The power emitted by the iron cylinder through thermal radiation is 198.04 W.
The power emitted by the iron cylinder through thermal radiation is 198.04 W. This is calculated as follows: Given: Length (l) of cylinder = 20 cm Radius (r) of cylinder = 4 cm Temperature (T) of cylinder = 700 °CE missivity (ε) of polished iron = 0.3Power emitted (P) = ?The power emitted by an object through thermal radiation can be calculated using the Stefan-Boltzmann law, which states that: P = εσAT⁴Where:P = power emittedε = emissivity of the objectσ = Stefan-Boltzmann constant = 5.67 x 10⁻⁸ W/(m²K⁴)A = surface area of the object T = temperature of the object. In this case, we need to convert the given dimensions to SI units: Length (l) of cylinder = 20 cm = 0.2 m Radius (r) of cylinder = 4 cm = 0.04 m Surface area (A) of cylinder = 2πrl + 2πr²= 2π(0.04)(0.2) + 2π(0.04)²= 0.0502 m²Now, we can substitute the given values into the formula and solve for P:P = 0.3 x (5.67 x 10⁻⁸) x 0.0502 x (700 + 273)⁴= 198.04 W. Therefore, the power emitted by the iron cylinder through thermal radiation is 198.04 W.
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A uniform hoop and a uniform solid cylinder have the same mass and radius. They both roll, without slipping, on a horizontal surface. If their total kinetic energies are equal, then the cylinder and the hoop have the same translational speed. the cylinder has a greater translational speed than the hoop. The translational speeds of the hoop and the cylinder cannot be compared without more information. the hoop has a greater translational speed than the cylinder.
If a uniform hoop and a uniform solid cylinder with the same mass and radius roll without slipping on a horizontal surface and have equal total kinetic energies, the hoop and the cylinder will have the same translational speed
When a hoop or a solid cylinder rolls without slipping, its total kinetic energy consists of both rotational and translational components. The rotational kinetic energy depends on the moment of inertia, which differs between the hoop and the cylinder due to their different shapes.
However, if the total kinetic energies of the hoop and the cylinder are equal, it implies that the rotational kinetic energies are also equal. Since the masses and radii of the hoop and the cylinder are the same, the only way for their rotational kinetic energies to be equal is if their angular velocities are equal.
Now, since both the hoop and the cylinder roll without slipping, their angular velocities are directly related to their translational speeds. In this scenario, if the angular velocities are the same, the translational speeds will also be the same.
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Consider a system in thermal equilibrium with a heat bath held at absolute temperature T. The probability of observing the system in some state r of energy Er is is given by the canonical probability distribution: Pr = exp(−β Er) Z , where β = 1/(k T), and Z = r exp(−β Er) is the partition function. (a) Demonstrate that the entropy can be written S = −k r Pr ln Pr. (b) Demonstrate that the mean Helmholtz free energy is related to the partition function according to Z = exp −β F .
a) The entropy can be written as S = -kΣ Pr ln Pr, where Pr is the probability of observing the system in state r with energy Er.
b) The mean Helmholtz free energy is related to the partition function according to Z = exp(-βF).
a) To demonstrate this, we start with the definition of entropy:
S = -kΣ Pr ln Pr.
We substitute
Pr = exp(-βEr)Z into the equation,
where β = 1/(kT) and Z = Σ exp(-βEr) is the partition function.
After substitution, we have
S = -kΣ (exp(-βEr)Z) ln (exp(-βEr)Z).
By rearranging terms and simplifying, we obtain
S = -kΣ (exp(-βEr)Z) (-βEr - ln Z).
Further simplification leads to S = kβΣ (exp(-βEr)Er) + kln Z, and since
β = 1/(kT), we have S = Σ PrEr + kln Z.
Finally, using the definition of mean energy as
U = Σ PrEr, we arrive at
S = U + kln Z, which is the expression for entropy.
b) To demonstrate this, we start with the definition of Helmholtz free energy:
F = -kTlnZ.
We rewrite this equation as
lnZ = -βF.
Taking the exponential of both sides, we obtain
exp(lnZ) = exp(-βF),
which simplifies to
Z = exp(-βF).
Therefore, the mean Helmholtz free energy is related to the partition function by Z = exp(-βF).
These relationships demonstrate the connections between entropy, probability distribution, partition function, and mean Helmholtz free energy in a system in thermal equilibrium with a heat bath at temperature T. The canonical probability distribution and partition function play crucial roles in characterizing the statistical behavior and thermodynamic properties of the system.
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A rock with a weight of 10N is attached to a vertical string. The rock is moving upward but is slowing down. Shod the force that the string exerts on the rock be greater than 10N, less than 10N, or equal to 10N? Neglect air resistance and explain using the correct Newton's Law.
The force exerted by the string on the rock should be greater than 10N, according to Newton's second law of motion.
Newton's second law of motion states that the net force acting on an object is equal to the product of its mass and acceleration. In this case, the rock is moving upward but slowing down, which means its acceleration is directed downward. Since the rock's weight is 10N, which is equivalent to the force of gravity acting on it, there must be an additional force exerted by the string to counteract this downward acceleration.
To understand this, let's consider the forces acting on the rock. The force of gravity pulls the rock downward with a force of 10N. To slow down the rock's upward motion, the string must exert a force greater than 10N in the upward direction. This additional force exerted by the string balances out the downward force of gravity, resulting in a net force of zero and causing the rock to slow down.
Therefore, the force exerted by the string on the rock should be greater than 10N to counteract the force of gravity and slow down the rock's upward motion.
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The inductor in the RLC tuning circuit of an AM radio has a
value of 450 mH .
Part A: What should be the value of the variable capacitor in
the circuit to tune the radio to 730 kHz?
Express your answe
The value of the variable capacitor should be 185.2 pF to tune the radio to 730 kHz.To tune the radio to 730 kHz, the value of the variable capacitor should be 185.2 pF.
The inductor in the RLC tuning circuit of an AM radio has a value of 450 mH. What should be the value of the variable capacitor in the circuit to tune the radio to 730 kHz?The required value of the variable capacitor in the circuit to tune the radio to 730 kHz should be 185.2 pF (pico-farad).
