difference between isotropic and homogeneous in turbulence

dut_thinker · October 28, 2010, 21:13

Some literature wrote that 'One might argue that no real turbulent flow is isotropic or even homogeneous in the large scales.'
It sounds that homogeneous is stricter than isotropic!
SO who can give me any hints about the difference between isotropic and homogeneous?

Any comments will be appreciated.

ganesh · October 29, 2010, 01:10

Dear Dut_thinker,

Isotropic turbulence demands that there is no mean shear, rotation or buoyancy effects in the flow as this can lead to anisotropy. Homogeneous turbulence is indicative of the fact that there are no mean flow gradients. In a more simpler sense, homogeneity deals with invariance in translation, isotropy deals with invariance in rotation. Take a look at MIT OCW notes on turbulence if you wish for more information.

Regards,

Ganesh

f-w · October 29, 2010, 13:26

http://books.google.com/books?id=HZs...page&q&f=false

Jade M · October 29, 2010, 13:48

Thanks f-w! This link is very helpful! I'm typing the information below in case the book disappears.

In homogeneous turbulence, the fluctuating velocity field u(x,t) is statistically homogeneous. It is consistent with this definition for the mean velocity gradients d(Ui)dxj to be non-zero but uniform. A good approximation to homogeneous turbulence can be achieved in wind-tunnel experiments and homogeneous turbulence is the simplest class of flows to study using DNS.

A statistically homoegeous field U(x,t) is, by definition, statistically invariant under translations (i.e. shifts in the origin of the coordinate system). If the field is also statistically invariant under rotations and reflections of the coordinate system, then it is (statistically) isotropic.

Reference: Turbulent Flows by S. B. Pope

simulationman · October 30, 2010, 23:34

An isotropic turbulent flow as other members have already replied, is basically a turbulent flow where the time averaged turbulent quantities ( like u r.m.s.) have the same value at each and every location.

A homogeneous flow on the other hand is one where the turbulent quantities at any given location are the same in all the directions. (ex. u r.m.s = v r.m.s.)

example a concrete wall may be isotropic if the concentration of steel and cement is the same at all locations in the wall. But it is not homogeneous because at any point, there may be steel in one direction and cement in the other direction.

Of course it is actually impossible to get either homogeneous or isotropic turbulence in a wind tunnel. But you can get close to it and ppl want to get close to it cause theoretically a homogeneous isotropic turbulence is very attractive.

And ya it is much more impossible to get actual 100% isortopic turbulence cause turbulent flows are by definition dissipative. So the turbulent quantities ( like u r.m.s.) will decay into heat energy with time. Unless you the right amount of energy at the right time it will not be isotropic.

MaRaz · January 1, 2013, 23:11

simulationman, Is definition of homogeneous and isotropic in your answer switched maybe?

FMDenaro · January 2, 2013, 11:10

just to make an example, often the turbulence in channel flow is simulated, the test is composed by two parallel plates that are replicated by periodic boundary conditions. The flow is substained by a forcing pressure gradient.
This flow is simultaneously homogeneous along the two directions of periodicity and inhomogeneous in the direction normal to walls

ndestrad · November 7, 2015, 23:44

Homogeneous turbulence: invariance in translation
Isotropic turbulence: invariance in rotation

Moreza7 · January 23, 2021, 06:15

Quote:

Originally Posted by Jade M

Thanks f-w! This link is very helpful! I'm typing the information below in case the book disappears.

In homogeneous turbulence, the fluctuating velocity field u(x,t) is statistically homogeneous. It is consistent with this definition for the mean velocity gradients d(Ui)dxj to be non-zero but uniform. A good approximation to homogeneous turbulence can be achieved in wind-tunnel experiments and homogeneous turbulence is the simplest class of flows to study using DNS.

A statistically homoegeous field U(x,t) is, by definition, statistically invariant under translations (i.e. shifts in the origin of the coordinate system). If the field is also statistically invariant under rotations and reflections of the coordinate system, then it is (statistically) isotropic.

