A LOT OF POINTS!! Best answer gets brainliest!

1) Which two of the following factors affect the momentum of an object: speed, velocity, mass, shape?

2) Can a small object can have a large momentum? Give an example.

3) How could you change the momentum of an object? What would you need to change?

4) A 5000kg truck and a 50 kg person have the same momentum. How is this possible?

Answer:

122444 Kg

Explanation:

Using the formula for gravitational force;

F= Gm1m2/r^2

Given that

G = constant of gravitation = 6.67 × 10−11 newton-metre2-kilogram−2.

m1 and m2 = the masses

r= distance of separation

Note that the question specifically mentioned that the masses are identical

so m1=m2 = m^2

F= Gm^2/r^2

Fr^2 = Gm^2

m^2 = Fr^2/G

m^2 = 1 × 1^2/6.67 × 10−11:

m =√ 6.67 × 10−11

m= 122444 Kg

When the object is at rest, there is a zero net force due the cancellation of the object's weight w with the normal force n of the table pushing up on the object, so that by Newton's second law,

∑ F = n - w = 0   →   n = w = mg = 112.5 N ≈ 113 N

where m = 12.5 kg and g = 9.80 m/s².

The minimum force F needed to overcome maximum static friction f and get the object moving is

F > f = 0.50 n = 61.25 N ≈ 61.3 N

which means a push of F = 15 N is not enough the get object moving and so it stays at rest in equilibrium. While the push is being done, the net force on the object is still zero, but now the horizontal push and static friction cancel each other.

So:

(a) Your free body diagram should show the object with 4 forces acting on it as described above. You have to draw it to scale, so whatever length you use for the normal force and weight vectors, the length of the push and static friction vectors should be about 61.3/112.5 ≈ 0.545 ≈ 54.5% as long.

(b) Friction has a magnitude of 15 N because it balances the pushing force.

(c) The object is in equilibrium and not moving, so the acceleration is zero.

Answer:

The correct answer is - the sound waves make vibration that travels through the string.

Explanation:

When an individual person talks into your paper cup telephone the person on the other end can feel the bottom of their cup vibrate. The sound waves create vibration go through the string that travels through the string to the end of the cup where vibrations can feel.

The sound waves are longitudinal waves that move or travel through different mediums like air, solid, or gas. The waves create vibration in the particles.

You could create a paper cup telephone but instead of using string, test out different materials and see if those materials will allow sound vibrations to travel through them

Explanation:

The mass of a truck = 5000 kg

Mass of a person = 50 kg

The momentum of a body is given by :

p = mv

m is mass

If momentum of the truck and the person is same. Let v₁ and v₂ are velocity of the truck and the person.

[tex]5000\times v_1=50\times v_2\\\\\dfrac{v_1}{v_2}=\dfrac{50}{5000}\\\\\dfrac{v_1}{v_2}=\dfrac{1}{100}\\\\v_2=100v_1[/tex]

So, it can only possible if the velocity of the person is 100 times of the velocity of the truck.

Answer:

(1)Work done by snail is 382.5 N

(2)Work done by ELEPHANT is 25160 N

(3)Work done by HANS is 2420 N

(4)Work done on block is 433 N

Explanation:

The work done due to force F applied at an angle θ from the horizontal to the body is give by

Work done = Fscosθ where, s is distance traveled by body

Case 1: F= 255N , s= 3.00m and θ = 60.[tex]0^0[/tex]

Work done = Fscosθ = 255 x 3.00 x cos60.[tex]0^0[/tex] = 382.5N

thus work done by snail is 382.5 N

Case 2: F= 200N , s= 150m and θ = 33.[tex]0^0[/tex]

Work done = Fscosθ = 200 x 150 x cos33.[tex]0^0[/tex] = 25160N

thus work done by elephant is 25160 N

Case 3: F= 22.9N , s= 129m and θ = 35.[tex]0^0[/tex]

Work done = Fscosθ = 22.9 x 129 x cos35.[tex]0^0[/tex] = 2420N

thus work done by Hans is 2420 N

Case 4: F= 100N , s= 5m and θ = 30.[tex]0^0[/tex]

Work done = Fscosθ = 100 x 5.00 x cos30.[tex]0^0[/tex] = 433N

thus work done on block is 433 N

(1)  The work done by the sailor is 382.5 J.

