Download No Slide Title

Survey
yes no Was this document useful for you?
   Thank you for your participation!

* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project

Document related concepts

Quantum vacuum thruster wikipedia , lookup

Classical mechanics wikipedia , lookup

Routhian mechanics wikipedia , lookup

Jerk (physics) wikipedia , lookup

Kinematics wikipedia , lookup

Newton's theorem of revolving orbits wikipedia , lookup

Center of mass wikipedia , lookup

Rotating locomotion in living systems wikipedia , lookup

Equations of motion wikipedia , lookup

Old quantum theory wikipedia , lookup

Laplace–Runge–Lenz vector wikipedia , lookup

Symmetry in quantum mechanics wikipedia , lookup

Rotational spectroscopy wikipedia , lookup

Centripetal force wikipedia , lookup

Tensor operator wikipedia , lookup

Inertia wikipedia , lookup

Torque wikipedia , lookup

Work (physics) wikipedia , lookup

Momentum wikipedia , lookup

Newton's laws of motion wikipedia , lookup

Classical central-force problem wikipedia , lookup

Precession wikipedia , lookup

Rigid body dynamics wikipedia , lookup

Hunting oscillation wikipedia , lookup

Theoretical and experimental justification for the Schrödinger equation wikipedia , lookup

Angular momentum wikipedia , lookup

Photon polarization wikipedia , lookup

Relativistic mechanics wikipedia , lookup

Angular momentum operator wikipedia , lookup

Relativistic angular momentum wikipedia , lookup

Transcript
PHYSICS 231
Lecture 21: Angular momentum
Neutron star
Remco Zegers
Walk-in hour: Monday 9:15-10:15 am
Helproom
PHY 231
1
In the previous episode..
=I
(compare to F=ma)
Moment of inertia I: I=(miri2)
: angular acceleration
I depends on the choice of rotation axis!!
PHY 231
2
Extended objects (like the stick)
M
I=(miri2)
=(m1+m2+…+mn)R2
=MR2
PHY 231
3
Some common cases
PHY 231
4
Falling bars (demo)
mass: m
L
Ibar=mL2/3
Fg
Compare the angular acceleration for 2 bars of different
mass, but same length.
=I=mL2/3 also =Fd=mgL/2 so =3g/(2L)
independent of mass!
Compare the angular acceleration for 2 bars of same mass,
but different length
=3g/(2L) so if L goes up,  goes down!
PHY 231
5
Example
A monocycle (bicycle with one wheel) has a wheel that
has a diameter of 1 meter. The mass of the wheel is 5
kg (assume all mass is sitting at the outside of the wheel).
The friction force from the road is 25 N. If the cycle
is accelerating with 0.3 m/s2, what is the force applied on
each of the paddles if the paddles are 30 cm from the
center of the wheel?
=I
=a/r so =0.3/0.5=0.6 rad/s
I=(miri2)=MR2=5(0.52)=1.25 kgm2
0.5m
F
25N
0.3m
friction=-25*0.5=-12.5
paddles=F*0.3+F*0.3=0.6F
0.6F-12.5=1.25*0.6, so F=22.1 N
PHY 231
6
Rotational kinetic energy
Consider a object rotating
with constant velocity. Each point
moves with velocity vi. The total
kinetic energy is:

1
1
1




 2 m v  2 m  r  2    m r
2
i i
i
i
2 2
i i
i
2
i i
i
2
 1 2
  2 I

KEr=½I2
Conservation of energy for rotating object:
[PE+KEt+KEr]initial= [PE+KEt+KEr]final
PHY 231
7
Example.
1m
Consider a ball and a block going down the same 1m-high slope.
The ball rolls and both objects do not feel friction. If both
have mass 1kg, what are their velocities at the bottom (I.e.
which one arrives first?). The diameter of the ball is 0.4 m.
Block: [½mv2+mgh]initial= [½mv2+mgh]final
1*9.8*1 = 0.5*1*v2 so v=4.4 m/s
Ball: [½mv2+mgh+½I2]initial= [½mv2+mgh+½I2]final
I=0.4*MR2=0.064 kgm2 and =v/R=2.5v
1*9.8*1 = 0.5*1*v2+0.5*0.064*(2.5v)2
so v=3.7 m/s Part of the energy goes to the rotation: slower!
8
PHY 231
Rotational kinetic energy
KEr=½I2
Conservation of energy for rotating object:
[PE+KEt+KEr]initial= [PE+KEt+KEr]final
Example.
A
mA=mB
B
1m
Same initial gravitational PE
Same final total KE
A has lower final linear KE, higher final rotational KE
A has lower final linear velocity
Angular momentum
    0  I  I 0
  I  I 

