The areas of the pistons are 20 cm^2 and 100 cm^2. A force of 10 N is applied to the small piston. How much force is on the large pistons?

While the boy is sitting on the chair it creates a force downward on the chair and therefore the chair takes it and gives off the equal amount of force. So while he is putting force downward the chair is putting the same force upward.

Answer: While the boy is sitting on the chair it creates a force downward on the chair and therefore the chair takes it and gives off the equal amount of force. So while he is putting force downward the chair is putting the same force upward.

Explanation:

Answer:

An electromagnet is a magnet that runs on electricity. Unlike a permanent magnet, the strength of an electromagnet can easily be changed by changing the amount of electric current that flows through it. The poles of an electromagnet can even be reversed by reversing the flow of electricity.

Answer:

solenoid & metal

Explanation:

Explanation:

(a) You can solve this using kinematics or energy.

Using kinematics:

a = F/m = 90 N / 4 kg = 22.5 m/s²

v₀ = 0 m/s

Δx = 5 m

Find: v

v² = v₀² + 2aΔx

v² = (0 m/s)² + 2 (22.5 m/s²) (5 m)

v = 15 m/s

Using energy:

W = ΔKE

Fd = ½ mv²

(90 N) (5 m) = ½ (4 kg) v²

v = 15 m/s

(b) ΔU = mg Δh

ΔU = (4 kg) (9.8 m/s) (12 m sin 40° − 15 m)

ΔU = -290 J

W = ΔU = -290 J

Answer:

Nuclear energy is that released by dividing the nuclei of heavy atoms (also called under the name Nuclear Fission)

Explanation:

In this process, a large amount of heat is generated that can be used to obtain mechanical energy, which is used to generate electrical energy.

Nuclear energy is a sustainable source of energy having a low impact on the environment.

a) 10 m/s

b) 25 m

Explanation:

a)

The body is moving with a constant acceleration, therefore we can solve the problem by using the following suvat equation:

[tex]v=u+at[/tex]

where

u is the initial velocity

v is the final velocity

a is the acceleration

t is the time

For the body in this problem:

u = 0 (the body starts from rest)

[tex]a=2 m/s^2[/tex] is the acceleration

t = 5 s is the time

So, the final velocity is

[tex]v=0+(2)(5)=10 m/s[/tex]

b)

In this second part, we want to calculate the distance travelled by the body.

We can do it by using another suvat equation:

[tex]v^2-u^2=2as[/tex]

where

u is the initial velocity

v is the final velocity

a is the acceleration

s is the distance travelled

Here we have

u = 0 (the body starts from rest)

[tex]a=2 m/s^2[/tex] is the acceleration

v = 10 m/s is the final velocity

Solving for s,

[tex]s=\frac{10^2-0^2}{2(2)}=25 m[/tex]

Answer:

brand name, or company

Explanation:

a brand name is  the kind of product they are selling. a company is the group of peaple that wok together.

Answer: maker or producer

Explanations:

Answer:

Mechanical waves

Explanation:

Waves are periodic oscillations, that carry energy, but not matter.

Waves are classified into two types:

- Mechanical waves: these waves are produced by the oscillations of the particles in a medium, which can oscillate along the  direction of propagation of the wave (longitudinal wave) or perpendicular to the direction of motion of the wave (transverse wave). These waves can only propagate in a medium, so they cannot travel in a vacuum. Examples of mechanical waves are sound waves.

- Electromagnetic waves: these waves are produced by the oscillations of electric and magnetic field. They are transverse waves. They are the only type of wave able to propagate through a vacuum (so, through space).

Therefore, the waves that need molecules in order to transfer energy are mechanical waves.

Work = (force)x(distance)

Since we're lifting, the 'force' is the weight of the apple.

Weight = (mass)x(gravity)

Weight = (0.180 kg)x(9.8 m/s^2)

Weight = 1.764 Newtons

2.0 J = (1.764 N) x (distance)

Distance = 2.0J / 1.764N

Distance = 1.13 meters

An apple is lifted "1.1337 meters" far.

Given values are:

Work done,

Mass,

or,

            = 0.18 kg

and,

As we know the formula,

→ [tex]Work \ done (W)= mgh[/tex]

or,

→                       [tex]h = \frac{W}{mg}[/tex]

By substituting the values, we get

→                          [tex]= \frac{2}{0.18\times 9.8}[/tex]

→                          [tex]= \frac{2}{1.764}[/tex]

→                          [tex]= 1.1337 \ meters[/tex]

Thus the above response is correct.

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Answer:

16.732 N

Explanation:

Given:

q1 = 0.00047 C = 4.7 x 10^-4 C

q2 = 0.00089 C = 8.9 x 10^-4 C

d = 15 m

k = 9 x 10^9 N m^2 / C^2

To Find:

F = ?

