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Chapter 9 1 Center of mass
Newton’s laws of motion are formulated for single particle. However, they can be extended without difficulty to systems of particles and bodies of finite dimensions.
We now consider two particles located on the x axis.
The position of the center of mass is defined by
21
2211
mm
xmxmxcm
where m1 and m2 are the masses of particle 1 and particle 2.
For the system with many particles,
the position of center of mass is given by
ii
iii
cm m
m
mmm
mmmr
rrrR
.....
.....
321
332211
where
iimM is the total mass of the system. Physically, the center of mass can be
interpreted as a weighted average position of the system of the particles. In the special case of a uniform gravitational field the center of mass coincides with the center of gravity.
For the continuous distribution of particles, the position of center of mass is given by
dm
dmzyx cmcmcmcm
rR ),,(
or
dm
zdmz
dm
ydmy
dm
xdmx
cm
cm
cm
2. Calculation of center of mass 2.1. Center of the mass for the uniform rod
22
2
0
0 L
L
L
dx
xdx
dm
xdmx L
L
cm
where is the line density (mass/length): = M/L 2.2 Center of the mass for the uniform triangle
32
32
12
1
3
2
2
3
2
2
32
0
2
22
0/
0
/
0
2
3
0
0/
0
/
0
b
a
baa
ab
dxa
bx
a
xbdx
dydx
ydydx
dxdy
ydxdy
dm
ydmy
a
a
baa
ba
dxa
bx
dxa
bxx
dydx
dyxdx
dxdy
xdxdy
dm
xdmx
a
a
abx
o
a
abx
o
a
cm
a
a
abx
o
a
abx
o
a
cm
where is the area density (mass/area). ((Geometry))
)3
,3
2()],()0,[(
3
1
23
2 babaa
OBOAOG
2.3 Center of mass for the half circle with radius a
((Solution))
0cmx from the symmetry.
aa
a
a
drdr
ddrr
rdrd
rdrdr
dm
ydmy a
a
cm 424.03
4
)2
(
3
12sin
sin2
3
00
00
2
3 Linear momentum 3.1 Definition of linear momentum
The linear momentum of the particle with a mass m and a velocity v, is defined by
p = mv The general statement of Newton’s second law
dt
dpF
or
vv
vFdt
dm
dt
dmm
dt
d )(
For a constant mass m, we have
av
F mdt
dm (conventional law)
3.2 System consisting of many particles
Now we apply the Newton’s second law to the motion of many particles shown in Fig.
Newton’s second law:
)(ei
jjii FFp
where jiF is the internal force applied on the i-th particle from the j-th particle (i ≠ j) and
)(eiF is the external force applied on the i-th particle.
________________________________________________________________________ We note that
ijji FF (Newton’s third law)
The forces two particles exert on each other are equal and opposite. (a) Weak law of action and reaction
(b) Definition for the strong law of action and reaction.
From the above equation, we have
)(
2
2
)( ei
jjiiii m
dt
dFFrp
or
i
ei
i
ei
j jji
iii
i
mdt
d
)(
)(
2
2
)(
F
FF
r
pP
or
)()(
2
2e
i
ei
iiim
dt
dFFrP ,
since ijji FF , where )(eF is the total external force. The center of mass RCM is the
average of the radii vectors, weighed in proportion to their mass,
CMi
ii Mm Rr
where M is the total mass defined by
i
imM .
Then we have
)(2
2
)( eCMM
dt
dFRP
,
or
)(2
2eCM
dt
dM F
RP
.
Motion of center of mass
x
y
O1 2 3 4
1
2
3
4
Fig. Typical motion of two bodies (with the same mass, red and blue circles) connecting by a uniform rod. The center of the mass is the midpoint of the two bodies. It shows a parabola-motion in the x-y plane.
Motion of center of mass
x
y
O1 2 3 4
1
2
3
4
Fig. Typical motion of two bodies (mass 2m for the red circles and mass m for blue
circles) connecting by a uniform rod. The center of the mass is deviated from the midpoint of the two bodies. It shows a parabola-motion in the x-y plane.
4. Conservation law of linear momentum If F(e) = 0, we have
0)( eFP
leading to
dt
dM CMR
P = conserved
This means that
0 if PPP (Momentum conservation law)
where Pi and Pf are the linear momentum in the initial state and the final state. ((Note))
When dt
d CMR= 0 at t = 0, RCM is independent of t.
