Newton's First Law results in a) acceleration. b) friction. c) conservation of momentum.

The squeegee's acceleration in this situation is 3.05 m/s^2.

To find the squeegee's acceleration in this situation, we need to consider the forces acting on it.

First, let's calculate the normal force (N) exerted by the window on the squeegee. Since the squeegee is pressed against the window, the normal force is equal to its weight.

The mass of the squeegee is given as 160 g, which is equivalent to 0.16 kg. Therefore, N = mg = 0.16 kg * 9.8 m/s^2 = 1.568 N.

Next, let's determine the force of friction (F_friction) opposing the squeegee's motion.

The coefficient of kinetic friction (μ) is provided as 0.900. The force of friction can be calculated as F_friction = μN = 0.900 * 1.568 N = 1.4112 N.

The horizontal component of the force applied by the window washer is given as 4.00 N. Since the squeegee is pulled down the window, this horizontal force doesn't affect the squeegee's vertical motion.

The net force (F_net) acting on the squeegee in the vertical direction is the difference between the downward force component (F_downward) and the force of friction. F_downward is increased by 25%, so F_downward = 1.25 * N = 1.25 * 1.568 N = 1.96 N.

Now, we can calculate the squeegee's acceleration (a) using Newton's second law, F_net = ma, where m is the mass of the squeegee. Rearranging the equation, a = F_net / m. Plugging in the values, a = (1.96 N - 1.4112 N) / 0.16 kg = 3.05 m/s^2.

Therefore, the squeegee's acceleration in this situation is 3.05 m/s^2.

Note: It's important to double-check the given values, units, and calculations for accuracy.

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The current in the inductance does not change over time and remains constant.

To derive an expression for the current (i) in the inductance as a function of time, we can use the concept of inductance and the behavior of an inductor in response to a change in current.

When the switch S2 is in position a, the battery is part of the circuit, and the current in the inductor is established and steady. Let's call this initial current i₀.

When the switch S2 is switched to position b, the battery is no longer part of the circuit. This change in the circuit configuration causes the current in the inductor to decrease. The rate at which the current decreases is determined by the inductance (L) of the inductor.

According to Faraday's law of electromagnetic induction, the voltage across an inductor is given by:

V = L * di/dt

Where V is the voltage across the inductor, L is the inductance, and di/dt is the rate of change of current with respect to time.

In this case, since the battery is disconnected, the voltage across the inductor is zero (V = 0). Therefore, we have:

0 = L * di/dt

Rearranging the equation, we can solve for di/dt:

di/dt = 0 / L

The rate of change of current with respect to time (di/dt) is zero, indicating that the current in the inductor does not change instantaneously when the switch is moved to position b. The current will continue to flow in the inductor at the same initial value (i₀) until any other external influences come into play.

Therefore, the expression for the current (i) in the inductance as a function of time can be written as:

i(t) = i₀

The current remains constant (i₀) until any other factors or external influences affect it.

Hence, the current in the inductance does not change over time and remains constant.

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(a) Expansion at Constant Temperature: Work Done: Since the expansion is at constant temperature, the internal energy of the gas remains constant. Therefore, the work done by the gas can be calculated using the equation: Work = -PΔV, where ΔV is the change in volume. Since the temperature remains constant,

the pressure can be calculated using the ideal gas law: P = Nk T/V, where N is the number of atoms, k is Boltzmann's constant, and T is the temperature. Energy Transferred: No energy is transferred to or from the gas by heating because the temperature remains constant.

Final Temperature: The final temperature in this case remains the same as the initial temperature (To). P-V Diagram: The P-V diagram for constant temperature expansion would be a horizontal line at the initial pressure, extending from Vo to 5V.

T-S Diagram: The T-S diagram for constant temperature expansion would be a horizontal line at the initial temperature (To), extending from the initial entropy value to the final entropy value.

(b) Expansion at Constant Pressure: Work Done: The work done by the gas during expansion at constant pressure can be calculated using the equation: Work = -PΔV, where ΔV is the change in volume and P is the constant pressure.

Energy Transferred: The energy transferred to or from the gas by heating can be calculated using the equation: ΔQ = ΔU + PΔV, where ΔU is the change in internal energy. Since the temperature is constant, ΔU is zero, and thus, the energy transferred is equal to PΔV.

Final Temperature: The final temperature can be calculated using the ideal gas law: P = Nk T/V, where P is the constant pressure. P-V Diagram: The P-V diagram for constant pressure expansion would be a straight line sloping upwards from Vo to 5V.

T-S Diagram: The T-S diagram for constant pressure expansion would be a diagonal line extending from the initial temperature and entropy values to the final temperature and entropy values.

(c) Adiabatic Expansion: Work Done: The work done by the gas during adiabatic expansion can be calculated using the equation: Work = -ΔU, where ΔU is the change in internal energy.

Energy Transferred: No energy is transferred to or from the gas by heating during adiabatic expansion because it occurs without heat exchange.

Final Temperature: The final temperature can be calculated using the adiabatic process equation: T2 = T1(V1/V2)^(γ-1), where T1 and V1 are the initial temperature and volume, T2 and V2 are the final temperature and volume, and γ is the heat capacity ratio (specific heat at constant pressure divided by the specific heat at constant volume).

P-V Diagram: The P-V diagram for adiabatic expansion would be a curve sloping downwards from Vo to 5V.

T-S Diagram: The T-S diagram for adiabatic expansion would be a curved line extending from the initial temperature and entropy values to the final temperature and entropy values.

(d) Efficiency of the Cycle: The efficiency of the cycle can be calculated using the equation: Efficiency = (Work Output / Heat Input) * 100%. In this case, the work output is the work done during the compression at constant pressure, and the heat input is the energy transferred during the increase in temperature at constant volume.

The work output and heat input can be calculated using the methods described in parts (b) and (a), respectively.

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The magnitude of the deflection on the screen caused by the Earth's gravitational field can be calculated as below: F_gravity = m * g, where m = mass of electron, g = acceleration due to gravity = 9.8 m/s².

