Contributed by:
Vector product and torque, Angular momentum, Conservation of angular momentum
1.
Phys 221
Chapter 11
Angular Momentum
© 2012, 2016 A. Dzyubenko
http://www.csub.edu/~adzyubenko © 2004, 2012 Brooks/Cole
1
2.
Vector Product
Given two vectors A and B, the vector product
(cross product) A×B is a vector C
having a magnitude
C AB sin
Θ is the angle
between
A and B
2
3.
Vector Product, cont
The quantity AB sin Θ is equal to the
area of the parallelogram formed by A and B
The direction of the vector C is perpendicular to
the plane formed by A and B
This direction is defined by the right-hand rule
AB sin
3
4.
Some Properties of the Cross Product
The vector product is not commutative
A B B A
The order is important!
Non-commutative…
If A is parallel to B (Θ = 0º or 180º), then A×B = 0
A×A= 0
Θ = 90º
AB sin
If A is perpendicular to B, then |A × B | = AB
The vector product obeys the distributive law:
A ( B C ) A B A C
4
5.
Some Properties of the
Cross Product, cont
The
derivative of the cross product with respect to
some variable such as t is
d dA dB
( A B ) B A
dt dt dt
It is important to preserve the
multiplicative order of A and B
5
6.
Unit Vectors
ˆi , ˆj , and kˆ form a set of
mutually perpendicular unit
vectors in a right-handed
coordinate system
ĵ
y
î x
z
k̂ 6
7.
Cross Products of Unit Vectors
The cross products of the rectangular unit vectors
ˆi , ˆj, and kˆ obey the following rules:
ˆi ˆi ˆj ˆj kˆ kˆ 0
ˆi ˆj ˆj ˆi kˆ
y
ˆj kˆ kˆ ˆj ˆi x
z
kˆ ˆi ˆi kˆ ˆj
Signs are interchangeable in cross product:
ˆi ( ˆj) ˆi ˆj
7
8.
Determinant Form of Cross Product
The cross product of any two vectors A (Ax, Ay, Az) and B
(Bx, By, Bz) can be expressed in the following determinant:
ˆi ˆj kˆ
Ay Az Az ˆ Ax Ay
A B Ax Ay Az ˆi Ax j kˆ
By Bz Bx Bz Bx By
Bx By Bz
or Trick to use:
A B ( Ay Bz Az B y ) ˆi y
( Az Bx Ax Bz ) ˆj x
( A B A B ) kˆ
x y y x
z
8
9.
Vector Product Example
Given
A 2ˆi 3ˆj; B ˆi 2ˆj
Find A B
A B (2ˆi 3ˆj) ( ˆi 2ˆj)
2ˆi ( ˆi ) 2ˆi 2ˆj 3ˆj ( ˆi ) 3 ˆj 2ˆj
0 4kˆ 3kˆ 0 7kˆ
9
10.
Torque Vector Example
Given the force and location
F (2.00 ˆi 3.00 ˆj) N
r (4.00 ˆi 5.00 ˆj) m
Find the torque produced
r F [(4.00ˆi 5.00ˆj)N] [(2.00 ˆi 3.00 ˆj)m]
[(4.00)(2.00)ˆi ˆi (4.00)(3.00)ˆi ˆj
(5.00)(2.00)ˆj ˆi (5.00)(3.00)ˆi ˆj
2.0 kˆ N m
10
11.
Vector Product and Torque
The torque vector τ is the cross
product of the position vector r
and force F
τ r F
The magnitude of the torque τ is
rF sin
φ is the angle between r and F
Vectorτ lies in a direction perpendicular to the plane
formed by the position vector r and the applied force F.
Along the axis of rotation!
11
12.
Rotational Dynamics
A particle of mass m
located at position r,
moves with linear momentum p
The net force on the particle:
F dp dt
Take the cross product on the left side
of the equation
dp dr dt v p
r F τ r
dt
Add the term dr dt p 0
dp dr d (r p )
τ r dt dt p ? τ dt 12
13.
