A hyperelastic fractional damage material model with memory

Accepted Manuscript

A Hyperelastic Fractional Damage Material Model with Memory Wojciech Sumelka, George Z. Voyiadjis PII: DOI: Reference:

S0020-7683(17)30290-1 10.1016/j.ijsolstr.2017.06.024 SAS 9631

To appear in:

International Journal of Solids and Structures

Received date: Revised date: Accepted date:

3 March 2017 7 June 2017 19 June 2017

Please cite this article as: Wojciech Sumelka, George Z. Voyiadjis, A Hyperelastic Fractional Damage Material Model with Memory, International Journal of Solids and Structures (2017), doi: 10.1016/j.ijsolstr.2017.06.024

This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.

ACCEPTED MANUSCRIPT W. Sumelka, G.Z. Voyiadjis - Compiled on 2017/06/27 at 19:32:02

1

A Hyperelastic Fractional Damage Material Model with Memory

2

Wojciech Sumelka∗ , George Z. Voyiadjis∗∗

3

∗

Poznan University of Technology, Institute of Structural Engineering, Piotrowo 5 street, 60-969 Pozna´n, Poland

5

[email protected]

6

7

∗∗

CR IP T

4

Boyd Professor, Department of Civil and Environmental Engineering, Louisiana State University,

9

Baton Rouge, LA 70803, USA

10

[email protected]

11

Keywords: hyperelasticity; scalar damage; fractional calculus; materials; damage mechanics.

M

AN US

8

ED

12

ABSTRACT

In this paper a scalar damage model for hyperelastic materials is considered. The novelty of

14

the proposed approach lies in the evolution law for the damage variable that is formulated with

15

the application of fractional calculus. In this way damage evolution includes the memory, or

16

in other words the current intensity of damage evolution, which is based on information from

17

the past - whose length is included in the fractional operator. Based on illustrative examples,

AC

CE

PT

13

18

the flexibility of the model to mimic experimentally observed material behaviour is presented.

19

1 Introduction

20

Continuum damage mechanics (CDM) has reached a high level of its maturity nowadays.

21

Herein on should mention the first concepts proposed by Kachanov [1] and Rabotnov [2], to1

ACCEPTED MANUSCRIPT W. Sumelka, G.Z. Voyiadjis - Compiled on 2017/06/27 at 19:32:02 gether with further developments by many groups like Lemaitre and Chaboche [3], Murakami

23

[4], Woo and Li [5], Krajcinovic [6], Chen and Chow [7], Voyiadjis et. al. [8, 9], Perzyna

24

[10], Sumelka [11] or competetive formulations like these quantified by irreversible entropy

25

and entropy generation rate by Basaran [12, 13, 14] or Sosnovskiy [15]. Within this differ-

26

ent types of damage models, one of the most important aspect is the definition of damage as

27

a mathematical object, namely one considers isotropic (scalar) and anisotropic (higher order

28

tensors) measures for material degradation. CDM concepts were applied for different types

29

of materials (e.g. metals, rocks, concrete, composites), a wide range of degradation types (e.g.

30

elastic-brittle damage, elastic-plastic damage, fatigue damage, corrosion damage) and different

31

processes (e.g. static, dynamic, coupled fields) - cf. Skrzypek and Ganczarski [16]. Nonethe-

32

less, constant development of new materials or advancing knowledge of existing ones (e.g.

33

biological) induces the necessity of further development of CDM, especially in the field of

34

definition of damage initiation and evolution criteria i.e. specific evolution equations for the

35

internal state variables. This crucial aspect can be formulated using different mathematical

36

tools, however as presented in recent papers, the fractal theory (for definition of fractal dam-

37

age variable) [17] or fractional calculus (for fatigue phenomena modeled as a change of the

38

fractional derivative order) [18] can be very effective. Herein, the new insight will be posed to

39

the last mentioned modelling technique for finite strains and original damage evolution law.

40

Fractional calculus (FC) is a branch of mathematical analysis which considers differential

41

equations of an arbitrary order [19, 20, 21]. From the point of view of mathematical modelling

42

of physical phenomena, the important aspects of FC are: (i) fractional differential operators

AC

CE

PT

ED

M

AN US

CR IP T

22

43

(FDO) are defined over an interval; (ii) there are infinitely many definitions of FDO [22]; (iii)

44

each FDO can have some specific properties [23] (e.g. FDO operating on a constant function

45

does not necessarily result in zero). It should be pointed out that to some extent, dependent on

46

the material being considered, there should exist the most proper choice of FDO.

