what happens to the current across a circuit when the voltage is doubled while the resistance is held back ​

Answer:1. A chair leaning on a wall

Explanation:

Distance = (speed) x (time)

Time = (distance) / (speed)

Time = (22 km) / (55 km/hr)

Time = (22/55) (hr)

Time = 0.4 hour  (that's 24 minutes)

' A ' and ' D ' are both correct statements.

Answer:

em waves do so because they require no medium to travel...space =vacuum)))

while sound waves that are longitudinal waves...require medium to travel......so in space it has vacuum.....it can't travel..

Answer:

F = 144 N

Explanation:

For this exercise we will use Neqwton's second law. Let's fix a reference system with the x-axis in the direction of the sled, let's write the forces for each part

Sack, let's use subscript 1

Y axis  

       N₁-W₁ = 0

       N₁ + W₁ = m₁ g

X axis

       fr₁ = m a₁

the expression for the friction force is

       fr = μ₁ N₁

we substitute

        μ₁ m₁ g = m a₁

Sled, subscript 2

Y axis

       N₂ - W₁ -W₂ = 0

       N₂ = W₁ + W₂

       N₂ = (m₁ + m₂) g

X axis

       F - fr₁ -fr₂ = m a₂

the expression for the deroce force is

      fr = μ N

we substitute

       F - μ₁ m₁g - μ₂ (m₁ + m₂) g = m a₂

as it indicates that the velocity is constant the acceleration of the sled is zero (a₂ = 0)

       F = μ₁  m₁g + μ₂  (m₁ + m₂) g

       F = g (m₁ (μ₁ + μ₂) + μ₂ m₂)

let's calculate

       F = 9.8 (50 (0.07 + 0.1) + 62 0.1)

       F = 144 N

Answer:heart

The hardest working muscle is the heart. It pumps out 2 ounces (71 grams) of blood at every heartbeat. Daily the heart pumps at least 2,500 gallons (9,450 liters) of blood. The heart has the ability to beat over 3 billion times in a person's life.

Explanation:hope this helps

Answer:

0.75m/s^2

Explanation:

3.6-1.2=2.4 m/s (Change in velocity)

2.4/3.2=0.75 m/s/s or m/s^2

Answer:

300 jules

Explanation:

Answer:

Linear magnification refers to the ratio of image length to object length measured in planes that are perpendicular to the optical axis. A negative value of linear magnification denotes an inverted image.

Explanation:

Answer:

i hope it help

Explanation:

stay happy and safe

Answer:

B. 1.1 m/s²

good luck, i hope this helps :)

Answer:

Two forces that act in opposite directions produce a resultant force that is smaller than either individual force. To find the resultant force subtract the magnitude of the smaller force from the magnitude of the larger force. The direction of the resultant force is in the same direction as the larger force.

To find the resultant force subtract the magnitude of the smaller force from the magnitude of the larger force. The direction of the resultant force is in the same direction as the larger force. A force of 5 N acts to the right, and a force of 3 N act to the left. Calculate the resultant force.

Answer:

Explanation:

Momentum

Answer:

Dalton's atomic theory

Explanation:

Dalton's atomic theory was the first to introduce the idea that all things are made from indivisible spheres called atoms and used evidence and research to back his findings. This theory was based on the law of constant composition and the law of conservation of mass. Also, this theory explains the matter in terms properties of atoms.

Answer:

3.7 kg

Explanation:

Start off by drawing and labeling a free-body diagram for the object. I have attached an image that I drew that shows all of the relevant forces acting on the object.

On the free-body diagram, we have the tension forces (T₁ and T₂), their x and y components, and the weight force (w).

We want to start off by finding the angle theta (Θ) so that we can use this angle when using Newton's Second Law later on in the problem to calculate the mass of the object.

We can find the angle Θ by using the fact that there are no unbalanced horizontal forces acting on the object, so the net force is zero.

This means that T₁ sin(40) is equal to T₂ sin(Θ). Set them equal to each other in an equation and solve for the angle Θ. We are given the tension forces: T₁ = 34 N and T₂ = 24 N.

Evaluate 34 * sin(40) and divide it by 24 to isolate sin(Θ).

Take the inverse sine of both sides of the equation.

Now that we have the angle Θ, we can use this to set up an equation involving mass using Newton's Second Law.

We know that there is a weight force directed downwards on the object, and this weight force is equal to mg (mass · gravitational acceleration).

There are two forces acting upwards on the object: the x-components of the two tension forces.

Using the fact that the object is not moving vertically, we know that the net force must equal 0 (since F = ma and acceleration = 0 m/s², therefore F = 0 N).

The sum of the forces in the y-direction will be equal to 0. Setting the upwards direction to be positive and the downwards direction to be negative, we can write this equation:

Add mg (weight force) to both sides of the equation.

Substitute 34 for T₁ and 24 for T₂.

The gravitational acceleration on Earth is 9.8 m/s². Substitute this value into the equation and solve for m, the mass of the object.

Evaluate the left side of the equation.