5. Sample problems 5.1 Sample problem 9-2 A uniform metal plate (radius 2R) from which a disk of radius R is stamped out
We consider two circles (linear combination) Circle (radius 2R and the area density ) centered at the origin (0, 0) Circle (radius R and the area density -) centered at (-R,0).
0
3)(3
)(
)]([])2([
))](([0])2([2
2
22
22
cm
cm
y
R
R
RR
RR
RRRx
5.2 Typical problem Problem 9-16*** (SP-09) (10-th edition)
Ricardo, of mass 80 kg, and Carmelita, who is lighter, are enjoying Lake Merced at dusk in a 30 kg canoe. When the canoe is at rest in the placid water, they exchange seats,
which are 3.0 m apart and symmetrically located with respect to the canoe’s center. If the canoe moves 40 cm horizontally relative to a pier post, what is Carmelita’s mass. ((Solution))
mR = 80 kg l = 2a = 3.0 m. M = 30 kg The position of the center of mass xcm does not change since there is no external force.
CR
RC
CR
CRcm mMm
axmMxaxm
mMm
axmMxaxmx
)()()()( 222111
or
)()()()( 222111 axmMxaxmaxmMxaxm RCCR
We put
yxx 21 Then we have
CR
CR
mMm
mmay
)(2
When y = 0.4m, we have mC = 57.6 kg.
5.3 Problem from Serway 8-39
Romeo (77.0 kg) entertains Juliet (55.0 kg) by playing his guitar from the rear of their boat at rest in still water, 2.70 m away from Juliet who is in the front of the boat. After the serenade, Juliet carefully moves to the rear of the boat (away from shore) to plant a kiss on Romeo’s cheek. How far does the 80.0-kg boat move toward the shore it is facing? ((Solution))
mR = 77.0 kg: weight of Romeo mJ = 55.0 kg: weight of Juliet M = 80.0 kg: mass of the canoe l =2a = 2.70 m The position of the center of mass xcm does not change since there is no external force.
JR
JR
JR
RJcm mMm
axmmMx
mMm
axmMxaxmx
))(()()( 22111
or
))(()()( 22111 axmmMxaxmMxaxm JRRJ
We put
yxx 21
Then we have
mmMm
amy
CR
J 70.0212
0.557.22
6 Elastic collision (head-on collision): one-dimensional
In the absence of the external force, the total linear momentum is conserved before and after the collision of two particles with mass m1 and m2. We consider the elastic collision where the total energy is conserved before and after the collision.
Momentum conservation law
22112211 umumvmvm Energy conservation law (elastic collision)
222
211
222
211 2
1
2
1
2
1
2
1umumvmvm
or
21
221112
21
221211
)(2
2)(
mm
vmmvmu
mm
vmvmmu
((Mathematica))
Clear"Global`";
eq1 m1 v1 m2 v2 m1 u1 m2 u2;
eq2 1
2m1 v12
1
2m2 v22
1
2m1 u12
1
2m2 u22;
eq3 Solveeq1, eq2, u1, u2 Simplify
u1 v1, u2 v2, u1 m1 v1 m2 v1 2 m2 v2
m1 m2,
u2 2 m1 v1 m1 v2 m2 v2
m1 m2
7 Perfectly inelastic collision
Momentum conservation law;
umumvmvm 212211 The energy is not conserved in this case. 8 2D collisions
ffi mmm 221111 vvv (Two-dimensional vectors)
From the above figure
222111
22211111
sinsin
coscos
ff
ffi
vmvm
vmvmvm
The solution is
)cos(
sin
)cos(
sin
21
11
2
12
21
211
if
if
vm
mv
vv
Here we assume the case of elastic collision (the energy conservation law)
222
211
211 2
1
2
1
2
1ffi vmvmvm
When m1 = m2, this condition is rewritten as
221
((Note)) In the general case (including the case of inelastic collision), the energy is not conserved.
)]2sin(sin[sin)(csc2
2
1
2
1
2
1
212111212
2
211
211
222
211
mmm
vm
vmvmvmKKEEE
i
iffifif
When m1 = m2,
2121212
11
sinsin)csc()cot(2
2
1
ivm
E
Figure Plot of E/Ei as a function of 2, where m1 = m2. 1 is changed as a
parameter:1 = 10°, 20°, 30°, 40°, 50°, 60°, 70°, and 80°. E/Ei becomes zero for 1 + 2 = /2 (elastic scattering).