Solution:

F = k x q1 x q2/d^2

F = 9 x 10^9 x 4.7 x 10^-4 x 8.9 x 10^-4 / 15 x 15

F = 9 x 4.7 x 8.9 x 10^9 x 10^-4 x 10^-4 / 225

F = 9 x 4.7 x 8.9 x 10^9 x 10^-8 / 225

F = 9 x 4.7 x 8.9 x 10 / 225

F = 418.3/25

F = 1673.2/100

Therefore, F = 16.732 N

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Answer:

E = 7231.2 [kWh]

Explanation:

All systems that produce work in the mechanical form of movement or heat, they have an efficiency that depends on the construction technology, ideally in each of these equipments is that their efficiencies are as high as possible, that is, its efficiency is close to 100%. For this case we have an equipment with 60% efficiency, this heating system is characterized since of the 12,052 kWh, it uses 60% of this value only to heat the house, the rest of energy is known as lost.

E = 12,052 * (60/100)

E = 7231.2 [kWh]

This amount of energy 7231.2 [kWh] is used for heating purposes.

Answer:

5 m/s2, left

Explanation:

We can solve the problem by applying Newton's second law of motion, which  states that:

[tex]\sum F=ma[/tex]

where:

[tex]\sum F[/tex] is the net force acting on an object

m is the mass of the object

a is its acceleration

In this problem, we have:

[tex]\sum F=30 N - 20 N = 10 N[/tex] (to the left) is the net force on the object

m = 2.0 kg is the mass

So, the acceleration is:

[tex]a=\frac{\sum F}{m}=\frac{10}{2.0}=5.0 m/s^2[/tex]

in the same direction as the force (left).

The mechanical advantage of an inclined plane can be calculated using the formula: MA = length of incline / height of incline. For example, if the length of the incline is 10 meters and the height of the incline is 2 meters, then the mechanical advantage would be 5.

The mechanical advantage of an inclined plane can be calculated using the formula:

Mechanical Advantage (MA) = length of incline / height of incline

In the case of a brick on an inclined plane, the length of the incline would be the distance along the surface of the plane and the height of the incline would be the vertical distance from the base of the incline to the top.

For example, if the length of the incline is 10 meters and the height of the incline is 2 meters, then the mechanical advantage would be 10 / 2 = 5.

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The mechanical advantage of an inclined plane can be calculated using the length and height of the incline, which tells us how much the plane multiplies the effort force, simplifying tasks like lifting heavy objects.

To calculate the mechanical advantage (MA) of an inclined plane, you can use the formula MA = Length of Incline / Height of Incline. The mechanical advantage tells you how much the inclined plane multiplies the effort force, allowing you to overcome the weight of the object with less force. This efficiency is due to the larger distance over which the force is applied when using the inclined plane as compared to lifting the object straight up.

The ideal mechanical advantage (IMA) is the theoretical maximum mechanical advantage you could get from an inclined plane if there were no energy losses due to friction. In reality, the actual mechanical advantage will be less than the ideal mechanical advantage because of frictional forces.

Applying this concept, pushing a brick up an inclined plane requires less force than lifting it vertically because the weight of the brick is distributed over a longer distance. The inclined plane, a simple machine, reduces the effort needed to raise the brick, similar to how ancient civilizations like the Egyptians used ramps to lift heavy blocks during pyramid construction.

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Answer:

4.3 L

Explanation:

Ideal gas law:

PV = nRT

Rearrange:

V / T = nR / P

Since n, R, and P are constant:

V₁ / T₁ = V₂ / T₂

Plug in values and solve:

(3.5 L) / (25 + 273.15 K) = V / (95 + 273.15 K)

V = 4.3 L

Answer:

Battery will run for t = 90 s

Explanation:

As we know that rate of flow of charge is known as electric current

So we will have

[tex]i = \frac{Q}{t}[/tex]

[tex]i = 0.11 A[/tex]

[tex]Q = 10 C[/tex]

now we have

[tex]t = \frac{Q}{i}[/tex]

[tex]t = \frac{10}{0.11}[/tex]

[tex]t = 90 s[/tex]

Given a flashlight that draws 0.11 amps and has a battery with 10 coulombs of charge, it can run for approximately 90.9 seconds before the battery is depleted.

The duration for which a flashlight can run is determined by the charge in its battery and the current it draws. To calculate the run time, we use the formula time (seconds) = total charge (coulombs) / current (amperes). Given that the flashlight draws 0.11 amps and has a battery containing 10 coulombs of charge, the run time can be calculated as follows:

Time = Total Charge / Current
Time = 10 coulombs / 0.11 amps
Time = approximately 90.9 seconds

Therefore, the flashlight can run for about 90.9 seconds before the battery is depleted.