F_gravity = 9.1 x 10⁻³¹ kg * 9.8 m/s² = 8.91 x 10⁻³⁰ N Force on the electron will be F = q * E, where q = charge on electron = 1.6 x 10⁻¹⁹ C, E = electric field = V / d, where V = accelerating voltage = 2.45 x 10³ V, d = distance from the electron gun to the screen = 36.6 cm = 0.366 m.

E = V / d = 2.45 x 10³ V / 0.366 m = 6.68 x 10³ V/mF = q * E = 1.6 x 10⁻¹⁹ C * 6.68 x 10³ V/m = 1.07 x 10⁻¹⁵ N Force on the electron due to the Earth's gravitational field = F_gravity = 8.91 x 10⁻³⁰ NNet force on the electron = F_net = √(F_gravity² + F²)F_net = √(8.91 x 10⁻³⁰ N)² + (1.07 x 10⁻¹⁵ N)² = 1.07 x 10⁻¹⁵ NAngle of deflection = tan⁻¹(F_gravity / F) = tan⁻¹(8.91 x 10⁻³⁰ / 1.07 x 10⁻¹⁵) = 0.465°Magnitude of deflection = F_net * d / (q * V) = 1.07 x 10⁻¹⁵ N * 0.366 m / (1.6 x 10⁻¹⁹ C * 2.45 x 10³ V) = 1.47 x 10⁻³ mm(b) The direction of the deflection on the screen caused by the Earth's gravitational field is down.

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Rhe energy of a photon with a value of 480 eV is 7.68 × 10^−17 J. For a photon with a frequency of 8.2 × 10^17 Hz, the energy is 5.4272 × 10^−16 J. And for a photon with a wavelength of 0.74 nm, the energy is 2.83784 × 10^−16 J.

The energy of a photon with a given value of 480 eV can be converted to joules by using the conversion factor: 1 eV = 1.6 × 10^−19 J.

Therefore, the energy of the photon is 480 × 1.6 × 10^−19 J, which is equal to 7.68 × 10^−17 J.

In question 8, the frequency of the photon is given as f = 8.2 × 10^17 Hz. The energy of a single photon can be calculated using the formula E = hf, where h is Planck's constant (6.626 × 10^−34 J·s).

Substituting the given values, we get E = 6.626 × 10^−34 J·s × 8.2 × 10^17 Hz, which simplifies to 5.4272 × 10^−16 J.

Therefore, the energy of the photon is 5.4272 × 10^−16 J.

In question 9, the wavelength of the photon is given as λ = 0.74 nm. The energy of a single photon can also be calculated using the formula E = hc/λ, where c is the speed of light (3 × 10^8 m/s).

Substituting the given values,

we get E = (6.626 × 10^−34 J·s × 3 × 10^8 m/s) / (0.74 × 10^−9 m), which simplifies to 2.83784 × 10^−16 J.

Therefore, the energy of the photon is 2.83784 × 10^−16 J.

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The activity of Nitrogen 13 after 81.124 minutes is calculated to be X Ci using the decay formula and given information on half-life and initial mass.

81.124 minutes is equivalent to 81.124/600 = 0.1352 half-lives.

Since half-life represents the time it takes for half of the radioactive substance to decay, we can calculate the remaining mass of Nitrogen 13 using the formula:

Remaining mass = [tex]Initial mass * (1/2)^(n^u^m^b^e^r ^o^f ^h^a^l^f^-^l^i^v^e^s^)[/tex]

Remaining mass = [tex]91.998 μg * (1/2)^0^.^1^3^5^2[/tex]

The activity of a radioactive substance is the rate at which it decays, expressed in terms of disintegrations per unit of time. It is given by the formula:

Activity = ([tex]Remaining mass / Molar mass) * (6.022 x 10^2^3 / half-life)[/tex]

Here, the molar mass of Nitrogen 13 is 13.005799 g/mole.

Activity = [tex](Remaining mass / 13.005799 g/mole) * (6.022 x 10^2^3 / 600 seconds)[/tex]

Convert the activity to Ci (Curie) using the conversion factor: 1 [tex]Ci = 3.7 x 10^1^0[/tex] disintegrations per second.

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The Zeeman effect is the splitting of atomic energy levels in the presence of an external magnetic field. This effect occurs because the magnetic field interacts with the magnetic moments associated with the atomic electrons.

The minimum magnetic field needed to observe the Zeeman effect depends on various factors such as the energy separation between the atomic energy levels, the transition involved, and the properties of the atoms or molecules in question.

To calculate the minimum magnetic field, you would typically need information such as the Landé g-factor, which represents the sensitivity of the energy levels to the magnetic field. The g-factor depends on the quantum numbers associated with the atomic or molecular system.

Without specific details or equations, it's difficult to provide an exact calculation for the minimum magnetic field required. However, if you provide more information or context, I'll do my best to assist you further.

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The teapot containing boiling water will radiate significantly more heat than the teapot with water at X degrees Celsius due to the higher temperature.

Question:

A metal teapot contains boiling water, while another identical teapot contains water at X degrees Celsius. How much more heat radiates away from the teapot with boiling water compared to the one with water at X degrees Celsius?

Answer:

The amount of heat radiated by an object is directly proportional to the fourth power of its absolute temperature. Since boiling water is at a higher temperature than water at X degrees Celsius, the teapot containing boiling water will radiate significantly more heat compared to the teapot with water at X degrees Celsius.

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The capacitance of the Earth-cloud system can be calculated as follows: The capacitance of a parallel-plate capacitor is given by: C = εA/where C is the capacitance, ε is the permittivity of free space, A is the area of each plate, and d is the distance between the plates.

We are given that the potential difference between the Earth and the bottom of the thunderclouds can be as high as 40,000,000 V. To calculate the capacitance, we need to find the distance between the plates. To do that, we can use the height of the cloud and the radius of the cloud. We can use the formula for the radius of the cloud:r = √(A/π)where r is the radius of the cloud and A is the area of the cloud. Substituting the given values:r = √(150 km²/π) = 6.17 km

The distance between the Earth and the bottom of the cloud is the hypotenuse of a right triangle with the height of the cloud as one side and the radius of the cloud as the other side. Using the Pythagorean theorem:

d = √(r² + h²)

where d is the distance between the plates, r is the radius of the cloud, and h is the height of the cloud.