47

It is important that the non-local action of FDO mentioned above, can operate on different

48

spaces, dependent on variables on which FDO acts (cf. Fig. 1). Namely, it can be a non-local 2

ACCEPTED MANUSCRIPT W. Sumelka, G.Z. Voyiadjis - Compiled on 2017/06/27 at 19:32:02 action in time (e.g. fractional viscous behavior of materials - cf. [24] and cited therein), non-

50

local action in a stress space (e.g. non-normal plastic flow [25]), or non-local action in space

51

variable (cf. [26, 27, 28, 29, 29, 30]). Herein, the non-locality in time, should be pointed out

52

as being the crux of this paper and is called memory [20]. For such class of non-local concept,

53

one can distinguish two cases: (i) full memory - when time fractional derivatives are taken over

54

the total time of the analysed process; and (ii) short memory - when the current state of the

55

mechanical system is influenced by the closest past events, characterised by the existence of a

56

characteristic time length scale `t (cf. Fig. 1).

ED

M

AN US

CR IP T

49

PT

Figure 1: Possible non-localities in mechanics vs. FDO operation on a specific field

In a further part of this paper we explore the concept of short memory connected with the

58

definition of (scalar) damage parameter evolution in terms of FC (fractional calculus) for hy-

59

perelastic materials. It will be observed that both, the order of damage evolution (order of

AC

CE

57

60

FC) and the applied characteristic time `t (range of FC action) control the intensity of damage

61

expansion - cf. Fig. 2. Thus, in this new formulation, two additional material parameters are

62

needed for practical applications, however, with a very positive and desired property of the

63

overall model, namely its flexibility to map the experimental results.

3

ACCEPTED MANUSCRIPT

CR IP T

W. Sumelka, G.Z. Voyiadjis - Compiled on 2017/06/27 at 19:32:02

AN US

Figure 2: The concept of short memory

64

2 Problem formulation

65

2.1

66

In this work isotropic hyperelasic materials are considered. It is assumed that there exists a

67

stress threshold above which damage appears in the material. Damage is modelled through

68

a scalar variable, thus the damaged range of the material behaviour is isotropic as well. The

69

evolution of damage is formulated with the application of the Caputo fractional derivative,

70

hence the current state of damage is influenced by past events - one says that the material has

71

a memory, or that the material is non-local in time.

AC

CE

PT

ED

M

Main Assumptions

72

73

74

2.2

Isotropic Hyperelastic Fractional Damage Material Model with Memory

One assumes the existence of the Helmholtz free-energy function in the general form

Ψ = Ψ(F),

4

(1)

ACCEPTED MANUSCRIPT W. Sumelka, G.Z. Voyiadjis - Compiled on 2017/06/27 at 19:32:02

75

where Ψ denotes the Helmholtz free-energy function, and F stands for deformation gradient.

76

Assuming that the elastic range is isotropic Eq. (1) reduces to

Ψ = Ψ(U) = Ψ(C) = Ψ(E),

(2)

where U is the right stretch tensor (U2 = C), C is the right Cauchy-Green tensor and E

78

denotes the Green-Lagrange strain tensor (2E = C − I).

79

For convenience the following restrictions for Ψ are assumed:

80

AN US

Ψ = Ψ(I) = 0,

CR IP T

77

and in general

Ψ(F) ≥ 0, and

M

81

Ψ is objective.

(5)

ED

˜ Ψ = Ψ(C, φ) = (1 − φ)Ψ(C),

(6)

CE

where φ is the scalar damage variable, together with the postulates:

AC

83

(4)

Next, one introduces the scalar damage concept based on the assumption that

PT

82

(3)

˜ Ψ(I) = 0,

(7)

˜ Ψ(C) ≥ 0,

(8)

˜ is objective, Ψ

(9)

84

85

5

ACCEPTED MANUSCRIPT W. Sumelka, G.Z. Voyiadjis - Compiled on 2017/06/27 at 19:32:02

86

and (10)

φ ∈ [0, 1], ˜ is the effective (undamaged) Helmholtz free-energy function. where Ψ

88

Based on the assumption that the Clausius-Planck inequality for purely mechanical processes

89

can be written as

˙ =S:E ˙ ≥ 0, ˙ −Ψ Dint = wint − Ψ

(11)

˜ ˙ ˜ ˙ = (1 − φ) ∂ Ψ(C) : C ˙ − Ψ(C) φ, Ψ ∂C

(12)

and utilizing the chain rule

AN US

90

CR IP T

87

where Dint is the density of dissipation, wint is the internal energy density, and S denotes the

92

second Piola-Kirchhoff stress tensor (S = F−1 P = ST and P is the first Piola-Kirchhoff stress

93

tensor). Therefore, one obtains

M

91

CE

thus

AC

95

96

!