((Mathematica))
f eq5 . 1
180x1, 2
180x2;
PlotEvaluateTablef, x1, 10, 80, 10, x2, 0, 90,
PlotStyle TableHue0.12 i, Thick, i, 0, 7,
AxesLabel "2 degrees", "EEi",
PlotRange 0, 90, 0.6, 0
20 40 60 80q2 degrees
-0.6
-0.5
-0.4
-0.3
-0.2
-0.1
0.0DEEi
9 Elastic collision of particles with the same mass Problem 9-75** (SP-09) (10-th edition)
A projectile proton with a speed of 500 m/s collides elastically with a target proton initially at rest. The two protons then move along perpendicular paths, with the projectile path at 60° from the original direction. After the collisions, what are the speeds of (a) the target proton and (b) the projectile proton? ((Solution))
ffi 211 vvv 2
22
12
1 ffi vvv
ffffffffi 212
22
12
212
22
12
1 2)( vvvvvvvvv
or 021 ff vv
In other words, v1f and v2f are perpendicular to each other.
Definition of impulse J
tttdt avifav
t
t
if
f
i
FFFJ
pppJ
)(
or
avttF
pJ
,
with
f
i
t
tifav dt
ttFF
1
The average force avF can be evaluated from the values of pJ and the time interval
((Impulse-momentum theorem))
The change in the momentum of a particle is equal to the impulse of the net force acting on the particle. ((Note))
A moving particle has momentum and kinetic energy, but it does not carry with it a force. The force required to cause a particle to stop depends on how big the momentum change is and on how quickly the momentum change occurs. ((Example)) Impulse example The change in momentum of an object during a collision is equal to the product of the average force acting on an object and the time over which it acts. ((Example)) SmartPhysics p.144-146 A ball with a mass of m = 1 kg is released from rest from an initial height of (hi = 1 m) above the floor. It bounces back to half its original height (hf = 0.5 m). If we assume the ball is in contact with the floor for a time of t = 10 ms, what is the average force on the ball during the collision?
((Solution))
1ih m. 5.0fh m. m = 1 kg. 10t ms.
(i) v1 is the velocity of the ball which falls from the height hi and touchs on the floor
)2(0 21
2ighv , or ighv 21 = 4.43 m/s
(ii) v2 is the velocity of the ball which bounces back from the floor
)2(0 22
2fghv , or fghv 22 = 3.13 m/s
Impulse
)()( 2112 vvmmvmvtFpJ av 7.56 N s
The average force avF is obtained as
756)( 21
t
vvmFav N.
10.2 Example Problem 9-38** (10-th edition)
In the overhead view of Fig., a 300 g ball with a speed v of 6.0 m/s strikes a wall at an angle of 30° and then rebounds with the same speed and angle. It is in contact with the wall for 10 ms. In unit-vector notation, what are (a) the impulse on the ball from the wall and (b) the average force on the wall from the ball?
m = 0.3 kg, v = 6.0 m/s, = 30, t = 10 ms
tFpJ av
where (a)
NsmvpJ 8.1sin2 (b)
Nt
JFav 180
11 Systems with varying mass: A rocket 11.1 Formulation
We assume that we are at rest relative to an inertial reference frame (the Earth), watching a rocket accelerate through deep space with no gravitational or atmospheric drag force acting on it.
We consider a rocket plus fuel that is initially at rest. When fuel is ejected out the back of the rocket, it acquires momentum, and so the rocket must move forward to acquire opposite momentum to cancel the fuel’s momentum, since the total momentum of the system remains constant.
Suppose that a rocket of mass M is moving at the velocity v with respect to the Earth. Now a mass of fuel (- dM) is ejected with the velocity u with respect to the Earth. The rocket now moves forward with mass (M+dM) and velocity (v+dv)
Momentum conservation law:
))(()( dvvdMMudMMv . (1)
Note that
Vrocket-Earth = Vrocket-fuel + Vfuel-Earth where
Vrocket-Earth (= v + d v) is the velocity of rocket relative to the Earth. Vrocket-fuel (= vrel) is the velocity of rocket relative to the exhaust fuel. Vfuel-Earth (= u) is the velocity of the exhaust fuel relative to the Earth.
