Answer:The gravitational force between two masses can be calculated using Newton's law of universal gravitation:
�
=
�
⋅
�
1
⋅
�
2
�
2
F=
r
2
G⋅m
1
⋅m
2
Where:
�
F is the gravitational force (1.05 × 10^4 N)
�
G is the gravitational constant (
6.674
×
1
0
−
11
N
⋅
m
2
/
kg
2
6.674×10
−11
N⋅m
2
/kg
2
)
�
1
m
1
is the mass of one asteroid (3.5 × 10^6 kg)
�
2
m
2
is the mass of the other asteroid (unknown)
�
r is the distance between the asteroids (100,000 m)
First, rearrange the equation to solve for the mass of the second asteroid (
�
2
m
2
):
�
2
=
�
⋅
�
2
�
⋅
�
1
m
2
=
G⋅m
1
F⋅r
2
Now plug in the values:
�
2
=
1.05
×
1
0
4
N
⋅
(
100
,
000
m
)
2
6.674
×
1
0
−
11
N
⋅
m
2
/
kg
2
⋅
3.5
×
1
0
6
kg
m
2
=
6.674×10
−11
N⋅m
2
/kg
2
⋅3.5×10
6
kg
1.05×10
4
N⋅(100,000m)
2
Calculating this gives:
�
2
≈
4.5
×
1
0
9
kg
m
2
≈4.5×10
9
kg
So, the mass of the other asteroid is approximately
4.5
×
1
0
9
kg
4.5×10
9
kg, which matches option B:
4.5
×
1
0
9
kg
4.5×10
9
kg.