Review. There are (one can say) three coequal theories of motion for a single particle: Newton’s second law, stating that the total force on the particle causes its acceleration; the work–kinetic energy theorem, stating that the total work on the particle causes its change in kinetic energy; and the impulse–momentum theorem, stating that the total impulse on the panicle causes its change in momentum. In this problem, you compare predictions of the three theories in one particular case. A 3.00-kg object has velocity 7.00 j ^ m / s . Then, a constant net force 12.0 i ^ N acts on the object for 5.00 s. (a) Calculate the object’s final velocity, using the impulse–momentum theorem. (b) Calculate its acceleration from a → = ( v → f − v → i ) / Δ t . (c) Calculate its acceleration from a → = ∑ F → / m . (d) Find the object’s vector displacement from Δ r → = v → i t + 1 2 a → t 2 (e) Find the work done on the object from W = F → ⋅ Δ r → . (f) Find the final kinetic energy from 1 2 m v f 2 = 1 2 m v → f ⋅ v → f . (g) Find the final kinetic energy from 1 2 m v i 2 + W . (h) State the result of comparing the answers to parts (b) and (c), and the answers to parts (f) and (g).
Review. There are (one can say) three coequal theories of motion for a single particle: Newton’s second law, stating that the total force on the particle causes its acceleration; the work–kinetic energy theorem, stating that the total work on the particle causes its change in kinetic energy; and the impulse–momentum theorem, stating that the total impulse on the panicle causes its change in momentum. In this problem, you compare predictions of the three theories in one particular case. A 3.00-kg object has velocity 7.00 j ^ m / s . Then, a constant net force 12.0 i ^ N acts on the object for 5.00 s. (a) Calculate the object’s final velocity, using the impulse–momentum theorem. (b) Calculate its acceleration from a → = ( v → f − v → i ) / Δ t . (c) Calculate its acceleration from a → = ∑ F → / m . (d) Find the object’s vector displacement from Δ r → = v → i t + 1 2 a → t 2 (e) Find the work done on the object from W = F → ⋅ Δ r → . (f) Find the final kinetic energy from 1 2 m v f 2 = 1 2 m v → f ⋅ v → f . (g) Find the final kinetic energy from 1 2 m v i 2 + W . (h) State the result of comparing the answers to parts (b) and (c), and the answers to parts (f) and (g).
Review. There are (one can say) three coequal theories of motion for a single particle: Newton’s second law, stating that the total force on the particle causes its acceleration; the work–kinetic energy theorem, stating that the total work on the particle causes its change in kinetic energy; and the impulse–momentum theorem, stating that the total impulse on the panicle causes its change in momentum. In this problem, you compare predictions of the three theories in one particular case. A 3.00-kg object has velocity
7.00
j
^
m
/
s
. Then, a constant net force
12.0
i
^
N
acts on the object for 5.00 s. (a) Calculate the object’s final velocity, using the impulse–momentum theorem. (b) Calculate its acceleration from
a
→
=
(
v
→
f
−
v
→
i
)
/
Δ
t
. (c) Calculate its acceleration from
a
→
=
∑
F
→
/
m
. (d) Find the object’s vector displacement from
Δ
r
→
=
v
→
i
t
+
1
2
a
→
t
2
(e) Find the work done on the object from
W
=
F
→
⋅
Δ
r
→
. (f) Find the final kinetic energy from
1
2
m
v
f
2
=
1
2
m
v
→
f
⋅
v
→
f
. (g) Find the final kinetic energy from
1
2
m
v
i
2
+
W
. (h) State the result of comparing the answers to parts (b) and (c), and the answers to parts (f) and (g).
(a)
Expert Solution
To determine
The final velocity of the object.
Answer to Problem 9.90AP
The final velocity of the object is (20i^+7j^)m/s.
Explanation of Solution
The mass of the object is 3kg, the velocity of the object is 7j^m/s and the net force acting on the object is 12i^N. The time duration is 5s.
