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Conservation of momentum
There are two kinds of forces that act in a body. They are:
1. Contact forces
2. Body forces
Contact forces arise due to contact between two bodies. Body forces are action at a distance forces like gravitational force. Similarly, while contact forces act per unit area of the boundary of the body, body forces act per unit mass of the body. Both these forces result in the generation of stresses.
Before deriving these conservation laws of momentum rigorously, we obtain the same using using an approximate analysis, as we did for the transformation of curves, areas and volumes. Moreover, we obtain these for a 2D body. Consider an 2D infinitesimal element in the current configuration with dimensions ∆x along the x direction and ∆y along the y direction, as shown in figure 5.1. We assume that the center of the infinitesimal element, O is located at (x + 0.5∆x, y + 0.5∆y).
We assume that the Cauchy stress, σ varies over the infinitesimal element in the current configuration, σ = Conservation of Momentum | Physics for EmSAT Achieve (x, y). That is we have assumed Eulerian description for the stress. Since, we are considering only 2D state of stress, the relevant Cartesian components of the stress are σxx, σyy, σxy and σyx. Expanding the Cartesian components of the stresses using Taylor’s series up to first order we obtain:

Conservation of Momentum | Physics for EmSAT Achieve

Also seen in figure 5.1 are the Cartesian components of the Cauchy stress acting on various faces of the infinitesimal element, obtained using the equations (5.18) through (5.21).
Now, we are interested in the equilibrium of the infinitesimal element in the deformed configuration under the action of these stresses and the body

Conservation of Momentum | Physics for EmSAT Achieve
Figure 5.1: 2D Infinitesimal element showing the variation of Cartesian components of the stresses on the various faces.


force, b with Cartesian components bx and balong the x and y direction respectively. Also, we shall assume that the infinitesimal element is accelerating with acceleration, a with Cartesian components ax and ay along the x and y direction respectively. Thus, force equilibrium along the x direction requires:

Conservation of Momentum | Physics for EmSAT Achieve

where ρ is the density and the element is assumed to have a unit thickness. Note that here ρ(∆x)(∆y)(1) gives the infinitesimal mass of the element and the stresses are multiplied by the respective areas over which they act to get the forces; since only the forces should satisfy the equilibrium equations. Simplifying, (5.22) we obtain:

Conservation of Momentum | Physics for EmSAT Achieve

Similarly, writing the force equilibrium equation along the y direction:

Conservation of Momentum | Physics for EmSAT Achieve

The above equation simplifies to:

Conservation of Momentum | Physics for EmSAT Achieve

Finally, we appeal to the moment equilibrium. Here we assume that there are no body couples or contact couples acting in the infinitesimal element. Since, we can take moment equilibrium about any point, for convenience, we do it about the point O, marked in figure 5.1, to obtain:

Conservation of Momentum | Physics for EmSAT Achieve

Simplifying the above equation we obtain:
Conservation of Momentum | Physics for EmSAT Achieve

which in the limit ∆x and ∆y tending to zero, the limit that we are interested in, reduces to requiring

σxy = σyx.                                                                              (5.28)

Thus, a plane Cauchy stress field should satisfy the equations (5.23), (5.25) and (5.28) for it to be admissible. Generalizing it for 3D, the Cauchy stress field should satisfy:

Conservation of Momentum | Physics for EmSAT Achieve

and

σxy = σyx, σxz = σzx, σyz = σzy.                                               (5.32)

The equations (5.29) through (5.31) are written succinctly as

ρa = div(σ) + ρb,                                                                     (5.33)

The equations (5.29) through (5.31) are written succinctly as ρa = div(σ) + ρb, (5.33) and equations (5.32) tells us that the Cauchy stress should be symmetric. Similarly, requiring a sector of cylindrical shell to be in equilibrium, under the action of spatially varying stresses, it can be shown that

Conservation of Momentum | Physics for EmSAT Achieve

and

σ = σθr, σrz = σzr, σθz = σ.                                                               (5.37)

has to hold.


