Magnet A has twice the magnetic field strength of Magnet B and at a certain distance pulls on magnet B with a force of 100 N. The amount of force that magnet A exerts on magnet B is A. at or about 50 N. B. exactly 100 N. C. more information is needed.
Answers
Answer:
50 N is the correct answer.
Related Questions
There are some cases where distance time graph of a particle is vertical . So could you please tell me when it is possible????
Which type of galaxy has arms that contain sites of active star formation and start close to a bulge in the center?A. ellipticalB. irregularC. barred spiralD. normal spiral
a bullet of mass m is fired into a block of mass m that is at rest. the block, with the bullet embedded, slides distance d across a horizontal surface. the coefficient of kinetic friction is μk.
Which unit is used to measure mass in the metric system
Answers
Answer:
0.7 hours
Explanation:
From the way back, we can calculate the distance between Irina's work and Irina's home. In fact, we know that the car takes 0.4 hourse traveling at 27 mph, so the distance covered should be
When Irina rides to work with her bike, she travels at a speed of 16 mph. So we can find the time she takes by dividing the total distance (10.8 miles) by her speed:
Time taken by Irina to reach home = 0.4 hour.
Then
In 1 hour the car traveled for a distance = 27 miles
So in 0.4 hour, the distance traveled by the car = 27 * 0.4 miles
= 10.8 miles
Now
While traveling to office, Irina travels 16 miles in = 1 hour
So
Irina travels 10.8 miles in = (16/10.8) hours
= 1.48 hours.]
So Irina takes 1.48 hours of bike riding to reach her place of work.
B).The Earth is Round
C).Force of Gravity Between 2 objects Decreases with Distance
D).Planets Move in circles
Answers
Kepler's first "law":
The orbits of the planets are ellipses, with the sun at one focus.
This would include Mars.
Explain why ultra-high voltages are
used to carry electricity over transmission lines.
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B. 3.8 m/s2
C. 2.4 m/s2
D. 9.8 m/s2
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Acceleration due to gravity on this planet will be 3.802 m / s^2
What are equations of motion?
Equation of motion are defined as equations that describe the behavior of a physical system in terms of its motion as a function of time
Using equation of motion
u=0
s= 2.3 m
t = 1.1 sec
to find = g (acceleration due to gravity on this planet)
s = u t + 1/2 (a ) (t ^(2))
s = 1/2 (g) (t^2)
2.3 = 1/2 (g) (1.1^2)
g = 2 * 2.3 /(1.1)^2
g = 4.6 /1.21= 3.802
correct answer is b) g = 3.802 m / s^2
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Answers
Part A: The enmeshed cars were moving at a velocity of approximately 8.66 m/s just after the collision.
Part B: Car A was traveling at a velocity of approximately 8.55 m/s just before the collision.
How to compute the above velocities
To find the speed of car A just before the collision in Part B, you can use the principle of conservation of momentum.
The total momentum of the system before the collision should equal the total momentum after the collision. You already know the total momentum after the collision from Part A, and now you want to find the velocity of car A just before the collision.
Let's denote:
- v_A as the initial velocity of car A before the collision.
- v_B as the initial velocity of car B before the collision.
In Part A, you found that the enmeshed cars were moving at a velocity of 8.66 m/s at an angle of 60 degrees south of east. You can split this velocity into its eastward and southward components. The eastward component of this velocity is:
v_east = 8.66 m/s * cos(60 degrees)
Now, you can use the conservation of momentum to set up an equation:
Total initial momentum = Total final momentum
(mass_A * v_A) + (mass_B * v_B) = (mass_A + mass_B) * 8.66 m/s (the final velocity you found in Part A)
Plug in the known values:
(1900 kg * v_A) + (1500 kg * v_B) = (1900 kg + 1500 kg) * 8.66 m/s
Now, you can solve for v_A:
(1900 kg * v_A) + (1500 kg * v_B) = 3400 kg * 8.66 m/s
1900 kg * v_A = 3400 kg * 8.66 m/s - 1500 kg * v_B
v_A = (3400 kg * 8.66 m/s - 1500 kg * v_B) / 1900 kg
Now, plug in the values from Part A to find v_A:
v_A = (3400 kg * 8.66 m/s - 1500 kg * 8.66 m/s) / 1900 kg
v_A = (29244 kg*m/s - 12990 kg*m/s) / 1900 kg
v_A = 16254 kg*m/s / 1900 kg
v_A ≈ 8.55 m/s
So, car A was going at approximately 8.55 m/s just before the collision in Part B.
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Answers
Answer:
1.1 x 10⁵m/s²
Explanation:
Given parameters:
Velocity = 452m/s
distance = 0.93m
Unknown:
Acceleration of the bullet = ?
Solution:
To solve this problem, we use one of the kinematics equation which is given below:
V² = U² + 2aS
V is the final velocity
U is the initial velocity = 0m/s
a is the unknown acceleration
S is the distance traveled
So;
452² = 0² + (2 x a x 0.93)
204304 = 1.86a
a = 1.1 x 10⁵m/s²
Final answer:
The acceleration of the bullet in the gun barrel can be calculated using the kinematic equation for motion. By substituying the given values into the equation, we find the acceleration to be approximately 1.095 x 10^5 m/s^2.
Explanation:
The subject of this question is Physics, specifically a topic under mechanics known as kinematics. The problem given can be solved using kinematic equations which are used to describe the motion of an object without considering the forces that cause it to move. In this case, the final velocity (vf) of the bullet is given as 452 m/s, the initial velocity (vi) is assumed to be 0 as it starts from rest, and the distance (d) is given as 0.93 m. We are asked to determine the value of acceleration (a).
Using the kinematic equation vf2 = vi2 + 2ad and substituting the given values, we get (452 m/s)2 = 0 + 2*a*0.93 m. We can rearrange to solve for acceleration to get: a = (452 m/s)2 / (2*0.93 m) = 109523.66 m/s2.
So, the acceleration of the bullet in the gun barrel is approximately 1.095 x 105 m/s2.
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