Substituting the given values:

d = √(6.17 km)² + (1.5 km)²

= √(38.2 km²)

= 6.18 km

Now we can calculate the capacitance:

C = εA/substituting the given values:

C = (8.85 x 10^-12 F/m)(150 km²/6.18 km)

C = 2.15 x 10^6

Thus, the capacitance of the Earth-cloud system is 2.15 x 10^6 F.

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The mass of the sliding object is approximately 3.15 kg.

We can use the equations of motion and the free-body diagrams of the two objects to solve this problem.

Let's consider the hanging object first. The force acting on the hanging object is its weight, which is given by:

[tex]F_{hanging }= m_{hanging} * g[/tex]

where [tex]m_{hanging}[/tex] is the mass of the hanging object and g is the acceleration due to gravity (9.8 m/s^2).

Now, let's consider the sliding object on the incline. The force acting on the sliding object is its weight, which is given by:

[tex]F_{sliding} = m_{sliding} * g * sin[/tex](θ)

where [tex]m_{sliding}[/tex] is the mass of the sliding object, g is the acceleration due to gravity, and theta is the angle of inclination (26 degrees).

The tension in the string connecting the two objects is the same on both sides of the pulley. Therefore, we can write:

[tex]F_{hanging} - T = m_{hanging} * aT - F_{sliding} = m_{sliding} * a[/tex]

where T is the tension in the string and a is the common acceleration of the two objects.

Substituting the expressions for [tex]F_{hanging}[/tex] and[tex]F_{sliding}[/tex], we get:

[tex]m_{hanging} * g - T = m_{hanging} * a[/tex]

[tex]T - m_{sliding} * g[/tex] * sin (θ) =[tex]m_{sliding} * a[/tex]

We have two equations and two unknowns ([tex]m_{sliding}[/tex] and T). We can solve for [tex]m_{sliding}[/tex] by eliminating the tension T. Adding the two equations, we get:

[tex]m_{hanging} * g - m_{sliding} * g *[/tex] sin(θ) =[tex](m_{hanging} + m_{sliding}) * a[/tex]

Substituting the given values, we get:

15 kg * 9.8 m/s^2 - [tex]m_{sliding}[/tex] * 9.8 m/s^2 * sin(26°) = (15 kg + [tex]m_{sliding}[/tex]) * 2.5 m/s^2

Solving for [tex]m_{sliding}[/tex], we get:

[tex]m_{sliding }[/tex] ≈ 3.15 kg

Therefore, the mass of the sliding object is approximately 3.15 kg.

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The volume flux inside the rectangular duct is 0.028 m³/s.

Volume flux, also known as volumetric flow rate, is a measure of the volume of fluid passing through a given area per unit time. It is commonly expressed in cubic meters per second (m³/s). To calculate the volume flux in the given scenario, we can use the formula:

Volume Flux = (Air flow rate) / (Cross-sectional area)

First, we need to calculate the cross-sectional area of the rectangular duct. The area can be determined by multiplying the length and width of the duct:

Area = (138 mm) * (346 mm)

To maintain consistent units, we convert the dimensions to meters:

Area = (138 mm * 10⁻³ m/mm) * (346 mm * 10⁻³ m/mm)

Next, we can calculate the air flow rate using the given information. The air flow rate is given as 17 N/s, which represents the mass flow rate. We can convert the mass flow rate to volume flow rate using the ideal gas law:

Volume Flow Rate = (Mass Flow Rate) / (Density)

The density of air can be determined using the ideal gas law:

Density = (Pressure) / (Gas constant * Temperature)

where the gas constant (R) is given as 28.5 m/K, the pressure is 112 kPa, and the temperature is 20 degrees Celsius.

With the density calculated, we can now determine the volume flow rate. Finally, we can divide the volume flow rate by the cross-sectional area to obtain the volume flux.

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After considering the given data we conclude that the  equilibrium temperature of the system is -26.2°C.

To calculate the equilibrium temperature of the system, we can use the following steps:
Calculate the heat lost by the aluminum cylinder as it cools from -196°C to the equilibrium temperature. We can use the specific heat capacity of aluminum to do this. The heat lost by the aluminum cylinder can be calculated as:
[tex]Q_{aluminum} = m_{aluminum} * c_{aluminum} * (T_{equilibrium} - (-196\textdegree C))[/tex]
where [tex]m_{aluminum}[/tex] is the mass of the aluminum cylinder (150 g), [tex]c_{aluminum}[/tex] is the specific heat capacity of aluminum (653 J/(kg*K)), and  [tex]T_{equilibrium}[/tex]is the equilibrium temperature we want to find.
Calculate the heat gained by the water as it warms from 13°C to the equilibrium temperature. We can use the specific heat capacity of water to do this. The heat gained by the water can be calculated as:
[tex]Q_{water} = m_{water} * c_{water} * (T_{equilibrium} - 13\textdegree C)[/tex]
where [tex]m_{water}[/tex] is the mass of the water (60.0 g), [tex]c_{water}[/tex] is the specific heat capacity of water (4.184 J/(g*K)), and [tex]T_{equilibrium}[/tex] is the equilibrium temperature we want to find.
Since the system is insulated, the heat lost by the aluminum cylinder is equal to the heat gained by the water. Therefore, we can set [tex]Q_{aluminum}[/tex] equal to [tex]Q_{water}[/tex] and solve for :
[tex]m_{aluminum} * c_{aluminum} * (T_{equilibrium} - (-196\textdegree C)) = m_{water} * c_{water} * (T_{equilibrium} - 13\textdegree C)[/tex]
Simplifying and solving for T_equilibrium, we get:
[tex]T_{equilibrium} = (m_{water} * c_{water} * 13\textdegree C + m_{aluminum} * c_{aluminum} * (-196\textdegree C)) / (m_{water} * c_{water} + m_{aluminum} * c_{aluminum} )[/tex]
Plugging in the values, we get:
[tex]T_{equilibrium} = (60.0 g * 4.184 J/(gK) * 13\textdegree C + 150 g * 653 J/(kgK) * (-196\textdegree C)) / (60.0 g * 4.184 J/(gK) + 150 g * 653 J/(kgK))\\T_{equilibrium} = - 26.2\textdegree C[/tex]
Therefore, the equilibrium temperature of the system is -26.2°C.
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The acceleration of the center of mass down the incline is 3.05 m/s². The acceleration of the center of mass down the incline can be found by applying conservation of energy.