Conservation of linear momentum 
Let At be an arbitrary sub-region in the configuration Bt of a body B. The total linear momentum, Γ(At), of the material particles occupying At is defined by

Conservation of Momentum | Physics for EmSAT Achieve

Next, we find the forces acting on the body. Since, the part At has been isolated from its surroundings, traction t(n)(x), introduced in the last chapter, acts on the boundary of the At . In addition to traction, which arises between parts of the body that are in contact, there exist forces like gravity which act on the material particles not through contact and are called body force. The body forces are denoted by b and are defined per unit mass. Hence, the resultant force, z acting on At is

Conservation of Momentum | Physics for EmSAT Achieve

Now, using Newton’s second law of motion, which states that the rate of change of linear momentum of the body must equal the resultant force that acts on the body in both magnitude and direction we obtain

Conservation of Momentum | Physics for EmSAT Achieve

Using (3.30), definition of acceleration, a and (5.16) the above equation can be written as

Conservation of Momentum | Physics for EmSAT Achieve

Next, using Cauchy’s stress theorem (4.3) and the divergence theorem (2.263) the above equation further can be reduced to

Conservation of Momentum | Physics for EmSAT Achieve  

Since, the above equation has to hold for Bt and any subset, At , of it

ρa = div(σ) + ρb.                                                                          (5.43)

Many a times, we are interested in cases for which a = o, then (5.43) becomes

div(σ) + ρb = o,                                                                             (5.44)

which is referred to as Cauchy’s equation of equilibrium. Further, there arises scenarios where the body forces can be neglected and in those cases div(σ) = o. Thus, divergence free stress fields are called self equilibrated stress fields.

Equation (5.43) is in spatial form, that is it assumes that   Conservation of Momentum | Physics for EmSAT AchieveConservation of Momentum | Physics for EmSAT Achieve  are known. But on most occasions, especially in solid mechanics, we know only the material form of these fields that is Conservation of Momentum | Physics for EmSAT Achieve and in those occasions it is difficult to obtain the spatial divergence of these fields. To make it easier at these instances, we seek a statement of balance of linear momentum in material form. For this, equation (5.42a) has to be modified. Towards this, we obtain

Conservation of Momentum | Physics for EmSAT Achieve

for which we have successively used equation (3.75), (5.14), (3.72) and definition of Piola-Kirchhoff stress (4.42) and the divergence theorem. Since, (5.45) has to hold for any arbitrary subpart of the reference configuration, we obtain the material differential form of the balance of linear momentum as

ρra = Div(P) + ρrb.                                                                                (5.46)

It is worthwhile to emphasize that irrespective of the choice of the independent variable, the equilibrium of the forces is established only in the current configuration. In other words, whether we use material or spatial description for the stress, the forces and moments have to be equilibrated in the deformed configuration and not the reference configuration.


Conservation of angular momentum 
Let At be an arbitrary sub-region in the configuration Bt of a body B. The total angular momentum, Ω(At), of the material particles occupying At is defined by

Conservation of Momentum | Physics for EmSAT Achieve

where xo is the point about which the moment is taken and p is the intrinsic angular momentum per unit volume in the current configuration. Next, we find the moment due to the forces acting on the body. As discussed before there are two kind of forces, surface or contact forces and body forces act on the body which contribute to the moment. Apart from moment arising due to applied forces, there could exist couples distributed per unit surface area, m and body couples c, defined per unit mass. Thus, m = Conservation of Momentum | Physics for EmSAT Achieve and c = Conservation of Momentum | Physics for EmSAT Achieve Hence, the resultant moment, ω acting on At is

Conservation of Momentum | Physics for EmSAT Achieve

However, in non-polar bodies that are the subject matter of the study here, there exist no body couples or couples distributed per unit surface area or intrinsic angular momentum, i.e., c = m = p = o. The balance of angular momentum states that the rate of change of the angular momentum must equal the applied momentum in both direction and magnitude. Hence,

Conservation of Momentum | Physics for EmSAT Achieve                                                                                          (5.49)

Further simplification of this balance principle involves some tensor algebra. First, we begin by calculating the left hand side of the above equation:

Conservation of Momentum | Physics for EmSAT Achieve

Since, v ∧ v = o and using equations (5.13) and (5.9), (5.50) reduces to

Conservation of Momentum | Physics for EmSAT Achieve

Next, we simplify the right hand side of the equation (5.49). Towards that, we first show that

Conservation of Momentum | Physics for EmSAT Achieve

where τ is the axial vector of (σ − σt ). We begin by establishing a few vector identities which enable us to establish (5.52).

