Respuesta :
Answer:
(a) r = 1.062·R[tex]_E[/tex] = [tex]\frac{531}{500} R_E[/tex]
(b) r = [tex]\frac{33}{25} R_E[/tex]
(c) Zero
Explanation:
Here we have escape velocity v[tex]_e[/tex] given by
[tex]v_e =\sqrt{\frac{2GM}{R_E} }[/tex] and the maximum height given by
[tex]\frac{1}{2} v^2-\frac{GM}{R_E} = -\frac{GM}{r}[/tex]
Therefore, when the initial speed is 0.241v[tex]_e[/tex] we have
v = [tex]0.241\times \sqrt{\frac{2GM}{R_E} }[/tex] so that;
v² = [tex]0.058081\times {\frac{2GM}{R_E} }[/tex]
v² = [tex]{\frac{0.116162\times GM}{R_E} }[/tex]
[tex]\frac{1}{2} v^2-\frac{GM}{R_E} = -\frac{GM}{r}[/tex] is then
[tex]\frac{1}{2} {\frac{0.116162\times GM}{R_E} }-\frac{GM}{R_E} = -\frac{GM}{r}[/tex]
Which gives
[tex]-\frac{0.941919}{R_E} = -\frac{1}{r}[/tex] or
r = 1.062·R[tex]_E[/tex]
(b) Here we have
[tex]K_i = 0.241\times \frac{1}{2} \times m \times v_e^2 = 0.241\times \frac{1}{2} \times m \times \frac{2GM}{R_E} = \frac{0.241mGM}{R_E}[/tex]
Therefore we put [tex]\frac{0.241GM}{R_E}[/tex] in the maximum height equation to get
[tex]\frac{0.241}{R_E} -\frac{1}{R_E} =-\frac{1}{r}[/tex]
From which we get
r = 1.32·R[tex]_E[/tex]
(c) The we have the least initial mechanical energy, ME given by
ME = KE - PE
Where the KE = PE required to leave the earth we have
ME = KE - KE = 0
The least initial mechanical energy to leave the earth is zero.
Answer:
a. 1.06R b. 1.32R c. GMm/R
Explanation:
a. Considering the conservation of mechanical energy,
K₁ + U₁ = K₂ + U₂ (1)where K₁ and K₂ = initial and final kinetic energies of projectile, and U₁ and U₂ = initial and final potential energies of projectile
K₁ = 1/2mv², K₂ = 0, U₁ = -GMm/R where R = radius of earth , U₂ = '-GMm/r where r = radius at maximum height.
So, inputting the variables into (1), we have
1/2mv² - GMm/R = 0 - GMm/r
1/2mv² = -GMm/r + GMm/R (2)
Now v = 0.241v₁ where v₁ =√(2GM/R) escape velocity
Substituting v into (2) above, we have
1/2m[0.241√(2GM/R)]² = -GMm/r + GMm/R
0.058GMm/R = -GMm/r + GMm/R
GMm/r = GMm/R -'0.058GMm/R
GMm/r = 0.942GMm/R
r = R/0.942
r = 1.06R
b. When K₁ = 0.241K wh6ere K = escape kinetic energy = GMm/R. So
K₁ + U₁ = K₂ + U₂
0.241GMm/R -'GMm/R = 0 -' GMm/r
-'0.759GMm/R = '-GMm/r
r = R/0.759 = 1.32R
c. If it is to escape earth, its initial velocity must equal the escape velocity.
So its least initial mechanical energy is its escape kinetic energy
1/2m[√(2GM/R)]² = GMm/R
