a solid cylinder with a radius of 3.8cm has the same mass as a solid sphere of radius R. If the sphere has the same moment of inertia about its center asthe cylinder about its axis, what is the sphere's radius?

Explanation:

If ignoring air friction, the horizontal component will not change.

If taking air friction into account, then horizontal component will decay.

The horizontal component of the velocity of a projectile changes with time due to the force of gravity acting on the projectile. Initially, the projectile will have a constant horizontal velocity, as there is no net force acting on it in the horizontal direction.

However, once the projectile is fired, the force of gravity will begin to act on it, causing its horizontal velocity to decrease. This decrease in horizontal velocity is due to the fact that gravity is an acceleration, which means that it will cause the projectile to slow down over time.

As the projectile moves further away from the point of launch, its horizontal velocity will continue to decrease until it reaches its terminal velocity. At this point, the horizontal velocity of the projectile will remain constant and will not change with time.

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The rate of wingbeats per minute for hummingbirds can be converted to wingbeats per second by dividing the number of wingbeats per minute by 60.

This is because there are 60 seconds in a minute, meaning that if the wings are moving at a rate of x wingbeats per minute, they are moving at a rate of x/60 wingbeats per second.

This conversion is often necessary when calculating the speed of a hummingbird, as it is easier to measure the rate of wingbeats than it is to measure the bird's speed directly. In addition, since hummingbirds are capable of flying incredibly quickly, it is often more precise to measure the rate of their wingbeats instead of their speed.

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When eight 7.0 W Christmas tree lights are connected in series to each other and to a 120 V source, the resistance of each bulb is 240 Ω.

What is a series circuit?A circuit that has only one pathway for the flow of electric current is called a series circuit. It means that in a series circuit, all the electrical elements are connected one after the other, and the current flows through each component in turn.

As a result, the current is equal throughout the circuit, and the sum of the voltages across each element equals the total voltage of the circuit.The current is the same in all resistors in a series circuit. The voltage is different across each resistor, but the sum of the voltage drops across all of the resistors in the circuit is equal to the applied voltage.

Voltage across each bulb:The voltage across each bulb is not the same in a series circuit. However, the sum of all the voltages across each bulb adds up to the total voltage of the circuit. Here, the total voltage of the circuit is 120 V. Therefore, the voltage across each bulb is 15 V (120/8=15).Resistance of each bulb:

We use Ohm's law, which states that resistance is equal to voltage divided by current, to calculate the resistance of each bulb. In this example, we have the voltage across each bulb, which is 15 V. We can calculate the current flowing through the circuit by dividing the total voltage by the total resistance, which is the resistance of a single bulb multiplied by the total number of bulbs.

The current flowing through the circuit is 0.5 A (120/240=0.5).We can now determine the resistance of each bulb by dividing the voltage across each bulb by the current flowing through it. Resistance of each bulb is 30 Ω (15/0.5=30).Answer: 30 Ω

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In panoramic imaging, the pivotal point or axis around which the cassette carrier and x-ray tubehead rotate is termed a rotational center .

The panoramic X-ray machine's tubehead and film carrier move around the patient's head, generating a curved or panoramic image of the patient's entire mouth and teeth.In the United States, the most common form of dental radiograph is the panoramic radiograph. A panoramic radiograph is an extraoral, non-invasive X-ray test that displays a panoramic view of the teeth, jaws, and surrounding structures. It is one of the most often used imaging tests in dental clinics because it provides a comprehensive view of the teeth and oral cavity.
In panoramic imaging, the pivotal point, or axis, around which the cassette carrier and x-ray tubehead rotate is termed a "rotation center."

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If the neutral of an unbalanced three-wire system is opened, the circuit becomes a 240 V open circuit. Since the line with the smaller load has a lower resistance, more than half the total voltage drops across it. That is, voltage rises above 120 volts.

When a neutral of an unbalanced three-wire system is opened, the circuit becomes a 240 V open circuit. This means that the voltage between the two hot wires (or line wires) in the circuit becomes 240 V.
In an unbalanced three-wire system, the current flows through both line wires and the neutral wire. The neutral wire carries the unbalanced current, which means it carries the difference between the current flowing through the two line wires. If the neutral wire is opened, the circuit becomes unbalanced because the current flowing through the two line wires is no longer equal. This causes the voltage between the two line wires to increase to 240 V.
Since the line with the smaller load has a lower resistance, it offers less opposition to the flow of current. This means that more current flows through this line, causing the voltage across this line to increase. The voltage across the other line decreases accordingly. If the load on one line is much greater than the load on the other line, then more than half the total voltage drops across the line with the smaller load. This causes the voltage on this line to rise above 120 volts.

