mathematical analysis in thermodynamics of incompressible...
TRANSCRIPT
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Mathematical analysis inthermodynamics of incompressible fluids
Josef Malek
Mathematical institute of Charles University in Prague, Faculty of Mathematics and PhysicsSokolovska 83, 186 75 Prague 8
June 16, 2008
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Contents
1 Mathematically self-consistent models of classical mechanics - modelsfor the system Spring - Weight
2 Thermodynamics of incompressible fluids
3 Constitutive equations
4 References
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Part #1
Mathematically self-consistent models of classicalmechanics - models for the system Spring - Weight
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System Spring - Weight/Description and assumptions
Bodies (weights) modeled asmass-points
Three Newton’s postulates:
F = 0 =⇒ straight-linemotionF = d
dt (mv) = m dvdt = m d2x
dt2
Any F exerts reaction −F
Motion allowed only in thevertical direction
Mass of the spring is neglected
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System Spring - Weight/Assumptions characterizingmaterial properties
Linear Spring:F2 = (0,−k(y + a), 0) (k > 0)
Resistance due to environment isneglected
d2ydt2 + k
m y = 0y(0) = y0
dydt (0) = y1
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System Spring - Weight/Assumptions characterizingmaterial properties
Linear Spring:F2 = (0,−k(y + a), 0) (k > 0)
Resistance proportional to the velocity:F3 = (0,−b dy
dt , 0) (b > 0)
d2ydt2 + b
mdydt + k
m y = 0y(0) = y0
dydt (0) = y1
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System Spring - Weight/Assumptions characterizingmaterial properties
Linear Spring:F2 = (0,−k(y + a), 0) (k > 0)
Resistance force due to environmentdepends on the velocity non-linearly:
F3 = (0, h(
dydt
), 0)
m d2ydt2 + h
(dydt
)+ ky = 0
y(0) = y0
dydt (0) = y1
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System Spring - Weight/Assumptions characterizingmaterial properties
Non-linear Spring: F2 = (0, g(y + a), 0)
Environment resistance neglected,linear, or non-linear
d2ydt2 + h( dy
dt ) + g(y) = 0
d2ydt2 = f (y , dy
dt )
Free fall due to gravity: F2 = (0, 0, 0)
d2ydt2 + h( dy
dt ) = 0 ⇐⇒ dvdt + h(v) = 0
dvdt = f (v) v(0) = v0
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System Spring - Weight/Mathematically self-consistentmodels
Simplifying assumptions =⇒ very crude approximation of the reality
Independently how accurate are models we are interested inmathematical self-consistency of the models: notion of solution
existence for arbitrary set of data (T , v0 (or y0 and y1), m, ....)uniquenesscontinuous dependence of solution on databoundedness of the velocitylong time behavior of solutions.
Mathematical self-consistency of models of incompressible fluidthermodynamics
Derivation of fluid thermodynamics models stems from the principlesof classical mechanics
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System Spring - Weight/Simple observations
Free fall due to gravity: first order equation for the velocity
Mathematical self-consistency of the equation of a ”slightly”generalized form dv
dt = f (v), v(0) = v0. Counterexamples:
existence/boundedness for any time interval - f (v) = v 2
uniqueness - f (v) = v 2/3
m dvdt + bv = f =⇒ m
2ddt |v |
2 + bm |v |
2 = fv =⇒
|v(t)|2 ≤ |v0|2e−bm
t +f 2
b2(1− e−
bm
t) pro t > 0
Derived models have a limited region where they can be useful
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Part #2
Thermodynamics of incompressible fluids
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Fluid
Definition
Fluid is a body that, in time scale of observation of interest, undergoesdiscernible deformation due to the application of a sufficiently small shearstress
v =∂χ
∂tFχ =
∂χ
∂X
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Long-lasting physical experiment
In 1927 at University of Queensland: liquid asphalt put inside the closedvessel, after three years the vessel was open and the asphalt has started todrop slowly.