How to calculate the value of the variable capacitor?
The resonant frequency of a series RLC circuit can be given by the formula,f = 1/(2π √(LC))Where,f = frequency in HertzL = Inductance in HenrysC = Capacitance in FaradsGiven that the inductance, L = 450 mH = 0.45 HFrequency, f = 730 kHz = 730000 HzThe formula can be rearranged to get the capacitance,C = 1/[(2πf)^2L]So, the capacitance, C = 1/[(2π × 730000)^2 × 0.45]C = 185.2 pFTherefore, the value of the variable capacitor should be 185.2 pF to tune the radio to 730 kHz.To tune the radio to 730 kHz, the value of the variable capacitor should be 185.2 pF.
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Q2 (a) Define the following forcing functions with suitable sketches. (ii) Impulse (iii) Sinusoidal (4]
The impulse is a forcing function that refers to an abrupt, brief, and intense disturbance. It has an infinite value at the beginning of the time axis and then returns to zero as time progresses. This type of forcing function is also known as a Dirac Delta function.
It represents an instant release of energy, and it can be used to model physical events such as a hammer hitting a nail or a bullet being fired.
Sinusoidal forcing functions are also referred to as harmonic forcing functions because they are used to describe sinusoidal wave patterns. Sinusoidal functions have an equation of the form f(t) = A sin (ωt + φ), where A represents the amplitude, ω is the angular frequency, and φ is the phase angle. The angular frequency is expressed in radians per second, while the phase angle determines the initial position of the sinusoidal wave.
The sinusoidal forcing function is a periodic function that oscillates back and forth, reaching maximum and minimum values repeatedly. The amplitude determines how high or low the sinusoidal function will reach while the frequency determines the number of oscillations per unit time. It is used to model physical phenomena such as the vibration of a spring or the movement of a pendulum.
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Fiber optics are an important part of our modern internet. In these fibers, two different glasses are used to confine the light by total internal reflection at the critical angle for the interface between the core (n core
=1.519) and the cladding (n cladding
=1.429). A 50% Part (a) Numerically, what is the largest angle (in degrees) a ray will make with respect to the interface internal reflection? θ max
= Hints: deduction per hint. Hints remaining: 2
deduction per feedback. (4 50% Part (b) Suppose you wanted the largest angle at which total internal reflection occurred to be θ max
=5 (6\%) Problem 6: Suppose a 200-mm focal length telephoto lens is being used to photograph mountains 9.5 km away. ( 50% Part (a) What is image distance, in meters, for this lens? d i
= \begin{tabular}{llll} \hline Hints: deduction per hint. Hints remaining: 1 & Feedback: \end{tabular}
This makes the critical angle 5 degrees. To prove this, we use the same formula:sinθc = n2/n1sin(5) = 1.054/1.519θc = 5 degrees
Fiber optics are an important part of our modern internet. In these fibers, two different glasses are used to confine the light by total internal reflection at the critical angle for the interface between the core (ncore=1.519) and the cladding (ncladding=1.429).A 50%Part
(a) Numerically, what is the largest angle (in degrees) a ray will make with respect to the interface internal reflection? θmax=In order to determine the angle that a ray will make with respect to the interface internal reflection, we use Snell's Law: n1sinθ1 = n2sinθ2
where:n1 is the refractive index of the medium the ray is coming fromθ1 is the angle of incidence measured from the normaln2 is the refractive index of the medium the ray is enteringθ2 is the angle of refraction measured from the normalWhen light travels from a medium of a higher refractive index to one of a lower refractive index (i.e. from the core to the cladding),
the angle of refraction is larger than the angle of incidence; that is, the ray is refracted away from the normal. At the critical angle, however, the angle of refraction is 90 degrees. Thus, sinθ2 = 1. Setting sinθ1 = n2/n1, we get the critical angle formula:sinθc = n2/n1θc = sin^(-1)(n2/n1)
The maximum angle a ray will make with respect to the interface internal reflection will be the complement of the critical angle:θmax = 90 - θc = 90 - sin^(-1)(n2/n1) = 90 - sin^(-1)(1.429/1.519) = 42.45 degrees50%Part (b) Suppose you wanted the largest angle at which total internal reflection occurred to be θmax=5°. You could achieve this by decreasing the refractive index of the cladding to ncladding = 1.054.
This makes the critical angle 5 degrees. To prove this, we use the same formula:sinθc = n2/n1sin(5) = 1.054/1.519θc = 5 degrees
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Analyze the operating principles and applications for any ONE (1) of the turbines listed below with appropriate sketches or diagrams: [Analisakan prinsip dan aplikasi operasi untuk mana-mana SATU (1) daripada turbin yang disenaraikan dihawah dengan lakaran atau gambar rajah yang sesuai:] (i) Kaplan turbine. [Turbin Kaplan.] (ii) Francis turbine. [Turbin Francis.] (iii) Pelton turbine. [Turbin Pelton.] (4 Marks/ Markah)
Operating Principles: The Francis turbine is a type of reaction turbine used for converting the energy of flowing water into mechanical energy. It is specifically designed to operate with medium to high head and medium flow rates.
The key operating principles of the Francis turbine include:
1. Water Inlet: The water enters the turbine through a spiral-shaped casing known as the scroll case or volute. The scroll case gradually distributes the water uniformly around the circumference of the runner.
2. Runner: The runner consists of a set of curved blades or vanes that are fixed to a central hub. These blades are designed to efficiently harness the kinetic energy of the water and convert it into rotational mechanical energy.
3. Guide Vanes: The guide vanes are adjustable blades located in the casing just before the water enters the runner. They control the flow of water and direct it onto the runner blades at the desired angle, optimizing the turbine's performance.
4. Water Flow and Pressure: As the water passes through the runner blades, it undergoes a change in direction, creating a pressure difference across the blades. The pressure difference generates a force on the blades, causing them to rotate.
5. Shaft and Generator: The rotational motion of the runner is transmitted to a shaft connected to a generator. The generator converts the mechanical energy into electrical energy, which can be used for various applications.