:

˙ C ˜ + Ψ(C) φ˙ ≥ 0. 2

(13)

From Eq. (13) it is clear that:

PT

94

ED

˜ ∂ Ψ(C) S − 2(1 − φ) ∂C

S − 2(1 − φ)

˜ ∂ Ψ(C) = 0, ∂C

(14)

˜ S = (1 − φ)S,

(15)

˜ Ψ(C) φ˙ ≥ 0,

(16)

and

97

˜ ˜ = 2 ∂ Ψ(C) where S is the effective (undamaged) second Piola-Kirchhoff stress tensor. It is ∂C

98

observed, that for the non-negative dissipation defined in Eq. (16), together with postulate

6

ACCEPTED MANUSCRIPT W. Sumelka, G.Z. Voyiadjis - Compiled on 2017/06/27 at 19:32:02

99

Eq. (8), the following is noted φ˙ ≥ 0.

Finally, the evolution of φ is postulated utilising the fractional differential operator in the form

101

C α t−`t Dt φ

102

1 = αΦ T

where the bracket h·i defines the ramp function, 1 = Γ(n − α)

Z

a

t

C

 Iφ −1 , τφ

(18)

D is the left-sided Caputo derivative

f (n) (τ ) dτ, (t − τ )α−n+1

for

t > a,

(19)

AN US

C α a Dt f (t)



CR IP T

100

(17)

where t denotes time variable, α is an order of derivative, T stands for characteristic time, Φ is

104

the overstress function, Iφ is the stress intensity invariant, τφ is the threshold stress for damage

105

evolution, Γ is the Euler gamma function, and n = bαc + 1. It should be emphasised that the

106

fractional velocity of damage to be defined needs identification of the damage order α and the

107

damage memory (time length scale) `t , in other words two additional material parameters are

108

postulated. This is in contrast with the classical case when α = 1 and memory does not play

109

any role. Moreover, the form of the evolution equation Eq. (18) induces rate dependence of the

110

overall constitutive model.

111

3 Examples

CE

PT

ED

M

103

3.1

Introductory Remarks

113

The main aim of this section is to present the influence of the fractional damage evolution

114

model on the material model defined in the preceding section. Due to this reason the effect of

115

both the damage order index α and the memory (time length scale) `t is examined in detail.

116

Furthermore, this parametric study is enriched by the examination of the rate effects.

AC

112

7

ACCEPTED MANUSCRIPT W. Sumelka, G.Z. Voyiadjis - Compiled on 2017/06/27 at 19:32:02

117

3.2

Ogden Strain-Energy Function

118

One assumes that the stain-energy function postulated in Eq. (6) takes the form of the Ogden

119

model, namely ˜ = Ψ(λ ˜ 1 , λ2 , λ3 ) = Ψ

N X µp p=1

αp

α

α

α

(20)

(λ1 p + λ2 p + λ3 p − 3),

where λ1 , λ2 , λ3 are the principal stretches (principal values of U), and µp , αp

121

are the material parameters for Ogden model. This allows one to analyse a wide class of other

122

common models like:

(p = 1, ..., N )

• Mooney-Rivilin model N = 2, α1 = 2, α2 = −2 with the constraint condition I3 (C) = λ21 λ22 λ23 = 1,

124

AN US

123

CR IP T

120

• neo-Hookean model N = 1, α1 = 2, or

126

• Varga model N = 1, α1 = 1.

M

125

3.3

The Constitutive Equation in the Principal Stretches Directions

128

Without loss of generality one limits the considerations to incompressible hyperelastic bodies.

129

Therefore, the constitutive model given by Eq. (14) can be now rewritten in the principal stretch

130

˜ = Ψ(λ ˜ 1 , λ2 , λ3 )) [31] directions form, namely (Ψ

AC

CE

PT

ED

127

˜ 1 1 ∂Ψ Sa = (1 − φ) − 2 p + λa λa ∂λa

!