Year Event1930 Plug trimmed off1938 (Dec) 1st drop1947 (Feb) 2nd drop1954 (Apr) 3rd drop1962 (May) 4th drop1970 (Aug) 5th drop1979 (Apr) 6th drop1988 (Jul) 7th drop2000 (28 Nov) 8th drop
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Balance equations of continuum physics
Balance of mass, linear and angular momentum, balance of energy and thesecond law of thermodynamics
%,t + div(%v) = 0
(%v),t + div(%v⊗ v)− div T = 0
TT = T(%(e + |v|2/2)
),t
+ div(%(e + |v|2/2)v) + div q = div (Tv)
% . . . densityv . . . velocitye . . . internal energyT . . . the Cauchy stressq . . . heat flux
Eulerian description - flows of fluid-like bodiesNo external sources - for simplicity
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Balance equations of continuum physics
Balance of mass, linear and angular momentum, balance of energy and thesecond law of thermodynamics
%,t + div(%v) = 0
(%v),t + div(%v⊗ v)− div T = 0
TT = T(%(e + |v|2/2)
),t
+ div(%(e + |v|2/2)v) + div q = div (Tv)
% . . . densityv . . . velocitye . . . internal energyT . . . the Cauchy stressq . . . heat flux
Eulerian description - flows of fluid-like bodiesNo external sources - for simplicity
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Balance equations of continuum physics
Balance of mass, linear and angular momentum, balance of energy and thesecond law of thermodynamics
%,t + div(%v) = 0
(%v),t + div(%v⊗ v)− div T = 0
TT = T(%(e + |v|2/2)
),t
+ div(%(e + |v|2/2)v) + div q = div (Tv)
% . . . densityv . . . velocitye . . . internal energyT . . . the Cauchy stressq . . . heat flux
Eulerian description - flows of fluid-like bodiesNo external sources - for simplicity
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Balance equations of continuum physics/2
B ⊂ Ω fix for all t ≥ 0:
d
dt
∫B% dx = −
∫∂B%v · n dS =⇒ FVM
= −∫
Bdiv(%v) dx =⇒ %t + div %v = 0
Choice B = x ∈ Ω; η(x) > r, where r ∈ (0,∞) and η ∈ D(Ω)
d
dt
∫B%η dx −
∫B%v · ∇η dx = 0 =⇒ weak solution, FEM
Oseen, Leray, . . . , Chen, Torres, Ziemer, . . . Feireisl:
weak formulation of balance equations - the primary setting
classical formulation of balance equations - the secondary setting
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Balance equations of continuum physics/2
B ⊂ Ω fix for all t ≥ 0:
d
dt
∫B% dx = −
∫∂B%v · n dS =⇒ FVM
= −∫
Bdiv(%v) dx =⇒ %t + div %v = 0
Choice B = x ∈ Ω; η(x) > r, where r ∈ (0,∞) and η ∈ D(Ω)
d
dt
∫B%η dx −
∫B%v · ∇η dx = 0 =⇒ weak solution, FEM
Oseen, Leray, . . . , Chen, Torres, Ziemer, . . . Feireisl:
weak formulation of balance equations - the primary setting
classical formulation of balance equations - the secondary setting
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”Equivalent” formulation of the balance of energy
%,t + div(%v) = 0
(%v),t + div(%v⊗ v)− div T = 0 (BLM)
TT = T(%(e + |v|2/2)
),t
+ div(%(e + |v|2/2)v) + div q = div (Tv)
is equivalent, provided that v is admissible test function in (BLM), to
%,t + div(%v) = 0
(%v),t + div(%v⊗ v)− div T = 0
TT = T
(%e),t + div(%ev) + div q = T · ∇v
Note that T · ∇v = T ·D where D := D(v) is the symmetric part of thevelocity gradient
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”Equivalent” formulation of the balance of energy
%,t + div(%v) = 0