Applications:
1.The Francis turbine is widely used in hydroelectric power plants due to its versatility and efficiency. It is suitable for both high head and medium head applications. Here are some of its applications:
2. Hydroelectric Power Generation: Francis turbines are commonly used in hydroelectric power plants to generate electricity. They are ideal for sites where the head of water is between 10 and 600 meters, and the flow rate is moderate.
3. Irrigation Systems: The Francis turbine can be employed in irrigation systems to drive pumps or lift water from a lower level to a higher level. It can efficiently harness the energy from water sources such as rivers, canals, or reservoirs.
4 .Pumped Storage Systems: In pumped storage power plants, excess electricity is used to pump water from a lower reservoir to an upper reservoir during periods of low demand. The Francis turbine is then used in reverse as a pump to release the stored water, generating electricity during peak demand periods.
5. Industrial Applications: Francis turbines can also be used in various industrial applications that require mechanical energy, such as powering large fans, compressors, or mills.
Overall, the Francis turbine is a versatile and efficient device used for converting the energy of flowing water into mechanical energy. Its adaptability to different head and flow conditions makes it a preferred choice for hydroelectric power generation and other water-driven applications.
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An athlete swings a 3.50−kg ball horizontally on the end of a rope. The ball moves in a circle of radius 0.820 m at an angular speed of 0.420rey/s. (a) What is the tangential speed of the bail? m/s (b) What is its centripetal acceleration? m/s 2
(c) If the maximum tension the rope can withstand before breaking is 81 N, what is the maximum tangential speed the ball can have? m/s
(a) The tangential speed of the ball can be calculated by multiplying the angular speed by the radius of the circle. (b) The centripetal acceleration of the ball can be determined using the formula ac = ω²r, where ac is the centripetal acceleration, ω is the angular speed, and r is the radius of the circle. (c) The maximum tangential speed the ball can have is limited by the maximum tension the rope can withstand.
(a) The tangential speed of the ball can be calculated as v = ωr, where v is the tangential speed, ω is the angular speed, and r is the radius of the circle.
(b) The centripetal acceleration of the ball is given by ac = ω²r, where ac is the centripetal acceleration, ω is the angular speed, and r is the radius of the circle.
(c) To find the maximum tangential speed, we equate the centripetal force to the tension in the rope, using the formula Fc = mv²/r, where Fc is the centripetal force, m is the mass of the ball, v is the tangential speed, and r is the radius of the circle. We solve for v by substituting the maximum tension value and rearranging the equation.
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The center of gravity and the center of mass of an object coincides with each other when when the mass of the body is uniformly distributed the gravitational field surrounding and within the body is uniform all of the choices is correct No answer text provided. The Young's Modulus of a certain material of definite geometry depends on material and geometry geometry only neither material nor geometry material only Two rods have the same geometry (length and cross-section), but made of different materials. One is made of steel (Y = 10 x 10¹0 Pa) while the other is made of rubber (Y= 0.005 x 1010 Pa). Which is more elastic? Osteel O same for both material O rubber
The center of gravity and the center of mass of an object coincide when the mass of the body is uniformly distributed and the gravitational field surrounding and within the body is uniform and the steel rod is more elastic than the rubber rod.
The center of gravity and the center of mass of an object coincide when certain conditions are met.
One of these conditions is that the mass of the body should be uniformly distributed.
This means that the mass is evenly distributed throughout the object, without any variations.
Additionally, the gravitational field surrounding and within the body should be uniform, meaning the strength of the gravitational force remains constant throughout the object.
Moving on to the Young's modulus, it is a measure of a material's stiffness or elasticity.
It determines how much a material will deform under stress.
The higher the Young's modulus, the stiffer or more elastic the material is. In the given scenario, the steel rod has a Young's modulus of 10 x 10¹⁰ Pa, while the rubber rod has a Young's modulus of 0.005 x 10¹⁰ Pa.
Comparing the Young's moduli of the two materials, we can see that the steel rod has a significantly higher value, indicating that it is more elastic or stiffer compared to the rubber rod.
This means that the steel rod will deform less under stress and exhibit greater elasticity than the rubber rod. Therefore, the steel rod is more elastic in this scenario.
In summary, the center of gravity and center of mass coincide under specific conditions, while the Young's modulus determines the elasticity of a material.
In the given scenario, the steel rod is more elastic than the rubber rod due to its higher Young's modulus.
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An object with a mass of 100 g is suspended from a spring having a spring constant of 104 dyne/cm and subjected to vibration. The object was pulled 3 cm from the equilibrium point and released from rest.
(a) Find the natural frequency ν0 and the period τ0.
(b) Find total energy.
(c) Find the maximum speed.
The natural frequency is 32.91 rad/s and the period of oscillation is 0.1916 s. The total energy of the oscillator is 0.05616 J and the maximum speed of the object is 0.9873 m/s.
Mass, m = 100 g = 0.1 kg
Spring constant, k = 104 dyne/cm = 104 N/m
Displacement, x = 3 cm = 0.03 m
Let's solve the problem using the following steps:
a. 1. Calculate the natural frequency
The natural frequency is given by:
ν₀ = 1/(2π) * √(k/m)
ν₀ = 1/(2π) * √(104/0.1)
ν₀ = 32.91 rad/s
Calculate the period:
2. The period of oscillation is given by:
τ₀ = 2π/ν₀
τ₀ = 2π/32.91
τ₀ = 0.1916 s
b. Calculate the total energy:
The total energy of a simple harmonic oscillator is given by:
E = (1/2) kx²
E = (1/2) * 104 * (0.03)²
E = 0.05616 J
c. Calculate the maximum speed:
The maximum speed is given by:
v_max = A * ν₀
where A is the amplitude of oscillation which is equal to the displacement x in this case. Thus,
v_max = x * ν₀
v_max = 0.03 * 32.91
v_max = 0.9873 m/s
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Find the force between two punctual charges with 2C and 1C, separated by a distance of 1 m of air. Write your answer in Newtons. NOTE: Constant k = 9 × 10⁹ Nm²C⁻²
A. 1.8×10⁹ N B. 18×10⁹ N C. 18×10⁻⁶ N D. 1.8×10⁻⁶ N
The force between two punctual charges of 2C and 1C, separated by 1m in air, is 18 × 10^9 Newtons. The correct answer is option B.