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The Burrows-Wheeler transform (BWT) is a data compression method that groups similar characters together by reordering a string of letters. As a result, the converted string has longer same-character runs.

than the original string. The local repeating patterns of the original string are exposed in the BWT. The BWT operates by cyclically rotating the original string and lexicographically sorting the rotations. The BWT is built from the final character of each rotation. The BWT exposes the local repeating patterns in the original string by grouping related characters together. This characteristic makes string compression simpler since same-character runs may be encoded more efficiently. As a result of lexicographically sorting the rotations, the BWT obtains longer same-character runs.

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The area of each plate is approximately 5.39 × 10⁻⁶m².

The capacitance C of a parallel-plate capacitor is given by:

C = ε₀ * A / d

where ε₀ is the permittivity of free space (8.85 x 10⁻¹²F/m), A is the area of each plate, and d is the distance between the plates.

It is given that the capacitance C is 6.0 pF and the distance between the plates d is 8.0 mm.

First, need to convert the capacitance to Farads (F) from picofarads (pF):

6.0 pF = 6.0 × 10⁻¹²F

Substituting the given values into the capacitance equation, can get:

6.0 × 10⁻¹²F = (8.85 × 10⁻¹²F/m) * A / (8.0 × 10⁻³ m)

Solving for A, we get:

A = C * d / ε₀

A = (6.0 × 10⁻¹² F) * (8.0 × 10⁻³m) / (8.85 × 10⁻¹²F/m)

A ≈ 5.39 × 10⁻⁶m²

Therefore, the area of each plate would be approximately 5.39 × 10⁶m².

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The work done by the external agent to bring the plates  of a capacitor closer together is about 0.625 μJ.

The work done by an external agent to move the plates of a capacitor is given by:

W = (1/2) * C * (Vf² - Vi²)

where W is the work done, C is the capacitance, Vf is the final voltage, and Vi is the initial voltage.

Initially, the capacitance of the capacitor is 5.0 μF and it is charged to 5 μC. Therefore, the initial voltage across the capacitor is:

Vi = Q / C = 5 μC / 5.0 μF = 1 V

When the plates are brought closer together, the capacitance of the capacitor becomes 10 μF, but the charge on the capacitor remains the same. Therefore, the final voltage across the capacitor is:

Vf = Q / C' = 5 μC / 10 μF = 0.5 V

Substituting these values into the equation for work, may get:

W = (1/2) * 5.0 μF * (0.5² - 1²) = 0.625 μJ

Therefore, the work done by the external agent to bring the plates closer together would be about 0.625 μJ.

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The initial momentum of the car is 27500 kg m/s.

In the case of the car traveling at a velocity of 25 m/s, it has a certain momentum. When the car comes to a stop, its momentum changes to zero, since the velocity becomes zero. This change in momentum occurs due to a force that acts on the car to bring it to a stop.  The initial momentum of the car can be calculated using the formula:

p = m*v

where p is the momentum, m is the mass, and v is the velocity.

Given that the mass of the car is 1100 kg and its velocity is 25 m/s, we have:

p = 1100 kg * 25 m/s = 27500 kg m/s

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The period of oscillation for the spring/mass system described by the equation x(t) = a sin(ωt) is 2π seconds, which is the time taken for the system to complete one full cycle of oscillation.

The position of a spring/mass system is given by the equation:

x(t) = a sin(ωt)

where x is the displacement of the mass from its equilibrium position, a is the amplitude of the oscillation, ω is the angular frequency, and t is time in seconds.

The period of oscillation, T, is defined as the time taken for the system to complete one full cycle of oscillation, i.e., for the mass to move from its initial position, through its maximum displacement, back to its initial position. Mathematically, we can express the period as:

T = 2π / ω

where ω is the angular frequency of the oscillation.