,

a = 1, 2, 3,

(21)

131

where Sa are the principal values of S, and p denotes the hydrostatic pressure.

132

Based on Eq. (21) the transformation to the principal Cauchy stress, the most intuitive stress

133

measure, is straightforward and is given by ˜ ∂Ψ σa = λ2a Sa = (1 − φ) −p + λa ∂λa 8

!

,

a = 1, 2, 3,

(22)

ACCEPTED MANUSCRIPT W. Sumelka, G.Z. Voyiadjis - Compiled on 2017/06/27 at 19:32:02

134

where σa are the principal values of Cauchy stress tensor σ = J −1 FSFT , (J = det(F)), and

135

p has to be determined from the balance of linear momentum and the boundary conditions.

136

3.4

137

To understand the concept of fractional damage with memory, without loss of generality, one

138

considers the behaviour of the overall model for uniaxial (incompressible) tension, hence

x = χ(X, t) = (1 + tnβ )X1 e1 + √

CR IP T

Solved Example

1 1 X2 e 2 + √ X3 e3 , n β 1+t 1 + tnβ

(23)

where nβ = const - thus parameter nβ controls the rate of the process Eq. (23), χ is the motion,

140

e is the base vector in current configuration, and x, X are spatial and material coordinates,

141

respectively.

142

Next, the deformation gradient for the motion of Eq. (23) in the matrix representation can be

143

expressed as

M

AN US

139



0 0

PT

ED

(1 + tnβ ) 0   ∂χ(X, t)   F = F(X, t) = = √ 1n 0  ∂X 1+t β    0 0

145

146

1

√

nβ

CE

1+t

     .    

(24)

Finally, the corresponding right-stretch tensor needed for stress calculation (cf. Eqs (21-22)) is given by

AC

144









λ1 0 0  (1 + tnβ ) 0             U =  0 λ2 0  =  √ 1n 0    1+t β          0 0 λ3 0 0



0 0 √

1 nβ

1+t

     .    

(25)

Based on the calculated stretches (Eq. (25)) the associated stress state resulting from the Ogden 9

ACCEPTED MANUSCRIPT W. Sumelka, G.Z. Voyiadjis - Compiled on 2017/06/27 at 19:32:02

147

˜ = Ψ(λ ˜ 1 )): model is given by (Ψ ˜ 1 ∂Ψ 1 S1 = (1−φ) − 2 p + λ1 λ1 ∂λ1

!

"

# N  α 1 1 X  αp −1 − 2p −1 = (1−φ) − 2 p + µp λ1 − λ1 , (26) λ1 λ1 p=1

S2 = S3 = −(1 − φ)λ1 p, 149

and finally applying the boundary conditions

⇒

150

thus one obtains

"

p = 0,

AN US

S2 = S3 = 0

CR IP T

148

# N  α 1 X  αp −1 − 2p −1 S1 = (1 − φ) µp λ1 − λ1 . λ1 p=1

(27)

(28)

(29)

Next, according to the formula Eq. (22), and simultaneously assuming that in the remaining

152

part of this analysis, the direction 1 will be considered only, the Cauchy stresses for the Ogden

153

model and other related models are as follows:

ED

• Ogden model (N=3)

PT

154

M

151

σ1 = (1 − φ)

CE

h

AC

(1 − φ) µ1

155

156



λα1 1

−

− λ1

α1 2



"

3 X

µp

p=1

+ µ2



λα1 2



α λ1 p

−

− λ1

α2 2

−

− λ1



αp 2



+ µ3

#



= λα1 3

−

− λ1

α3 2

i

;

(30)

• Mooney-Rivilin model

  σ1 = (1 − φ) µ1 λ21 − λ−1 + µ2 λ−2 ; 1 1 − λ1

• neo-Hookean model


  σ1 = (1 − φ) µ1 λ21 − λ−1 ; 1 10

(31)

(32)

ACCEPTED MANUSCRIPT W. Sumelka, G.Z. Voyiadjis - Compiled on 2017/06/27 at 19:32:02

157

• Varga model

h  i −1 σ1 = (1 − φ) µ1 λ1 − λ1 2 .