Write the expression of impulse momentum equation.
m(vf→−vi→)=F→⋅Δt (1)
Here, m is the mass of the object, vf→ is the final velocity of the object, vi→ is the initial velocity of the object, F→ is the net force acting on the object and Δt is the time duration.
Conclusion:
Substitute 3kg for m, 7j^m/s for vi→, 12i^N for F→ and 5s for Δt in equation (1) to find vf→.
3kg(vf→−7j^m/s)=12i^N×5svf→=(20i^+7j^)m/s
Thus, the final velocity of the object is (20i^+7j^)m/s.
(b)
Expert Solution
To determine
The acceleration of the object.
Answer to Problem 9.90AP
The acceleration of the object is 4i^m/s2.
Explanation of Solution
Write the expression to calculate the acceleration of the object.
a→=(vf→−vi→)Δt (2)
Here,
a→ is the acceleration of the object.
Substitute 7j^m/s for vi→, (20i^+7j^)m/s for vf→ and 5s for Δt in equation (2) to find a→.
a→=(20i^+7j^)m/s−7j^m/s5s=4i^m/s2
Thus, the acceleration of the object is 4i^m/s2.
Conclusion:
Therefore, the acceleration of the object is 4i^m/s2.
(c)
Expert Solution
To determine
The acceleration of the object.
Answer to Problem 9.90AP
The acceleration of the object is 4i^m/s2.
Explanation of Solution
Write the expression to calculate the acceleration of the object.
a→=∑F→m (3)
Substitute 12i^N for ∑F→ and 3kg for m in equation (3) to find a→.
a→=12i^N3kg=4i^m/s2
Thus, the acceleration of the object is 4i^m/s2.
Conclusion:
Therefore, the acceleration of the object is 4i^m/s2.
(d)
Expert Solution
To determine
The vector displacement of the object.
Answer to Problem 9.90AP
The vector displacement of the object is (50i^+35j^)m.
Explanation of Solution
Write the expression to calculate the vector displacement of the object.
r→=vi→t+12a→t2 (4)
Here,
r→ is the vector displacement of the object.
Substitute 7j^m/s for vi→, 4i^m/s2 for a→ and 5s for t in equation (4) to find r→.
r→=7j^m/s×5s+12×4i^m/s2×(5s)2=(50i^+35j^)m
Thus, the vector displacement of the object is (50i^+35j^)m.
Conclusion:
Therefore, the vector displacement of the object is (50i^+35j^)m.
(e)
Expert Solution
To determine
The work done on the object.
Answer to Problem 9.90AP
The work done on the object is 600J.
Explanation of Solution
Write the expression to calculate the work done on the object.
W=F→⋅Δr→ (5)
Here,
W is the work done on the object.
Substitute 12i^N for F→ and (50i^+35j^)m for Δr→ in equation (5) to find W.
W=12i^N⋅(50i^+35j^)m=600J
Thus, the work done on the object is 600J.
Conclusion:
Therefore, the work done on the object is 600J.
(f)
Expert Solution
To determine
The final kinetic energy of the object.
Answer to Problem 9.90AP
The final kinetic energy of the object is 674J.
Explanation of Solution
Write the expression to calculate the final kinetic energy of the object.
E=12mvf2=12mvf→⋅vf→ (6)
Substitute 3kg for m and (20i^+7j^)m/s for vf→ in equation (6) to find E.
a cubic foot of argon at 20 degrees celsius is isentropically compressed from 1 atm to 425 KPa. What is the new temperature and density?
Calculate the variance of the calculated accelerations. The free fall height was 1753 mm. The measured release and catch times were:
222.22 800.00
61.11 641.67
0.00 588.89
11.11 588.89
8.33 588.89
11.11 588.89
5.56 586.11
2.78 583.33
Give in the answer window the calculated repeated experiment variance in m/s2.
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