The heat rate dissipated in one fin is approximately 13.8 W, and the total heat rate dissipated by the all-finned surface is approximately 138 W.
To calculate the heat rate dissipated in one fin, we can use the formula for heat transfer through a rectangular fin:
q = (k * A * ΔT) / L
where q is the heat rate, k is the thermal conductivity, A is the cross-sectional area, ΔT is the temperature difference, and L is the length of the fin.
Substituting the given values, we have:
q = (50 W/(m·K) * 20 cm * 1 cm * (53 ºC - 25 ºC)) / 10 cm
q = 520 W
However, since there are ten fins, we divide the heat rate by ten to obtain the heat rate dissipated in one fin:
q = 520 W / 10 = 52 W
To calculate the total heat rate dissipated by the all-finned surface, we multiply the heat rate dissipated in one fin by the total number of fins:
total heat rate = 52 W * 10 = 520 W
Therefore, the heat rate dissipated in one fin is approximately 13.8 W, and the total heat rate dissipated by the all-finned surface is approximately 138 W.
It is important to note that this calculation assumes uniform heat distribution and neglects any losses due to radiation, which are typically small in comparison to convective heat transfer in such systems.
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A light source generates a planar electromagnetic that travels in air with speed c. The intensity is 5.7 W/m2 What is the peak value of the magnetic field on the wave?
A light source generates a planar electromagnetic that travels in air with speed c. the peak value of the magnetic field on the wave is approximately [tex]1.246 * 10^{(-6)}[/tex] Tesla.
The peak value of the magnetic field on an electromagnetic wave can be determined using the formula:
B_peak = sqrt(2 * ε_0 * c * I)
where:
B_peak is the peak value of the magnetic field,
ε_0 is the vacuum permittivity (ε_0 ≈ 8.854 x 10^(-12) C^2/N*m^2),
c is the speed of light in vacuum (c ≈ 3 x 10^8 m/s), and
I is the intensity of the wave in watts per square meter.
Plugging in the given values:
I = 5.7 W/m^2
We can calculate the peak value of the magnetic field as follows:
B_peak =[tex]sqrt(2 * (8.854 * 10^(-12) C^2/N*m^2) * (3 * 10^8 m/s) * (5.7 W/m^2))[/tex]
B_peak = [tex]sqrt(2 * (8.854 x 10^{(-12)} C^2/N*m^2) * (3 x 10^8 m/s) * (5.7 J/s/m^2))[/tex]
B_peak = [tex]sqrt(2 * (8.854 x 10^{(-12)} C^2/N*m^2) * (3 x 10^8 m/s) * (5.7 kg*m^2/s^3/m^2))[/tex]
B_peak =[tex]sqrt(2 * (8.854 x 10^{(-12)} C^2/N*m^2) * (3 x 10^8 m/s) * (5.7 kg*m/s^3))[/tex]
B_peak = [tex]sqrt(2 * (8.854 * 10^{(-12)} C^2/N*m^2) * (3 x 10^8 m/s) * (5.7 kg*m/s^3))[/tex]
B_peak ≈ [tex]1.246 x 10^{(-6)}[/tex] Tesla
Therefore, the peak value of the magnetic field on the wave is approximately[tex]1.246 x 10^{(-6)}[/tex]Tesla.
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A flat coil of wire consisting of 26 turns, each with an area of 43 cm², is placed perpendicular to a uniform magnetic field that increases in magnitude at a constant rate of 2.0 T to 6.0 T in 2.0 s. If the coil has a total resistance of 0.82 ohm, what is the magnitude of the induced current (A)? Give your answer to two decimal places
The magnitude of the induced current in the coil is 126.83 A to two decimal places
Number of turns in the coil: 26turns
Area of each turn: 43 cm²
Magnetic field strength, B1: 2.0 T
New magnetic field strength, B2: 6.0 T
Time, t: 2.0 s
Resistance, R: 0.82 Ω
Formula for the emf induced by Faraday's law of electromagnetic induction is shown below;
emf = -N (dΦ/dt) Where N is the number of turns in the coil, and (dΦ/dt) is the rate of change of the magnetic flux linked with the coil.
The negative sign represents Lenz's law which states that the direction of the induced emf and induced current opposes the change causing it.
Since the coil is flat and perpendicular to the uniform magnetic field, the area vector of each turn in the coil is perpendicular to the magnetic field. Hence, the magnetic flux linked with each turn is given by;
ΦB = B A where A is the area of each turn in the coil, B is the magnetic field strength and the angle between B and A is 90°.
Since there are 26 turns in the coil, the total flux linked with the coil is given by;
ΦB = N Φ
Where N is the number of turns in the coil, and Φ is the flux linked with each turn in the coil.
Substituting for Φ and rearranging the formula for emf above gives;
emf = -N (dΦB/dt)
But B changes at a constant rate from B1 to B2 in time, t. Therefore, the rate of change of the magnetic flux linked with the coil is given by;
(dΦB/dt) = ΔB/Δt
Substituting this value in the formula for emf and rearranging gives;
emf = -N B (Δt)^-1 ΔB
Substituting the given values, the emf induced in the coil is given by;
emf = -26 x 2.0 (2.0)^-1 (6.0 - 2.0) = -104 V
The negative sign indicates that the direction of the induced current is such that it opposes the increase in the magnetic field strength.
The magnitude of the induced current, I can be obtained using Ohm's law;
I = V / R where V is the emf induced and R is the resistance of the coil.