The force between two punctual charges can be calculated using Coulomb's Law:
F = k * (|q₁| * |q₂|) / r²,
where F is the force, k is the electrostatic constant, |q₁| and |q₂| are the magnitudes of the charges, and r is the distance between them.
Given:
|q₁| = 2 C,
|q₂| = 1 C,
r = 1 m,
k = 9 × 10^9 Nm²C⁻².
Substituting the values into the formula:
F = (9 × 10^9 Nm²C⁻²) * (|2 C| * |1 C|) / (1 m)²
= (9 × 10^9 Nm²C⁻²) * (2 C * 1 C) / (1 m)²
= (9 × 10^9 Nm²C⁻²) * 2 C² / 1 m²
= 18 × 10^9 N.
Therefore, the force between the two charges is 18 × 10^9 Newtons.
The correct answer is option B: 18×10⁹ N.
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Consider a D/A converter for audio signals consisiting of a zero-order-hold interpolator followed by a continuous- time lowpass filter with positive passband between 0 and 20KHz and stopband starting at fa = 40KHz. = Assume we want to convert a digital signal originally sampled at 16KHz. What is the minimum oversampling factor that we need to use?
The minimum oversampling factor needed for this D/A converter to accurately represent the original audio signal sampled at 16 KHz is 2.5.
To determine the minimum oversampling factor needed for the given D/A converter, we need to consider the Nyquist-Shannon sampling theorem.
According to the Nyquist-Shannon theorem, in order to accurately reconstruct a continuous-time signal from its digital samples, the sampling frequency must be at least twice the highest frequency component of the signal. This is known as the Nyquist rate.
In this case, the digital signal was originally sampled at 16 KHz. To satisfy the Nyquist rate, the minimum oversampling factor required would be:
Minimum oversampling factor = (Nyquist rate) / (original sampling rate)
= 2 * 20 KHz / 16 KHz
= 2.5
Therefore, the minimum oversampling factor needed for this D/A converter to accurately represent the original audio signal sampled at 16 KHz is 2.5.
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A flashlight bulb carries a current of 0.33 A for 94 s .
How much charge flows through the bulb in this time?
Express your answer using two significant figures.
How many electrons?
Express your answer using two significant figures.
The number of electrons that flow through the bulb in this time is approximately [tex]1.94 * 10^{20[/tex] electrons.
To determine the charge that flows through the flashlight bulb, we can use the equation:
Q = I * t
Where:
Q is the charge in Coulombs (C),
I is the current in Amperes (A), and
t is the time in seconds (s).
Given:
Current, I = 0.33 A
Time, t = 94 s
Using the formula, we can calculate the charge Q:
Q = 0.33 A * 94 s
= 31.02 C
Therefore, the charge that flows through the bulb in this time is approximately 31.02 Coulombs.
To find the number of electrons, we can use the fact that 1 electron has a charge of approximately[tex]1.6 *10^{(-19)[/tex]Coulombs.
Number of electrons = [tex]Q / (1.6 * 10^{(-19)} C)[/tex]
Substituting the value of Q:
Number of electrons = [tex]31.02 C / (1.6 * 10^{(-19)} C)[/tex]
≈ [tex]1.94 * 10^{20[/tex]electrons
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A generator connected to an RLC circuit has an rms voltage of 150 V and an rms current of 33 mA .A generator connected to an RLC circuit has an rms voltage of 150 V and an rms current of 33 mA .
If the resistance in the circuit is 3.0 kΩ and the capacitive reactance is 6.7 kΩ , what is the inductive reactance of the circuit?
The required solution is:Inductive reactance of the circuit is 1.38 kΩ.
Given information: The rms voltage (Vrms) of the generator = 150 VThe rms current (Irms) in the circuit = 33 mAThe resistance (R) in the circuit = 3.0 kΩThe capacitive reactance (Xc) = 6.7 kΩThe formula to calculate the inductive reactance (XL) of the circuit is given as,XL = √[R² + (Xl - Xc)²]where,XL is the inductive reactanceXc is the capacitive reactance of the circuit. R is the resistance of the circuit.
Substituting the given values in the formula,XL = √[ (3.0 kΩ)² + (Xl - 6.7 kΩ)²]⇒ XL² = (3.0 kΩ)² + (XL - 6.7 kΩ)²⇒ XL² = 9.0 kΩ² + XL² - 2 * 6.7 kΩ * XL + (6.7 kΩ)²⇒ 0 = 9.0 kΩ² - 2 * 6.7 kΩ * XL + (6.7 kΩ)²⇒ 0 = (3.0 kΩ - XL) (3.0 kΩ + XL) - (6.7 kΩ)²XL = (6.7 kΩ)² / (3.0 kΩ + XL)⇒ (3.0 kΩ + XL) XL = (6.7 kΩ)²⇒ XL² + 3.0 kΩ * XL - (6.7 kΩ)² = 0Solving for XL using the quadratic formula, we get,XL = 1.38 kΩ and XL = -4.38 kΩ.
Since inductive reactance can never be negative, we ignore the negative value.So, the inductive reactance of the circuit is 1.38 kΩ (approximately).Hence, the required solution is:Inductive reactance of the circuit is 1.38 kΩ.
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The displacement of a wave traveling in the positive x-direction is D(x,t)=(3.5cm)sin(2.5x−134t)D(x,t)=(3.5cm)sin(2.5x−134t), where x is in m and t is in s.
A.) What is the frequency of this wave?
B.) What is the wavelength of this wave?
C.) What is the speed of this wave?
The answers to the given questions are:A) 134/(2π) HzB) 0.8π m ≈ 2.51 mC) 533.33 m/
A. The frequency of a wave is given by the formula: `f = w/2π`. Where w is the angular frequency. We can obtain the angular frequency by comparing the wave equation `y = A sin (ωt ± kx)` with the given wave equation `D (x, t) = (3.5 cm) sin (2.5x - 134t)`. From the given equation, we can see that: `ω = 134`Therefore, the frequency is given by: `f = ω/2π = 134/(2π) Hz`B. The wavelength of the wave is given by the formula `λ = 2π/k`.