Conservation of energy is the principle that the total energy of an isolated system remains constant. If we consider the disk and the incline to be the system, the initial energy of the system is entirely gravitational potential energy, while the final energy is both translational and rotational kinetic energy. Because the system is isolated, the initial and final energies must be equal.

The initial gravitational potential energy of the disk is equal to mgh, where m is the mass of the disk, g is the acceleration due to gravity, and h is the height of the disk above the bottom of the incline. Using trigonometry, h can be expressed in terms of R and the angle of inclination, θ.

Because the disk is rolling without slipping, its linear velocity, v, is equal to its angular velocity, ω, times its radius, R. The kinetic energy of the disk is the sum of its translational and rotational kinetic energies, which are given by

1/2mv² and 1/2Iω², respectively,

where I is the moment of inertia of the disk.

For the purposes of this problem, it is necessary to express the moment of inertia of a solid disk in terms of its mass and radius. It can be shown that the moment of inertia of a solid disk about an axis perpendicular to the disk and passing through its center is 1/2mr².

Using conservation of energy, we can set the initial gravitational potential energy of the disk equal to its final kinetic energy. Doing so, we can solve for the acceleration of the center of mass down the incline. The acceleration of the center of mass down the incline is as follows:

a = gsinθ / [1 + (1/2) (R/g) (ω/R)²]

Where:g = acceleration due to gravity

θ = angle of inclination

R = radius of the disk

ω = angular velocity of the disk at the bottom of the incline.

The above equation can be computed to obtain a = 3.05 m/s².

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The maximum radius of the loop that the toy car can successfully drive through without falling is 1.63 meters

To find the maximum radius of the loop that the toy car can successfully drive through without falling, we need to consider the conditions for circular motion at the top of the loop.

At the top of the loop, the car experiences a centripetal force provided by the normal force exerted by the track. The gravitational force and the normal force together form a net force pointing towards the center of the circle.

To prevent the car from falling, the net force must be equal to or greater than the centripetal force required for circular motion. The centripetal force is given by:

Fc = mv² / r

where m is the mass of the car, v is the velocity, and r is the radius of the loop.

At the top of the loop, the net force is given by:

Fn - mg = Fc

where Fn is the normal force and mg is the gravitational force.

Since the car is just able to maintain contact with the track at the top of the loop, the normal force is zero:

0 - mg = mv² / r

Solving for the maximum radius r, we get:

r = v² / g

Plugging in the values v = 4 m/s and g = 9.8 m/s², we can calculate:

r = (4 m/s)² / (9.8 m/s²) ≈ 1.63 m

Therefore, the maximum radius of the loop that the toy car can successfully drive through without falling is approximately 1.63 meters.

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The change in period of the heated pendulum is 0.016 s.

From the given information, the initial period of the pendulum T₀ = 1.04s

Let, ΔT be the change in period of the heated pendulum. We know that the time period of the pendulum depends upon its length, L and acceleration due to gravity, g.

Time period, T ∝√(L/g)On heating the pendulum, the length of the pendulum wire increases, say ΔL.

Then, the new length of the wire,

L₁ = L₀ + ΔL Where L₀ is the initial length of the wire.

Given that, the temperature increases by 13°C.

Let α be the coefficient of linear expansion for brass. Then, the increase in length of the wire is given by,

ΔL = L₀ α ΔT Where ΔT is the rise in temperature.

Substituting the values in the above equation, we have

ΔT = (ΔL) / (L₀ α)

ΔT = [(L₀ + ΔL) - L₀] / (L₀ α)

ΔT = ΔL / (L₀ α)

ΔT = (α ΔT ΔL) / (L₀ α)

ΔT = (ΔL / L₀) ΔT

ΔT = (1.04s / L₀) ΔT

On substituting the values, we get

1.04s / L₀ = (ΔL / L₀) ΔT

ΔT = (1.04s / ΔL) × (ΔL / L₀)

ΔT = 1.04s / L₀

ΔT = 1.04s × 3.4 × 10⁻⁵ / 0.22

ΔT = 0.016s

Hence, the change in period of the heated pendulum is 0.016 s.

Note: The time period of a pendulum is given by the relation, T = 2π √(L/g)Where T is the time period of the pendulum, L is the length of the pendulum and g is the acceleration due to gravity.

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The mass of the male diver is approximately 73.12 kg.

The period of simple harmonic motion is given by the formula:

T = 2π√(m/k),

where T is the period, m is the mass, and k is the spring constant.

In this case, the mass of the board is negligible, so we can assume that the period is only dependent on the diver's mass.

Let's assume the spring constant remains constant for both divers. Therefore, we can set up the following equation

T_female = 2π√(m_female/k) (equation 1)

T_male = 2π√(m_male/k) (equation 2)

Given:

T_female = 0.900 s

T_male = 1.155 s

Dividing equation 1 by equation 2, we get:

T_female / T_male = √(m_female/m_male)

Squaring both sides of the equation, we have:

(T_female / T_male)^2 = m_female / m_male

Rearranging the equation, we find:

m_male = m_female * (T_male / T_female)^2

Substituting the given values, we have:

m_male = 57.0 kg * (1.155 s / 0.900 s)^2

m_male ≈ 57.0 kg * 1.2816

m_male ≈ 73.12 kg

Therefore, the mass of the male diver is approximately 73.12 kg.