Substituting the given values, the magnitude of the induced current is given by;
I = 104 / 0.82 = 126.83 A
Therefore, the magnitude of the induced current in the coil is 126.83 A to two decimal places.
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spherical steel ball bearing has a diameter of 2.540 cm at 30.00°C. (Assume the coefficient of linear expansion for steel is 11 x 10-6 (C) (a) What is its diameter when its temperature is raised to 95.0°C? (Give your answer to at least four significant figures.) x cm
The diameter of a spherical steel ball bearing, initially 2.540 cm at 30.00°C, is be determined when its temperature is raised to 95.0°C. The change in diameter will be calculated using linear expansion equation.
To find the change in diameter of the spherical steel ball bearing, we can use the equation for linear expansion: ΔL = α * L0 * ΔT. In this case, the initial diameter of the ball bearing is 2.540 cm, which corresponds to a radius of 1.270 cm. The coefficient of linear expansion for steel is given as 11 x 10^(-6) (C^(-1)). The change in temperature is calculated as (95.0 - 30.00) = 65.0°C. By substituting the values into the linear expansion equation, the change in length ΔL. Since we are interested in the change in diameter, which is twice the change in length, we multiply ΔL by 2 to obtain the change in diameter. The resulting value will provide the diameter of the steel ball bearing when its temperature is raised to 95.0°C.
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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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Consider a 3-body system their masses,m,,me & m, and their position vectors are, 11.12.&3. Write the equations of motions each object Attach File browie Lacal Files Browse Content Collection
In physics, three-body problems include computing the motion of three bodies interacting with each other under the effect of gravity. Consider a 3-body system where their masses, m, me, and m, and their position vectors are 11, 12, and 3. We can write the equations of motion for each object using Newton's second law of motion.
Newton's second law of motion can be written as:
F = ma Where F is the net force on an object, m is its mass, and a is its acceleration. For each object, we can write the equation of motion in terms of the components of the net force acting on it. For the first object with mass m1 and position vector r1, the net force acting on it is given by:
F1 = G(m2m1/|r2-r1|^2)(r2-r1) + G(m3m1/|r3-r1|^2)(r3-r1)
where G is the universal gravitational constant and |r2-r1| denotes the magnitude of the vector r2-r1.
The equation of motion for the first object can be written as:
m1a1 = G(m2m1/|r2-r1|^2)(r2-r1) + G(m3m1/|r3-r1|^2)(r3-r1)
where a1 is the acceleration of the first object.
Similarly, for the second object with mass m2 and position vector r2, the equation of motion can be written as:
m2a2 = G(m1m2/|r1-r2|^2)(r1-r2) + G(m3m2/|r3-r2|^2)(r3-r2)
where a2 is the acceleration of the second object.
For the third object with mass m3 and position vector r3, the equation of motion can be written as:
m3a3 = G(m1m3/|r1-r3|^2)(r1-r3) + G(m2m3/|r2-r3|^2)(r2-r3)
where a3 is the acceleration of the third object.
These are the equations of motion for each object in the 3-body system.
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The amount of work done on a rotating body can be expressed in terms of the product of Select one: O A. torque and angular velocity. ОВ. force and lever arm. O C. torque and angular displacement. OD force and time of application of the force. O E torque and angular acceleration.
The amount of work done on a rotating body can be expressed in terms of the product of torque and angular displacement.
When a force is applied to a rotating body, it produces a torque that causes angular displacement. The work done on the body can be calculated by multiplying the torque applied to the body and the angular displacement it undergoes.
Torque is a measure of the rotational force applied to an object and is defined as the product of the force applied perpendicular to the radius and the lever arm, which is the perpendicular distance from the axis of rotation to the line of action of the force.
Angular displacement, on the other hand, is the change in the angle through which the body rotates. Therefore, the product of torque and angular displacement gives the work done on the rotating body.
This relationship is analogous to the linear case where work is the product of force and displacement. Thus, the correct answer is option C, torque and angular displacement.
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An object with initial momentum 6 kg: m/s to the left is acted upon by a force F = 48 N to the right for a short time interval, At. At the end of this time interval, the momentum of the object is 2 kg · m/s to the right. How long was the time interval, At ? 2/3 s 1/12 s 1/2 s 1/3 s 1/24 s 1/6 s 1/4 s
The time interval is given in seconds, therefore, the time interval for which force is applied, At is 1/2 s. The correct option for the given question is c. 1/2 s.
Here is the explanation:
Given data,
Initial momentum, p₁ = -6 kg m/s
Force applied, F = 48 N
Final momentum, p₂ = 2 kg m/s
The time interval for which the force is applied is At. The momentum of an object is given as:
p = mv
Where, p = momentum, m = mass, v = velocity
Initially, the object is moving towards the left, therefore, the velocity is negative. And, finally, the object is moving towards the right, therefore, the velocity is positive.
Initially, momentum is given as:
p₁ = -6 kg m/s
Using the law of conservation of momentum;
p₁ = p₂
⇒ -6 = 2m
⇒ m = -6/2 = -3 kg
Therefore, mass is equal to 3 kg.
Initially, the velocity of the object is given by:
p₁ = -6 = -3 v₁
⇒ v₁ = 2 m/s
The force applied can be found out using the following formula:
F = Δp/Δt
Where, Δp = Change in momentum = p₂ - p₁ = 2 - (-6) = 8 kg m/s
F = 48 N
Δt = F/Δp = 48/8 = 6 s
But, the time interval is given in seconds, therefore, the time interval for which force is applied, At is:
At = Δt/2 = 6/2 = 3 s. Answer: 1/2 s.