From the given wave equation `D (x, t) = (3.5 cm) sin (2.5x - 134t)`, we can see that: `k = 2.5`. Therefore, the wavelength of the wave is given by: `λ = 2π/k = 2π/2.5 m = 0.8π m ≈ 2.51 m`C. The speed of a wave is given by the formula: `v = λf`. From parts (a) and (b), we know that: `f = 134/(2π) Hz` and `λ ≈ 2.51 m`. Therefore, the speed of the wave is given by: `v = λf ≈ 2.51 × 134/(2π) m/s ≈ 533.33 m/s`.Therefore, the answers to the given questions are:A) 134/(2π) HzB) 0.8π m ≈ 2.51 mC) 533.33 m/s
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A horizontal power line carries a current of 4230 A from south to north. Earth's magnetic field (76.0μT) is directed toward the north and is inclined downward at 59.0° to the horizontal. Find the (a) magnitude and (b) direction of the magnetic force on 100 m of the line due to Earth's field.
(a) Number ___________ Units ________
(b) ______
Magnitude of the magnetic force due to Earth's field is 320 N and the direction of the magnetic force is westward.
The magnetic force (F) on a current-carrying wire of length l, carrying a current I in a magnetic field of strength B, can be expressed as:
F = B I l sin θ
where θ is the angle between the direction of the magnetic field and the wire.
θ = 59° (in the downward direction)
B = 76.0 μT = 76.0 × 10⁻⁶ TB = 76.0 × 10⁻⁶ TI = 4230 Al = 100 m
(a) Magnitude of the magnetic force:
F = B I l sin θ= (76.0 × 10⁻⁶) × (4230) × (100) × sin 59.0°= 320 N
Therefore, the magnitude of the magnetic force due to Earth's field is 320 N.
(b) Direction of the magnetic force:
As the magnetic field is directed toward the north and the current flows from south to north, the direction of the magnetic force can be determined using the right-hand rule. Place your right hand such that the thumb points towards the direction of the current, the fingers point towards the direction of the magnetic field, and the palm points towards the direction of the magnetic force. Therefore, the direction of the magnetic force is westward.
Therefore, the magnitude of the magnetic force is 320 N and the direction of the magnetic force is westward.
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A plane flies east 300 km for 1.00 hr, then turns north and continues another 300 km for 1.00 hr. What direction was the average acceleration of the plane? north northwest southeast southwest northeast
The plane initially flies east for 1.00 hour and then turns north for another 1.00 hour. The average acceleration of the plane is in the northeast direction.
The average acceleration of an object is determined by the change in its velocity over a given time interval.
In this case, the plane initially flies east for 1.00 hour and then turns north for another 1.00 hour.
To find the direction of the average acceleration, we need to consider both the change in velocity and the time interval.
The plane's initial velocity is solely in the east direction, and after the turn, its velocity has a northward component.
The change in velocity involves a change in direction as well as magnitude.
Since the plane's velocity vector changes from solely eastward to having both eastward and northward components, the average acceleration vector will point in a direction between east and north.
To determine the specific direction, we can consider the angle between the initial and final velocity vectors.
The angle between east and north is 45 degrees, which corresponds to the northeast direction. Therefore, the average acceleration of the plane is in the northeast direction.
In summary, the average acceleration of the plane is in the northeast direction.
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where are Ascaris and Arthropods found ?class 10
Answer:
Ascaris and Arthropods are both types of organisms found in the animal kingdom. Ascaris are parasitic worms, commonly referred to as roundworms, which can be found in warm climates all over the world. Arthropods, on the other hand, are a large group of animals, including insects, arachnids, and crustaceans, that typically have jointed legs and a hard exoskeleton. Arthropods are found in almost all environments, from oceans to deserts to the tops of mountains.
Explanation:
In Circuit 64 your voltmeters were accurate in the sense that they (more or less) correctly read the actual voltages in the circuits, but they were inaccurate (for very large resistors) in that these readings are NOT the true voltage across the second resistor when the meter is not there. Now suppose you are in a different setting, with two voltmeters and a high resistance circuit. If meter A "correctly" reads 6.70 volts across a resistor in a circuit and meter B "correctly" reads 6.90V across the same resistor in the same circuit, which meter is giving you the value closest to the true value with no meters present? Explain. (4) 6. The last line of the first column (V1 reading WITHOUT the Simpson) is for the 4.7MQ. Take the value you have and use it to solve for the actual resistance of the Fluke meter. How? Suppose the resistors are both 4.70MQ and use your voltage of the power supply (if you did not write it down, use 3.00V). Remember the question that asked you to find the AV of R* when you knew IR of the other resistor? Well, here you know AV of the parallel combination of R₂ and the meter. "Reverse engineer" things to find the total current from the power supply, then the total resistance (and or you can go directly to find the Reg of the parallel combination, then solve for the meter resistance.
In the given scenario, if meter A correctly reads 6.70 volts across a resistor in a circuit and meter B correctly reads 6.90 volts across the same resistor in the same circuit, meter A is providing a value closer to the true voltage with no meters present.
When using voltmeters in high-resistance circuits, the presence of the voltmeter can affect the actual voltage across the resistor being measured. In this case, we have two voltmeters, A and B, both reading the voltage across the same resistor. If meter A reads 6.70 volts and meter B reads 6.90 volts, we need to determine which value is closer to the true voltage.
Since the voltmeters are accurate in the sense that they correctly read the actual voltages in the circuits, we can infer that the true voltage across the resistor lies between the readings of meters A and B. Considering that meter A reads 6.70 volts and meter B reads 6.90 volts, we can conclude that meter A provides a value closer to the true voltage. This is because the actual voltage is likely slightly lower than the reading on meter B, making meter A's reading more accurate in this case.
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A block is pushed with a force of 100N along a level surface. The block is 2 kg and the coefficient of friction is 0.3. Find the blocks acceleration.