Answer:

2.5m/s2

Explanation:

The following were obtained from the question:

F = 600N

M = 240 kg

a =?

Recall: F = Ma

a = F/M

a = 600/240

a = 2.5m/s2

Therefore, the acceleration of the motorcycle is 2.5m/s2

Answer:

Explanation:

force(f)=600N

Mass(m)=240kg

Acceleration(a)=?

Acceleration=force/mass

Acceleration=600/240

Acceleration=2.5m/s^2

Jumping on a trampoline is a classic example of conservation of energy, from potential into kinetic. It also shows Hooke's laws and the spring constant. Furthermore, it verifies and illustrates each of Newton's three laws of motion.

Explanation

When we jump on a trampoline, our body has kinetic energy that changes over time. Our kinetic energy is greatest, just before we hit the trampoline on the way down and when you leave the trampoline surface on the way up. Our kinetic energy is 0 when you reach the height of your jump and begin to descend and when are on the trampoline, about to propel upwards.

Potential energy changes along with kinetic energy. At any time, your total energy is equal to your potential energy plus your kinetic energy. As we go up, the kinetic energy converts into potential energy.

Hooke's law is another form of potential energy. Just as the trampoline is about to propel us up, your kinetic energy is 0 but your potential energy is maximized, even though we are at a minimum height. This is because our potential energy is related to the spring constant and Hooke's Law.

Answer: The answer is B :) !

Explanation:

You will get it correct loves !

Final answer:

The strength of an electromagnet can be increased by using more coils of wire around the iron core, which concentrates the magnetic field and enhances it through the electric current passing through the additional coils. So the correct option is B.

Explanation:

The strength of an electromagnet can be increased by a few different methods. One way is to use more coils of wire around the iron core, as the amount of current flowing through these additional coils will result in a stronger magnetic field. This is because the magnetic field produced by each coil of wire adds together to create a more concentrated field inside the core. In fact, the strength of the magnetic field in a solenoid is directly proportional to the number of turns in the coil and the electric current passing through it. Using a ferromagnetic core, such as iron, also increases the strength of the electromagnet because the ferromagnetic material enhances the magnetic field within the coil.

Therefore, the correct answer to the question, 'How could the strength of an electromagnet be increased?' is B) Use more coils of wire around the nail.

Answer:

speed is defined as distance travelled per unit time

Answer: Speed is the measure of how fast an object is moving.

Explanation: Speed is expressed as the ratio of the distance travelled per unit time.

it is a transverse wave

A transverse wave is the one that sets the particles of medium into oscillations perpendicular to the direction of wave propagation. So yes, a transverse wave needs a materialistic medium to propagatee.

Examples of transverse waves include:

ripples on the surface of water.

vibrations in a guitar string.

a Mexican wave in a sports stadium.

electromagnetic waves – eg light waves, microwaves, radio waves.

transverse waves require a material medium and propogate by means of vibrations of the medium perpendicular to the direction of travel. ... Electromagnetic (EM) waves (such as light) are also transverse waves but they do not require a medium and thus can pass through a vacuum

Answer:Correct Answers are Mid ocean ridges are sites of seafloor spreading and Younger ocean floor is created

Explanation : Hess was a geophysicist. In 1960, he proposed a theory which is later became known as 'Sea Floor Spreading'. Hess discovered that the oceans were shallower in the middle. According to Hess, From Earth's mantle molten material is continuously flowing along the crests of the mid-ocean ridges . As soon as temperature of  magma decreases, it is pushed away from the flanks of the ridges. Due to this process a younger ocean floor is created.Hess also proposed that due to light weight of continental crust, it didn't sink back into the deep earth at trenches as did the oceanic crust.

Final answer:

Hess's law states that the enthalpy change of a reaction is equal to the sum of the enthalpy changes of its individual steps. This reflects the nature of enthalpy as a state function and allows for the calculation of enthalpy changes for complex reactions, such as using the Born-Haber cycle for lattice energies.

Explanation:

The concept described in the theory proposed by Hess is Hess's law, which states the enthalpy change of a reaction is the sum of the enthalpy changes of the individual steps that make up the reaction. In other words, the total enthalpy change for a reaction does not depend on the pathway taken from reactants to products but is the same for any series of steps leading from the initial state to the final state. This principle is particularly useful for calculating the enthalpy changes for reactions where direct measurement is challenging.

Hess's law is a reflection of the fact that enthalpy (H) is a state function, meaning that its value is determined by the initial and final states of a system, irrespective of the path taken to get there. Hess's law allows chemists to use established enthalpy changes of known reactions (like those listed in thermochemical tables) to calculate the enthalpy change for a complex reaction. For instance, the Born-Haber cycle utilizes Hess's law to determine the lattice energy of ionic compounds.