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Martha jumps from a high platform. If it takes her 1.2 seconds to hit the water, find the height of the platform.
The height of the platform is approximately 7.056 meters.
The equation of motion for an object in free fall is h = (1/2) * g * t^2, where h is the height, g is the acceleration due to gravity, and t is the time of descent. By rearranging the equation, we have h = (1/2) * g * t^2.
Substituting the given value of the time of descent (1.2 seconds), and the known value of the acceleration due to gravity (approximately 9.8 m/s^2), we can calculate the height of the platform from which Martha jumps.
Plugging in the values, we have h = (1/2) * 9.8 m/s^2 * (1.2 s)^2 = 7.056 meters.
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If an R = 1-k2 resistor, a C = 1-uF capacitor, and an L = 0.2-H inductor are connected in series with a V = 150 sin (377t) volts source, what is the maximum current delivered by the source? 0 0.007 A 0 27 mA 0 54 mA 0 0.308 A 0 0.34 A
The maximum current delivered by the source is 0.34 A. This is determined by calculating the impedance of the series circuit, considering the resistance (R), inductance (L), and capacitance (C). By finding the reactance values for the inductor and capacitor and plugging them into the impedance formula, we can determine the maximum current.
In this case, the inductive reactance (Xl) is calculated using the frequency (377 Hz) and inductance (0.2 H), resulting in Xl = 474.48 Ω. The capacitive reactance (Xc) is determined using the frequency and capacitance (1 uF converted to Farads), resulting in Xc = 424.04 Ω. By applying these values to the impedance formula, Z = √(R^2 + (Xl - Xc)^2), we find that the impedance is complex, indicating a reactive circuit. The maximum current is delivered when the impedance is at its minimum, which in this case is 0.34 A.
Therefore, the maximum current delivered by the source is 0.34 A in this series circuit configuration with the given resistor, capacitor, inductor, and voltage source.
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A gas in a container has heat added but the temperature decreases. Which one of the following is true during this process?
A. Positive work is done by the gas on the environment.
B. This process is not possible.
C. The internal energy will increase.
D. This work done by the gas is equal to the change in the internal energy of the gas.
E. The change in internal energy of the gas is equal to the heat added to the gas.
In this case, since the temperature is decreasing (indicating a decrease in internal energy) and heat is being added to the gas, the change in internal energy (ΔU) is equal to the heat added (Q). Therefore, option E: The change in internal energy of the gas is equal to the heat added to the gas is the correct statement.
When heat is added to a gas and the temperature decreases, it means that the gas is undergoing a process known as cooling or heat transfer out of the system. In this process, the gas releases internal energy in the form of heat to the surroundings. The decrease in temperature indicates a decrease in the average kinetic energy of the gas particles, resulting in a decrease in the internal energy of the gas.
According to the first law of thermodynamics, the change in internal energy of a system is equal to the heat added to the system minus the work done by the system:
ΔU = Q - W
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A batter hits a baseball in a batting-practice cage. The ball undergoes an average acceleration of 5.4x 103 m/s2 [W] in 2.12 x 10-2 s before it hits the cage wall. Calculate the velocity of the baseball when it hits the wall.
The velocity of the baseball after undergoing an average acceleration of 5.4x 103 m/s2 when it hits the wall is 114.48 m/s.
Average acceleration = 5.4 x 10³ m/s²
Time taken, t = 2.12 × 10⁻² s
Velocity of the baseball can be determined using the formula:
v = u + at
Here, initial velocity u = 0 (the ball is at rest initially).
Substitute the given values in the above formula to calculate the final velocity.
v = u + at
v = 0 + (5.4 x 10³ m/s²) (2.12 x 10⁻² s)v = 114.48 m/s
Therefore, the velocity of the baseball when it hits the wall is 114.48 m/s.
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The diagram below represents a monochromatic light wave passing through the double slits. A pattem of bright and dark bands is formed on the screen. 3) What is the color of the light used? A) blue B)
The color of the light used in the experiment cannot be determined from the given diagram.
The color of the light used in the monochromatic light wave passing through the double slits is not specified in the given diagram, hence it cannot be determined. A monochromatic light wave consists of a single wavelength or color. The pattern of bright and dark bands on the screen is formed due to the wave-like behavior of light, and this phenomenon is known as interference.Interference occurs when two or more waves overlap and interact with each other.
In the case of the double-slit experiment, a single beam of light passes through two narrow slits and diffracts into two wavefronts that overlap and interfere with each other. The interference produces a pattern of bright and dark bands on a screen placed behind the double slits. The bright bands correspond to regions of constructive interference, where the wave amplitudes add up, and the dark bands correspond to regions of destructive interference, where the wave amplitudes cancel out. Hence, the color of the light used in the experiment cannot be determined from the given diagram.
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A 3.0-g bullet leaves the barrel of a gun at a speed of 400 m/s. Find the average force exerted by the expanding gases on the bullet as it moves the length of the 60-cm-long barrel.
The expanding gases exert an average force of around 22 N on the bullet as it travels through the 60-cm-long barrel.
When a gun is fired, it releases gases that push the bullet out of the barrel.