(%v),t + div(%v⊗ v)− div T = 0 (BLM)
TT = T(%(e + |v|2/2)
),t
+ div(%(e + |v|2/2)v) + div q = div (Tv)
is equivalent, provided that v is admissible test function in (BLM), to
%,t + div(%v) = 0
(%v),t + div(%v⊗ v)− div T = 0
TT = T
(%e),t + div(%ev) + div q = T · ∇v
Note that T · ∇v = T ·D where D := D(v) is the symmetric part of thevelocity gradient
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Entropy
(%e),t + div(%ev) + div q = T · ∇v (1)
Continuum thermodynamics (Callen 1985): there is η (specific entropydensity) being a function of state variables, here η = η(e), fulfilling:
η is increasing function of e =⇒ 1θ =: ∂η∂e or e = e(η) =⇒ θ = ∂e
∂η
η → 0+ as θ → 0+
S(t) :=∫
Ω%∗η(t, ·)dx goes to its maximum as t →∞ provided that the
body is thermally and mechanically isolated
(1) is equivalent to
∂η
∂e
(%[e,t + v · ∇e
])+
div q
θ=
T ·D(v)
θ
%[η,t + η · ∇v
]+ div
(q
θ
)=
1
θ
[T ·D(v)
]− q · ∇θ
θ2
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Entropy
(%e),t + div(%ev) + div q = T · ∇v (1)
Continuum thermodynamics (Callen 1985): there is η (specific entropydensity) being a function of state variables, here η = η(e), fulfilling:
η is increasing function of e =⇒ 1θ =: ∂η∂e or e = e(η) =⇒ θ = ∂e
∂η
η → 0+ as θ → 0+
S(t) :=∫
Ω%∗η(t, ·)dx goes to its maximum as t →∞ provided that the
body is thermally and mechanically isolated
(1) is equivalent to
∂η
∂e
(%[e,t + v · ∇e
])+
div q
θ=
T ·D(v)
θ
%[η,t + η · ∇v
]+ div
(q
θ
)=
1
θ
[T ·D(v)
]− q · ∇θ
θ2
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Entropy
(%e),t + div(%ev) + div q = T · ∇v (1)
Continuum thermodynamics (Callen 1985): there is η (specific entropydensity) being a function of state variables, here η = η(e), fulfilling:
η is increasing function of e =⇒ 1θ =: ∂η∂e or e = e(η) =⇒ θ = ∂e
∂η
η → 0+ as θ → 0+
S(t) :=∫
Ω%∗η(t, ·)dx goes to its maximum as t →∞ provided that the
body is thermally and mechanically isolated
(1) is equivalent to
∂η
∂e
(%[e,t + v · ∇e
])+
div q
θ=
T ·D(v)
θ
%[η,t + η · ∇v
]+ div
(q
θ
)=
1
θ
[T ·D(v)
]− q · ∇θ
θ2
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Second law of thermodynamics/1
(%η),t
+ div(%ηv) + div(q
θ
)= ξ with θξ := T ·D(v)− q · ∇θ
θ(2)
Second law of thermodynamics: ξ ≥ 0
Stronger requirement: T ·D(v) ≥ 0 (entropy production due to work being converted into heat) and− q·∇θ
θ ≥ 0 (entropy production due to heat conduction)
We shall use the constitutive equations that automatically meet theserequirements
Minimum principle for e
if e0 ≥ C∗ in Ω then e(t, ·) ≥ C∗ in Ω for all t
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Second law of thermodynamics/2
(%η),t
+ div(%ηv) + div(q
θ
)= ξ with θξ ≥ T ·D(v)− q · ∇θ
θ
In terms of the internal energy η = η(e)
e,t + div(ev) + div q ≥ T ·D(v)
or, using the balance of energy,(|v|2),t− 2 div(Tv) + div
(v|v|2
)≤ 0
Suitable weak solution (in the sense of Caffarelli, Kohn, Nirenberg): Inaddition to equations representing balance of mass, linear momentum andenergy we require that solution satisfies one of the formulations of thesecond law of thermodynamics
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Incompresibility
Definition
Volume of any chosen subset (at initial time t = 0) remains constantduring the motion.