We get the relation
u = v + dv - vrel. (2) Substituting Eq.(2) for u into Eq.(1), we get
))(()( dvvdMMvdvvdMMv rel
or
dMdvvdMMdvMvdMvdMdvvdMMv rel .
or
MdvdMvrel 0 ,
or
dt
dvM
dt
dMvrel 0
Then we have
rel
rel
rel
Rvdt
dMv
dt
dMv
dt
dvM
)( (first rocket equation).
where
vrel: the fuel’s exhaust velocity relative to the rocket.
relRvT the thrust of the rocket engine (N)
R (=-dM/dt) the rate of fuel consumption Here we assume that vrel is constant. Then we have
M
dMvdv
dMvMdv
rel
rel
)ln(i
frel
M
M
relif M
Mv
M
dMvdvvv
f
i
,
or
)ln(f
irelif M
Mvvv
(second rocket equation)
We make a plot of rel
if
v
vv as a function of
f
i
M
M
10 20 30 40 50MiMf0
1
2
3
4vf-vive
11.2 The case for constant R (=-dM/dt) and vrel.
Here we assume that R (= -dM/dt) and vrel are independent of t. Then we have
dt
dMR
Rvdt
dvM rel
From the second equation, M is obtained as
RtMM 0
or
00
1M
Rt
M
M
where M0 is the initial mass at t = 0 and t<M0/R. Then we have
0
0
0 /1
/
MRt
MRv
RtM
Rv
M
Rv
dt
dv relrelrel
or
tM
Rvdt
MRt
MRvdvvv
o
rel
trel
1
1ln
/1
/
0 0
00
where 100
M
Rt.
(a) Plot of (v-v0)/vrel vs = Rt/M0.
)1
1ln(0
relv
vv
0.2 0.4 0.6 0.8 1.0x=RtM0
1
2
3
4
v-v0vrel
Note that in the limit of →0 (or t→0)
32)
1
1ln(
320
relv
vv
(b) Plot of M/M0 vs = Rt/M0.
10M
M
0.2 0.4 0.6 0.8 1.0x=RtM0
0.2
0.4
0.6
0.8
1.0
MM0
In conclusion:
The velocity of the rocket is proportional to the time in early stage. As the mass of rocket decreases in the late stage, the velocity of the rocket rapidly increases. ((Note)) The velocity of rocket
102 miles/h = 47.7 m/s 103 miles/h=0.447 km/s = 447 m/s 104 miles/h = 4.4704 km/s
The velocity for the orbit on the earth
91.7E
Eorbit R
GMv km/s = 1.77 x 104 miles/h
The escape velocity form the earth:
19.112
E
Eescape R
GMv km/s = 2.50 x 104 miles/h.
11.3 Problem 9-78 (10-th edition)
Consider a rocket that is in deep space and at rest relative to an inertial reference frame. The rocket’s engine is to be fired for a certain interval. What must be the rocket’s mass ratio (ratio of initial to final mass) over that interval if the rocket’s original speed relative to the inertial frame is to be equal to (a) the exhaust speed (speed of the exhaust products relative to the rocket) and (b) 2.0 times the exhaust speed? ((Solution)) Second rocket equation with vi = 0 and vf = v;
)exp(
)ln(0
relf
i
f
irelif
v
v
M
M
M
Mvvvv
(a) If v = vrel, we obtain 72.21 eM
M
f
i
(b) If v = 2 vrel,, we obtain 39.72 eM
M
f
i
11.4 Problem 9-79 (10-th edition)
A rocket that is in deep space and initially at rest relative to an inertial reference frame has a mass of 2.55 x 105 kg, of which 1.81 x 105 kg is fuel. The rocket engine is then fired for 250 s while fuel is consumed at the rate of 480 kg/s. The speed of the exhaust products relative to the rocket is 3.27 km/s. (a) What is the rocket’s thrust? After the 250 s firing, what are (b) the mass and (c) the speed of the rocket? ((Solution)) (a) The thrust of the rocket is given by T = Rvrel where R (=- dM/dt) is the rate of fuel consumption and vrel is the speed of the exhaust gas relative to the rocket. For this problem R = 480 kg/s and vrel = 3.27 103 m/s, so
T = R vrel =1.57 x 106 N (b) The mass of fuel ejected is given by Mfuel = R t , where t is the time interval of the burn. Thus, Mfuel = (480 kg/s)(250 s) = 1.20 105 kg. The mass of the rocket after the burn is
Mf = Mi – Mfuel = (2.55 – 1.20) x 105 kg = 1.35 x 105 kg. (c) Since the initial speed is zero, the final speed is given by the second rocket equation
)ln(f
irelf M
Mvv = 2.08 x 103 m/s
______________________________________________________________________ 11.5
Problem 9-76 (10-th edition) A 6090 kg space probe moving nose-first toward Jupiter at 105 m/s relative to the Sun fires its rocket engine, ejecting 80.0 kg of exhaust at a speed of 253 m/s relative to the space probe. What is the final velocity of the probe? ((Solution)) Second rocket equation;
)ln(f
irelif M
Mvvv
vf = 105 m/s + (253 m/s) ln(6090 kg/6010 kg) = 108 m/s.