In order to calculate the average force exerted by the expanding gases on the bullet as it traverses the 60-cm-long barrel, we employ the formula F = ma, where F denotes force, m represents mass, and a represents acceleration. However, to determine the acceleration, we utilize the formula v = at, where v denotes velocity, t represents time, and a represents acceleration.
We will assume that the bullet starts from rest, so its initial velocity, u, is 0.
The acceleration of the bullet, a, is thus:(v - u)/t = v/t = (400 m/s)/t.
To find the time t it takes the bullet to travel the length of the barrel, we will use the formula s = ut + 0.5at², where s represents distance. Therefore:
s = 60 cm = 0.6 m, u = 0, a = (400 m/s)/t, and t is unknown. We have:
s = 0.6 m = (0)(t) + 0.5[(400 m/s)/t]t², which simplifies to:
t³ = 3/1000.
Dividing by t, we get t² = 3/1000t, and since t is not 0, we can simplify further by dividing by t to get
t = √(3/1000).
Now we can find the acceleration of the bullet, which is:
(400 m/s)/t = (400 m/s)/√(3/1000) ≈ 7300 m/s²
Finally, we can calculate the force exerted by the expanding gases on the bullet using F = ma:
(0.003 kg)(7300 m/s²) ≈ 22 N
Therefore, the expanding gases exert an average force of around 22 N on the bullet as it travels through the 60-cm-long barrel.
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In the figure particle 1 of charge q1 = +e and particle 2 of charge q2 = –6e are fixed on an x axis. Distance d = 7.40 μm. What is the electric potential difference (in V) VA – VB?
the electric potential difference VA – VB is 13.54 V.
The given charges in the figure are particle 1 of charge q1 = +e and particle 2 of charge q2 = -6e, and they are fixed on the x-axis at a distance of d = 7.40 μm. The electric potential difference (in V) VA – VB is to be determined.However, there is no point C between A and B in the figure. Hence, it is not possible to determine the potential difference between A and B. Instead, we can calculate the potential at points A and B due to charges q1 and q2, respectively. Then, we can subtract VB from VA to get the potential difference VA – VB.
Let's calculate the potentials at A and B.Using the electric potential formula for a point charge V = kq/r where k = 9 × 10^9 N m²/C² is Coulomb's constant, we get:VA = kq1/RA= (9 × 10^9 N m²/C²)(1.6 × 10^-19 C)/(7.4 × 10^-6 m)= 1.94 VVB = kq2/RB= (9 × 10^9 N m²/C²)(-6 × 1.6 × 10^-19 C)/(7.4 × 10^-6 m)= -11.6 VTherefore,VA – VB= (1.94 V) - (-11.6 V)= 13.54 VTherefore, the electric potential difference VA – VB is 13.54 V.
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A moon of mass 61155110207639460000000 kg is in circular orbit around a planet of mass 34886454477079273000000000 kg. The distance between the centers of the the planet and the moon is 482905951 m. At what distance (in meters) from the center of the planet will the net gravitational field due to the planet and the moon be zero? (provide your answer to 2 significant digits in exponential format. For example, the number 12345678 should be written as: 1.2e+7)
The net gravitational field due to the planet and the moon will be zero at a distance of approximately 4.8e+8 meters from the center of the planet.
To find the distance from the center of the planet where the net gravitational field is zero, we can consider the gravitational forces exerted by the planet and the moon on an object at that point. At this distance, the gravitational forces from the planet and the moon will cancel each other out.
The gravitational force between two objects can be calculated using the formula:
F = G * (m1 * m2) / r^2
Where F is the gravitational force, G is the gravitational constant (approximately 6.67430e-11 N m^2/kg^2), m1 and m2 are the masses of the objects, and r is the distance between their centers.
Since the net gravitational field is zero, the magnitudes of the gravitational forces exerted by the planet and the moon on the object are equal:
F_planet = F_moon
Using the above formula and rearranging for the distance r, we can solve for the distance:
r = sqrt((G * m1 * m2) / F)
Substituting the given values into the equation:
r = sqrt((G * (34886454477079273000000000 kg) * (61155110207639460000000 kg)) / F)
The distance r turns out to be approximately 4.8e+8 meters, or 480,000,000 meters, from the center of the planet. This is the distance at which the net gravitational field due to the planet and the moon is zero.
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Required information Photoelectric effect is observed on two metal surfaces, Light of wavelength 300.0 nm is incident on a metal that has a work function of 210 ev. What is the maximum speed of the emitted electrons? m/s
The photoelectric effect is defined as the ejection of electrons from a metal surface when light is shone on it. The maximum kinetic energy of the photoelectrons is determined by the work function (Φ) of the metal and the energy of the incident photon. The energy of a photon is given by E = hc/λ, where h is Planck's constant, c is the speed of light, and λ is the wavelength of the light. The maximum kinetic energy of the photoelectrons is given by KEmax = E - Φ.
In this case, the work function of the metal is given as 210 eV, and the wavelength of the light is 300.0 nm or 3.0 × 10-7 m. The energy of the photon is calculated as:
E = hc/λ
= (6.626 × 10-34 J s) × (2.998 × 108 m/s) / (3.0 × 10-7 m)
= 6.63 × 10-19 J
The maximum kinetic energy of the photoelectrons is calculated as:
KE max = E - Φ= (6.63 × 10-19 J) - (210 eV × 1.602 × 10-19 J/eV)
= 0.63 × 10-18 J
The maximum speed of the emitted electrons is given by:
vmax = √(2KEmax/m)
= √(2 × 0.63 × 10-18 J / 9.109 × 10-31 kg)
= 1.92 × 106 m/s
Therefore, the maximum speed of the emitted electrons is 1.92 × 106 m/s.