for all t: |Vt | = |V0| ⇐⇒ det Fχ = 1
Taking the derivative w.r.t. time and using the identity
ddt
det Fχ = div v det Fχ
we conclude that
div v = 0
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Balance equations for Inhomogeneous incompressible fluids
Balance equations
%,t + div(%v) = 0
(%v),t + div(%v⊗ v)− div T = 0 (BLM)(%(e + |v|2/2)
),t
+ div(%(e + |v|2/2)v) + div q = div (Tv)
Consequences of incompressibility
div v = 0 and T = −pI + S
div v = 0
%t + v · ∇% = 0
(%v)t + div(%v⊗ v)− div S = −∇p(%(e + |v|2/2)
),t
+ div(%(e + |v|2/2 + p)v) + div q = div (Sv)
S and q: additional (the so-called) constitutive equations
Homogeneous fluids: the density is constant
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Balance equations for Inhomogeneous incompressible fluids
Balance equations
%,t + div(%v) = 0
(%v),t + div(%v⊗ v)− div T = 0 (BLM)(%(e + |v|2/2)
),t
+ div(%(e + |v|2/2)v) + div q = div (Tv)
Consequences of incompressibility
div v = 0 and T = −pI + S
div v = 0
%t + v · ∇% = 0
(%v)t + div(%v⊗ v)− div S = −∇p(%(e + |v|2/2)
),t
+ div(%(e + |v|2/2 + p)v) + div q = div (Sv)
S and q: additional (the so-called) constitutive equations
Homogeneous fluids: the density is constant
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Balance equations for Inhomogeneous incompressible fluids
Balance equations
%,t + div(%v) = 0
(%v),t + div(%v⊗ v)− div T = 0 (BLM)(%(e + |v|2/2)
),t
+ div(%(e + |v|2/2)v) + div q = div (Tv)
Consequences of incompressibility
div v = 0 and T = −pI + S
div v = 0
%t + v · ∇% = 0
(%v)t + div(%v⊗ v)− div S = −∇p(%(e + |v|2/2)
),t
+ div(%(e + |v|2/2 + p)v) + div q = div (Sv)
S and q: additional (the so-called) constitutive equations
Homogeneous fluids: the density is constantJ. Malek (MFF UK) Analysis for incompressible fluid flows June 16, 2008 21 / 36
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Balance equations for homogeneous incompressible fluids
div v = 0 (3)
v,t + div(v⊗ v)− div S = −∇p (4)
(e + |v|2/2),t + div((e + |v|2/2 + p)v) + div q = div (Sv) (5)
e,t + div(ev) + div q ≥ S ·D(v) (6)
Constitutive equations for S and q (next section)
Boundary conditions (internal flows)
Initial data
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IBVP
div v = 0
v,t + div(v⊗ v)− div S = −∇p
(e + |v|2/2),t + div((e + |v|2/2 + p)v) + div q = div (Sv)
Data
Ω ⊂ R3 bounded open connected container, T ∈ (0,∞) length of timeinterval
v(0, ·) = v0, e(0, ·) = e0 in Ω
α that appears in boundary conditions (thermally and mechanically orenergetically isolated body)
Task Mathematical Consistency of a Model - for any set of data to find uniquelydefined, smooth, solution (notion of solution, its existence, uniqueness, regularity)
Weak solution - solution dealing with averages
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IBVP
div v = 0
v,t + div(v⊗ v)− div S = −∇p
(e + |v|2/2),t + div((e + |v|2/2 + p)v) + div q = div (Sv)
Data
Ω ⊂ R3 bounded open connected container, T ∈ (0,∞) length of timeinterval
v(0, ·) = v0, e(0, ·) = e0 in Ω
α that appears in boundary conditions (thermally and mechanically orenergetically isolated body)
Task Mathematical Consistency of a Model - for any set of data to find uniquelydefined, smooth, solution (notion of solution, its existence, uniqueness, regularity)
Weak solution - solution dealing with averages