12. Homework and SP-09 12.1 Problem 9-14 (SP-09) (10-th edition)
In Fig., two particles are launched from the origin of the coordinate system at time t = 0. Particle 1 of mass m1 = 5.00 g is shot directly along the x axis on a frictionless floor, with constant speed 10.0 m/s. Particle of mass m2 = 3.00 g is shot with a velocity of magnitude 20.0 m/s, at an upward angle such that it always directly above particle 1. (a) What is the maximum height Hmax reached by the c.o.m. of the two-particle system? In unit-vector notation, what are the (b) velocity and (b) acceleration of the c.o.m. when the c.o.m. reaches Hmax?
((Solution)) m1 = 5.00g, m2 = 3.00 g, v1 = 10.0 m/s, v2 = 20 m/s
)sin,cos(
),0,(
222
11
gtvv
v
v
v
r1 =(x1, y1) r2 =(x2, y2)
21
2211
21
2211
21
2211
,
,
mm
mm
mm
mm
mm
mm
com
com
com
aaA
vvV
rrR
12.2 Problem 9-37 (SP-09) (10-th edition)
A soccer player kicks a soccer ball of mass 0.45 kg that is initially at rest. The player’s foot is in contact with the ball for 3.0 x 10-3 s, and the force of the kick is given by
NtttF ])100.2()100.6[()( 296 for st 3100.30 , where t is in seconds. Find the magnitudes of (a) the impulse on the ball due to the kick, (b) the average force on the ball from the player’s foot during the period of contact, (c) the maximum force on the ball from the player’s foot during the period of contact, and (d) the ball’s velocity immediately after it loses contact with player’s foot.
((Solution))
0.5 1.0 1.5 2.0 2.5 3.0t ms
1000
2000
3000
4000
F N
a = 6.0 x 106, b = 2.0 x 109 t0 = 3.0 x 10-3 s, m = 0.45 kg The force is given by
2)( btattF The impulse J:
0
0
)(t
dttFJ
The average force Fav:
0t
JFav
12.3 Problem 9-70*** (SP-09) (10-th edition)
In Fig., puck 1 of mass m1 = 0.20 kg is sent sliding across a frictionless lab bench, to undergo a one-dimensional elastic collision with stationary puck 2. Puck 2 then slides off the bench and lands a distance d from the base of the bench. Puck 1 rebounds from the collision and slides off the opposite edges of the bench, landing a distance 2d from the base of the bench. What is the mass of puck2? (Hint: Be careful with signs).
2
1
2
1gthy
tux
or
h
gdu
g
hudx
g
ht
gthy
22
22
2
02
10
1
1
2
For the mass m2,
h
gdu
g
hudx
g
ht
gthy
2
2
2
02
10
2
2
2
Then we have
2
1
22
2
1
2
h
gd
h
gd
u
u (2)
From Eqs.(1) and (2), we have
12
112
12
111
2
2
2
mm
vmu
mm
vmu
(3)
The energy conservation law:
222
211
211 2
1
2
1
2
1umumvm
The substitution of Eq.(3) into the energy conservation law leads to
02
)5(
21
11211
mm
vmmmm
Thus we get
12 5mm 12.4 Problem 9-64** (SP-09) (10-th edition) A steel ball of mass 0.500 kg is fastened to a cord that is 70.0 cm long and fixed at the far end. The ball is then released when the cord is horizontal (Fig.) At the bottom of its path, the ball strikes a 2.50 kg steel block initially at rest on a frictionless surface. The collision is elastic, find (a) the speed of the ball and (b) the speed of the block, both just after the collision. ((Solution))
M = 2.50 kg, m = 0.5 kg, R = 0.7 m. Energy conservation law
2
2
1mvmgR or smgRv /70.32
Momentum conservation law
mVMUmv The collision is elastic.
