Euler's equation for one-dimensional flow (Landau Lifshitz)

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The discussion centers on deriving Euler's equation for one-dimensional flow of an ideal fluid as presented in Landau & Lifshitz's Fluid Mechanics. The key point is that the coordinate x of a fluid particle is expressed as a function of the Lagrangian variable a and time t, leading to the mass conservation condition ρdx = ρ₀da. The authors formulate Euler's equation, emphasizing that in one-dimensional flow, the velocity and gradient are aligned, which simplifies the equation by eliminating the convective term. The relationship between the Euler derivative and the convective derivative is clarified, showing they are equivalent in this context. The discussion concludes with an acknowledgment of the clarity provided in understanding these concepts.
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One page 5 in Landau & Lifshitz Fluid Mechanics (2nd edition), the authors pose the following problem:
Write down the equations for one-dimensional motion of an ideal fluid in terms of the variables a, t, where a (called a Lagrangian variable) is the x coordinate of a fluid particle at some instant t=t0.

The authors then go on to give their solutions and assumptions. Here are the important parts:

The coordinate x of a fluid particle at an instant t is regarded as a function of t and its coordinate a at the initial instant: x=x(a,t).

For the condition of mass conversation the authors arrive at (where ρ_0=ρ(a) is the given initial density distribution):
<br /> ρ\mathrm{d}x=ρ_0 \mathrm{d}a<br />

or alternatively:
<br /> ρ\left(\frac{∂x}{∂a}\right)_t=ρ_0<br />

Now the authors go on to write out Euler's equation, where I start to miss something. With the velocity of the fluid particle v=\left(\frac{∂x}{∂t}\right)_a and \left(\frac{∂v}{∂t}\right)_a the rate of change of the velocity of the particle during its motion, they write for Euler's equation:
<br /> \left(\frac{∂v}{∂t}\right)_a=−1ρ_0 \left(\frac{∂p}{∂a}\right)_t<br />

How are the authors arriving at that equation?

In particular, when looking at the full Euler's equation:
<br /> \frac{∂v}{∂t}+(\mathbf{v}⋅\textbf{grad})\mathbf{v}=−1 ρ\, \textbf{grad}\, p<br />

what happens with the second term on the LHS, (\mathbf{v}⋅\textbf{grad})\mathbf{v}? Why does it not appear in the authors' solution?
 
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jedishrfu said:
Could it be that (v.grad)v is zero meaning the v is perpendicular to grad v?

This. It's a 1-D flow, so the gradient and velocity must be parallel or anti-parallel to one another.
 
That's precisely the point of this exercise.
The derivation is simple: consider a bunch of particles in a range [a,a+da],
and apply Newtons law on this bunch of particles.
You will immediately get the result.
The point is that

\left(\frac{dv}{dt}\right) = \left(\frac{∂v}{∂t}\right)_a

Note that by definition:

\left(\frac{∂v}{∂t}\right) = \left(\frac{∂v}{∂t}\right)_x

The gradient term (convective term) is precisely the variation of velocity that comes from "following the fluid".
The Euler view, where a is taken constant, follows the fluid.
Therefore the "Euler derivative" incorporates the convective term: it is the change of speed when following the fluid.
 
boneh3ad said:
This. It's a 1-D flow, so the gradient and velocity must be parallel or anti-parallel to one another.


Maybe I am being dense, but isn't this a contradiction to what the author above said (namely that gradient and vector are perpendicular)?
 
Landau never said that "gradient and vector are perpendicular".
Here is what he said in the solution to this exercise:

SOLUTION. In these variables the co-ordinate x of any fluid particle at any instant is regarded
as a function of t and its co-ordinate a at the initial instant: x = x(a, t). The condition
of conservation of mass during the motion of a fluid element (the equation of continuity)
is accordingly written ... , or
where ... is a given initial density distribution. The velocity of a fluid particle is, by
definition, ... , and the derivative ... gives the rate of change of the velocity
of the particle during its motion. Euler's equation becomes
and the adiabatic equation is ... .

The message of this exercice is that the "Euler derivative" (derivative when following the fluid) is the same thing as the convective derivative

\left(\frac{∂v}{∂t}\right)_a = \frac{dv}{dt} = \frac{∂v}{∂t}+(\mathbf{v}⋅\textbf{grad})\mathbf{v}

where by definition

\left(\frac{∂v}{∂t}\right) = \left(\frac{∂v}{∂t}\right)_x
 
maajdl said:
Landau never said that "gradient and vector are perpendicular".
Here is what he said in the solution to this exercise:



The message of this exercice is that the "Euler derivative" (derivative when following the fluid) is the same thing as the convective derivative

\left(\frac{∂v}{∂t}\right)_a = \frac{dv}{dt} = \frac{∂v}{∂t}+(\mathbf{v}⋅\textbf{grad})\mathbf{v}

where by definition

\left(\frac{∂v}{∂t}\right) = \left(\frac{∂v}{∂t}\right)_x


Thank you! Your explanation pointed me in the right direction. :-)
 

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