Reynolds stress: Difference between revisions

Revision as of 15:33, 30 August 2009

In the context of fusion plasmas, the Reynolds stress is a mechanism for generation of sheared flow from turbulence.

Starting from the incompressible momentum balance equation, neglecting the dissipative pressure tensor: ^[1]

{\frac {\partial u_{y}}{\partial t}}+\nabla _{x}\left(u_{x}u_{y}\right)=-\nabla _{y}P+{\frac {1}{\rho }}\left({\vec {j}}\times {\vec {B}}\right)_{y}

Averaging over a magnetic surface (i.e., over y), the right-hand side cancels:

{\frac {\partial u_{y}}{\partial t}}+\nabla _{x}\left(u_{x}u_{y}\right)=0

Now, writing the flow as the sum of a mean and a fluctuating part

u={\bar {u}}+{\tilde {u}}

one obtains

{\frac {\partial {\bar {u}}_{y}}{\partial t}}+\nabla _{x}\left\langle {\tilde {u}}_{x}{\tilde {u}}_{y}\right\rangle =0

Here, the Reynolds stress tensor appears:

R_{xy}=\left\langle {\tilde {u}}_{x}{\tilde {u}}_{y}\right\rangle

and it is clear that a non-zero value of the gradient of the Reynolds stress (of fluctuating flow components) can drive a laminar flow.

References

↑ R. Balescu, Aspects of Anomalous Transport in Plasmas, Institute of Physics Pub., Bristol and Philadelphia, 2005, ISBN 9780750310307

[1] R. Balescu, Aspects of Anomalous Transport in Plasmas, Institute of Physics Pub., Bristol and Philadelphia, 2005, ISBN 9780750310307

[1]

@@ Line 4: / Line 4: @@
 <ref>R. Balescu, ''Aspects of Anomalous Transport in Plasmas'', Institute of Physics Pub., Bristol and Philadelphia, 2005, ISBN 9780750310307</ref>
-:<math>\frac{\partial u_x}{\partial t} + \nabla_y \left ( u_y u_x \right ) = -\nabla_x P + \frac{1}{\rho} \left ( \vec{j} \times \vec{B} \right )_x</math>
+:<math>\frac{\partial u_y}{\partial t} + \nabla_x \left ( u_x u_y \right ) = -\nabla_y P + \frac{1}{\rho} \left ( \vec{j} \times \vec{B} \right )_y</math>
-Averaging over a [[Flux surface|magnetic surface]] (assuming it exists), the right-hand side cancels ([[MHD equilibrium]]):
+Averaging over a [[Flux surface|magnetic surface]] (i.e., over ''y''), the right-hand side cancels:
-:<math>\frac{\partial u_x}{\partial t} + \nabla_y \left ( u_y u_x \right ) = 0</math>
+:<math>\frac{\partial u_y}{\partial t} + \nabla_x \left ( u_x u_y \right ) = 0</math>
 Now, writing the flow as the sum of a mean and a fluctuating part
@@ Line 16: / Line 16: @@
 one obtains
-:<math>\frac{\partial \bar{u}_x}{\partial t} + \nabla_y \left \langle \tilde{u}_y \tilde{u}_x \right \rangle = 0</math>
+:<math>\frac{\partial \bar{u}_y}{\partial t} + \nabla_x \left \langle \tilde{u}_x \tilde{u}_y \right \rangle = 0</math>
 Here, the Reynolds stress tensor appears:
-:<math>R_{xy} = \left \langle \tilde{u}_y \tilde{u}_x \right \rangle</math>
+:<math>R_{xy} = \left \langle \tilde{u}_x \tilde{u}_y \right \rangle</math>
 and it is clear that a non-zero value of the ''gradient'' of the Reynolds stress (of fluctuating flow components) can drive a laminar flow.

Reynolds stress: Difference between revisions

Revision as of 15:33, 30 August 2009

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