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IBVP
div v = 0
v,t + div(v⊗ v)− div S = −∇p
(e + |v|2/2),t + div((e + |v|2/2 + p)v) + div q = div (Sv)
Data
Ω ⊂ R3 bounded open connected container, T ∈ (0,∞) length of timeinterval
v(0, ·) = v0, e(0, ·) = e0 in Ω
α that appears in boundary conditions (thermally and mechanically orenergetically isolated body)
Task Mathematical Consistency of a Model - for any set of data to find uniquelydefined, smooth, solution (notion of solution, its existence, uniqueness, regularity)
Weak solution - solution dealing with averages
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IBVP
div v = 0
v,t + div(v⊗ v)− div S = −∇p
(e + |v|2/2),t + div((e + |v|2/2 + p)v) + div q = div (Sv)
Data
Ω ⊂ R3 bounded open connected container, T ∈ (0,∞) length of timeinterval
v(0, ·) = v0, e(0, ·) = e0 in Ω
α that appears in boundary conditions (thermally and mechanically orenergetically isolated body)
Task Mathematical Consistency of a Model - for any set of data to find uniquelydefined, smooth, solution (notion of solution, its existence, uniqueness, regularity)
Weak solution - solution dealing with averages
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Boundary conditions
(e + |v|2/2),t + div((e + |v|2/2 + p)v) + div q− div (Sv) = 0
d
dt
(∫Ω
E (t, x) dx
)+
∫∂Ω
[(E + p)v · n + q · n− Sv · n] dS = 0
Mechanically and thermally isolated body, Navier’s slip on [0,T ]× Ω:
v · n = 0 q · n = 0
λ(Sn)τ + (1− λ)vτ = 0 for λ ∈ (0, 1) uτ := u− (u · n)n
λ = 0 =⇒ no-slip λ = 1 =⇒ slip
Energetically isolated body, Navier’s slip on [0,T ]× Ω:
v · n = 0 q · n = −α|vτ |2
(Sn)τ + αvτ = 0 α := (1− λ)/λ
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Boundary conditions
(e + |v|2/2),t + div((e + |v|2/2 + p)v) + div q− div (Sv) = 0
d
dt
(∫Ω
E (t, x) dx
)+
∫∂Ω
[(E + p)v · n + q · n− Sv · n] dS = 0
Mechanically and thermally isolated body, Navier’s slip on [0,T ]× Ω:
v · n = 0 q · n = 0
λ(Sn)τ + (1− λ)vτ = 0 for λ ∈ (0, 1) uτ := u− (u · n)n
λ = 0 =⇒ no-slip λ = 1 =⇒ slip
Energetically isolated body, Navier’s slip on [0,T ]× Ω:
v · n = 0 q · n = −α|vτ |2
(Sn)τ + αvτ = 0 α := (1− λ)/λ
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Boundary conditions
(e + |v|2/2),t + div((e + |v|2/2 + p)v) + div q− div (Sv) = 0
d
dt
(∫Ω
E (t, x) dx
)+
∫∂Ω
[(E + p)v · n + q · n− Sv · n] dS = 0
Mechanically and thermally isolated body, Navier’s slip on [0,T ]× Ω:
v · n = 0 q · n = 0
λ(Sn)τ + (1− λ)vτ = 0 for λ ∈ (0, 1) uτ := u− (u · n)n
λ = 0 =⇒ no-slip λ = 1 =⇒ slip
Energetically isolated body, Navier’s slip on [0,T ]× Ω:
v · n = 0 q · n = −α|vτ |2
(Sn)τ + αvτ = 0 α := (1− λ)/λ
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Boundary conditions
(e + |v|2/2),t + div((e + |v|2/2 + p)v) + div q− div (Sv) = 0
d
dt
(∫Ω
E (t, x) dx
)+
∫∂Ω
[(E + p)v · n + q · n− Sv · n] dS = 0
Mechanically and thermally isolated body, Navier’s slip on [0,T ]× Ω:
v · n = 0 q · n = 0
λ(Sn)τ + (1− λ)vτ = 0 for λ ∈ (0, 1) uτ := u− (u · n)n
λ = 0 =⇒ no-slip λ = 1 =⇒ slip
Energetically isolated body, Navier’s slip on [0,T ]× Ω:
v · n = 0 q · n = −α|vτ |2
(Sn)τ + αvτ = 0 α := (1− λ)/λ
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”Equivalent” formulation of the balance of energy/1
div v = 0
v,t + div(v⊗ v)− div S = −∇p
(e + |v|2/2),t + div((e + |v|2/2 + p)v) + div q = div (Sv)