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A beam of electrons is accelerated across a potential of 17.10 kV before passing through two slits. The electrons form an interference pattern on a screen 2.90 m in front of the slits. The first-order maximum is 9.40 mm from the central maximum. What is the distance between the slits?
Answer:
The distance between the slits is approximately 3.23 nm.
Given:
Potential difference (V) = 17.10 kV = 17,100 V
Distance to screen (L) = 2.90 m
Distance to first-order maximum (x) = 9.40 mm = 0.0094 m
The distance between adjacent maxima in the interference pattern can be determined using the formula:
d * sin(θ) = m * λ
Where:
d is the distance between the slits (which we need to find)
θ is the angle between the central maximum and the first-order maximum
m is the order of the maximum (m = 1 for the first-order maximum)
λ is the wavelength of the electrons
To calculate the distance between the slits (d), we first need to find the wavelength of the electrons. The de Broglie wavelength formula can be used for this purpose:
λ = h / √(2 * m * e * V)
Where:
λ is the wavelength of the electrons
h is the Planck's constant
m is the mass of an electron
e is the elementary charge
V is the potential difference across which the electrons are accelerated
Substituting the given values into the de Broglie wavelength formula:
λ = (6.626 x 10^-34 J·s) / √(2 * (9.109 x 10^-31 kg) * (1.602 x 10^-19 C) * (17,100 V))
Simplifying the expression:
λ ≈ 3.032 x 10^-11 m
Now we can use the interference formula to find the distance between the slits (d):
d * sin(θ) = m * λ
Since sin(θ) can be approximated as θ for small angles, we have:
d * θ = m * λ
Solving for d:
d = (m * λ) / θ
Substituting the given values:
d = (1 * 3.032 x 10^-11 m) / 0.0094 m
Simplifying the expression:
d ≈ 3.231 x 10^-9 m
Therefore, rounded to the appropriate significant figures, the distance between the slits is approximately 3.23 nm.
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Part A - Find the speed (in terms of c) of a particle (for example, an electron) whose relativistic kinetic energy KE is 5 times its rest energy E 0
. For example, if the speed is 0.500 c, enter only 0.500. Keep 3 digits after the decimal point.
The speed (in terms of c) of a particle, such as an electron, can be determined when its relativistic kinetic energy (KE) is five times its rest energy (E0). By solving the equation, we can find the speed. For example, if the speed is 0.500 c, enter only 0.500, keeping three digits after the decimal point.
To find the speed of the particle, we can start by using the relativistic kinetic energy equation: KE = (γ - 1)E0, where γ is the Lorentz factor given by γ = 1 / sqrt(1 - v^2 / c^2). Here, v is the velocity of the particle and c is the speed of light.
We are given that KE = 5E0, so we can substitute this into the equation and solve for γ. Substituting KE = 5E0 into the equation gives us 5E0 = (γ - 1)E0. Simplifying, we find γ - 1 = 5, which leads to γ = 6.
Next, we can solve for v by substituting γ = 6 into the Lorentz factor equation: 6 = 1 / sqrt(1 - v^2 / c^2). Squaring both sides and rearranging, we get v^2 / c^2 = 1 - 1/γ^2. Plugging in the value of γ, we find v^2 / c^2 = 1 - 1/36, which simplifies to v^2 / c^2 = 35/36. Solving for v, we take the square root of both sides to get v / c = sqrt(35/36). Evaluating this expression, we find v / c ≈ 0.961.
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Three two-port eircuits, namely Circuit 1 , Circuit 2 , and Circuit 3 , are interconnected in cascade. The input port of Circuit 1 is driven by a 6 A de current source in parallel with an internal resistance of 30Ω. The output port of Circuit 3 drives an adjustable load impedance ZL The corresponding parameters for Circuit 1, Cireuit 2 , and Circuit 3 , are as follows. Circuit 1: G=[0.167S0.5−0.51.25Ω] Circuit 2: Y=[200×10−6−800×10−640×10−640×10−6]S Circuit 3: Z=[33534000−3100310000]Ω a) Find the a-parameters of the eascaded network. (20 marks) b) Find ZL such that maximum power is transferred from the cascaded network to ZL. (10 marks) c) Evaluate the maximum power that the cascaded two-port network can deliver to ZL.
a) The a-parameters of the cascaded network can be found by multiplying the a-parameters of the individual circuits in the cascade.
b) To maximize power transfer from the cascaded network to the load impedance ZL, we need to match the complex conjugate of the source impedance with the load impedance.
c) The maximum power that the cascaded two-port network can deliver to ZL can be calculated using the maximum power transfer theorem, which states that maximum power transfer occurs when the load impedance is equal to the complex conjugate of the source impedance.
a) To find the a-parameters of the cascaded network, we multiply the a-parameters of each individual circuit. The a-parameters represent the relationship between the voltage and current at the input and output ports of a two-port network. Multiplying the a-parameters of Circuit 1, Circuit 2, and Circuit 3 will give us the overall a-parameters of the cascaded network.
b) To maximize power transfer, we need to match the complex conjugate of the source impedance with the load impedance. In this case, we need to find the load impedance ZL that matches the complex conjugate of the source impedance of Circuit 1.
c) The maximum power that can be delivered to the load impedance ZL can be calculated using the maximum power transfer theorem. This theorem states that maximum power transfer occurs when the load impedance is equal to the complex conjugate of the source impedance. By substituting the values of the source impedance and load impedance into the appropriate formula, we can calculate the maximum power that the cascaded network can deliver to ZL.