Reference: Turbulent Flows by S. B. Pope

How can it be possible that for homogeneous turbulence where by definition:

$\langle U(x,t)\rangle = \langle U(x+r,t)\rangle$

then, the gradient

$\frac{\partial{\langle U_i\rangle}}{\partial{x_j}}$

be non-zero?!! I mean it MUST be zero!

Quote:

Originally Posted by ganesh

Dear Dut_thinker,
Isotropic turbulence demands that there is no mean shear, rotation or buoyancy effects in the flow as this can lead to anisotropy. Homogeneous turbulence is indicative of the fact that there are no mean flow gradients. In a more simpler sense, homogeneity deals with invariance in translation, isotropy deals with invariance in rotation. Take a look at MIT OCW notes on turbulence if you wish for more information.

Regards,

Ganesh

For isotropic turbulence, we say that the statistical properties of the turbulence are invariant under rotations which means for example at a specific point in the domain we have:
$\langle\bar{u^{'2}}\rangle = \langle\bar{v^{'2}}\rangle = \langle\bar{w^{'2}}\rangle$
I think this issue has nothing to do with mean shear! Then why mean shear is zero?!

FMDenaro · January 23, 2021, 07:05

Quote:

Originally Posted by Moreza7

How can it be possible that for homogeneous turbulence where by definition:

$\langle U(x,t)\rangle = \langle U(x+r,t)\rangle$

then, the gradient

$\frac{\partial{\langle U_i\rangle}}{\partial{x_j}}$

be non-zero?!! I mean it MUST be zero!

For isotropic turbulence, we say that the statistical properties of the turbulence are invariant under rotations which means for example at a specific point in the domain we have:
$\langle\bar{u^{'2}}\rangle = \langle\bar{v^{'2}}\rangle = \langle\bar{w^{'2}}\rangle$
I think this issue has nothing to do with mean shear! Then why mean shear is zero?!

Plane channel flow is an example of flow homogeneous in the streamwise direction while being non-homogeneous in normal direction. It has dU/dy different from zero.

Moreza7 · January 23, 2021, 07:56

Quote:

Originally Posted by FMDenaro

Plane channel flow is an example of flow homogeneous in the streamwise direction while being non-homogeneous in normal direction. It has dU/dy different from zero.

Thanks for your reply.
Plane channel flow is a partially homogeneous flow (in x and z directions). I think the author is talking about a totally homogeneous flow (in every direction).
Also, if the flow is homogeneous in one direction, it does not mean that velocity must have a constant gradient in other non-homogeneous directions.

Moreza7 · January 23, 2021, 11:11

I think these statements are the best definitions of isotropic and homogeneous turbulent flow:

A turbulent flow is said to be isotropic if:

rotation and buoyancy are not important and can be neglected,
there is no mean flow.

Rotation and buoyancy forces tend to suppress vertical motions and create an anisotropy between the vertical and the horizontal directions. The presence of a mean flow with a particular orientation can also introduce anisotropies in the turbulent velocity and pressure fields.

A turbulent flow is said to be homogeneous if:

there are no spatial gradients in any averaged quantity.

This is equivalent to assume that the statistics of the turbulent flow are not a function of space.

[MIT OCW]

October 28, 2010, 21:13	difference between isotropic and homogeneous in turbulence	#1
dut_thinker New Member Join Date: Feb 2010 Posts: 12 Rep Power: 16	Some literature wrote that 'One might argue that no real turbulent flow is isotropic or even homogeneous in the large scales.' It sounds that homogeneous is stricter than isotropic! SO who can give me any hints about the difference between isotropic and homogeneous? Any comments will be appreciated.

October 29, 2010, 01:10		#2
ganesh Member ganesh Join Date: Mar 2009 Posts: 40 Rep Power: 17	Dear Dut_thinker, Isotropic turbulence demands that there is no mean shear, rotation or buoyancy effects in the flow as this can lead to anisotropy. Homogeneous turbulence is indicative of the fact that there are no mean flow gradients. In a more simpler sense, homogeneity deals with invariance in translation, isotropy deals with invariance in rotation. Take a look at MIT OCW notes on turbulence if you wish for more information. Regards, Ganesh kcavatar and vivek05 like this.