(33)

Finally, in the numerical procedure, for the subsequent time points ti (t ∈ [0, tf ] where tf is a

159

time for which λ1 = 10) the following flow chart is applied:

CR IP T

158

160

• calculate current the right-stretch tensor U|t=ti (Eq. (25))

161

• calculate current stress intensity invariant Iφ |t=ti

162

• test Iφ > τφ ◦ NO - φ|t=ti = φ|t=ti−1

164

◦ YES - update damage variable according to Eq. (18) • calculate stresses (Eqs (30)-(33)).

M

165

AN US

163

It is important that for damage update that the approximation of Caputo operator proposed in

167

[32] was used. Therefore the LHS of Eq. (18), for t = tm , can be written as

ED

166

PT

a = t0 < t1 < ... < tk < ... < tm = t,

C α a Dt φ(t)|t=tm m−1 X

∼ =

t−a tm − t0 = , m m

m ≥ 2,

(34)

 hn−α [(m − 1)n−α+1 − (m − n + α − 1)man−α ]φ(n) (t0 ) + Γ(n − α + 2)

CE

168

h=

AC

[(m − k + 1)n−α+1 − 2(m − k)n−α+1 + (m − k − 1)n−α+1 ]φ(n) (tk ) + φ(n) (tm ) , (35)

k=1

169

where φ(n) (tk ) denotes the classical n-th derivative at t = tk . It should be pointed out that

170

approximation Eq. (35) is a weighted sum of classical n-th derivatives at points from the past

171

(first two terms) and at current time point (t = tm - third term). In the following examples it is

172

assumed that α ∈ (0, 1], therefore n = 1. Thus, in the computational scheme, two first terms

173

of Eq. (35) are considered on the RHS of Eq. (18) (and approximated utilising the backward 11

ACCEPTED MANUSCRIPT W. Sumelka, G.Z. Voyiadjis - Compiled on 2017/06/27 at 19:32:02

174

difference), whereas the third term after the approximation of φ(1) (tm ), utilising the backward

175

difference also, allowed one finally to calculate the needed updated value of the damage vari-

176

able φ(tm ) = φ|t=ti .

3.5

Damage evolution

178

One assumes that the overstress function for fractional damage evolution takes the form of the

179

power function Φ



CR IP T

177

  nφ Iφ Iφ −1 = −1 , τφ τφ

(36)

where nφ is a material parameter.

181

One assumes additionally that I˜φ has an analogous form to the strain-energy function under

182

consideration (by analogy to Huber-Mises-Hencky plasticity where the equivalent stress is

183

proportional to the deviatoric part of the strain energy), thus e.g. for the Ogden model

M

I˜φ =

AN US

180

N X µ∗p

where µ∗p , αp∗ , nφ

α∗

αp

(37)

(p = 1, ..., N ) are material parameters for stress intensity invariant.

PT

184

α∗

ED

p=1

α∗

(λ1 p + λ2 p + λ3 p − 3), ∗

4 Results and Application

186

4.1

CE

185

AC

Numerical study

187

The material parameters used in this study, assumed by analogy to [33], are summarised in

188

Table 1. It should be emphasised that parameters nβ , α and `t will vary dependent on the case

189

considered.

12

ACCEPTED MANUSCRIPT W. Sumelka, G.Z. Voyiadjis - Compiled on 2017/06/27 at 19:32:02

Tab. 1 - Benchmark material parameters α1 = α1∗ = 1.3

µ1 = µ∗1 = 1.0 N m−2

α2 = α2∗ = 5.0

µ2 = µ∗2 = 0.0019 N m−2

T = 1.0 s

τφ = 20 N m−2

α ∈ (0, 1)

nφ = 2.0

CR IP T

α3 = α3∗ = −2.0 µ3 = µ∗3 = 0.0159 N m−2

In the first part of the analysis the material behaviour, for the stretch range λ1 ∈ [1, 10], without

191

damage effects, was considered (cf. Figs 3-4). In Fig. 3 the stress intensity invariant (Eq. (37))

192

vs. principal stretch, for different Ogden type models is presented. The discrepancy between

193

the solutions is clear, and the classical Ogden model shows the most intensive non-linearity.

194

The same conclusions can be stated for Fig. 4 where stress ratios (Eqs (30)-(33)) vs. principal

195

stretch are shown. Because of this observations the classical Ogden model was chosen for

196

further analysis.

197

The second part of the study includes the analysis of damage evolution for the Ogden model,

198

for a motion defined in Eq. (23) assuming different rates of deformation (nβ ∈ {1, 5, 10}),

199

different orders of evolution (α ∈ {0.3, 0.5, 0.7, 0.9, 0.95, 1.0}) and constant memory (`t =

202

M

ED

of order of damage evolution is more pronounced and intensifies as α
0.3.