222
2
1
2
1
2
1mVMUmv
smMm
mvU
smvMm
MmV
/23.12
/47.2
13. Problems from Sewway 13.1 Serway Problem 8-51
A small block of mass m = 0.500 kg is released from rest at the top of a curve-shaped frictionless wedge of mass M = 3.00 kg, which sits on a frictionless, horizontal surface. When the block leaves the wedge, the velocity is measured to be v = 4.00 m/s to the right. (a) What is the velocity of the wedge after the block reaches the horizontal surface? (b) What is the height h of the wedge? ((Solution))
((Solution)) M = 3.00 kg m = 0.500 kg v = 4.00 m/s (a) The initial momentum of the system is zero, which remains constant through the motion (the momentum conservation). When the block of mass m leaves the wedge, we have
0 MVmv or
V = 0.667 m/s
(b) Energy conservation
Ei = Ef where
22
2
1
2
1MVmvE
mghE
f
i
Then we have h = 0.952 m. 13.2 Serway Problem 8-58
A cannon is rigidly attached to a carriage, which can move along horizontal rails but is connected to a post by a large spring, initially stretched and with force constant k = 2.00 x 104 N/m. The cannon fires a 200-kg projectile at a velocity of 125 m/s directed 45.0° above the horizontal. (a) Assuming that the mass of the cannon and its carriage is 5000 kg, find the recoil
speed of the cannon. (b) Determine the maximum extension of the string. (c) Find the maximum force the spring exerts on the carriage. (d) Consider the system consisting of the cannon, carriage, and projectile. Is the
momentum of this system conserved during the firing? Why or why not?
((Solution)) k = 2.00 x 104 N/m mp = 200 kg; mass for the projectile vp = 125 m/s; velocity for the projectile = 45.0°. M = 5000 kg for the cannon and carriage
(a) Use conservation of the horizontal component of momentum for the system of the
shell, the cannon, and the carriage, from just before to just after the cannon firing.
045cos recoilpp Mvvm
or
vrecoil = -3.54 m/s (b) Use conservation of energy for the system of the cannon, the carriage, and the
spring from right after the cannon is fired to the instant when the cannon comes to rest.
Ef = Ei.
where
2max
2
2
12
1
kxE
mvE
f
recoili
Then we have
mvk
mx recoil 77.1max
(c) NkxF 4
maxmax 1054.3
(d) No. The rail exerts a vertical external force (the normal force) on the cannon and prevents it from recoiling vertically. Momentum is not conserved in the vertical direction. The spring does not have time to stretch during the cannon firing. Thus, no external horizontal force is exerted on the system (cannon, carriage, and shell) from just before to just after firing. Momentum of this system is conserved in the horizontal direction during this interval. ________________________________________________________________________ Appendix A.1 Ballistic pendulum
The ballistic pendulum is an apparatus used to measure the speed of a fast-moving projectile, such as a bullet. A bullet of mass m1 is fired into a large block of wood of mass m2 suspended from some light wires. The bullet embeds in the block, and the entire system swings through a height h. The speed of the bullet can be determined from the measurement of h.
(a) Momentum conservation law on the collision
ummmvm )(0. 2121 or
21
1
mm
vmu
, (1)
where v is the velocity of bullet before the collision and u is the velocity of bullet and block. _________________________________________________________________________
_______________________________________________________________________ (b) Energy conservation law: The kinetic energy at the point A is given by
221 )(
2
1ummK A .
The potential energy at the point C is given by
ghmmUB )( 21 Then we have
ghmmumm )()(2
121
221 , (2)
where h is the height between the point A and the point B. From Eqs.(1) and (2), we have
ghm
mmv 2
1
21
.
A.2 A variable-mass drop We consider a raindrop falling through a cloud of small water droplets Some of these small droplets adhere to the raindrop, thereby increasing its mass as it falls. The force of the rain drop is
dt
dmv
dt
dvm
dt
dpFext .