t
 t 
L  I
L  L0 L


t
t
if    0 then L  0
Conservation of angular momentum
If the net torque equals zero, the
angular momentum L does not change
Iii=Iff
PHY 231
10
Conservation laws:
In a closed system:
•Conservation of energy E
•Conservation of linear momentum p
•Conservation of angular momentum L
PHY 231
11
Neutron star
Sun: radius: 7*105 km
Supernova explosion
Neutron star: radius: 10 km
Isphere=2/5MR2 (assume no mass is lost)
sun=2/(25 days)=2.9*10-6 rad/s
Conservation of angular momentum:
Isunsun=Insns
(7E+05)2*2.9E-06=(10)2*ns
ns=1.4E+04 rad/s so period Tns=5.4E-04 s !!!!!!
PHY 231
12
Kepler’s second law
Area(D-C-SUN)=Area(B-A-SUN)
A line drawn from the sun to the elliptical orbit of a planet
sweeps out equal areas in equal time intervals.
This is the same as the conservation of angular momentum:
IABAB=ICDCD Iplanet at x=(Mplanet at x)(Rplanet at x)2
planet at x =(vplanet at x)/(Rplanet at x)
The spinning lecturer…
A lecturer (60 kg) is rotating on a platform with =2 rad/s
(1 rev/s). He is holding two 1 kg masses 0.8 m away from his
body. He then puts the masses close to his body (R=0.0 m).
Estimate how fast he will rotate (marm=2.5 kg).
Iinitial=0.5MlecR2+2(MwRw2)+2(0.33Marm0.82)
2
=1.2+1.3+1.0=
3.5
kgm
0.4m
0.8m
Ifinal =0.5MlecR2=1.2 kgm2
Conservation of angular mom. Iii=Iff
3.5*2=1.2*f
f=18.3 rad/s (approx 3 rev/s)
PHY 231
14
‘2001 a space odyssey’ revisited
A spaceship has a radius of 100m and
I=5.00E+8 kgm2. 150 people (65 kg pp)
live on the rim and the ship rotates
such that they feel a ‘gravitational’
force of g. If the crew moves to the
center of the ship and only the captain
would stay behind, what ‘gravity’ would
he feel?
Initial: I=Iship+Icrew=(5.00E+8) + 150*(65*1002)=5.98E+8 kgm2
Fperson=mac=m2r=mg so =(g/r)=0.31 rad/s
Final: I=Iship+Icrew=(5.00E+8) + 1*(65*1002)=5.01E+8 kgm2
Conservation of angular momentum Iii=Iff
(5.98E+8)*0.31=(5.01E+8)*f so f=0.37 rad/s
m2r=mgcaptain so gcaptain=13.69 m/s2
PHY 231
15
The direction of the rotation axis
L
L
The rotation in the horizontal plane is
reduced to zero: There must have been a large
net torque to accomplish this! (this is why you
can ride a bike safely; a wheel wants to keep turning
in the same direction.)
The conservation of angular momentum not only holds
for the magnitude of the angular momentum, but also
for its direction.
PHY 231
16
Rotating a bike wheel!
L
L
A person on a platform that can freely rotate is holding a
spinning wheel and then turns the wheel around.
What will happen?
Initial: angular momentum: Iwheelwheel
Closed system, so L must be conserved.
Final: -Iwheel wheel+Ipersonperson
PHY 231
person=
2Iwheel wheel
Iperson
17
Demo: defying gravity!
PHY 231
18
Global warming
The polar ice caps contain 2.3x1019 kg of
ice. If it were all to melt, by how much
would the length of a day change?
Mearth=6x1024 kg Rearth=6.4x106 m
Before global warming: ice does not give moment of inertia
Ii=2/5*MearthR2earth=2.5x1038 kgm2
i=2/(24*3600 s)=7.3x10-5 rad/s
After ice has melted:
If=Ii+2/3*MR2ice=2.5x1038+2.4x1033=2.500024x1038
f=iIi/If=7.3x10-5*0.9999904
The length of the day has increased by
0.9999904*24 hrs=0.83 s.
PHY 231
19
Two more examples
What is the tension in the tendon?
Does not move!
Rotational equilibrium:
30N
12.5N
0.2L
0.5L
T=0.2LTsin(155o)=0.085LT
w=0.5L*30sin(40o)=-9.64L
F=L*12.5sin(400)=-8.03L
=-17.7L+0.085LT=0
T=208 N
L
PHY 231
20
A top
A top has I=4.00x10-4 kgm2. By pulling
a rope with constant tension F=5.57 N,
it starts to rotate along the axis AA’.
What is the angular velocity of the top
after the string has been pulled 0.8 m?
Work done by the tension force:
W=Fx=5.57*0.8=4.456 J
This work is transformed into kinetic energy of the top:
KE=0.5I2=4.456 so =149 rad/s=23.7 rev/s
PHY 231
21