To find the period of the spring/mass system described by the equation x(t) = a sin(ωt), we need to determine the value of ω. Comparing this equation to the standard form of a sinusoidal wave, y = A sin(ωt + φ), we can see that ω is the coefficient of t inside the sine function, i.e., ω = 2π / T.

In our equation x(t) = a sin(ωt), ω is the coefficient of t, which is just ω = 1. Therefore, we can determine the period of oscillation as:

T = 2π / ω

= 2π / 1

= 2π seconds

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Joules of energy required to heat 145.0 g of water from 14°C to boiling (100°C) is : 53,972.48 Joules of energy

Amount of energy that is transferred from one system to surroundings because of temperature difference is called heat.

A we know : Q = m c ΔT

Q is amount of heat energy required (in joules) ; m is mass of the water (in grams) ; c is specific heat capacity of water (4.184 J/g°C) ; ΔT is change in temperature (in °C)

ΔT = final temperature - initial temperature

= 100°C - 14°C

ΔT = 86°C

As Q = m c ΔT

= 145.0 g * 4.184 J/g°C * 86°C

Q = 53,972.48 J

Therefore, approximately 53,972.48 joules of energy are required to heat 145.0 g of water from 14°C to boiling (100°C).

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Answer:

The average speed of the lizard was 2.25 meters per second.

Explanation:

To find the average speed of the lizard, we need to use the formula:

Average speed = Total distance ÷ Total time

First, we need to find the total distance the lizard ran. He ran 3.0 meters to his friend's house and then ran back halfway, so he ran a total distance of:

3.0 + (1/2)3.0 = 4.5 meters

Next, we need to find the total time it took the lizard to run this distance. We're told that it took 2.0 seconds in total, so the time for the first leg of the journey (from the rock to his friend's house) must have been half of that, or 1.0 second. The time for the second leg (from his friend's house back to the rock) must also have been 1.0 second.

Now we can plug in the values into the formula:

Average speed = Total distance ÷ Total time

Average speed = 4.5 meters ÷ 2.0 seconds

Average speed = 2.25 meters per second

Explanation:

Average speed =3.0 × 2.0

= 6.0

The current going through the Amperian loop is approximately 0.67 A.

We have to Compute the cross-sectional area of the whole wire to determine the current flowing through the Amperian loop:

Since the radius of the wire is 6 cm, the area A_total is given by the formula

A_total = πr² = π(6 cm)² ≈ 113.1 cm².

The current is distributed uniformly over the wire's cross-sectional area. The total current is 6 A, so the current density J is given by

J = I_total / A_total = 6 A / 113.1 cm² ≈ 0.053 A/cm².

The Amperian loop is concentric to the wire and passes through point P, which is 2 cm from the center. The area A_loop is given by

A_loop = πr² = π(2 cm)² ≈ 12.57 cm².

The current density J is constant across the wire's cross-sectional area, so the current I_loop through the Amperian loop is given by

I_loop = J × A_loop = 0.053 A/cm² × 12.57 cm² ≈ 0.67 A.

So, 0.67 A  is The current flowing through the Amperian loop.

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Answer:

The angle of refraction is the angle made by a refracted ray with perpendicular to the refracting surface.

n = sin(i)/sin(r)

= sin(45 deg)/sin(30 deg)

= sqrt(2)

= 1.41

Answer: The x-component of the acceleration is [tex]-0.45m/s^{2}[/tex]

There u go (:

When the air inside a balloon is heated and its volume is held constant, the pressure increases, causing an increase in the number of air molecules inside the balloon.

When the air inside a balloon is heated, the temperature of the air increases, causing the air molecules to gain kinetic energy and move faster. As the molecules move faster, they collide with each other and the walls of the balloon more frequently, exerting a greater force on the walls.

If the volume of the balloon remains constant, the pressure inside the balloon will increase as a result of the increase in temperature. This increase in pressure causes the air molecules to move more vigorously and spread out. However, if we assume that the volume of the balloon remains constant, the air molecules do not have any extra space to move into. Therefore, the pressure increase will lead to an increase in the number of air molecules inside the balloon.

This can be explained by the ideal gas law, which states that PV = nRT, where P is the pressure, V is the volume, n is the number of moles of gas, R is the ideal gas constant, and T is the temperature. Assuming that the volume of the balloon is constant and the amount of air (moles of gas) inside the balloon remains the same, an increase in temperature will lead to an increase in pressure. Therefore, to satisfy the ideal gas law, the number of air molecules inside the balloon must increase.