Suppose the mass of the raindrops depends on the distance x that it has fallen. Then m = kx, where k is constant, and dm/dt = kv. This gives
)(kvvdt
dvmmg
or
2vdt
dvxxg
since Fext = mg. Reference: K.S. Krane, Am. J. Phys. 49, 113 (1981). We assume that v = dx/dt = v0 and x = x0 at t = 0. We solve this problem (nonlinear differential equation) using the Mathematica (NDSolve) numericallty.
0.1 0.2 0.3 0.4t
0.0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
x
Fig. x vs t, where v0 = 0 and x0 = 0.01 – 0.20 (x0 = 0.02)
0.1 0.2 0.3 0.4t
0.5
1.0
1.5
2.0
u
Fig. dx/dt vs t, where v0 = 0 and x0 = 0.01 – 0.20 (x0 = 0.02).
Raindrop
Clear"Global`"g 9.8;
timexx0_, u0_, tmax_, opts__ :
Modulenumso1, numgraph,
numso1 NDSolvext ut ut2 g xt, xt ut, x0 x0, u0 u0,
xt, ut, t, 0, tmax;
numgraph PlotEvaluatext . numso11, t, 0, tmax, opts, DisplayFunction Identitytimelistx
timex, 0, 0.4, PlotStyle Hue4.5 0.01, Thick, AxesLabel "t", "x",
Background LightGray, PlotRange All, DisplayFunction Identity & Range0.01, 0.2, 0.02; Showtimelistx, DisplayFunction $DisplayFunction
0.1 0.2 0.3 0.4t
0.0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
x
B. Center of mass frame and laboratory frame for elastic collision B.1 Momentum conservation and the energy conservation
m1 m2
v1 iL
v1 fL
v2 fL
q1L
q2L
Fig. Laboratory frame. The initial momentum is Liim 1v . The scattering angle of
the particle 1 with mass m1 is L1 .
In the laboratory frame, the velocities of the particles 1 and 2 before and after collision, are defined by
Li1v , L
i2v , Lf1v , L
f2v ,
where
02 Liv
since the particle with mass m2 is at rest before the collision. The center of mass velocity is given by
LiCM mm
m1
21
1 vv
In the center of mass frame
CMi1v , CM
i2v , CMf1v , CM
f2v ,
We have the relation
CMCMi
Li vvv 11 , CM
CMi
Li vvv 22 , (1a)
CMCM
fLf vvv 11 , CM
CMf
Lf vvv 22 , (1b)
where
LiCM
Li
CMi mm
m1
21
211 vvvv
, L
iCMLi
CMi mm
m1
21
122 vvvv
.
(i) The momentum conservation in the laboratory frame;
Lf
Lf
Li
Li mmmm 22112211 vvvv .
which means that the velocity of the center of mass remains unchanged before and after the collision. Using Eqs.(1a) and (1b), we get
)()( 221111 CMCM
fCMCM
fLi mmm vvvvv
or
0)( 21112211 CMLi
CMf
CMf mmmmm vvvv
or
02211 CMf
CMf mm vv , or CM
fCM
f m
m1
2
12 vv (2)
(ii) The energy conservation law;
222
2
11
2
22
2
11 2
1
2
1
2
1
2
1 Lf
Lf
Li
Li vmvmvmvm
Using Eqs.(1a) and (1b), we get
2112
22
2
11 2
1)(
2
1
2
1 LiCM
CMfCM
CMf mmm vvvvv
or
2112
2112112
222
11 2
1))((
2
1)()(
2
1)(
2
1 LiCMCM
CMf
CMf
CMf
CMf mmmmmmm vvvvvvv
or
212
21
2
112
222
11 2
1))((
2
1
2
1)(
2
1)(
2
1 LiCM
Li
CMf
CMf mmmmm vvvvv (3)
where is the reduced mass and is given by
21
21
mm
mm
.
Using Eqs.(2) and (3),
212
12
12
211 2
1)(
2
1)(
2
1 Li
CMf
CMf m
mmm vvv
or
2121
2121
2
212
11 2
1)(
2
1)(
2
1 Li
CMf
CMf mm
mm
m
mm vvv
or
21
121 mm
vmv
LiCM
f , and
21
112 mm
vmv
LiCM
f
and
Li
LiCM
fCMf v
mm
vmmvv 1
21
12121
)(
in magnitudes.
In conclusion we have
CMf
CMf m
m1
2
12 vv . L
iCMi mm
m1
21
12 vv
.
with
21
1211 mm
vm LiCM
iCM
f vv .
