PHY PHYSICS 231 Lecture 21: Angular momentum Remco Zegers Walk-in hour: Monday 9:15-10:15 am Helproom Neutron star
PHY In the previous episode.. =I (compare to F=ma ) Moment of inertia I: I=( m i r i 2 ) : angular acceleration I depends on the choice of rotation axis!!
PHY Extended objects (like the stick) I=( m i r i 2 ) =(m 1 +m 2 +…+m n )R 2 =MR 2 M
PHY Some common cases
PHY Falling bars (demo) L mass: m FgFg Compare the angular acceleration for 2 bars of different mass, but same length. =I =mL 2 /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! I bar =mL 2 /3
PHY 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/s 2, what is the force applied on each of the paddles if the paddles are 30 cm from the center of the wheel? 25N 0.5m 0.3m F =I =a/r so =0.3/0.5=0.6 rad/s I=( m i r i 2 )=MR 2 =5(0.5 2 )=1.25 kgm 2 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 Rotational kinetic energy Consider a object rotating with constant velocity. Each point moves with velocity v i. The total kinetic energy is: KE r =½I 2 Conservation of energy for rotating object: [PE+KE t +KE r ] initial = [PE+KE t +KE r ] final
PHY 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: [½mv 2 +mgh] initial = [½mv 2 +mgh] final 1*9.8*1 = 0.5*1*v 2 so v=4.4 m/s Ball: [½mv 2 +mgh+½I 2 ] initial = [½mv 2 +mgh+½I 2 ] final I=0.4*MR 2 =0.064 kgm 2 and =v/R=2.5v 1*9.8*1 = 0.5*1*v *0.064*(2.5v) 2 so v=3.7 m/s Part of the energy goes to the rotation: slower!
Rotational kinetic energy KE r =½I 2 Conservation of energy for rotating object: [PE+KE t +KE r ] initial = [PE+KE t +KE r ] final Example. 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 A B m A =m B
PHY Angular momentum Conservation of angular momentum If the net torque equals zero, the angular momentum L does not change I i i =I f f
PHY Conservation laws: In a closed system: Conservation of energy E Conservation of linear momentum p Conservation of angular momentum L
PHY Neutron star Sun: radius: 7*10 5 km Supernova explosion Neutron star: radius: 10 km I sphere =2/5MR 2 (assume no mass is lost) sun =2 /(25 days)=2.9*10 -6 rad/s Conservation of angular momentum: I sun sun =I ns ns (7E+05) 2 *2.9E-06=(10) 2 * ns ns =1.4E+04 rad/s so period T ns =5.4E-04 s !!!!!!
Kepler’s second law A line drawn from the sun to the elliptical orbit of a planet sweeps out equal areas in equal time intervals. Area(D-C-SUN)=Area(B-A-SUN) This is the same as the conservation of angular momentum: I AB AB =I CD CD I planet at x =(M planet at x )(R planet at x ) 2 planet at x =(v planet at x )/(R planet at x )
PHY 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 (m arm =2.5 kg). 0.4m 0.8m I initial =0.5M lec R 2 +2(M w R w 2 )+2(0.33M arm ) = = 3.5 kgm 2 I final =0.5M lec R 2 =1.2 kgm 2 Conservation of angular mom. I i i =I f f 3.5*2 =1.2* f f =18.3 rad/s (approx 3 rev/s)
PHY ‘2001 a space odyssey’ revisited A spaceship has a radius of 100m and I=5.00E+8 kgm 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=I ship +I crew =(5.00E+8) + 150*(65*100 2 )=5.98E+8 kgm 2 F person =ma c =m 2 r=mg so = (g/r)=0.31 rad/s Final: I=I ship +I crew =(5.00E+8) + 1*(65*100 2 )=5.01E+8 kgm 2 Conservation of angular momentum I i i =I f f (5.98E+8)*0.31=(5.01E+8)* f so f =0.37 rad/s m 2 r=mg captain so g captain =13.69 m/s 2
PHY The direction of the rotation axis The conservation of angular momentum not only holds for the magnitude of the angular momentum, but also for its direction. 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.) L L
PHY Rotating a bike wheel! LL 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: I wheel wheel Closed system, so L must be conserved. Final: - I wheel wheel +I person person person = 2I wheel wheel I person
PHY Demo: defying gravity!
PHY Global warming The polar ice caps contain 2.3x10 19 kg of ice. If it were all to melt, by how much would the length of a day change? M earth =6x10 24 kg R earth =6.4x10 6 m Before global warming: ice does not give moment of inertia I i =2/5*M earth R 2 earth =2.5x10 38 kgm 2 i =2 /(24*3600 s)=7.3x10 -5 rad/s After ice has melted: I f =I i +2/3*MR 2 ice =2.5x x10 33 = x10 38 f = i I i /I f =7.3x10 -5 * The length of the day has increased by *24 hrs=0.83 s.
PHY Two more examples 12.5N 30N 0.2L 0.5L L Does not move! What is the tension in the tendon? Rotational equilibrium: T =0.2LTsin(155 o )=0.085LT w =0.5L*30sin(40 o )=-9.64L F =L*12.5sin(40 0 )=-8.03L =-17.7L+0.085LT=0 T=208 N
PHY A top A top has I=4.00x10 -4 kgm 2. 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