In the third part of the study the same configuration as for the second was repeated for constant rate of deformation (nβ = 1) and different orders of evolution (α ∈ {0.3, 0.5, 0.7, 0.9, 0.95, 1.0}) and different memories (`t ∈ {0.001, 0.01, 0.1}s) - cf. Fig. 6.

AC

203

PT

201

0.01s) - cf Fig. 5. It is observed that as the rate of deformation is higher (nβ
10) the influence

CE

200

AN US

190

204

205

206

207

208

209

It is observed that damage evolution intensifies as α
0.3 for all cases, whereas for growing

memory (`t
0.1s) the answer of the material is stabilizing.

Finally, the fourth part of the study covers the analysis of stresses, for analogous conditions as in the second part also - cf. Figs 7-8. For clarity on all plots the undamaged answer of the material is presented. It is observed that for lower rates (nβ
0.5) damage is slightly 13

ACCEPTED MANUSCRIPT W. Sumelka, G.Z. Voyiadjis - Compiled on 2017/06/27 at 19:32:02

210

211

212

213

influenced by the order of evolution α. This situation is different for higher rates (nβ
5)

where the order of evolution dominates the behaviour. Nonetheless, in all cases the lower damage evolution order (α
0.3), the most severe softening of the material is observed.

As a concluding remark of this parametric analysis one can state the advantages of fractional model compared to the classical one (curves for α = 1 in Figs 5-8). It is clear that fractional ef-

215

fects are observed only when α ∈ (0, 1), then damage evolution is controlled by two additional

216

material parameters α ([α] = [−]) and time length scale (range of memory) `t ([`t ] = [s]). In

217

fractional range one obtains a variety of solutions that considerably differs both quantitatively

218

and qualitatively. This states the strength of fractional model (of crucial importance from the

219

point of view of modelling), namely for a limited set of new material parameters one covers a

220

broad range of possible material behaviours keeping simultaneously clear physical interpreta-

221

tion.

AC

CE

PT

ED

M

AN US

CR IP T

214

Figure 3: Stress intensity invariant vs. principal stretch - without damage

14

ACCEPTED MANUSCRIPT

AN US

CR IP T

W. Sumelka, G.Z. Voyiadjis - Compiled on 2017/06/27 at 19:32:02

AC

CE

PT

ED

M

Figure 4: Stress ratios vs. principal stretch - without damage

15

ACCEPTED MANUSCRIPT

AC

CE

PT

ED

M

AN US

CR IP T

W. Sumelka, G.Z. Voyiadjis - Compiled on 2017/06/27 at 19:32:02

Figure 5: Evolution of damage parameter for different rates of deformation (nβ ∈ {1, 5, 10}) 16 and `t = 0.01s)

ACCEPTED MANUSCRIPT

AC

CE

PT

ED

M

AN US

CR IP T

W. Sumelka, G.Z. Voyiadjis - Compiled on 2017/06/27 at 19:32:02

Figure 6: Evolution of damage parameter for different values of the memory parameter `t ∈ 17 {0.001, 0.01, 0.1}s and nβ = 1

ACCEPTED MANUSCRIPT

CE

PT

ED

M

AN US

CR IP T

W. Sumelka, G.Z. Voyiadjis - Compiled on 2017/06/27 at 19:32:02

AC

Figure 7: (Top) Ogden stresses for different evolutions of damage parameter; (Bottom) magnification - (nβ ∈ {0.5} and constant memory parameter `t = 0.01s)

18

ACCEPTED MANUSCRIPT

CE

PT

ED

M

AN US

CR IP T

W. Sumelka, G.Z. Voyiadjis - Compiled on 2017/06/27 at 19:32:02

AC

Figure 8: Ogden stresses for different evolutions of damage parameter (for different rates of deformation nβ ∈ {1, 5} and constant memory parameter `t = 0.01s)

222

4.2

Identification for failure of the abdominal aortic aneurysm

223

To show the applicability of the presented model one considers the analysis of failure of the

224

abdominal aortic aneurysm (AAA) [34]. For this purpose the Ogden model (N = 3) was used 19

ACCEPTED MANUSCRIPT W. Sumelka, G.Z. Voyiadjis - Compiled on 2017/06/27 at 19:32:02 to capture the experimentally observed softening in AAA [34].

