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2 years ago

You're riding a unicorn at 25 m/s and come to a uniform stop at a red light 20m away. What's your acceleration?

Physics

2 answers:

NNADVOKAT [17]2 years ago

8 0

The answer is -15.625m/s².

Acceleration is the change in velocity over a period of time. It can be computed using the formula:

$a = \dfrac{vf-vi}{t}$

Where:

vf = final velocity

vi = initial velocity

t = time

Now let's see what was given in your problem:

The car was moving at 25m/s and then came to a stop. So initially it was moving and then it stopped. This means the final velocity will be 0m/s because it stopped moving.

But look at the problem, it shows no time. We need to solve for time from the time it moved till it reached the red light 20 m away.

Time can be computed using the kinematics formula:

$d = \dfrac{vi+vf}{2} *t$

We just derive the formula from the equation by filling out what we know first.

$20m = \dfrac{25m/s+0m/s}{2}(t)$

$20m = 12.5m/s{2}(t)$

$\dfrac{20m}{12.5m/s}=t$
$1.6s=t$

The time it took from the point it was moving till it stopped is 1.6s. We can now use this in our acceleration formula.

$a = \dfrac{0m/s-25m/s}{1.6s}$

$a = \dfrac{-25m/s}{1.6s}$

$a = -15.625m/s^{2}$

Notice that the acceleration is negative. This means that the car decelerated or slowed down.

strojnjashka [21]2 years ago

5 0

Answer:

My acceleration is 15.63 m/s² (slowing down)

Explanation:

The expression for the acceleration is equal:

$v^{2} _{f} -v^{2} _{i} =2ax$

Where

vi = initial speed = 25 m/s

vf = final speed = 0

x = displacement = 20 m

Replacing and clearing the acceleration "a":

$a=\frac{v^{2} _{f} -v^{2} _{i} }{2x} =\frac{0-25^{2} }{2*20} =--15.63m/s^{2}$

The negative sign of acceleration means that it is slowing down

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natta225 [31]

Answer:

The correct option is;

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Explanation:

Given that the thermal energy of the system is the energy possessed by the system by virtue of the increased motion of the particles by virtue of a transfer of heat, when the content of the system is heated

The thermal energy, Q is given by the following equation;

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Given that the graduated cylinder with more water has more mass and therefore, more water molecules, than the cylinder with less water, the cylinder with more water has more thermal energy.

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A hot piece of iron is thrown into the ocean and its temperature eventually stabilizes. Which of the following statements concer

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E. The ocean gains more entropy than the iron loses.

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Answer:

the length of the now stationary spacecraft = 89.65m

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Where in this question;

L = 71m and v = 0.610 c

Thus;

71 = L_o (√(1 - ((0.61c)²/c²))

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2 years ago

A stationary particle of charge q = 2.1 × 10-8 c is placed in a laser beam (an electromagnetic wave) whose intensity is 2.9 × 10

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(a) The intensity of the electromagnetic wave is related to the amplitude of the electric field by
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where
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$\epsilon_0$ is the electric permittivity
E is the amplitude of the electric field

By substituting the numbers of the problem and re-arranging the equation, we can find E:
$E= \frac{2 I}{c \epsilon_0} = \frac{2 ( 2.9 \cdot 10^3 Wm^{-2})}{(3 \cdot 10^8 m/s)(8.85 \cdot 10^{-12} Fm^{-1})} =2.2 \cdot 10^6 N/C$

Now that we have the intensity of the electric field, we can calculate the electric force on the charge:
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(b) We can calculate the amplitude of the magnetic field starting from the amplitude of the electric field:
$B= \frac{E}{c}= \frac{2.2 \cdot 10^6 N/C}{3 \cdot 10^8 m/s}=7.3 \cdot 10^{-3} T$

The magnetic force is given by
$F=qvB \sin \theta$
where v is the particle's speed, B the magnetic field intensity and $\theta$ the angle between B and v.
In this case the charge is stationary, so v=0, and so the magnetic force is zero: F=0.

(c) The electric force has not changed compared to point (a), because it does not depend on the speed of the particle, so we have again F=0.046 N.

(d) This time, the particle is moving with speed $v=3.7 \cdot 10^4 m/s$ , in a direction perpendicular to the magnetic field (so, the angle $\theta$ is $90^{\circ}$ ), and so by using the intensity of the magnetic field we found in point (b), we can calculate the magnetic force on the particle:
$F=qvB \sin \theta = (2.1 \cdot 10^{-8}C)(3.7 \cdot 10^4 m/s)(7.3 \cdot 10^{-3} T)(\sin 90^{\circ} )=$
$=5.7 \cdot 10^{-6} N$

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2 years ago