21
1122 mm
vm LiCM
iCM
f vv .
m1 m2
v1 iCM v2 i
CM
v1 fCM=v1 i
CM
v2 fCM=v2 i
CM
qCM
Fig. The center of mass frame. 21
1211 mm
vmvv
LiCM
fCMi
,
CM
LiCM
fCMi v
mm
vmvv
21
1122 . L
iCMi
CMi
CMf
CMf vvvvv 12121 . The scattering
angle of the particle 1 with mass m1 is CM . Note that
Li
Li
Li
CMf
CMf
CMCM
fCMCM
fLf
Lf
vmm
vm
mm
vm1
21
12
21
11
12
1212
||
)()(
vv
vvvvvv
Li
Li
Li
CMi
CMi
CMCMiCM
CMi
Li
Li
v
mm
m
mm
m
1
121
21
21
1
12
1212 )()(
vv
vv
vvvvvv
That is, the rate at which two objects approach each other before an elastic collision is the same at the rate at which they separate afterward. We can use this result to identify elastic collisions in any inertial reference frame. Namely, the relative velocity of two objects at a given time, that is, the difference in the velocity vectors of the objects must be the same in all inertial reference frames. B.2 Scattering angles CM , L
1 and L2
The y and z components of CMfv1 and CM
fv2 ;
CMLiCMCM
fy
CMf mm
vmv sinsin
21
1211
v
CMLiCMCM
fz
CMf mm
vmv coscos
21
1211
v
CMLiCMCM
fy
CMf mm
vmv sinsin
21
1122
v
CMLiCMCM
fz
CMf mm
vmv coscos
21
1122
v
where the z axis is in the horizontal direction and the y axis is in the vertical direction. Using Eq.(1b), we have
CMCM
fLf vvv 11 , CM
CMf
Lf vvv 22 ,
or
CMLiCMCM
fyCMy
CMfy
Lf mm
vmv sinsin
21
12111
vvv
Li
CM
LiCM
Li
CMCMCM
f
zCMz
CMfz
Lf
vmm
mm
mm
vm
mm
vm
vv
121
21
21
11
21
12
1
11
)cos(
cos
cos
vvv
CMLi
yCMy
CMfy
Lf mm
vm sin21
1122
vvv
Li
CM
LiCM
Li
zCMz
CMfz
Lf
vmm
mm
mm
vm
mm
vm
121
11
21
11
21
11
22
)cos(
cos
vvv
where
LiCM mm
m1
21
1 vv
.
The scattering angle in the laboratory scheme is obtained as
CM
CM
z
Lf
y
LfL
mm
m
cos
sintan
21
2
1
1
1
v
v
2cot
cos1
sin
cos
sintan
11
1
2
2
2
CM
CM
CM
CM
CM
z
Lf
y
LfL
mm
m
v
v
When m1 = m2, we have
2
tan
2cos2
2cos
2sin2
cos1
sintan
21
CM
CM
CMCM
CM
CML
.
Then we have
221
LL
since
1tantan 21 LL .
vCM
v2 fCM=vCM v1 f
CM
v1 iL
v1 fCM
qCM qL
m2m1 =2
Fig. The relation between scattering angle in the laboratory frame and in the
center of mass frame. 21
1211 mm
vmvv
LiCM
fCMi
, CM
LiCM
fCMi v
mm
vmvv
21
1122 .
CMf
CMf
Li vvv 211 . CM
iCMi
Li vvv 211 . In this figure, we assume that m2/m1 = 2.
APPENDIX C Energy of a system of many particles The kinetic energy of many particles is given by
i
iiimK )(2
1vv
The velocity in the laboratory frame iv is given by
CMiCMi vvv
where vCM is the velocity of the center of mass and CM
iv is the velocity in the center of
mass frame. Then K can be rewritten as
CMrel
i
CMiiCM
iCM
CMii
i
CMiiCM
i
CMiCM
CMiCMi
i
CMiCM
CMiCMi
KK
mM
mmM
m
mK
22
22
22
)(2
1
2
1
)()(2
1
2
1
)2[2
1
)()(2
1
vv
vvvv
vvvv
vvvv
where
0)( CMCMi i
CMiiCMii MMmm vvvvv
Then K consists of the kinetic energy of the center of mass (KCM) and the kinetic energy of the objects as viewed in the center of mass frame (Krel).