Angular Momentum
d (r p )
τ dt looks similar in form to F dp dt
Define the instantaneous angular momentum L of
a particle relative to the origin O as the cross
product of the particle’s instantaneous position
vector r and its instantaneous linear momentum p
L r p
The torque acting on a particle dL
is equal to the time rate of change
of the particle’s angular momentum τ dt
13
14.
Angular Momentum, cont
dL
τ dt F dp dt
Isthe rotational analog of Newton’s second law
for translational motion
Torque causes the angular momentum L to change
just as force causes linear momentum p to change
Is valid only if Σ τ and L are measured
about the same origin
The expression is valid for any origin fixed
in an inertial frame
14
15.
More About Angular Momentum
The SI unit of angular momentum is
kg·m2/s
L is perpendicular to the plane
formed by r and p
The magnitude and the direction of
L depend on the choice of origin
The magnitude of L is
φ is the angle between r and p
L mvr sin
L is zero when r is parallel to p (φ = 0º or 180º)
L = mvr when r is perpendicular to p (φ = 90º)
15
16.
Angular Momentum of a System
of Particles: Motivation
The Newton’s second law for a system of particles
The net external force on a system of particles
is equal to the time rate of change of the total
linear momentum of the system
dp tot
Fext dt
Isthere a similar statement
that can be made for
rotational motion?
16
17.
Angular Momentum of a System, cont.
The total angular momentum of a system of
particles is the vector sum of the angular
momenta of the individual particles
L tot L1 L 2 ... L n L i
i
Differentiate with dL tot dL i
respect to time:
i
dt i dt i
The total angular momentum d L tot
varies in time according
to the net external torque:
τ ext
dt
17
18.
Angular Momentum of a System
Relative to the System’s
Center of Mass
The resultant torque acting on a system about an
axis through the center of mass equals the time rate
of change of angular momentum of the system
regardless of the motion of the center of mass
This theorem applies even if the center of mass is
accelerating, provided τ and L are evaluated relative to
the center of mass
18
19.
Angular Momentum of a Rotating
Rigid Object L I
z
Each particle rotates in the xy plane
about the z axis with an angular
speed
The magnitude of the angular
momentum of a particle of mass mi
about z axis is
2
L i mi vi ri mi ri
The angular momentum 2 2
of the whole object is Lz Li mi ri mi ri
i i i
I is the moment of inertia of the object 19
20.
Angular Momentum of a Rotating
Rigid Object, cont
Differentiate with respect to time,
noting that I is constant for a rigid
object dL d
z
I I
dt dt
is the angular acceleration relative to the axis of rotation
ext I
Ifa symmetrical object rotates about a fixed axis passing
through its center of mass, you can write in vector form
L Iω L is the total angular momentum measured
with respect to the axis of rotation 20
21.
A solid sphere and a hollow sphere have the
same mass and radius. They are rotating with
the same angular speed.
The one with the higher angular momentum is
(a) the solid sphere
(b) the hollow sphere
(c) they both have the same angular speed
(d) impossible to determine
21
22.
Conservation of Angular Momentum
The total angular momentum of a system is
constant in both magnitude and direction if the
resultant external torque acting on the system is
zero. That is, if the system is isolated
d L tot L tot constant
ext 0
dt Li L f
For an isolated system consisting of N particles
N
L tot L n constant
n 1 22
23.
Conservation of Angular Momentum, cont
Ifthe mass of an isolated system
undergoes redistribution in some
way, the system’s moment of
inertia I changes
A change in I for an isolated
system requires a change in ω
Li L f I ii I f f
23
24.
Conservation Laws for an
Isolated System
Energy,
Ei E f
linear momentum,
and angular momentum pi p f
of an isolated system
all remain constant
L i L f
Manifestations of some certain symmetries of space
24
25.
Angular Momentum as a
Fundamental Quantity
The concept of angular momentum is also valid
on a submicroscopic scale
Angular momentum is an intrinsic property of
atoms, molecules, and their constituents
Fundamental unit of momentum is
h 2
h is called Planck’s constant
1.054 10 34 kg m 2 s
s, p, d, f, …
electronic orbitals: L=0, 1, 2, 3, … in terms of 25
26.
Reading assignment: Gyroscopes
26
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