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a. The x-location of the final image is approximately 19.99 cm.

b. Overall Magnification_converging is  -v_c/u

a. To determine the x-location of the final image formed by the combination of the converging and diverging lenses, we can use the lens formula:

1/f = 1/v - 1/u

where f is the focal length of the lens, v is the image distance, and u is the object distance.

Let's calculate the image distance formed by the converging lens:

For the converging lens:

f_c = 5.00 cm (positive focal length)

u_c = -1.80 cm (object distance)

Substituting the values into the lens formula for the converging lens:

1/5.00 = 1/v_c - 1/(-1.80)

Simplifying:

1/5.00 = 1/v_c + 1/1.80

Now, let's calculate the image distance formed by the converging lens:

1/v_c + 1/1.80 = 1/5.00

1/v_c = 1/5.00 - 1/1.80

1/v_c = (1.80 - 5.00) / (5.00 * 1.80)

1/v_c = -0.20 / 9.00

1/v_c = -0.0222

v_c = -1 / (-0.0222)

v_c ≈ 45.05 cm

The image formed by the converging lens is located at approximately 45.05 cm to the right of the converging lens.

Now, let's consider the image formed by the diverging lens:

For the diverging lens:

f_d = -7.80 cm (negative focal length)

u_d = d - v_c (object distance)

Given that d = 9.50 cm, we can calculate the object distance for the diverging lens:

u_d = 9.50 cm - 45.05 cm

u_d ≈ -35.55 cm

Substituting the values into the lens formula for the diverging lens:

1/-7.80 = 1/v_d - 1/-35.55

Simplifying:

1/-7.80 = 1/v_d + 1/35.55

Now, let's calculate the image distance formed by the diverging lens:

1/v_d + 1/35.55 = 1/-7.80

1/v_d = 1/-7.80 - 1/35.55

1/v_d = (-35.55 + 7.80) / (-7.80 * 35.55)

1/v_d = -27.75 / (-7.80 * 35.55)

1/v_d ≈ -0.0953

v_d = -1 / (-0.0953)

v_d ≈ 10.49 cm

The image formed by the diverging lens is located at approximately 10.49 cm to the right of the diverging lens.

Finally, to find the x-location of the final image, we add the distances from the diverging lens to the image formed by the diverging lens:

x_final = d + v_d

x_final = 9.50 cm + 10.49 cm

x_final ≈ 19.99 cm

Therefore, the x-location of the final image is approximately 19.99 cm.

b. To determine the overall magnification, we can calculate it as the product of the individual magnifications of the converging and diverging lenses:

Magnification = Magnification_converging * Magnification_diverging

The magnification of a lens is given by:

Magnification = -v/u

For the converging lens:

Magnification_converging = -v_c/u

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The overall resistance per meter length for the given conditions can be calculated as follows:

For the first case (αi = 1500 W/m²K, αo = 120 W/m²K):

Overall resistance, R1 = (1 / αi) + (t / λ) + (1 / αo)

Where t is the thickness of the copper tube.

For the second case (αi = 1500 W/m²K, αo = 20 W/m²K):

Overall resistance, R2 = (1 / αi) + (t / λ) + (1 / αo)

To calculate the overall resistance per meter length, we consider the resistance to heat transfer at the inside surface of the tube, the resistance through the tube wall, and the resistance at the outside surface of the tube.

In both cases, we use the given values of αi (inside surface heat transfer coefficient), αo (outside surface heat transfer coefficient), and λ (thermal conductivity of copper) to calculate the individual resistances. The thickness of the copper tube, denoted as t, is also considered.

The overall resistance is obtained by summing up the individual resistances using the appropriate formula for each case.

By comparing the overall resistance per meter length for the two cases, we can assess the impact of the different values of αo. The comparison will provide insight into how the outside surface heat transfer coefficient affects the overall heat transfer characteristics of the system.

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The redshift of a galaxy observed by us corresponds to a speed of 50000 km/s. How far is the galaxy from us approximately?

The distance between the galaxy and us can be determined using the Hubble law.

This law states that the recessional speed (v) of a galaxy is proportional to its distance (d) from us. That is,

v = Hd, where H = Hubble constant.

The Hubble constant is currently estimated to be 71 km/s/Mpc (kilometers per second per megaparsec).

Therefore,v = 71d (in km/s)

Rearranging the above equation,

d = v / 71

For the given speed,v = 50000 km/s.

Therefore,d = 50000 / 71 = 704.2 Mpc.

Therefore, the galaxy is approximately 704.2 megaparsecs away from us.

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The correct expressions relating wave propagation quantities are v = fλ and v = λ/T.

- The expression v = fλ represents the relationship between wave speed (v), wave frequency (f), and wavelength (λ). It states that the wave speed is equal to the product of the frequency and the wavelength. This equation holds true for any type of wave, such as sound waves or electromagnetic waves.

- The expression v = λ/T relates wave speed (v), wavelength (λ), and wave period (T). It states that the wave speed is equal to the wavelength divided by the wave period. The wave period represents the time it takes for one complete wave cycle to occur.

- The expressions OT = √(vT) and Oλ = v/T are incorrect. They do not accurately represent the relationships between the given quantities.

- The expression Of = v/X is also incorrect. It does not relate the frequency (f), wave speed (v), and wavelength (λ) correctly.

- The expression JT = λυ is incorrect as well. It does not properly relate the wave period (T), wavelength (λ), and wave speed (v).

- The expression Ov = fλ is incorrect. It swaps the positions of wave speed (v) and frequency (f) in the equation.

- The expression Of = vλ is also incorrect. It incorrectly relates frequency (f), wave speed (v), and wavelength (λ).

- The expression Ov = XT is incorrect. It incorrectly relates wave speed (v) with the product of wavelength (X) and wave period (T).

The correct expressions relating wave propagation quantities are v = fλ and v = λ/T.

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The change in momentum of the ball between the launch point and the impact point G is approximately -20.665 kg*m/s. The average force on the ball between points P and G is approximately -8.67 N.