is equivalent (if v is admissible test function in BM) to
div v = 0
v,t + div(v⊗ v)− div S = −∇p
e,t + div(ev) + div q = S ·D(v)
Helmholtz decomposition u = udiv +∇g v
Leray’s projector P : u 7→ udiv
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”Equivalent” formulation of the balance of energy/2
div v = 0
v,t + div(v⊗ v)− div S = −∇p
(e + |v|2/2),t + div((e + |v|2/2 + p)v) + div q = div (Sv)
is equivalent (if v is admissible test function in BM) to
div v = 0
v,t + P div(v⊗ v)− P div S = 0
e,t + div(ev) + div q = S ·D(v)
Advantages/Disadvantages
+ pressure is not included into the 2nd formulation
+ minimum principle for e if S ·D(v) ≥ 0
− S ·D(v) ∈ L1 while Sv ∈ Lq with q > 1
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”Equivalent” formulation of the balance of energy/2
div v = 0
v,t + div(v⊗ v)− div S = −∇p
(e + |v|2/2),t + div((e + |v|2/2 + p)v) + div q = div (Sv)
is equivalent (if v is admissible test function in BM) to
div v = 0
v,t + P div(v⊗ v)− P div S = 0
e,t + div(ev) + div q = S ·D(v)
Advantages/Disadvantages
+ pressure is not included into the 2nd formulation
+ minimum principle for e if S ·D(v) ≥ 0
− S ·D(v) ∈ L1 while Sv ∈ Lq with q > 1
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Part #3
Constitutive equations
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Newtonian fluids
Definition
The viscosity: the coefficient of the proportionality between the shear rateand the shear stress.
Simple shear flow: v(x , y , z) = (v(y), 0, 0)
Newton: The resistance arising from the want of lubricity in parts of thefluid, other things being equal, is proportional to the velocity with whichthe parts are separated from one another.
Txy = νv ′(y) g(Txy , v′(y)) = 0
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Generalized Newtonian fluids
Experimental data show that the viscosity may depend on the pressure,shear rate, temperature, concentration, ..., density (if fluid isinhomogeneous)
Txy = νv ′(y) ν = ν(p, θ, |v ′(y)|) S = ν(p, θ, |D(v)|2)D
Examples:
T = −pI + 2µ0D, tr D = 0
T = −pI + 2µ0|D|r−2D r ∈ [1,∞)
T = −pI + 2µ0
(1 + |D|2
) r−22 D
T = −pI + 2µ0 exp(αp)D or T =
−pI +(1 + αµ(p, θ) + |D|2
) r−22 D
T = −pI + 2ν(p, %, θ)D = −pI + A√% exp
(B(p+D%2)
θ
)D
T = −pI + 2µ0 exp(1/θ − 1/θ0)(1 + αµ(p, θ) + |D|2
) r−22 D
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Implicitely constituted fluids
More general implicit relations
G (Txy , v′(y)) = 0 or G (p, θ,Txy , v
′(y)) = 0 G(p, θ,S,D) = 0
have the ability to capture complicated responses of materials without anyneed to introduce (non-physical) internal variable constitutive theories, etc.Implicit relations
algebraic
rate type
integral
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Newtonian versus non-Newtonian fluids
Incompressible Newtonian fluid
T = −pI + 2µD, tr D = 0
Departures from Newtonian behavior (at a simple shear flow)
Dependence of the viscosity on the shear rate
Dependence of the viscosity on the pressure
The presence of the yield stress (or other activation or deactivationcriteria)
The presence of the normal stress differences
Stress relaxation
Nonlinear creep
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Fourier fluids - heat conducting fluids
Definition
The heat conductivity: the coefficient of the proportionality between theheat flux q and the temperature gradient ∇θ.