(2)  The work done by elephant is 25160 J.

(3) The work done by Hans upon the backpack is 2420 J.

(4)  The required work done on block is 433 J.

Let us solve these questions in parts. All these questions are based on the work done. The work done due to force F applied at an angle θ from the horizontal to the body is give by,

[tex]W =F \times s \times cos \theta[/tex]

Here, s is the distance covered by the body.

(1)

Given data:

F= 255N , s= 3.00m and θ = 60.

The work done is calculated as,

W = Fscosθ

W= 255 x 3.00 x cos60 = 382.5 J.

Thus, the work done by the sailor is 382.5 J.

(2)

Given data:

F= 200N , s= 150m and θ = 33.

The work done by the elephant is calculated as,

W = Fscosθ

W= 200 x 150 x cos33. = 25160 J

Thus, the work done by elephant is 25160 J.

(3)

Given data:

F= 22.9N , s= 129m and θ = 35.

Then the work done upon the backpack is calculated as,

W= Fscosθ

W= 22.9 x 129 x cos35. = 2420 J

Thus, the work done by Hans upon the backpack is 2420 J.

(4)

Given data:

F= 100N , s= 5m and θ = 30.

The work done is calculated as,

W = Fscosθ

W= 100 x 5.00 x cos30. = 433 J

Thus, the required work done on block is 433 J.

Learn more about the work done here:

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Answer:

1.1x10^-4 N

Explanation:

F = G[(m_1*m_2)/r^2]

G = Gravitational constant 6.67433x10^-11 (N*m^2)/(kg^2)

m_1 = mass 1

m_2 = mass 2

r = radius between objects

F = G[(0.5kg*0.33kg)/(0.001m)^2]

F = 1.1x10^-4 N

Answer:

True

Explanation:

Answer:

Momentum, p = 23250 kg m/s

Explanation:

Given that

Mass of a car, m = 1550 kg

Speed pf car, v = 15 m/s

We need to find the momentum of the car. The formula for the momentum of an object is given by :

p = mv

Substituting all the values in the above formula

p = 1550 kg × 15 m/s

p = 23250 kg m/s

So, the momentum of the car is 23250 kg m/s.

Answer:

Distance.  A light-year is the distance a single photon of light can travel in empty space in a year.

Answer:

D-Distance

Explanation:

Answer:

Explanation:

Crinoid fossils can be found on the shore of Lake Michigan because during the Carboniferous period, all of what is now the United States, except for a small part of the upper Midwest, and all of the states along the East Coast, except for Florida, was covered by a warm, shallow inland sea(seawater), and since crinoid fossils live in sea water, they washed up on many places like Lake Michigan.

Answer:

Explanation:

Crinoid fossils can be found on the shore of Lake Michigan because during the Carboniferous period, all of what is now the United States, except for a small part of the upper Midwest, and all of the states along the East Coast, except for Florida, was covered by a warm, shallow inland sea(seawater), and since crinoid fossils live in sea water, they washed up on many places like Lake Michigan.

Answer:

1.429*10^-5 m

Explanation:

From the question, we are given that

Diameter of the cable, d = 3 cm = 0.03 m

Force on the cable, F = 2 kN

Young Modulus, Y = 2*10^11 Pa

Area of the cable = πd²/4 = (3.142 * 0.03²) / 4 = 0.0028 / 4 = 0.0007 m²

The fractional length = Δl/l

Δl/l = F/AY

Δl/l = 2000 / 0.0007 * 2*10^11

Δl/l = 2000 / 1.4*10^8

Δl/l = 1.429*10^-5 m

Therefore, the fractional length is 1.429*10^-5 m long

Answer:

8

Explanation:

Answer:

rotational equilibrium

Explanation:

Answer:

Explanation:

The work done by an object can be found by using the formula

workdone = force × distance

From the question we have

workdone = 5000 × 15

We have the final answer as

Hope this helps you

Answer:

F = 250 [N] (Force exerted by Sunita)

Explanation:

First we must understand the use of the lever, in the attached picture we see that it is fulcrum and other features.