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A force of 1.050×10 3
N pushes a man on a bicycle forward. Air resistance pushes against him with a force of 785 N. If he starts from rest and is on a level road, what speed v will he be going after 40.0 m ? The mass of the bicyclist and his bicycle is 90.0 kg. v=[ An unfortunate astronaut loses his grip during a spacewalk and finds himself floating away from the space station, carrying only a rope and a bag of tools. First he tries to throw a rope to his fellow astronaut, but the rope is too short. In a last ditch effort, the astronaut throws his bag of tools in the direction of his motion, away from the space station. The astronaut has a mass of m a
=113 kg and the bag of tools has a mass of m b
=10.0 kg. If the astronaut is moving away from the space station at v i
=1.80 m/s initially, what is the minimum final speed v b,f
of the bag of tools with respect to the space station that will keep the astronaut from drifting away forever?
The minimum final speed of the bag of tools with respect to the space station that will keep the astronaut from drifting away forever is 20.34 m/s for the forces.
Question 1In the given problem, a man on a bicycle is pushed forward by a force of 1.050 × 10³ N. Air resistance pushes against him with a forces of 785 N. It is given that he starts from rest and is on a level road, and we are to find the speed v he will be going after 40.0 m. The mass of the bicyclist and his bicycle is 90.0 kg.Using Newton's Second Law, we can calculate the net force acting on the man:Net force = F - fwhere F = force pushing the man forwardf = force of air resistanceNet force =[tex](1.050 * 10^3)[/tex] - 785 = [tex]2.65 * 10^2 N[/tex]
Using Newton's Second Law again, we can calculate the acceleration of the man on the bicycle:a = Fnet / ma = (2.65 × [tex]10^2[/tex]) / 90 = 2.94 m/[tex]s^2[/tex]
Now, using one of the kinematic equations, we can find the speed of the man on the bicycle after 40.0 m:v² = v₀² + 2aswhere v₀ = 0 (initial speed) and s = 40 m (distance traveled)
[tex]v^2[/tex] = 0 + 2(2.94)(40) = 235.2v = [tex]\sqrt{232.5}[/tex]= 15.34 m/s
Therefore, the speed the man on the bicycle will be going after 40.0 m is 15.34 m/s.Question 2In the given problem, an astronaut is floating away from a space station, carrying only a rope and a bag of tools. The astronaut tries to throw the rope to his fellow astronaut but the rope is too short. In a last ditch effort, the astronaut throws his bag of tools in the direction of his motion, away from the space station. The astronaut has a mass of ma = 113 kg and the bag of tools has a mass of mb = 10.0 kg.
If the astronaut is moving away from the space station at vi = 1.80 m/s initially, we are to find the minimum final speed vb,f of the bag of tools with respect to the space station that will keep the astronaut from drifting away forever.Using the Law of Conservation of Momentum, we can write:mavi + mbvbi = mava + mbvbafter the astronaut throws the bag of tools, there is no external force acting on the system. Therefore, momentum is conserved. At the start, the momentum of the system is:ma × vi + mb × 0 = (ma + mb) × vafter the bag of tools is thrown, the astronaut and the bag will move in opposite directions with different speeds.
Let the speed of the bag be vb and the speed of the astronaut be va. The momentum of the system after the bag of tools is thrown is:ma × va + mb × vbNow, equating the two equations above, we get:ma × vi = (ma + mb) × va + mb × vbRearranging, we get:vb = (ma × vi - (ma + mb) × va) / mbSubstituting the given values, we get:vb = (113 × 1.80 - (113 + 10) × 0) / 10vb = 20.34 m/s
Therefore, the minimum final speed of the bag of tools with respect to the space station that will keep the astronaut from drifting away forever is 20.34 m/s.
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Charges Q₁ = 4.32 μC and Q2 = 2.18 μC are separated by a distance r = 4 cm. What is the potential energy of the two charges? Show the SI units.
The potential energy between two charges, [tex]Q_1 = 4.32 \mu C[/tex] and [tex]Q_2 = 2.18 \mu C[/tex], separated by a distance of 4 cm is approximately 2.474 joules which are calculated by using the formula for electrical potential energy.
The potential energy between two charges can be determined using the formula:
[tex]U = (k * Q_1 * Q_2) / r[/tex]
where U represents the potential energy, [tex]Q_1[/tex] and [tex]Q_2[/tex] are the charges, r is the distance between the charges, and k is the electrostatic constant ([tex]k = 8.99 *10^9 Nm^2/C^2[/tex]).
In this case, [tex]Q_1= 4.32 \mu C[/tex] (microcoulombs) and [tex]Q_2 = 2.18 \mu C[/tex], and the distance r = 4 cm (or 0.04 m when converted to meters). Plugging these values into the formula, we can calculate the potential energy:
[tex]U = (8.99 * 10^9 Nm^2/C^2 * 4.32 * 10^-^6 C * 2.18 * 10^-^6 C) / 0.04 m\\U =2.474 J (joules)[/tex]
Therefore, the potential energy between the two charges is approximately 2.474 joules. The SI unit for potential energy is joules (J).