226

Material parameters for AAA are shown in Table 2 and they were calibrated in Matlab software

227

based on soft computing methods (quasi static uniaxial tension test) to obtain best fitting of the

228

strain-stress curves (see Fig. 9). It is observed that up to λ1 = 1.65 AAA follows the path of

229

an undamaged hyperelastic material model, while for λ1 > 1.65 softening appears. It is clear

230

from Fig. 9 that the numerical results using the proposed hyperelastic fractional damage model

231

conform with the observed experimental results. Tab. 2 - AAA material parameters

CR IP T

225

µ1 = µ∗1 = 75.0 N cm−2

α2 = α2∗ = 11.0

µ2 = µ∗2 = 0.1425 N cm−2

AN US

α1 = α1∗ = 1.3

α3 = α3∗ = −1.0 µ3 = µ∗3 = 1.1925 N cm−2 τφ = 14.5 N cm−2

T = 0.5 s α = 0.75

nφ = 1.7

AC

CE

PT

ED

M

`t = 0.065s

Figure 9: Numerical vs. experimental [34] results

20

ACCEPTED MANUSCRIPT W. Sumelka, G.Z. Voyiadjis - Compiled on 2017/06/27 at 19:32:02

5 Conclusions

233

In this paper a new isotropic hyperelasic material model accounting for isotropic damage,

234

where damage evolution is described in terms of fractional calculus, is formulated in the frame-

235

work of thermodynamics. Two additional material parameters are introduced in this new for-

236

mulation compared with classical formulations: (i) order of damage evolution; and (ii) memory

237

(time length scale) of damage evolution. Both parameters allow flexible modelling of material

238

softening as presented based on benchmark solutions and especially applied in final analysis

239

of failure of the abdominal aortic aneurysm.

240

The obtained results allow to formulate the flowing conclusions:

242

AN US

241

CR IP T

232

• because of damage evolution definition which utilises the concept of overstress function, in the softening range of material operation rate effects are observed, • for lower orders of damage velocity, intensification of damage evolution is shown,

244

• the dependence of fractional damage velocity on time length scale (memory) shows that

245

for long memory (in relation to characteristic time) changes in softening become limited.

247

ED

PT

[1] L.M. Kachanov. Time of the rupture process under creep conditions. Izv. AN SSR, Otd. Tekh. Nauk, 8:26–31, 1958.

AC

248

References

CE

246

M

243

249

250

251

252

[2] Ju.N. Rabotnov. Damage from creep. Zhurn. Prikl. Mekh. Tekhn. Phys., 2:113–123, 1963.

[3] J. Lemaitre and J.L. Chaboche. Aspect phenomenologique de la rapture per endommagement. Zhurn. Prikl. Mekh. Tekhn. Phys., 2:113–123, 1963.

21

ACCEPTED MANUSCRIPT W. Sumelka, G.Z. Voyiadjis - Compiled on 2017/06/27 at 19:32:02

255

256

257

258

259

260

261

262

55:280–286, 1988. [5] C.W. Woo and D.L. Li. A universal physically consistent definition of material damage. International Journal of Solids and Structures, 30(15):2097–2108, 1993. [6] D. Krajcinovic. Continuum damage mechanics: when and how? International Journal of Damage Mechanics, 4:217–229, 1995.

CR IP T

254

[4] S. Murakami. Mechanical modeling of matrial damage. Transactions of the ASME,

[7] X.F. Chen and C.L. Chow. On damage strain energy release rate Y. International Journal of Damage Mechanics, 4(3):251–263, 1995.

AN US

253

[8] G.Z. Voyiadjis and Park T. Anisotropic damage effect tensor for symmetrization of the effective stress tensor. Transactions of the ASME, 64:106–110, 1997. [9] G.Z. Voyiadjis and P.I. Kattan. Evolution of fabric tensors in damage mechanics of

264

solids with micro-cracks: Part I - theory and fundamental concepts. Mechanics Research

265

Communications, 34:145–154, 2007.

268

269

ED

[11] W. Sumelka and T. Łodygowski. Reduction of the number of material parameters by ann approximation. Computational Mechanics, 52:287–300, 2013. [12] C. Basaran and C.Y. Yan. A thermodynamic framework for damage mechanics of solder

AC

270

tions, 53:235–316, 2005.