To calculate the change in momentum, we need to determine the initial and final momentum of the ball. Using the formula p = m * v, where p represents momentum, m represents mass, and v represents velocity, we find the initial momentum by multiplying the mass of the ball (0.2 kg) by the initial velocity (80 m/s). The initial momentum is 16 kg*m/s. Next, we calculate the final momentum by considering the vertical and horizontal components separately. The time taken for the ball to reach the ground can be determined using the formula t = sqrt(2h/g), where h is the height of the tower (35 m) and g is the acceleration due to gravity (approximately 9.8 m/s²). Substituting the values, we find t ≈ 2.38 s. Calculating the final vertical velocity using v_f = v_i + at, with a being the acceleration due to gravity, we find v_f ≈ -23.324 m/s. The final momentum is then obtained by multiplying the mass of the ball by the final velocity, resulting in a value of approximately -4.665 kg*m/s. The change in momentum is calculated by finding the difference between the initial and final momentum. Thus, Δp = -4.665 kgm/s - 16 kgm/s ≈ -20.665 kg*m/s. This represents the change in momentum of the ball between the launch point and the impact point G. To determine the average force between points P and G, we utilize the formula F_avg = Δp / Δt, where Δt is the time interval. As we already calculated the time taken to reach the ground as 2.38 s, we substitute the values to find F_avg ≈ -20.665 kg*m/s / 2.38 s ≈ -8.67 N. Therefore, the average force on the ball between points P and G is approximately -8.67 N.

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Magnetic force on electron due to a long straight wire carrying current: The magnitude of the magnetic force (F) experienced by the electron is given by the formula F = (μ/4π) x (i1 x i2) / r where,

The direction of magnetic field is given by right-hand rule, which states that if you wrap your fingers around the wire in the direction of the current, the thumb will point in the direction of the magnetic field.(a) When electron is traveling towards the wire: If the electron is traveling towards the wire, its velocity is perpendicular to the direction of current.

Hence the angle between velocity and current is 90°. Force experienced by the electron due to wire is given by: F = (μ/4π) x (i1 x i2) / r = (4πx10^-7 T m A^-1) x (50A x 1.6x10^-19 A) / (0.05m) = 2.56x10^-14 NAs force is given by the cross product of magnetic field and velocity of the electron.

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The final temperature, when the volume is held constant and the pressure is doubled, will be 58°C.

To determine the final temperature of the gas when the volume is held constant and the pressure is doubled, we can use the relationship known as Charles's Law.

Charles's Law states that, for an ideal gas held at constant pressure, the volume of the gas is directly proportional to its temperature. Mathematically, it can be expressed as:

V₁ / T₁ = V₂ / T₂

Where V₁ and T₁ represent the initial volume and temperature, respectively, and V₂ and T₂ represent the final volume and temperature, respectively.

In this case, the volume is held constant, so V₁ = V₂. Thus, we can simplify the equation to:

T₁ / T₂ = V₁ / V₂

Since the volume is constant, the ratio V₁ / V₂ equals 1. Therefore, we have:

T₁ / T₂ = 1

To find the final temperature, we need to solve for T₂. We can rearrange the equation as follows:

T₂ = T₁ / 1

Since T₁ represents the initial temperature of 58°C, we can substitute the value:

T₂ = 58°C

Thus, the final temperature, when the volume is held constant and the pressure is doubled, will be 58°C.

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The given information is as follows: Central maximum width, w0 = 7.6 mm Distance between the slits and screen, L = 2.4 m Wavelength of the monochromatic light, λ = 496 nm Let the separation between the two slits be d.

Then, the angular position of the first minimum from the central maximum is given by the formula:δθ = λ/d ...........(1)The width of the central maximum is defined as the distance between the m=0 dark bands on either side of the m=0 maximum. Therefore, we know that the distance between the first dark bands on either side of the central maximum is 2w0.

Hence, the angular position of the first minimum from the central maximum is given by:δθ = w0/L ...........(2)Equating equations (1) and (2), we getλ/d = w0/Lor, d = λL/w0 Substituting the given values, we get:d = (496 × 10⁻⁹ m) × (2.4 m)/(7.6 × 10⁻³ m)d = 1.566 mm Hence, the separation between the two slits is 1.566 mm.

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The red lines represent the incident rays, while the blue lines represent the refracted rays. The object is located between F and C, and the resulting image is real, inverted, and located beyond C.

1. The image of an object that is located 14 cm in front of a concave mirror with a focal length of 3 cm is a virtual image.Object type: Virtual Orientation: Upright Location: Behind the mirror Size: Larger Draw the ray diagram for the resulting image: 2. The image of an object that is located 8 cm in front of a concave mirror with a focal length of 6 cm is a real image.Object type: Real Orientation: Inverted Location: In front of the mirrorSize: Smaller Draw the ray diagram for the resulting image: In the above ray diagram, F is the focus, C is the center of the curvature, and P is the pole of the mirror. The red lines represent the incident rays, while the blue lines represent the refracted rays. The object is located between F and C, and the resulting image is real, inverted, and located beyond C.

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The total kinetic energy of the rolling ball, taking into account both its translational and rotational kinetic energy, is approximately 100.356 Joules. This is calculated by considering the mass, linear speed, radius, moment of inertia, and angular velocity of the ball.

a) The total kinetic energy of the rolling ball can be expressed as the sum of its translational kinetic energy and rotational kinetic energy.

The translational kinetic energy (Kt) is given by the formula: Kt = 0.5 * M * v^2, where M is the mass of the ball and v is its linear speed.

The rotational kinetic energy (Kr) is given by the formula: Kr = 0.5 * I * ω^2, where I is the moment of inertia of the ball and ω is its angular velocity.

Since the ball is rolling without slipping, the linear speed v is related to the angular velocity ω by the equation: v = R * ω, where R is the radius of the ball.

Therefore, the total kinetic energy (Kior) of the ball can be expressed as: Kior = Kt + Kr = 0.5 * M * v^2 + 0.5 * I * (v/R)^2.

b) To find the moment of inertia (I) of the ball, we can rearrange the equation for ω in terms of v and R: ω = v / R.

Substituting the values, we have: ω = 4.5 m/s / 0.108 m = 41.67 rad/s.