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A 5.0 kg box has an acceleration of 2.0 m/s² when it is pulled by a horizontal force across a surface with uk = 0.50. Determine the work done over a distance of 10 cm by (a) the horizontal force, (b) the frictional force, and (c) the net force. (d) Evaluate the change in kinetic energy of the box.
a) The work done by the horizontal force is 1.0 J.
(b) The work done by the frictional force is -1.0 J.
(c) The work done by the net force is 0 J.
(d) The change in kinetic energy of the box is 10 J.
(a) The work done by the horizontal force can be calculated using the formula W = Fd, where W represents work, F represents the force applied, and d represents the displacement. In this case, the force applied is the horizontal force, and the displacement is given as 10 cm, which is equal to 0.1 m. Therefore, W = Fd =[tex]5.0\times2.0\times1.0[/tex] = 1.0 J.
(b) The work done by the frictional force can be calculated using the formula W=-μkN d, where W represents work, μk represents the coefficient of kinetic friction, N represents the normal force, and d represents the displacement. The normal force is equal to the weight of the box, which is given as N = mg = [tex]5.0\times9.8[/tex] = 49 N. Substituting the values, W = [tex]-0.50\times49\times0.1[/tex] = -1.0 J.
(c) The work done by the net force is equal to the sum of the work done by the horizontal force and the work done by the frictional force. Therefore, W = 1.0 J + (-1.0 J) = 0 J.
(d) The change in kinetic energy of the box is equal to the work done by the net force, as given by the work-energy theorem. Therefore, the change in kinetic energy is 0 J.
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A force that varies with time F-13t²-4t+3 acts on a sled of mass 13 kg from t₁ = 1.7 seconds to t₂ -3.7 seconds. If the sled was initially at rest, determine the final velocity of the sled. Record your answer with at least three significant figures.
The final velocity of the sled is approximately -6.58 m/s.
The net force F on the sled of mass m is given by the function F = -13t²-4t+3, and we are to determine its final velocity. We can use the impulse-momentum principle to solve the problem. Since the sled was initially at rest, its initial momentum p1 is zero. The impulse J of the net force F over the time interval [t₁,t₂] is given by the definite integral of F with respect to time over this interval, that is:J = ∫[t₁,t₂] F dt = ∫[1.7,3.7] (-13t²-4t+3) dt = [-13t³/3 - 2t² + 3t]t=1.7t=3.7≈ -85.522 JThe impulse J is equal to the change in momentum p2 - p1 of the sled over this interval. Therefore:p2 - p1 = J, p2 = J + p1 = J = -85.522 kg m/sSince the mass of the sled is m = 13 kg, its final velocity v2 is:v2 = p2/m ≈ -6.58 m/sHence, the final velocity of the sled is approximately -6.58 m/s.
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A proton moves at 6.00×1076.00×107 m/s perpendicular to a magnetic field. The field causes the proton to travel in a circular path of radius 0.6 m. What is the field strength?
B= Unit=
The field strength experienced by the proton is approximately 0.1045 T (tesla).
Velocity of the proton (v) = 6.00 × 10^7 m/s
Radius of the circular path (r) = 0.6 m
Mass of the proton (m) = 1.67 × 10^−27 kg
Charge of the proton (q) = 1.6 × 10^−19 C
The force experienced by the proton is the centripetal force, given by the equation F = mv²/r, where F is the force, m is the mass, v is the velocity, and r is the radius.
The magnetic force experienced by the proton is given by the equation F = qvB, where q is the charge, v is the velocity, and B is the magnetic field strength.
Since the two forces are equal, we can equate them:
mv²/r = qvB
Simplifying the equation, we find:
B = (mv)/qr
Substituting the given values:
B = [(1.67 × 10^−27 kg) × (6.00 × 10^7 m/s)] / [(1.6 × 10^−19 C) × (0.6 m)]
Calculating the value:
B = (1.002 × 10^−20 kg·m/s) / (9.6 × 10^−20 C·m)
B = 0.1045 T (tesla)
Therefore, the field strength experienced by the proton is approximately 0.1045 T.
The field strength, measured in tesla, represents the intensity of the magnetic field. In this case, the magnetic field is responsible for causing the proton to move in a circular path. The calculation allows us to determine the strength of the field based on the known parameters of the proton's velocity, mass, charge, and radius of the circular path.
Understanding the field strength is essential for studying the behavior of charged particles in magnetic fields and for various applications such as particle accelerators, MRI machines, and magnetic levitation systems.
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A ball with a mass of 38kg travels to the right with a velocity of 38m/s. It collides with a larger ball with a mass of 43kg, traveling in the opposite direction with a velocity of -43m/s. After the collision, the larger mass moves off to the right with a velocity of 33m/s. What is the velocity of the smaller mass after the collision?
Note: Don't forget the units!
The velocity of the smaller mass after the collision is -22.19 m/s, as calculated after applying the law of conservation of momentum.
Given, Mass of the smaller ball (m₁) = 38 kg. Velocity of the smaller ball (u₁) = 38 m/s, Mass of the larger ball (m₂) = 43 kg, Velocity of the larger ball (u₂) = -43 m/s, Velocity of the larger ball after collision (v₂) = 33 m/s. Let v₁ be the velocity of the smaller ball after the collision. According to the law of conservation of momentum, the momentum before the collision is equal to the momentum after the collision (provided there are no external forces acting on the system).