Identity - 1: If u and v are arbitrary vectors then u ∧ v is the axial vector of the skew-symmetric tensor vu uv.
Proof: It is straightforward to verify that vu − uv is skewsymmetric. Then we observe that

( u − u  v)(u ∧ v) = {u � (u ∧ v)}v − {v � (u ∧ v)}u = o,                         (5.53)

hence, the axial vector of vu−uv is a scalar multiple of u∧v. Accordingly,

(v ⊗ u − u ⊗ v)a = (a � u)v − (a � v)u = α(u ∧ v) ∧ a,                                   (5.54)

for any vector a. Now, we have to show that α = 1. Setting a = u in the above equation and then forming a scalar product on each side with v we have

(u � u)(v � v) − (u � v)2 = α{( v) ∧ u} � v                                                     (5.55)

Using (2.36) we find that

α{(u ∧ v) ∧ u} � v = α[(u � u)(v � v) − (u � v)2 ].                                               (5.56)

Comparing equations (5.55) and (5.56) we find that α = 1. Identity - 2: For any vector a, b, c in the vector space

a ∧ (bc) = (bc − cb)a.                                                                             (5.57)

This identity follows immediately from the above identity.

Identity - 3: Let At be a regular region with boundary ∂A, let n be the outward unit normal to ∂At and let u be a vector field and σ a tensor field, each continuous in At and continuously differentiable in the interior of At . Then

Conservation of Momentum | Physics for EmSAT Achieve

Towards proving this identity, note that

Conservation of Momentum | Physics for EmSAT Achieve

where a is an arbitrary constant vector. To obtain the above we have made use of the identities

Conservation of Momentum | Physics for EmSAT Achieve

and the definition of the gradient. Further, since a is arbitrary in (5.59) we have the identity

Conservation of Momentum | Physics for EmSAT Achieve

Taking the transpose of the above identity, we obtain the required vector identity (5.58).
Now, we are in a position to prove (5.52). For this we replace b by (x−xo) and c by σn in (5.57) and then integrating each side over the surface ∂At we obtain

Conservation of Momentum | Physics for EmSAT Achieve

a being an arbitrary vector. From (5.58) it follows that

Conservation of Momentum | Physics for EmSAT Achieve

Substituting the above equations in (5.63), we obtain

Conservation of Momentum | Physics for EmSAT Achieve

Again using (5.57) and the definition of axial vector to a skew-symmetric tensor (2.98) the above equations can be reduced to a

Conservation of Momentum | Physics for EmSAT Achieve   

and hence the required identity (5.52), since a is an arbitrary vector. Substituting (5.51) and (5.52) in (5.49) yields
Conservation of Momentum | Physics for EmSAT Achieve

Since, the body also satisfies the balance of linear momentum (5.43), the first term on the RHS is zero. Hence, the balance of angular momentum requires


Conservation of Momentum | Physics for EmSAT Achieve

Here we are interested only in non-polar bodies and hence, p = c = m = o. Therefore, (5.69) simplifies to requiring

Conservation of Momentum | Physics for EmSAT Achieve

Since, this has to hold for any arbitrary subparts of the body, Bt , τ = o. Consequently,

σ = σt                                                             (5.71)

hat is the Cauchy stress tensor has to be symmetric in non-polar bodies.

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FAQs on Conservation of Momentum - Physics for EmSAT Achieve

1. What is conservation of momentum?
Ans. Conservation of momentum is a fundamental principle in physics that states that the total momentum of a closed system remains constant, provided there are no external forces acting on it. This means that the momentum before an event or interaction is equal to the momentum after the event or interaction.
2. How is momentum calculated?
Ans. Momentum is calculated by multiplying an object's mass by its velocity. The formula for momentum is momentum = mass × velocity. The SI unit for momentum is kilogram-meter per second (kg·m/s).
3. What is an example of conservation of momentum in real life?
Ans. One example of conservation of momentum in real life is the recoiling of a gun after firing a bullet. When a bullet is shot out of a gun, the gun will recoil in the opposite direction with an equal amount of momentum. This demonstrates the conservation of momentum as the total momentum of the system (gun + bullet) remains constant.
4. Can momentum be lost?
Ans. Momentum cannot be lost in a closed system. According to the principle of conservation of momentum, the total momentum of a closed system remains constant. However, within an open system, momentum can be transferred or lost to external forces.
5. How does conservation of momentum relate to collisions?
Ans. Conservation of momentum is particularly important in analyzing collisions. During a collision between two objects, the total momentum of the system before the collision is equal to the total momentum after the collision, assuming no external forces are involved. This principle allows us to predict the velocities of objects after a collision based on their masses and initial velocities.
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