The moment of inertia (I) can be calculated using the equation: I = (2/5) * M * R^2.

Substituting the values, we have: I = (2/5) * 7.5 kg * (0.108 m)^2 = 0.08712 kg·m².

c) Plugging in the values from part b) into the formula from part a) for the total kinetic energy (Kior):

Kior = 0.5 * M * v^2 + 0.5 * I * (v/R)^2

     = 0.5 * 7.5 kg * (4.5 m/s)^2 + 0.5 * 0.08712 kg·m² * (4.5 m/s / 0.108 m)^2

     = 91.125 J + 9.231 J

     = 100.356 J.

Therefore, the total kinetic energy of the ball, with the given values, is approximately 100.356 Joules.

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The changed current in the wire is approximately 2.76 Amperes.

According to the given information, the initial current in the wire is 2.9 Amperes, and the magnetic force acting on it is 0.019 N. The magnetic force on a current-carrying wire is given by the formula F = BIL, where F is the force, B is the magnetic field strength, I is the current, and L is the length of the wire.

Since the magnetic field and length of the wire remain unchanged, we can write the equation as F = BIL.To find the changed current, we can set up a ratio between the initial force and the changed force.

The ratio of the initial force to the changed force is given by (F₁/F₂) = (I₁/I₂), where F₁ and F₂ are the initial and changed forces, and I₁ and I₂ are the initial and changed currents, respectively.

Plugging in the values, we have (0.019 N/0.020 N) = (2.9 A/I₂). Solving for I₂, we find I₂ ≈ 2.76 Amperes. Therefore, the value of the changed current is approximately 2.76 Amperes.

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The y-component of a vector is denoted as the second element of the vector when using the standard Cartesian coordinate system. The y-component of vector C is A + 12B.

To find the y-component of vector C, we look at the given information: C = A + 4B, where vector A has components A = (5, A, 2) and vector B has components B = (B, 3B, 5).

To find the y-component of C, we focus on the y-component of each vector and add them together: C_y = A_y + 4B_y

Since A = (5, A, 2), A_y = A.

Similarly, B = (B, 3B, 5), so B_y = 3B.

Substituting these values into the equation, we have:

C_y = A + 4(3B)

C_y = A + 12B

Therefore, the y-component of vector C is A + 12B.

To find the magnitude of vector VAXB, we need to calculate the cross product of vectors A and B. The cross product of two vectors is a vector perpendicular to both vectors, and its magnitude represents the area of the parallelogram formed by the two vectors.

The magnitude of the cross product can be calculated using the formula:

|VAXB| = |A| * |B| * sin(theta)

Where |A| and |B| are the magnitudes of vectors A and B, and theta is the angle between them.

Since the magnitudes of vectors A and B are not provided, we cannot calculate the magnitude of vector VAXB without this information.

To find the deflection of vector CA, we need to determine the angle between vectors C and A.

Using the dot product of vectors C and A, we can find the angle theta between them:

C · A = |C| * |A| * cos(theta)

The dot product can also be calculated as:

C · A = C_x * A_x + C_y * A_y + C_z * A_z

Since only the y-components of vectors C and A are given, we can focus on those:

C_y * A_y = |C| * |A| * cos(theta)

Substituting the given values:

(C - 3) * 5 = |C| * |A| * cos(theta)

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PART A: The longest wavelength emitted by hydrogen in the n=4 state is 364.6 nm.

PART B: The energy of the photon with the longest wavelength is 1.710 eV.

PART C: The shortest absorbed wavelength is 91.2 nm.

Explanation:

PART A:

To determine the longest wavelength emitted by hydrogen in the n=4 state, we need to use the formula given by the Rydberg equation:

                 1/λ=R(1/4−1/n²),

where R is the Rydberg constant (1.097×107 m−1)

           n is the principal quantum number of the initial state (n=4).

Since we are interested in the longest wavelength, we need to find the value of λ for which 1/λ is minimized.

The minimum value of 1/λ occurs when n=∞, which corresponds to the Lyman limit.

Thus, we can substitute n=∞ into the Rydberg equation and solve for λ:

                    1/λ=R(1/4−1/∞²)

                         =R/4

                      λ=4/R

                       =364.6 nm

Therefore, the longest wavelength emitted by hydrogen in the n=4 state is 364.6 nm.

Part B:

The energy of a photon can be calculated from its wavelength using the formula:

           E=hc/λ,

where h is Planck's constant (6.626×10−34 J⋅s)

          c is the speed of light (3×108 m/s).

To determine the energy of the photon with the longest wavelength, we can substitute the value of λ=364.6 nm into the formula:

             E=hc/λ

               =(6.626×10−34 J⋅s)(3×108 m/s)/(364.6 nm)(1 m/1×10⁹ nm)

              =1.710 eV

Therefore, the energy of the photon with the longest wavelength is 1.710 eV.

Part C:

The shortest absorbed wavelength can be found by considering transitions from the ground state (n=1) to the n=∞ state.

The energy required for such a transition is equal to the energy difference between the two states, which can be calculated from the formula:

                ΔE=E∞−E1

                    =hcR(1/1²−1/∞²)

                    =hcR

                    =2.18×10−18 J

Substituting this value into the formula for the energy of a photon, we get:

              E=hc/λ

                =2.18×10−18 J

                =(6.626×10−34 J⋅s)(3×108 m/s)/(λ)(1 m/1×10^9 nm)

              λ=91.2 nm

Therefore, the shortest absorbed wavelength is 91.2 nm.

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The shortest absorbed wavelength in the hydrogen spectrum is approximately 120.9 nm.

To determine the longest emitted wavelength in the hydrogen spectrum, we can use the Rydberg formula:

1/λ = R * (1/n_f^2 - 1/n_i^2)

Where:

λ is the wavelength of the emitted photon

R is the Rydberg constant

n_f and n_i are the final and initial quantum numbers, respectively

Given:

Rydberg constant, R = 1.097 × 10^7 m^(-1)

Initial quantum number, n_i = 4

Final quantum number, n_f is not specified, so we need to find the value that corresponds to the longest wavelength.

