values of the horizontal displacement and stress components to drop, increasing the two-temperature parameter value causes the values of these functions to rise, as shown in the figures.

The given model will be valuable for scientists working on micropolar thermoelasticity in understanding the viscoelastic characteristics of human soft tissue and may lead to enhanced diagnostic applications. The findings may be used to both theoretical and empirical wave propagation.

• The fractional parameter α highly influences all variables.

• According to this work, we can treat the theory of conformable fractional order generalized micropolar thermoelasticity as an improvement in studying thermoelastic materials, we have to construct a new ranking for materials according to their fractional parameter α, where this parameter becomes a new conductor of its ability to conduct heat under the effect of thermoelastic properties, we use these properties in the factory of glasses and ceramic.

Author contributions

SE-S: Software, Writing–review and editing. AE-B: Methodology, Writing–original draft. HA: Writing–original draft.

Funding

The author(s) declare financial support was received for the research, authorship, and/or publication of this article.

Acknowledgments

Authors extend their appreciation to Princess Nourah Bint Abdulrahman University for funding this research under researchers supporting project number PNURSP2023R154, Princess Nourah Bint Abdulrahman University, Riyadh, Saudi Arabia.

Conflict of interest

The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.

Publisher’s note

All claims expressed in this article are solely those of the authors and do not necessarily represent those of their affiliated organizations, or those of the publisher, the editors and the reviewers. Any product that may be evaluated in this article, or claim that may be made by its manufacturer, is not guaranteed or endorsed by the publisher.

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Nomenclature

Appendix

Researchers in the field of thermoelasticity have all employed fractional derivatives to develop the heat conduction equation based on these derivatives

kθ,ii=ρcE1+τ0αα!αtαθ,t+γT01+τ0αα!αtαe,t1+τ0αα!αtαQ(A1)

They arrived at this equation through the utilization of the following definitions:

(i) Riemann-Liouville definition. For αn1,n, the α derivatives of f is

Daαft=1Γnαdndtnatfxtxαn+1dx.(A2)

(ii) Caputo definition. For αn1,n, the α derivatives of f is

Daαft=1Γnαatfnxtxαn+1dx.(A3)

Nevertheless, these two definitions possess certain limitations that can be summarized as follows:

(i) The Riemann-Liouville derivatives do not hold true for

Daα1=0Daα1=0 for the caputo derivative,if α is not natural.(A4)

(ii) None of the fractional derivatives fulfill the well-known formula for the derivative of the product of two functions:

Daαfg=fDaαg+gDaαf.(A5)

(iii) None of the fractional derivatives comply with the established formula for the derivative of the division of two functions:

Daαf/gt=gDaαffDaαgg2.(A6)

(iv) None of the fractional derivatives abide by the chain rule.

Daαfogt=fαgtgαt.(A7)

(v) Fractional derivatives do not abide by the general rule DαDβf=Dα+βf It was necessary to adopt another definition of fractional derivatives, which is the "Conformable fractional derivatives," in order to overcome the limitations discussed above [47, 48].

The fractional derivatives of the order α0,1 of the absolutely continuous function ft is

dαftdtα=t1αdftdt(A8)

Keywords: conformable fractional order theory, rotation, micropolar thermoelasticity, viscosity, one relaxation time, two-temperatures, normal mode analysis

Citation: El-Sapa S, El-Bary AA and Atef HM (2023) The influence of rotation and viscosity on generalized conformable fractional micropolar thermoelasticity with two temperatures. Front. Phys. 11:1267808. doi: 10.3389/fphy.2023.1267808

Received: 27 July 2023; Accepted: 03 October 2023;
Published: 23 October 2023.

Edited by:

Gang (Gary) Ren, Berkeley Lab (DOE), United States

Reviewed by:

Emad Awad, Alexandria University, Egypt
Eduard-Marius Craciun, Ovidius University, Romania

Copyright © 2023 El-Sapa, El-Bary and Atef. This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.

*Correspondence: H. M. Atef, aGl0aGFtX2FsaUBzY2kuZG11LmVkdS5lZw==

Disclaimer: All claims expressed in this article are solely those of the authors and do not necessarily represent those of their affiliated organizations, or those of the publisher, the editors and the reviewers. Any product that may be evaluated in this article or claim that may be made by its manufacturer is not guaranteed or endorsed by the publisher.