Landau, Lifschitz: The heat flux is related to the variation of temperaturethrough the fluid. . . . We can then expand q as a series of powers oftemperature gradient, taking only the first terms of the expansion. Theconstant term is evidently zero since q must vanish when ∇θ does so.Thus we have
q = −κ∇θ
The coefficient κ is in general a function of temperature and pressure.Examples:
q = −κ∇θq = −κ(θ, p)∇θq(∇θ) = q(0) + ∂z(0)∇θ + 1/2∂
(2)z (0)∇θ ⊗∇θ
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Implicitely constituted heat conducting fluids
More general implicit relations
r(q,∇θ) = 0 r(q, p, θ,∇θ,D) = 0
Implicit relations
algebraic
rate type
integral
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Part #4
References
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References/1
1 E. Feireisl, J. Malek: On the Navier-Stokes Equations with temperature-dependenttransport coefficients, Differ. Equ. Nonlinear Mech., pp. Art. ID 90916, 14p., 2006
2 M. Bulıcek, E. Feireisl, J. Malek: Navier-Stokes-Fourier system for incompressible fluidswith temperature dependent material coefficients, to appear in Nonlinear Analysis andReal World Applications, 2008
3 M. Bulıcek, J. Malek, K. R. Rajagopal: Navier’s slip and Evolutionary Navier-Stokes-Likesystems with Pressure and Shear-Rate Dependent Viscosity, Indiana University Math. J.56, 51–85, 2007
4 M. Bulıcek, J. Malek, K. R. Rajagopal: Mathematical analysis of unsteady flows of fluidswith pressure, shear-rate and temperature dependent material moduli, that slip at solidboundaries, revised version considered in SIAM J. Math. Anal., 2008
5 M. Bulıcek, L. Consiglieri, J. Malek: Slip boundary effects on unsteady flows ofincompressible viscous heat conducting fluids with a nonlinear internal energy-temperaturerelationship, to appear as the preprint at http://ncmm.karlin.mff.cuni.cz, 2008
6 M. Bulıcek, L. Consiglieri, J. Malek: On Solvability of a non-linear heat equation with anon-integrable convective term and the right-hand side involving measures, to appear asthe preprint at http://ncmm.karlin.mff.cuni.cz, 2008
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References/2
1 J. Malek and K.R. Rajagopal: Mathematical Issues Concerning the Navier-StokesEquations and Some of Its Generalizations, in: Handbook of Differential Equations,Evolutionary Equations, volume 2, 371-459, 2005
2 J. Frehse, J. Malek and M. Steinhauer: On analysis of steady flows of fluids withshear-dependent viscosity based on the Lipschitz truncation method, SIAM J. Math.Anal. 34, 1064-1083, 2003
3 L. Diening, J. Malek and M. Steinhauer: On Lipschitz truncations of Sobolev functions(with variable exponent) and their selected applications, accepted to ESAIM: Control,Optimization and Calculus of Variations, published online, 2007
4 J. Hron, J. Malek and K.R. Rajagopal: Simple Flows of Fluids with Pressure DependentViscosities, Proc. London Royal Soc.: Math. Phys. Engnr. Sci. 457, 1603–1622, 2001
5 M. Franta, J. Malek and K.R. Rajagopal: Existence of Weak Solutions for the DirichletProblem for the Steady Flows of Fluids with Shear Dependent Viscosities, Proc. LondonRoyal Soc. A: Math. Phys. Engnr. Sci. 461, 651–670, 2005
6 J. Malek, M. Ruzicka and V.V. Shelukhin: Herschel-Bulkley Fluids: Existence andregularity of steady flows, Mathematical Models and Methods in Applied Sciences, 15,1845–1861, 2005
7 P. Gwiazda, J. Malek and A. Swierczewska: On flows of an incompressible fluid with adiscontinuous power-law-like rheology, Computers & Mathematics with Applications, 53,531–546, 2007
8 M. Bulıcek, P. Gwiazda, J. Malek and A. Swierczewska-Gwiazda: On steady flows of anincompressible fluids with implicit power-law-like rheology, accepted to Adv. Calculus ofVariations 2008
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