The block's acceleration is 4.9 m/s².
1. Determine the normal force (N) acting on the block. The normal force is equal to the weight of the block, which can be calculated using the formula: N = m * g, where m is the mass of the block and g is the acceleration due to gravity (approximately 9.8 m/s²). In this case, the mass of the block is 2 kg, so the normal force is N = 2 kg * 9.8 m/s² = 19.6 N.
2. Calculate the maximum frictional force (F_friction_max) using the formula: F_friction_max = μ * N, where μ is the coefficient of friction. In this case, the coefficient of friction is 0.3, so the maximum frictional force is F_friction_max = 0.3 * 19.6 N = 5.88 N.
3. Determine the net force acting on the block. Since the block is pushed with a force of 100 N, the net force (F_net) is equal to the applied force minus the frictional force: F_net = F_applied - F_friction_max = 100 N - 5.88 N = 94.12 N.
4. Use Newton's second law of motion to find the acceleration (a) of the block. According to the law, the net force is equal to the mass of the object multiplied by its acceleration: F_net = m * a. Rearranging the equation, we have: a = F_net / m. Plugging in the values, we get: a = 94.12 N / 2 kg = 47.06 m/s².
5. However, since the question asks for the block's acceleration, which includes the effects of friction, we need to take into account the opposing force of friction. The actual net force (F_net_actual) acting on the block is given by: F_net_actual = F_applied - F_friction = 100 N - F_friction. In this case, F_friction is the force of friction, which is equal to the coefficient of friction (μ) multiplied by the normal force (N): F_friction = μ * N = 0.3 * 19.6 N = 5.88 N.
6. Using the actual net force, we can calculate the acceleration (a_actual) of the block by rearranging Newton's second law: a_actual = F_net_actual / m = (100 N - 5.88 N) / 2 kg = 94.12 N / 2 kg = 47.06 m/s².
Therefore, the block's acceleration is 4.9 m/s².
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A small and a large block (mass M and 2M respectively) are arranged on a horizontal surface as shown below. A student pushes on the left side of the small block so that the entire system accelerates to the right. How does the net force on the small block Fs compare to the net force on the large block F₁? Fs=FL Fs < FL 0/2 pts Fs > FL
The net force on the small block (Fs) is equal to the net force on the large block (F₁).
According to Newton's third law of motion, for every action, there is an equal and opposite reaction. When the student pushes on the left side of the small block, an equal and opposite force is exerted by the small block on the student's hand. This force is transmitted through the small block to the large block due to their contact.
Since the small and large blocks are in contact, they experience the same magnitude of force but in opposite directions. Therefore, the net force on the small block is equal in magnitude and opposite in direction to the net force on the large block.
In a system where both blocks are accelerating to the right, there must be an unbalanced force acting on the system. This unbalanced force is provided by the student's push and is transmitted through both blocks. As the large block has a greater mass, it requires a larger force to accelerate it compared to the smaller block. However, the net force acting on each block, Fs and F₁, will be equal in magnitude, satisfying Newton's third law.
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An adiabatic process is one in which i. no heat enters or leaves the system. ii. only mass is allowed crossing the boundary. iii. the temperature of the system changes. iv. the change in internal energy is equal to the mechanical workdone. O a. ii, iii and iv O b. i, ii, iii and iv O c. i, iii and iv O d. i, ii and iii
An adiabatic process is one in which no heat enters or leaves the system, and the change in internal energy is equal to the mechanical work done. Therefore, the correct answer is option c. I, iii, and iv.
An adiabatic process is characterized by the absence of heat transfer between the system and its surroundings. In other words, no heat enters or leaves the system during an adiabatic process
(i). However, this does not imply that only mass is allowed to cross the system boundary
(ii). Adiabatic processes can occur in both open and closed systems. Additionally, during an adiabatic process, the temperature of the system can change
(iii). This change in temperature is a result of the work done on or by the system. The change in internal energy is equal to the mechanical work done (iv) because there is no heat transfer to account for. Thus, the correct answer is option c. I, iii, and iv.
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A +10 C charge exerts a force on an electron that is: Select one: a. Attractive and inversely proportional to the square of the distance between the charges b. Attractive and directly proportional to the square of the distance between the charges c. Repulsive and inversely proportional to the square of the distance between the charges d. Repulsive and directly proportional to the square of the distance between the charges
A +10 C charge exerts a force on an electron that is: c. Repulsive and inversely proportional to the square of the distance between the charges.
A negatively charged subatomic particle known as an electron can be free (not bound) or attached to an atom. One of the three main types of particles within an atom is an electron that is bonded to it; the other two are protons and neutrons. The nucleus of an atom is made up of protons and electrons together. The positive charge of a proton balances the negative charge of an electron. An atom is in a neutral condition when it contains the same amount of protons and electrons.
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At what frequency will a 50-mH inductor have a reactance XL = 7000? 0 352 Hz O 777 Hz 0 1.25 kHz O 2.23 kHz O 14 kHz
The frequency at which a 50-mH inductor will have a reactance XL = 7000 is 1.25 kHz.
Frequency is a fundamental concept in physics and refers to the number of cycles or oscillations of a wave that occur in one second. It is measured in hertz (Hz). In the context of the given question, the frequency is being asked in relation to an inductor's reactance.
Reactance is the opposition of an electrical component, such as an inductor, to the flow of alternating current (AC). The reactance of an inductor, XL, depends on its inductance and the frequency of the AC signal passing through it. In this case, when the reactance XL of a 50-mH inductor is 7000, the corresponding frequency is 1.25 kHz (kilohertz).
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choose the correct answer For this system The heater is off when O Comparator Reference value Te • TaTd • Ta=0 • Td=0 True Emor Heater signal False Temperature measuring device Room Any values for dynamic characteristics are indicated in instrument data sheets and only apply when the instrument is used underspecified environmental conditions. Room temperature . true or false?
The statement "The heater is off when O Comparator Reference value Te • TaTd • Ta=0 • Td=0" is true and The second statement "Any values for dynamic characteristics are indicated in instrument data sheets and only apply when the instrument is used under specified environmental conditions. Room temperature." is false.