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The magnitude of the impulse delivered to the particle is 32 kg m/s when its mass is 4 kg, horizontal speed is 5.0 m/s and the rebound speed is 3.0 m/s.

First, let's find the initial momentum of the particle:
Initial momentum (p_initial) = mass × initial velocity
p_initial = 4.0 kg × 5.0 m/s
p_initial = 20 kg m/s

Next, let's find the final momentum of the particle after it rebounds. Since the particle moves in the opposite direction after rebounding, its final velocity will be negative:
Final momentum (p_final) = mass × final velocity
p_final = 4.0 kg × (-3.0 m/s)
p_final = -12 kg m/s

Now, we can find the change in momentum, which is the impulse delivered to the particle:
Impulse = p_final - p_initial
Impulse = (-12 kg m/s) - (20 kg m/s)
Impulse = -32 kg m/s

The magnitude of the impulse is the absolute value of the impulse, so:
Magnitude of impulse = |-32 kg m/s|
Magnitude of impulse = 32 kg m/s

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The box experiences the greatest change in its momentum during this time interval of 1.5 s to 3.5 s.

To determine when the box experiences the greatest change in its momentum, we need to consider Newton's second law of motion, which states that the force exerted on an object is equal to the rate of change of its momentum. Mathematically, this is represented as:

F = Δp / Δt

Where F is the force exerted, Δp is the change in momentum, and Δt is the time interval.

Since frictional forces are negligible in this case, the force exerted by the force probe is the only force acting on the box. Therefore, to find the greatest change in momentum, we need to look for the time interval during which the force is at its maximum.

Based on the graph provided (which you need to observe), identify the time interval during which the force exerted on the box is at its highest. This time interval corresponds to the greatest change in the box's momentum. The slope of the line is steeper between 1.5 seconds to 3.5 seconds. This means that the box experiences the greatest change in its momentum during this time interval.So, the correct answer is 1.5 s to 3.5 s.

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The equipment that has a grinding head on wheels or tracks that moves through brush and grinds it up is called a forestry mulcher.

A forestry mulcher is an essential tool used in forestry management, land clearing, and other activities that involve clearing trees and vegetation. It is a powerful machine designed to handle tough brush, shrubs, trees, and other vegetation.

The equipment is commonly used in forest management activities such as clearing woodlands, parkland, pastureland, and other large areas. Forestry mulchers are used to grind and mulch trees, bushes, and shrubs into small pieces that can be spread on the ground as a layer of mulch.

The mulch can help control soil erosion and retain moisture in the soil.The forestry mulcher is equipped with a grinding head that contains cutting teeth or blades. The grinding head is attached to a hydraulic arm that can be raised and lowered to adjust the cutting depth.

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The value that is measured by the slope of a position-time graph is velocity. It is a vector quantity that measures the rate of change of an object's position.

It is calculated by taking the slope of a position-time graph which can be done by finding the change in position (displacement) divided by the change in time. Velocity is determined by the distance an object moves in a given period of time and its direction of motion. An object's velocity is constantly changing as it accelerates, decelerates, and changes direction.

The formula for velocity is velocity = displacement/time.

Velocity can be represented by a line on the graph that is parallel to the x-axis and has a slope that is equal to the velocity of the object.

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complete question: Please select the word from the list that best fits the definition: Value that is measured by the slope of a position-time graph.

a) Momentum

b) Velocity

c) Acceleration

d) Displacement

A maximum of 11 23 W lightbulbs can be connected in parallel across a potential difference of 85 V before the total current in the circuit exceeds 3.0 A.

We can use Ohm's law to find the current drawn by a single 23 W lightbulb:

P = VI

23 W = V x I

I = 23 W / V

Substituting the given values, we get:

I = 23 W / 85 V

I = 0.27 A

To find the maximum number of lightbulbs that can be connected in parallel without exceeding a total current of 3.0 A, we divide the total current by the current drawn by a single lightbulb:

N = 3.0 A / 0.27 A

N ≈ 11

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Second law expression that describes a simple harmonic oscillator is F= -mbω²x

When it comes to simple harmonic oscillators, the expression of the second law that applies is given by:

F= -mbω²x

Here, F is the force of the oscillator, x is the displacement of the oscillator from its equilibrium position, m is the mass of the oscillator, b is a positive nonzero constant (which represents the friction force), and ω is the angular frequency of the oscillator (which depends on the mass and the spring constant).