Current in the circuit is 0.8 A

Explanation:

Charge = Current × Time

⇒ Q = I × t

Given, charge, Q = 240 C and time = 5 mins = 5 × 60 = 300 seconds

⇒ I = Q/t = 240/300 = 0.8 A

"Displacement" is the distance and direction between the start-point and the end-point, regardless of the route taken on the way.

From this definition, it's easy to see that the bee's displacement at the end of the adventure is zero.

The bee's distance and average speed could also be calculated using the given information, but are not requested.

The total displacement of the bee is calculated by subtracting the return displacement from the forward displacement, resulting in a total displacement of 41.4 meters in the direction of the initial forward flight.

To calculate the total displacement of the bee, we need to consider the distance traveled in each direction and then sum these distances, taking into account the direction of travel. Initially, the bee flies forward at 4.9m/s for 48s, and then it returns along its previous route at 5.1m/s for 38s.

First, we calculate the forward displacement:
4.9m/s * 48s = 235.2m

Then, the return displacement:
5.1m/s * 38s = 193.8m

Since displacement is a vector quantity, we must consider the direction. The total displacement would be the forward displacement minus the return displacement because the bee returns along its previous route.

Total displacement = 235.2m - 193.8m = 41.4m

Therefore, the total displacement of the bee, rounded to the nearest thousandth if necessary, is 41.4m in the direction of the initial forward flight.

Answer:

750 kN

Explanation:

Pressure = force / area

P = F / A

1,150,000 Pa = F / 0.65 m²

F = 747,500 N

Rounded to two significant figures, the force is 750,000 N, or 750 kN.

Answer:

Soft  bumpy   smooth

Explanation:

The new speed of 22 kg block is 1.57 m/s

Explanation:

Given-

Mass, [tex]m_{1}[/tex]= 22 kg

speed, [tex]v_{1}[/tex] = 5 m/s

[tex]m_{2}[/tex] = 29 kg

[tex]v_{2i[/tex] = 4.6 m/s

New speed of [tex]m_{2}[/tex], [tex]v_{2f}[/tex] = 7.2 m/s

New speed of [tex]m_{1}[/tex], [tex]v_{1f}[/tex] = ?

This is the case of elastic collision.

So,

[tex]M_{1}[/tex] X  [tex]V_{1i}[/tex]+ [tex]M_{2}[/tex] X [tex]V_{2i}[/tex] = [tex]M_{1}[/tex] X [tex]V_{1f}[/tex] + [tex]M_{2}[/tex] X [tex]V_{2f}[/tex]

22 X 5 + 29 X 4.6 = 22 X[tex]V_{1f}[/tex] + 29 X 7.2

22 [tex]V_{1f}[/tex] + 208.8 = 243.4

22 [tex]V_{1f}[/tex]= 34.6

[tex]V_{1f}[/tex]= 1.57 m/s

Therefore, the new speed of 22 kg block is 1.57 m/s

Answer:

- 2/5

Explanation:

Data obtained from the question include

x1 (x coordinate 1)= 5c

x2 (x coordinate 2) = 8

Δx (change in x coordinate) = x2 - x1 = 8 - 5c

y1 (y coordinate 1) = 10

y2 (coordinate 2) = 40

Δy (change in y coordinate) = y2 - y1 = 40 - 10 = 30

m (gradient) = 3

The gradient is also called the slope and it is represented mathematically as:

Gradient = (change in y coordinate)/(change in x coordinate)

M = Δy/Δx

3 = 30/ 8 - 5c

Cross multiply to express in linear form as shown below:

3(8 - 5c) = 30

Clear the bracket

24 - 15c = 30

Collect like terms

- 15c = 30 - 24

- 15c = 6

Divide both side by - 15

c = 6/-15

c = - 2/5

Therefore, the value of c is - 2/5

Answer:

C. scientists possess varied talents and interests.

Explanation:

The above passage suggests clearly that often times, scientists possess varied talents and interests.

Cases were made of  Abū Rayhān al-Bīrūnī and Robert Hooke. Both were scientists and had the same time had interests in other disciplines.

Therefore, we can argue that the tone set by the author conveys a clear focal point that often times, scientists possess varied talents and interests.

Answer:

c

Explanation:

Answer: a= 50 m/s²

Explanation: Acceleration is force per unit mass.

a= F/ m

= 10 N / 0.2 kg

= 50 m/s²

Answer:

Hello there use something that looks like this

Explanation:

This is an accurate representation of something you are working on!

As you can see the wire and the core are represented on the left and is showing how it can be represented on your right hand and how they are similar!