PT

267

[10] P. Perzyna. The thermodynamical theory of elasto-viscoplasticity. Engineering Transac-

CE

266

M

263

271

272

273

274

275

joints. ASME Journal of Electronic Packaging, 120(4):379–384, 1998.

[13] C. Basaran and S. Nie. An irreversible thermodynamic theory for damage mechanics of solids. International Journal of Damage Mechanics, 13(3):205–224, 2004. [14] S. Li and C. Basaran. A computational damage mechanics model for thermomigration. Mechanics of Materials, 41(3):271–278, 2009.

22

ACCEPTED MANUSCRIPT W. Sumelka, G.Z. Voyiadjis - Compiled on 2017/06/27 at 19:32:02

277

278

279

280

281

[15] L. A. Sosnovskiy and S. S. Sherbakov. Mechanothermodynamic entropy and analysis of damage state of complex systems. Entropy, 18(7):268, 2016. [16] J.J. Skrzypek and A. Ganczarski. Modeling of Material Damage and Failure of Structures: Theory and Applications. Springer-Verlag, Berlin, 1999. [17] X.H.J. Yang. A study of damage mechanics theory in fractional dimensional space. Acta Mechanica Sinica, 31(3):300–310, 1999.

CR IP T

276

[18] Michele Caputo and Mauro Fabrizio. Damage and fatigue described by a fractional

283

derivative model. Journal of Computational Physics, 293:400 – 408, 2015. Fractional

284

PDEs.

288

289

290

[20] I. Podlubny. Fractional Differential Equations, volume 198 of Mathematics in Science

M

287

1984-1991.

and Engineering. Academin Press, 1999.

ED

286

[19] K. Nishimoto. Fractional Calculus, volume I-IV. Descatres Press, Koriyama, Japan,

[21] A.A. Kilbas, H.M. Srivastava, and J.J. Trujillo. Theory and Applications of Fractional Differential Equations. Elsevier, Amsterdam, 2006.

PT

285

AN US

282

[22] E.C. Oliveira and J.A.T. Machado. A review of definitions for fractional derivatives

292

and integral. Mathematical Problems in Engineering, 2014(Article ID 238459):6 pages,

293

2014.

AC

CE

291

294

295

296

297

[23] T. Abdeljawad. On conformable fractional calculus. Journal of Computational and Applied Mathematics, 279:57–66, 2015.

[24] F. Mainardi. Fractional calculus and waves in linear viscoelasticity. Imperial College Press, London, 2010.

23

ACCEPTED MANUSCRIPT W. Sumelka, G.Z. Voyiadjis - Compiled on 2017/06/27 at 19:32:02

298

[25] W. Sumelka and M. Nowak. Non-normality and induced plastic anisotropy under frac-

299

tional plastic flow rule: A numerical study. International Journal for Numerical and

300

Analytical Methods in Geomechanics, 40:651–675, 2016.

307

308

309

310

311

312

313

314

nal of Elasticity, 107:107–123, 2012.

[29] W. Sumelka. Thermoelasticity in the framework of the fractional continuum mechanics. Journal of Thermal Stresses, 37(6):678–706, 2014.

[30] K. A. Lazopoulos and A. K. Lazopoulos. On fractional bending of beams. Archive of Applied Mechanics, 86(6):1133–1145, 2016. [31] P. Haupt. Continuum Mechanics and Theory of Materials. Springer, second edition, 2002.

[32] Z. Odibat. Approximations of fractional integrals and Caputo fractional derivatives. Applied Mathematics and Computation, 178:527–533, 2006. [33] G.A. Holzapfel. Nonlinear Solid Mechanics - A Continuum Approach for Engineering.

AC

315

CR IP T

306

[28] C.S. Drapaca and S. Sivaloganathan. A fractional model of continuum mechanics. Jour-

AN US

305

elasticity. European Physical Journal Special Topics, 193:193–204, 2011.

M

304

[27] A. Carpinteri, P. Cornetti, and A. Sapora. A fractional calculus approach to nonlocal

ED

303

Acta Mechanica, 208(1-2):1–10, 2009.

PT

302

[26] T.M. Atanackovic and B. Stankovic. Generalized wave equation in nonlocal elasticity.

CE

301

316

317

318

Wiley, 2000.

[34] K.Y. Volokha and D.A. Vorp. A model of growth and rupture of abdominal aortic aneurysm. Journal of Biomechanics, 41:1015–1021, 2008.

24