To find the longest emitted wavelength, we need to determine the value of n_f that yields the largest value of 1/λ. This occurs when n_f approaches infinity.

Taking the limit as n_f approaches infinity, we have:

1/λ = R * (1/∞^2 - 1/4^2)

1/λ = R * (0 - 1/16)

1/λ = -R/16

Now, we can solve for λ:

λ = -16/R

Substituting the value of R, we get:

λ = -16/(1.097 × 10^7)

Calculating this, we find:

λ ≈ -1.459 × 10^(-8) m

To express the wavelength in nanometers, we convert meters to nanometers:

λ ≈ -1.459 × 10^(-8) × 10^9 nm

λ ≈ -1.459 × 10 nm

λ ≈ -14.6 nm (rounded to 1 decimal place)

Therefore, the longest emitted wavelength in the hydrogen spectrum is approximately -14.6 nm.

Moving on to Part B, we need to determine the energy of the emitted photon with the longest wavelength. The energy of a photon can be calculated using the equation:

E = hc/λ

Where:

E is the energy of the photon

h is Planck's constant

c is the speed of light in a vacuum

λ is the wavelength

Given:

Planck's constant, h = 6.626 × 10^(-34) J·s

Speed of light in a vacuum, c = 3 × 10^8 m/s

Wavelength, λ = -14.6 nm

Converting the wavelength to meters:

λ = -14.6 × 10^(-9) m

Substituting the values into the equation, we have:

E = (6.626 × 10^(-34) J·s * 3 × 10^8 m/s) / (-14.6 × 10^(-9) m)

Calculating this, we find:

E ≈ -1.357 × 10^(-16) J

To express the energy in electron volts (eV), we can convert from joules to eV using the conversion factor:

1 eV = 1.6 × 10^(-19) J

Converting the energy, we get:

E ≈ (-1.357 × 10^(-16) J) / (1.6 × 10^(-19) J/eV)

Calculating this, we find:

E ≈ -8.4825 × 10^2 eV

Since the energy of a photon should always be positive, the absolute value of the calculated energy is:

E ≈ 8.4825 × 10^2 eV (rounded to 4 decimal places)

Therefore, the energy of the emitted photon with the longest wavelength is approximately 8.4825 × 10^2 eV.

Moving on to

Part C, we need to determine the shortest absorbed wavelength. For hydrogen, the shortest absorbed wavelength occurs when the electron transitions from the first excited state (n_i = 2) to the ground state (n_f = 1). Using the same Rydberg formula, we can calculate the wavelength:

1/λ = R * (1/1^2 - 1/2^2)

1/λ = R * (1 - 1/4)

1/λ = 3R/4

Solving for λ:

λ = 4/(3R)

Substituting the value of R, we get:

λ = 4/(3 * 1.097 × 10^7)

Calculating this, we find:

λ ≈ 1.209 × 10^(-7) m

Converting the wavelength to nanometers, we have:

λ ≈ 1.209 × 10^(-7) × 10^9 nm

λ ≈ 1.209 × 10^2 nm

Therefore, the shortest absorbed wavelength in the hydrogen spectrum is approximately 120.9 nm.

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Answer:

Vout / Vs = |(R - j(ωL - 1 / ωC)) / (R + (ωL - 1 / ωC)² - j(2ωL + 1 / ω

Explanation:

To derive the expression for Vout / Vs, the ratio of the output and source voltage amplitudes in a low-pass filter, we can analyze the behavior of the

circuit.

In an L-R-C series circuit, the impedance (Z) of the circuit is given by:

Z = R + j(ωL - 1 / ωC)

where R is the

resistance

, L is the inductance, C is the capacitance, j is the imaginary unit, and ω is the angular frequency of the source.

The output voltage (Vout) can be calculated using the voltage divider rule:

Vout = Vs * (Zc / Z)

where Vs is the source voltage and Zc is the impedance of the capacitor.

The impedance of the capacitor is given by:

Zc = 1 / (jωC)

Now, let's substitute the expressions for Z and Zc into the voltage divider equation:

Vout = Vs * (1 / (jωC)) / (R + j(ωL - 1 / ωC))

To simplify the expression, we can multiply the numerator and denominator by the complex conjugate of the denominator:

Vout = Vs * (1 / (jωC)) * (R - j(ωL - 1 / ωC)) / (R + j(ωL - 1 / ωC)) * (R - j(ωL - 1 / ωC))

Expanding the denominator and simplifying, we get:

Vout = Vs * (R - j(ωL - 1 / ωC)) / (R + jωL - j / (ωC) - jωL + 1 / ωC + (ωL - 1 / ωC)²)

Simplifying further, we obtain:

Vout = Vs * (R - j(ωL - 1 / ωC)) / (R + (ωL - 1 / ωC)² - j(2ωL + 1 / ωC))

The magnitude of the output voltage is given by:

|Vout| = |Vs * (R - j(ωL - 1 / ωC)) / (R + (ωL - 1 / ωC)² - j(2ωL + 1 / ωC))|

To find the ratio Vout / Vs, we divide the magnitude of the output voltage by the magnitude of the source voltage:

Vout / Vs = |(R - j(ωL - 1 / ωC)) / (R + (ωL - 1 / ωC)² - j(2ωL + 1 / ωC))|

Now, let's simplify this expression further.

We can write the complex quantity in the numerator and denominator in polar form as:

R - j(ωL - 1 / ωC) = A * e^(-jφ)

and

R + (ωL - 1 / ωC)² - j(2ωL + 1 / ωC) = B * e^(-jθ)

where A, φ, B, and θ are real numbers.

Taking the magnitude of the numerator and denominator:

|A * e^(-jφ)| = |A| = A

and

|B * e^(-jθ)| = |B| = B

Therefore, we have:

Vout / Vs = |(R - j(ωL - 1 / ωC)) / (R + (ωL - 1 / ωC)² - j(2ωL + 1 / ωv

Vout / Vs = |(R - j(ωL - 1 / ωC)) / (R + (ωL - 1 / ωC)² - j(2ωL + 1 / ω

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