The moment that the load exerts with respect to the fulcrum should be calculated, as the distance is 1 [m].

[tex]M=F*d\\M=1000*1\\M=1000[N*m][/tex]

Now Sunita must exert the same moment using the remaining distance (4 [m]).

[tex]1000=F_{sunita}*4\\F_{sunita}=1000/4\\F_{sunita}=250 [N][/tex]

Answer:

yes

Explanation:

if your destination is on the top floor, but you are facing towards the bottom floor, you are facing the wrong way. It's all relative. Honestly, I hate this question, because then it turns into, is it possible to go backwards anywhere. Backwards and forwards, right and left, it's all relative to which way you are facing and where you want to go. If something is on the left and you turn 180 degrees, then that thing is on the right. If you are going forward towards your house and you turn around, you are now going backwards, relative to your house. But if your perspective is relative to that tree in the opposite direction of your house, you are now facing the right way. See, it's all relative to where you are going.

Answer:

.

Explanation:

Answer:

5m/s/s

Explanation:

The units for velocity is m/s.

The units for acceleration is m/s/s

So, Determine the change in velocity and divide it by the time that change took place.

(30m/s - 10m/s)/4s = 20m/s/(4s) = 5m/s/s

Answer:

[tex]P_2 - P_1 = 1.8 * 10^4\ Pa[/tex]

Explanation:

Given

[tex]Height (h) = 1.70m[/tex]

Required

Determine the difference in the blood pressure from feet to top

This is calculated using Pascal's second law.

The second law is represented as:

[tex]P_2 = P_1 + pgd[/tex]

Subtract P1 from both sides

[tex]P_2 - P_1 = pgd[/tex]

Where

[tex]p = blood\ density = 1.06 * 10^3kg/m^3[/tex]

[tex]g = acceleration\ of\ gravity = 9.8N/kg[/tex]

[tex]d =height = 1.70m[/tex]

P2 - P1 = Blood Pressure Difference

So, the expression becomes:

[tex]P_2 - P_1 = 1.06 * 10^3 * 9.8 * 1.70[/tex]

[tex]P_2 - P_1 = 17659.6Pa[/tex]

[tex]P_2 - P_1 = 1.8 * 10^4\ Pa[/tex]

Hence, the difference in blood pressure is approximately [tex]1.8 * 10^4\ Pa[/tex]

Answer:

5.99 m  = 6 m

Explanation:

PE = m*g*h

235.2 J = (4 kg)(9.81 m/s^2)(h)

h = (235.2 J)/(9.81*4)

h = 5.99 m

h = 6 m

Answer:

The y-axis represents position relative to the starting point, and the x-axis represents time.

Explanation:

Answer:

Explanation:

From the given information; the diagram below shows a clearer understanding.

The blood pressure in the brain [tex]P_{brain} = P_{heart} - \delta ( a - g ) h[/tex]

= 13300 - 1060 (12-9.81) 0.35

=  13300 -  1060 (2.19) 0.35

= 13300 - 812.49

= 12487.51  Pa

The blood pressure in the feet [tex]P_{feet} = P_{heart} + \delta (a + g) h[/tex]

= 13300 + 1060 (12 + 9.81) 1.45

= 13300 + 1060( 21.81 ) 1.45

= 13300 + 33521.97

= 46821.97 Pa

Answer:

Explanation:

[tex]P_brain = P_heart - y(a - g)h\\\\P_brain = 13300 - 1060 (12-9.81)0.35\\\\P_brain = 12487.51 pa\\\\[/tex]

[tex]P_feet = P_heart + y(a+g)*h_r\\\\P_feet = 13300 + 1060(12+9.81)*(1.8-0.35)\\\\P_feet = 46821.97pa[/tex]

For more information, visit

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Answer:

Power = 0.25 Watts

Explanation:

Given:

Work done = 0.50 Joule of work

Time taken = 2.0 second

Find:

Power

Computation:

Power = Work done / Time taken

Power = 0.50 J / 2

Power = 0.25 Watts

If the tired squirrel does all this work in 2 seconds with work of 0.5 J the power is 0.25 Watts.

