From c9972217e9dcc202cdb227690ddb949066c9ccdb Mon Sep 17 00:00:00 2001 From: =?UTF-8?q?V=C3=ADctor?= Date: Mon, 31 Jul 2023 02:36:51 +0300 Subject: [PATCH] updated fluid mechanics --- Physics/4th/Fluid_mechanics/Fluid_mechanics.tex | 4 ++-- 1 file changed, 2 insertions(+), 2 deletions(-) diff --git a/Physics/4th/Fluid_mechanics/Fluid_mechanics.tex b/Physics/4th/Fluid_mechanics/Fluid_mechanics.tex index 6f088e1..98a6642 100644 --- a/Physics/4th/Fluid_mechanics/Fluid_mechanics.tex +++ b/Physics/4th/Fluid_mechanics/Fluid_mechanics.tex @@ -5,7 +5,7 @@ \begin{multicols}{2}[\section{Fluid mechanics}] \subsection{Equations of motion} \subsubsection{Euler's equations} - In this section we will describe the motion of a fluid with a set of equation that result from the conservation of mass, momentum and energy. From what follows, let $D\subseteq \RR^3$ be a region filled with a fluid. For each time $t$ and $\vf{x}\in D$ we assume that the fluid has a well-defined mass density $\rho(\vf{x},t)$\footnote{The assumption that $\rho$ exists is a continuum assumption. Clearly, it does not hold if the molecular structure of matter is taken into account. For most macroscopic phenomena occurring in nature, it is believed that this assumption is extremely accurate.}. Finally, we denoted by $\vf{u}(\vf{x},t)$ the velocity of the fluid at time $t$ and position $\vf{x}$. For the moment, we will also assume that $\rho$ and $\vf{u}$ are smooth functions. + In this section we will describe the motion of a fluid with a set of equation that result from the conservation of mass, momentum and energy. From what follows, let $D\subseteq \RR^3$ be a region filled with a fluid. For each time $t$ and $\vf{x}\in D$ we assume that the fluid has a well-defined mass density $\rho(\vf{x},t)$\footnote{The assumption that $\rho$ exists is a continuum assumption. Clearly, it does not hold if the molecular structure of matter is taken into account. For most macroscopic phenomena occurring in nature, it is believed that this assumption is extremely accurate.}. Finally, we denot by $\vf{u}(\vf{x},t)$ the velocity of the fluid at time $t$ and position $\vf{x}$. For the moment, we will also assume that $\rho$ and $\vf{u}$ are smooth functions. \begin{proposition}[Conservation of mass]\label{FLM:conservationofmass} Let $W\subseteq D$ be a fixed subregion of $D$. Then: $$ @@ -38,7 +38,7 @@ \begin{sproof} Compute the time derivative of $\vf{u}(t,\vf{x}(t))$ using the Chain rule. \end{sproof} - For any continuum, forces acting on a piece of material are of two types. First, there are forces of stress, whereby the piece of material is acted on by forces across its surface by the rest of the continuum. Second, there are external, or body, forces such as gravity or a magnetic field, which exert a force per unit volume on the continuum. + For any continuum, forces acting on a piece of material are of two types. First, there are forces of stress, whereby the piece of material is acted on by forces across its surface by the rest of the continuum. Second, there are external or body, forces such as gravity or a magnetic field, which exert a force per unit volume on the continuum. \begin{definition}[Ideal fluid] An \emph{ideal fluid} has the following property: for any motion of the fluid there is a function $p(\vf{x},t)$ called the \emph{pressure} such that if $S$ is a surface in the fluid with a chosen unit normal $\vf{n}$, the force of stress exerted across the surface $S$ per unit area at $\vf{x}\in S$ at time $t$ is $p(\vf{x},t)\vf{n}$. Thus, the total force of stress exerted inside a region $W\subseteq D$ is given by: $$