This expression is derived from the second law of motion, which states that the force applied to an object is proportional to the acceleration of the object (F = ma).

In the case of a simple harmonic oscillator, the force acting on the oscillator is given by the Hooke's law force, which is proportional to the displacement of the oscillator from its equilibrium position.

Therefore, we can substitute this force into the second law of motion equation to get the expression above.

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The line integral is zero for path A, proportional to the magnitude for path B, and depends on the angle for path C.

The line basic of a vector field addresses the amount of scalar results of the vector field and minuscule relocation along a way or bend.  For a uniform attractive field, the line vital along way A, which is opposite to the attractive field, is zero. Along way B, which is lined up with the attractive field, the line vital is non-zero and is relative to the size of the attractive field and the length of the way.

Along way C, which is bended and not equal or opposite to the attractive field, the line basic relies upon the point between the way and the attractive field at each point. In the event that the point is consistent along the way, the line essential will be corresponding to the size of the attractive field and the length of the way.

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The submarine is 26 m below the surface of fresh water. The density of sea water is 1.3 times the density of fresh water. The pressure due to fresh water at a depth of 26 m is 255660 Pa.

The pressure due to the sea water at a depth of 20 m can be calculated using the formula:

P = ρgh

where ρ is the density of the sea water, g is the acceleration due to gravity, and h is the depth of the submarine.

Assuming a density of sea water to be 1030 kg/m³ and g to be 9.81 m/s², we get:

P = 1030 x 9.81 x 20 = 202086 Pa

Now, to calculate the pressure due to fresh water at a depth of 26 m, we can use the same formula with the density of fresh water and the given depth:

P = ρgh

Assuming a density of fresh water to be 1000 kg/m³, and g to be 9.81 m/s², we get:

P = 1000 x 9.81 x 26 = 255660 Pa

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Answer: the average density of the combined world is 256/81 times the average density of the original two worlds.

Explanation:

The total mass of the two original worlds is 2M, and their average density is given by:

ρ0 = 2M/(4/3 πR^3) = 3M/(2πR^3)

The final radius of the combined world is 3/4R, so its volume is:

V = 4/3 π(3/4R)^3 = 27/64 πR^3

The mass of the combined world is still 2M, so its density is:

ρ = 2M/V = 128M/(27πR^3)

The ratio of the average density of the combined world to that of the original worlds is:

ρ/ρ0 = (128M/(27πR^3)) / (3M/(2πR^3)) = 256/81

The bank angle of the airplane is approximately 75.9°.

The bank angle of the aerobatic airplane can be found using the centripetal force equation and the weight of the pilot. The equation is:

tan(θ) = ([tex]V^{2}[/tex]) / (r * g)

where θ is the bank angle, v is the velocity (60.0 m/s), r is the radius (255 m), and g is the acceleration due to gravity (9.81 m/s²).

Solving for θ, we get:

tan(θ) = (60.[tex]0^{2}[/tex]) / (255 * 9.81)
θ = arctan(3.926)

θ ≈ 75.9°

The bank angle of the airplane is approximately 75.9°.

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72 feet is the length of pendulum if π = 3.14 and the period is 9.42 seconds.

In the example question, the pendulum's period T (in seconds) is calculated as T = 2(L/32), where L is the pendulum's length (in feet).

The length must be determined if = 3.14 and the period is 9.42 seconds.

T = 9.42 seconds

Adding the values to the formula now:

9.42 = 2*3.14*√(L/32)

9.42 = 6.28*√(L/32)

6.28 divided on both sides gives us

√(L/32) = 1.5

square on both sides, we obtain

(L/32) = 2.25

32 multiplied on both sides gives us

L = 72

The length is therefore 72 feet if = 3.14 and the time period is 9.42 seconds.

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The velocity of the airplane is approximately 69.84 m/s.