The statement is false because instrument data sheets provide detailed information about the dynamic characteristics of instruments, such as response time, accuracy, or frequency response. However, these characteristics are specified under specific environmental conditions, which may include temperature ranges, humidity levels, or other factors. Merely assuming "room temperature" is not sufficient to accurately apply the specified values.
Instrument performance can be significantly influenced by environmental factors, and variations in temperature can affect the instrument's behavior and measurements. Different materials used in instrument construction can exhibit varying thermal expansion properties, leading to potential changes in calibration and accuracy.
To ensure the instrument operates as intended and provides accurate results, it is crucial to consult the instrument data sheet and consider the specified environmental conditions. Adhering to the recommended operating conditions will help maintain the instrument's performance, reliability, and accuracy in real-world applications.
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In an isentropic compression, P₁= 100 psia. P₂= 200 psla, V₁ = 10 m³, and k=1.4. Find V₂ OA 4.500 in ³ OB.3.509 in ³ OC.5.000 in ³ OD.6.095 in ³
The correct option is OA 4.500 in ³.
In an isentropic compression, P₁= 100 psia, P₂= 200 psia, V₁ = 10 m³, and k = 1.4. We have to find V₂.The formula for isentropic compression of an ideal gas is given as:P₁V₁ᵏ=P₂V₂ᵏwhereP₁ is the initial pressureV₁ is the initial volumeP₂ is the final pressureV₂ is the final volumek is the specific heat ratio of the gasSubstituting the given values in the formula:100 × 10ᵏ = 200 × V₂ᵏOn dividing both sides by 200, we get:50 × 10ᵏ = V₂ᵏTaking the kth root on both sides:V₂ = (50 × 10ᵏ)^(1/k)Substituting k = 1.4V₂ = (50 × 10¹⁴/10¹⁰)^(1/1.4)V₂ = (50 × 10^4)^(5/7)V₂ = 4500 cubic inchesHence, the correct option is OA 4.500 in ³.
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A planet is in an elliptical orbit around a sun. Which statement below is true about the torque on the planet due to the sun? Since the force on the planet points along its direction of motion, the torque on it is always positive. Since the gravitational force on the planet passes through its axis of rotation, there is no torque generated by this force. Since the force on the planet changes as it moves around its orbit, the torque on it is not constant. O None of these choices is correct. Imagine propping up a ladder against a wall. Which of the following is an essential condition for the ladder to be in static equilibrium? The ladder must lean at an angle greater than 45 degrees. The ground can be frictionless. The vertical wall must be very rough. None of these choices is correct. If the speed with which a fluid flows is V and the cross-sectional area of the stream is A, then what does the quantity (AV) signify? The volume of the fluid flowing per unit area. The total mass of the fluid. None of these choices is correct. The mass of the fluid flowing per unit volume. Can water evaporate at 10°C? Why, or why not? Yes, because a small fraction of water molecules will be moving fast enough to break free and enter vapor phase even at 10°C. O No, because 10°C is too far below the boiling point of water. Yes, because 10°C is well above the evaporating point of water. No, because evaporation at 10°C requires a much higher pressure. 0 0 O
Regarding the torque on a planet in an elliptical orbit around a sun, the correct statement is: None of these choices is correct. The torque on the planet due to the sun is not determined solely by the direction of the force or the alignment of the gravitational force with the axis of rotation.
In an elliptical orbit, the force on the planet from the sun is not always along its direction of motion. As the planet moves in its elliptical path, the force vector changes its direction, resulting in a varying torque on the planet. Therefore, none of the given choices accurately describes the torque on the planet.
When propping up a ladder against a wall, an essential condition for the ladder to be in static equilibrium is that the ground cannot be frictionless. Friction between the ladder and the ground is necessary to prevent the ladder from sliding or rotating. If the ground were completely frictionless, the ladder would not be able to maintain a stable position against the wall.
The quantity (AV), where V is the speed of fluid flow and A is the cross-sectional area of the stream, represents the volume of the fluid flowing per unit time. Multiplying the velocity by the cross-sectional area gives the volume of fluid passing through that area in a given time interval.
Water cannot evaporate at 10°C because 10°C is too far below the boiling point of water. Evaporation occurs when molecules at the surface of a liquid gain enough energy to transition into the vapor phase. While some water molecules will possess sufficient kinetic energy to evaporate even at temperatures below the boiling point, the rate of evaporation is much lower compared to higher temperatures. At 10°C, the average kinetic energy of water molecules is not high enough for a significant number of molecules to escape into the vapor phase. Thus, water does not readily evaporate at 10°C.
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a) What is the thinnest film of MgF2 (n=1.38) on glass (n=1.5) that produces a strong reflection for 600 nm orange light? b) What is the thinnest film that produces a minimum reflection, like an anti-reflection coating?
Answer:
a) Strong reflection for 600 nm orange light is approximately 217.39 nm.
b) Anti-reflection coating, is approximately 434.78 nm.
a) To determine the thinnest film of MgF2 on glass that produces a strong reflection for 600 nm orange light, we can use the concept of thin film interference.
The condition for strong reflection is when the phase change upon reflection is 180 degrees.
The phase change due to reflection from the top surface of the film is given by:
Δφ = 2πnt/λ
Where Δφ is the phase change,
n is the refractive index of the film (MgF2),
t is the thickness of the film, and
λ is the wavelength of the light.
For strong reflection, the phase change should be 180 degrees. Therefore, we can set up the equation:
2πnt/λ = π
Simplifying the equation:
nt/λ = 1/2
Rearranging the equation to solve for the thickness of the film:
t = (λ/2n)
Wavelength of orange light, λ = 600 nm = 600 x 10^(-9) m
Refractive index of MgF2, n = 1.38
Substituting the values into the equation:
t = (600 x 10^(-9) m) / (2 x 1.38)
t ≈ 217.39 nm
Therefore, the thinnest film of MgF2 on glass that produces a strong reflection for 600 nm orange light is approximately 217.39 nm.
b) To determine the thinnest film that produces a minimum reflection, like an anti-reflection coating, we need to consider the condition for destructive interference. For minimum reflection, the phase change upon reflection should be 0 degrees.