Divide both sides of the equation by 9.8.

Round this to two significant figures since the problem gives us the tension forces to two sig figs.

The mass of the object shown is around 3.7 kg.

Answer:

3.7 kg

Explanation:

Start off by drawing and labeling a free-body diagram for the object. I have attached an image that I drew that shows all of the relevant forces acting on the object.

On the free-body diagram, we have the tension forces (T₁ and T₂), their x and y components, and the weight force (w).

We want to start off by finding the angle theta (Θ) so that we can use this angle when using Newton's Second Law later on in the problem to calculate the mass of the object.

We can find the angle Θ by using the fact that there are no unbalanced horizontal forces acting on the object, so the net force is zero.

This means that T₁ sin(40) is equal to T₂ sin(Θ). Set them equal to each other in an equation and solve for the angle Θ. We are given the tension forces: T₁ = 34 N and T₂ = 24 N.

T₁ sin(40) = T₂ sin(Θ)

34 * sin(40) = 24 * sin(Θ)

Evaluate 34 * sin(40) and divide it by 24 to isolate sin(Θ).

0.9106157804 = sin(Θ)

Take the inverse sine of both sides of the equation.

Θ = sin⁻¹(0.9106157804)

Θ = 65.59058699°

Now that we have the angle Θ, we can use this to set up an equation involving mass using Newton's Second Law.

We know that there is a weight force directed downwards on the object, and this weight force is equal to mg (mass · gravitational acceleration).

There are two forces acting upwards on the object: the x-components of the two tension forces.

Using the fact that the object is not moving vertically, we know that the net force must equal 0 (since F = ma and acceleration = 0 m/s², therefore F = 0 N).

The sum of the forces in the y-direction will be equal to 0. Setting the upwards direction to be positive and the downwards direction to be negative, we can write this equation:

∑Fᵧ =  T₁ cos(40) + T₂ cos(65.59058699) - mg = 0

Add mg (weight force) to both sides of the equation.

T₁ cos(40) + T₂ cos(65.59058699) = mg

Substitute 34 for T₁ and 24 for T₂.

34 * cos(40) + 24 * cos(65.59058699) = mg

The gravitational acceleration on Earth is 9.8 m/s². Substitute this value into the equation and solve for m, the mass of the object.

34 * cos(40) + 24 * cos(65.59058699) = m(9.8)

Evaluate the left side of the equation.

35.96360799 = 9.8m

Divide both sides of the equation by 9.8.

m = 3.669755918

Round this to two significant figures since the problem gives us the tension forces to two sig figs.

m ≈ 3.7 kg

The mass of the object shown is around 3.7 kg.

Answer:

Extension, e = 0.4 meters

Explanation:

Given the following data;

Force = 40N

Spring constant, k = 100N/m

To find the extension;

Force = spring constant * extension

Substituting into the equation, we have

40 = 100 * extension

Extension, e = 40/100

Extension, e = 0.4 meters

Therefore, the spring can be compressed by the force over a distance of 0.4 meters.

Answer:

speed = distance/time

Therfore,

speed = 500/4.3

= 116.27 ~ 116.3

So, the speed of the car is 116.3 mile/h

Hope it helps!

Answer:

Its A

Explanation:Your using motion to crank which is kinetic energy

Answer:

False.

Explanation:

Potential of Hydrogen is the full form of PH.

Potential of Hydrogen tells about the acidity or basicity of the solution.

The pH of a solution is a measure of the concentration of hydrogen ions [tex](H+)[/tex] ions and hydroxide ions [tex](OH-)[/tex] in a solution.

So, the given statement is false.

Answer:

f = V/λ = 329/0.42 = 783 Hz

:)

Answer:

The relationship the exist between the rams is a mild one.

Explanation:

because i said so

the answer is 80 diveded by 8 equalzzzz

.infinite.

&

also

.virtual.

Explanation:

Electrical energy is energy derived from electric potential energy or kinetic energy. When used loosely, electrical energy refers to energy that has been converted from electric potential energy.

HOPE THIS HELPS YOU

Answer:

Hi!

Explanation:

Its kinetec energy moving by electric charges.

Answer:

The concave mirror is a converging mirror so that it is used for many purposes, It is used as a torch to reflect the light, It is used in the aircraft landing at the airports to guide the aeroplanes, It is used in shaving to get an enlarged and erect image of the face.

Explanation:

Answer:

[tex]v = 0.25m/s[/tex]

Explanation:

Given

[tex]\lambda = 0.02m[/tex] --- Wavelength

[tex]T = 8.0 * 10^{-2}s[/tex] --- Period

Required

Determine the velocity of the wave

This is calculated using:

[tex]v = \frac{\lambda}{T}[/tex]

[tex]v = \frac{0.02m}{8.0*10^{-2}s}[/tex]

[tex]v = \frac{0.02m}{8.0*0.01s}[/tex]

[tex]v = \frac{0.02m}{0.08s}[/tex]

[tex]v = 0.25m/s[/tex]

Hence, the velocity is 0.25m/s