To find the velocity of the airplane flying at a standard sea level with a density of 1.23 kg/m³, static pressure of 1.01 x  [tex]10^{5}[/tex] N/m², and a pitot-static tube reading of 1.04 x  [tex]10^{5}[/tex] N/m², we can use Bernoulli's equation, which is applicable for steady, incompressible, and irrotational flow.

The Bernoulli's equation is given by: P₁ + 0.5ρV₁² + ρgh = P₂ + 0.5ρV₂² + ρgh₂ Since we're considering only horizontal flight, the potential energy terms (ρgh) can be canceled out. Additionally, since the pitot-static tube measures the total pressure (dynamic pressure + static pressure), P₂ is the total pressure (1.04 x  [tex]10^{5}[/tex] N/m²), and P₁ is the static pressure (1.01 x 10^5 N/m²).

The density ρ is given as 1.23 kg/m³. Now, rearrange the equation to solve for V₁ (the velocity of the airplane): V₁² = 2(P₂ - P₁) / ρ Substitute the given values: V₁² = 2(1.04 x [tex]10^{5}[/tex] N/m² - 1.01 x  [tex]10^{5}[/tex] N/m²) / 1.23 kg/m³ Calculate the result: V₁² = 2(3 x 10 N/m²) / 1.23 kg/m³ V₁² ≈ 4878.05 m²/s² Now, take the square root to find the velocity: V₁ = √4878.05 m²/s² ≈ 69.84 m/s

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The capacitance of the first capacitor is 4.283 pF, and the capacitance of the second capacitor is 4.817 pF.

When two capacitors are connected in parallel, their equivalent capacitance is given by the equation:

Ceq = C1 + C2

Where C1 and C2 are the capacitances of the two capacitors connected in parallel.

When two capacitors are connected in series, their equivalent capacitance is given by the equation:

1 / Ceq = 1 / C1 + 1 / C2

Where C1 and C2 are the capacitances of the two capacitors connected in series.

Let the capacitances of the two capacitors be C1 and C2 respectively. According to the given information, when they are connected in parallel, their equivalent capacitance is 9.10 pF. Therefore,Ceq = C1 + C2 = 9.10 pf

Similarly, when they are connected in series, their equivalent capacitance is 1.61 pF. Therefore, 1/Ceq = 1/C1 + 1/C2⇒ 1/1.61 = 1/C1 + 1/C2⇒ 1/C1 + 1/C2 = 0.62111 ------(1)Substitute C2 = 9.10 - C1 in equation (1).⇒ 1/C1 + 1/(9.10 - C1) = 0.62111. Solve for C1.C1 = 4.283 pF. Therefore, C2 = 9.10 - C1 = 9.10 - 4.283 = 4.817 pF.

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Answer:

I = 0,23 A

P = 3,45 W

Explanation:

Given:

V1 = 1,5 V

P1 = 345 mW = 0,345 W

V2 = 15 V

We know that:

P1 = V1 × I

From here, we can make I the subject and find the current:

I = P1/V1

I = 0,345/1,5 = 0,23 A

P2 = V2 × I

P2 = 15 × 0,23 = 3,45 W

The current going through the circuit when a battery with voltage 1.5 V is connected to a fan that uses 345 mW of power is 0.23 A and the power used by the fan now is 34.5 W.

1. To find the current going through the circuit with a 1.5 V battery, we can use the formula P = VI, where P is power, V is voltage, and I is current. Rearrange the formula to solve for I: I = P/V.

With a 1.5 V battery: Power (P) = 345 mW = 0.345 W (converted from milliwatts to watts), and
Voltage (V) = 1.5 V

I = P/V = 0.345 W / 1.5 V = 0.23 A
The current going through the circuit is 0.23 A.

2. If the fan is connected to a battery with V=15 V and we assume that the resistance of the fan remains constant, we can use Ohm's law (V = IR) to find the new current and then find the new power.

First, find the resistance (R): R = V/I = 1.5 V / 0.23 A ≈ 6.52 Ω
Now, find the new current with V=15 V: [tex]I_{new}[/tex] = V/R = 15 V / 6.52 Ω ≈ 2.3 A
Finally, find the power now: P = VI = 15 V * 2.3 A ≈ 34.5 W

When the fan is connected to a battery with V=15 V, it uses 34.5 W of power.

To know more about voltage , refer here

https://brainly.com/question/13521443#

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