Using the same equation as above:
2πnt/λ = 0
Simplifying the equation:
nt/λ = 0
Since the thickness of the film cannot be zero, we need to consider the next possible value that gives destructive interference. In this case, we can choose a thickness that results in a phase change of 360 degrees (or any multiple of 360 degrees).
nt/λ = 1
Rearranging the equation to solve for the thickness:
t = λ/n
Substituting the values:
t = (600 x 10^(-9) m) / 1.38
t ≈ 434.78 nm
Therefore, the thinnest film of MgF2 on glass that produces a minimum reflection, like an anti-reflection coating, is approximately 434.78 nm.
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Radon (Rn) is a radioactive, colourless, odourless, tasteless noble gas that accounts for more than half of the total radiation dose received by the Irish population. Radon-222 has a half-life of 3.8 days and the activity of 1 g is 3.7 x 10¹⁰ Bq. (i) Radon-222 undergoes alpha decay. Show the decay equation for this including atomic number, mass and element symbols in your answer. (ii) Calculate the decay constant for Radon-222. (iii) Calculate the number of Radon-222 atoms present in 1g.
Radon-222 has a half-life of 3.8 days and the activity of 1 g is 3.7 x 10¹⁰ Bq. (I)an atom of radon-222 (atomic number 86, mass number 222) decays into an atom of polonium-218 (atomic number 84, mass number 218) by emitting an alpha particle (helium nucleus, 2 protons and 2 neutrons).(II)The decay constant for Radon-222 is 3.16 × 10⁻⁵ s⁻¹.(iii)There are 1.1 × 10¹⁵ radon-222 atoms present in 1 g.
(i) The decay equation for the alpha decay of radon-222 is as follows:
86 222 Rn → 2 4 He + 84 218 Po
This means that an atom of radon-222 (atomic number 86, mass number 222) decays into an atom of polonium-218 (atomic number 84, mass number 218) by emitting an alpha particle (helium nucleus, 2 protons and 2 neutrons).
(ii) The decay constant for radon-222 can be calculated using the following equation:
λ = ln(2) / T
where:
λ is the decay constant (s⁻¹)
ln(2) is the natural logarithm of 2 (0.693)
T is the half-life (s)
Substituting the values for T, we get:
λ = ln(2) / 3.8 days
= 0.063 days⁻¹
= 3.16 × 10⁻⁵ s⁻¹
(iii) The number of radon-222 atoms present in 1 g can be calculated using the following equation:
N = A / λ
where:
N is the number of atoms
A is the activity (Bq)
λ is the decay constant (s⁻¹)
Substituting the values for A and λ, we get:
N = 3.7 × 10¹⁰ Bq / 3.16 × 10⁻⁵ s⁻¹
= 1.1 × 10¹⁵ atom
Therefore, there are 1.1 × 10¹⁵ radon-222 atoms present in 1 g.
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An alpha particle (q = +2e, m = 4.00 u) travels in a circular path of radius 4.49 cm in a uniform magnetic field with B = 1.47 T. Calculate (a) its speed, (b) its period of revolution, (c) its kinetic energy, and (d) the potential difference through which it would have to be accelerated to achieve this energy. (a) Number _____________ Units _____________
(b) Number _____________ Units _____________ (c) Number _____________ Units _____________ (d) Number _____________ Units _____________
(a) The speed of the alpha particle is 4.41 × 10⁵ m/s.
(b) The period of revolution of the alpha particle is 3.26 × 10⁻⁸ s.
(c) The kinetic energy of the alpha particle is 2.00 × 10⁻¹² J.
(d) The potential difference through which the alpha particle would have to be accelerated to achieve this energy is 6.25 × 10⁶ V.
Charge of alpha particle, q = +2e = +2 × 1.6 × 10⁻¹⁹ C = +3.2 × 10⁻¹⁹ C
Mass of alpha particle, m = 4.00 u = 4.00 × 1.66 × 10⁻²⁷ kg = 6.64 × 10⁻²⁷ kg
Radius of the path, r = 4.49 cm = 4.49 × 10⁻² m
Magnetic field, B = 1.47 T
(a) Speed of the alpha particle can be calculated using the formula
v = (qBr/m)
Here,
q = Charge on the particle,
B = Magnetic field,
r = radius of circular path,
m = Mass of the particle
Substituting the values, we get
v = (qBr/m)
= [(+3.2 × 10⁻¹⁹ C) × (1.47 T) × (4.49 × 10⁻² m)] / (6.64 × 10⁻²⁷ kg)
= 4.41 × 10⁵ m/s
Therefore, the speed of the alpha particle is 4.41 × 10⁵ m/s.
Number: 4.41 × 10⁵; Units: m/s
(b) The period of revolution of the alpha particle is given by
T = (2πr) / v
Substituting the values, we get
T = (2πr) / v
= [(2π) × (4.49 × 10⁻² m)] / (4.41 × 10⁵ m/s)
= 3.26 × 10⁻⁸ s
Therefore, the period of revolution of the alpha particle is 3.26 × 10⁻⁸ s.
Number: 3.26 × 10⁻⁸ ; Units: s
(c) Kinetic energy of the alpha particle is given by
K = (1/2) mv²
Substituting the values, we get
K = (1/2) mv²
= (1/2) (6.64 × 10⁻²⁷ kg) (4.41 × 10⁵ m/s)²
= 2.00 × 10⁻¹² J
Therefore, the kinetic energy of the alpha particle is 2.00 × 10⁻¹² J.
Number: 2.00 × 10⁻¹²; Units: J
(d) The potential difference through which the alpha particle would have to be accelerated to achieve this energy can be calculated using the formula
dV = K / q
Substituting the values, we get
dV = K / q
= (2.00 × 10⁻¹² J) / (+3.2 × 10⁻¹⁹ C)
= 6.25 × 10⁶ V
Therefore, the potential difference through which the alpha particle would have to be accelerated to achieve this energy is 6.25 × 10⁶ V.
Number: 6.25 × 10⁶; Units: V
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