October 29, 2010, 13:48		#4
Jade M Senior Member Join Date: Feb 2010 Posts: 148 Rep Power: 17	Thanks f-w! This link is very helpful! I'm typing the information below in case the book disappears. In homogeneous turbulence, the fluctuating velocity field u(x,t) is statistically homogeneous. It is consistent with this definition for the mean velocity gradients d(Ui)dxj to be non-zero but uniform. A good approximation to homogeneous turbulence can be achieved in wind-tunnel experiments and homogeneous turbulence is the simplest class of flows to study using DNS. A statistically homoegeous field U(x,t) is, by definition, statistically invariant under translations (i.e. shifts in the origin of the coordinate system). If the field is also statistically invariant under rotations and reflections of the coordinate system, then it is (statistically) isotropic. Reference: Turbulent Flows by S. B. Pope lvcheng, kcavatar, Anunay and 1 others like this.

October 30, 2010, 23:34		#5
simulationman New Member Join Date: Oct 2010 Posts: 7 Rep Power: 15	An isotropic turbulent flow as other members have already replied, is basically a turbulent flow where the time averaged turbulent quantities ( like u r.m.s.) have the same value at each and every location. A homogeneous flow on the other hand is one where the turbulent quantities at any given location are the same in all the directions. (ex. u r.m.s = v r.m.s.) example a concrete wall may be isotropic if the concentration of steel and cement is the same at all locations in the wall. But it is not homogeneous because at any point, there may be steel in one direction and cement in the other direction. Of course it is actually impossible to get either homogeneous or isotropic turbulence in a wind tunnel. But you can get close to it and ppl want to get close to it cause theoretically a homogeneous isotropic turbulence is very attractive. And ya it is much more impossible to get actual 100% isortopic turbulence cause turbulent flows are by definition dissipative. So the turbulent quantities ( like u r.m.s.) will decay into heat energy with time. Unless you the right amount of energy at the right time it will not be isotropic. AntonioMezzacapo likes this.

January 1, 2013, 23:11	Mistake maybe?!	#6
MaRaz New Member Join Date: Jan 2013 Posts: 1 Rep Power: 0	simulationman, Is definition of homogeneous and isotropic in your answer switched maybe? rakend reddy, hassansalem, Roark and 5 others like this.

October 29, 2010, 13:26		#3
f-w Senior Member Join Date: Apr 2009 Posts: 156 Rep Power: 17	http://books.google.com/books?id=HZs...page&q&f=false

January 2, 2013, 11:10		#7
FMDenaro Senior Member Filippo Maria Denaro Join Date: Jul 2010 Posts: 6,785 Rep Power: 71	just to make an example, often the turbulence in channel flow is simulated, the test is composed by two parallel plates that are replicated by periodic boundary conditions. The flow is substained by a forcing pressure gradient. This flow is simultaneously homogeneous along the two directions of periodicity and inhomogeneous in the direction normal to walls

November 7, 2015, 23:44	Update?	#8
ndestrad New Member Nick Join Date: Oct 2013 Posts: 2 Rep Power: 0	Homogeneous turbulence: invariance in translation Isotropic turbulence: invariance in rotation EddySouth likes this.

January 23, 2021, 11:11		#12
Moreza7 Senior Member Join Date: Jan 2018 Posts: 121 Rep Power: 8	I think these statements are the best definitions of isotropic and homogeneous turbulent flow: A turbulent flow is said to be *isotropic* if: rotation and buoyancy are not important and can be neglected, there is no mean flow. Rotation and buoyancy forces tend to suppress vertical motions and create an anisotropy between the vertical and the horizontal directions. The presence of a mean flow with a particular orientation can also introduce anisotropies in the turbulent velocity and pressure fields. A turbulent flow is said to be *homogeneous* if: there are no spatial gradients in any averaged quantity. This is equivalent to assume that the statistics of the turbulent flow are not a function of space. [MIT OCW]

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