Given:

Mass, m = 1 kg

Work, W = 0.5 J

Time, t = 2 s

The concept of power, which measures the pace at which work is done or the rate at which energy is transmitted or converted, is crucial to physics. It measures how quickly energy is produced or utilized in a system, to put it simply. In the International System of Units (SI), power is a scalar quantity and is measured in watts (W).

The power is given by:

Power  = Work ÷ Time

P = 0.50 Joules ÷ 2 seconds

P  = 0.25 Watts

Hence, the power exerted by the tired squirrel is 0.25 Watts.

To learn more about Power, here:

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Answer:

I believe the answer is specific gravity

Explanation:Hope this helps :)

Answer:

Since it is falling freely, the only force on it is its weight, w. w = m ⋅ g = 1000kg ⋅ 9.8m s2 = 9800N To draw a Free Body Diagram, draw an elevator cage (I am sure you would get lots of points for drawing it with intricate detail) with a downward force of 9800 N. I hope this helps,

Explanation:

Explanation:

❀ [tex] \underline {{\underline{ \text{Given} }}}: [/tex]

❀ [tex] \underline{ \underline{ \text{To \: find}}} : [/tex]

❀ [tex] \underline{ \underline{ \text{Solution}}} : [/tex]

[tex] \boxed{ \sf{force = mass \times acceleration}}[/tex]

Plug the known values :

⟶[tex] \sf{1000 \times 9.8}[/tex]

⟶ [tex] \sf{9800 \: N}[/tex]

[tex] \red{\boxed{ \boxed{ \tt{⟿ \: Our \: final \: answer : 9800 \: N}}}}[/tex]

Hope I helped !♡

Have a wonderful day / night ! ツ

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Answer:

the correct result is r = 3.71 10⁸ m

Explanation:

For this exercise we will use the law of universal gravitation

          F = [tex]- \frac{m_{1} m_{2} }{r^2}[/tex]

We call the masses of the Earth M, the masses of the moon m and the masses of the rocket m ', let's set a reference system in the center of the Earth, the distance from the Earth to the moon is d = 3.84 108 m

rocket force -Earth

          F₁ = - \frac{m' M }{r^2}

rocket force - Moon

          F₂ = - \frac{m' m }{(d-r)^2}

in the problem ask for what point the force has the relation

          2 F₁ = F₂

let's substitute

          2 [tex]2 \frac{M}{r^2} = \frac{m}{(d-r)^2}[/tex]

          (d-r) ² = [tex]\frac{m}{2M}[/tex] r²

           d² - 2rd + r² = \frac{m}{2M} r²

           r² (1 -\frac{m}{2M}) - 2rd + d² = 0

Let's solve this quadratic equation to find the distance r, let's call

           a = 1 - \frac{m}{2M}

           a = 1 - [tex]\frac{7.36 10^{22} }{2 \ 5398 10^{24}}[/tex] = 1 - 6.15 10⁻³

           a = 0.99385

            a r² - 2d r + d² = 0

           r =  [tex]\frac {2d \frac{+}{-} \sqrt{4d^2 - 4 a d^2}} {2a}[/tex]

           r = [2d ± 2d [tex]\sqrt{1-a}[/tex]] / 2a

           r = [tex]\frac{d}{a}[/tex]   (1 ± √ (1.65 10⁻³)) =  [tex]\frac{d}{a}[/tex] (1 ± 0.04)

           r₁ = \frac{d}{a} 1.04

           r₂ = \frac{d}{a} 0.96

let's calculate

           r₁ = [tex]\frac{3.84 10^8}{0.99385}[/tex] 1.04

           r₁ = 401.8 10⁸ m

          r₂ = \frac{3.84 10^8}{0.99385} 0.96

          r₂ = 3.71 10⁸ m

therefore the correct result is r = 3.71 10⁸ m

Answer:

physical

Explanation:

it is a real life model that was built