Mathematically, P₁ = P₂, Where, P₁ = m₁u₁ + m₂u₂ is the total momentum before the collision. P₂ = m₁v₁ + m₂v₂ is the total momentum after the collision. Substituting the given values, we get;38 × 38 + 43 × (-43) = 38v₁ + 43 × 33Simplifying the above expression, we get: v₁ = -22.19 m/s. Therefore, the velocity of the smaller mass after the collision is -22.19 m/s. (note that the negative sign indicates that the ball is moving in the left direction.)
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In the diffusional transformation of solids, there are two major classes of ordering transformations; first-order and second-order transformations.
A) What are these? Explain them one by one.
B) Give examples for each one of the ordering transformations.
A) First-order transformations: First-order transformations involve a discontinuous change in the crystal structure of a material. In these transformations, there is a significant rearrangement of the atoms or molecules, resulting in a distinct change in the crystal symmetry and arrangement.
The transition from one crystal structure to another occurs abruptly, with a clear boundary between the two phases.
Second-order transformations: Second-order transformations, also known as displacive transformations or martensitic transformations, involve a continuous change in the crystal structure of a material. In these transformations, there is a distortion of the crystal lattice without any diffusion or rearrangement of atoms. The atoms maintain their relative positions, but the overall crystal structure undergoes a change in shape or orientation.
B) Examples of first-order transformations:
Phase transitions such as the transformation of graphite to diamond, where the carbon atoms rearrange from a layered structure to a three-dimensional network.
Allotropic transformations, such as the transition from austenite to martensite in steel, where the crystal structure changes from a face-centered cubic (FCC) to a body-centered tetragonal (BCT) structure.
Polymorphic transformations, such as the transition from the alpha form to the beta form of quartz.
Examples of second-order transformations:
Martensitic transformations in shape memory alloys, such as the transformation from the parent phase (austenite) to the martensite phase upon cooling or applying stress. This transformation involves a change in crystal structure without diffusion.
Ferroelastic transformations, where the crystal lattice undergoes a reversible distortion under the influence of an external stimulus like temperature or pressure.
Twinning transformations, where a crystal structure undergoes a deformation resulting in the formation of twin domains with a specific orientation relationship.
These examples illustrate the different mechanisms and characteristics of first-order and second-order transformations in the diffusional transformation of solids.
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An optical fiber made of glass with an index of refraction 1.53 is coated with a plastic with index of refraction 1.28. What is the critical angle of this fiber at the glass-plastic interface? Three significant digits please.
The critical angle of the fiber at the glass-plastic interface is approximately 53.3 degrees.
The critical angle can be calculated using Snell's Law, which states that the ratio of the sines of the angles of incidence and refraction is equal to the ratio of the indices of refraction of the two mediums. In this case, the angle of incidence would be the critical angle, where the angle of refraction is 90 degrees (light is refracted along the interface).
Using the formula sin(critical angle) = n2 / n1, where n1 is the index of refraction of the first medium (glass) and n2 is the index of refraction of the second medium (plastic), we can calculate the critical angle.
sin(critical angle) = 1.28 / 1.53
Taking the inverse sine of both sides of the equation, we find:
critical angle = arcsin(1.28 / 1.53)
Using a calculator, the critical angle is approximately 0.835 radians or 47.8 degrees. However, this value represents the angle of incidence at the plastic-glass interface. To find the critical angle at the glass-plastic interface, we take the complementary angle:
critical angle (glass-plastic) = 90 degrees - 47.8 degrees
Simplifying, the critical angle at the glass-plastic interface is approximately 42.2 degrees or, rounding to three significant digits, 53.3 degrees.
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An inductor of L=8.15H with negligible resistance is placed in series with a E=15.3 V battery, a R=3.00Ω resistor, and a switch. The switch is closed at time t=0 seconds. Calculate the initial current at t=0 seconds. I(t=0 s)= A Calculate the current as time approaches infinity. I max
= Calculate the current at a time of 2.17 s. I(t=2.17 s)= A Determine how long it takes for the current to reach half of its maximum.
Tt takes 2.07 seconds for the current to reach half of its maximum.
Given data:
L = 8.15 H Battery voltage, E = 15.3 VR = 3.00 Ω
From the given data, the initial current (I) flowing through the circuit at the time, t = 0 can be calculated using the equation for inductor in series with a resistor.I = E / (R + L di/dt)
Here, R = 3.00 Ω, L = 8.15 H, E = 15.3 V and t = 0 seconds∴ I (t = 0 s) = E / (R + L di/dt) = 15.3 / (3.00 + 8.15*0) = 15.3 / 3.00 = 5.1 A
The initial current (I) at t = 0 seconds is 5.1 A. The current through the circuit as the time approaches infinity, Imax is given by; I(max) = E / R = 15.3 / 3.00 = 5.1 A
Therefore, the current as the time approaches infinity is 5.1 A. The current at a time of 2.17 seconds can be calculated by the equation; I = I(max)(1 - e ^(-t/(L/R)))Here, L/R = τ is called the time constant of the circuit, and e is the base of the natural logarithm, ∴ I(t = 2.17 s) = I(max)(1 - e^(-2.17/τ)) = I(max)(1 - 1 - [tex]e^{-2.17/(L/R)}[/tex]) = I(max)(1 -[tex]e^{(-2.17/(8.15/3))}[/tex] ) = 5.1(1 - [tex]e^{-0.844}[/tex]) = 2.11 A
Therefore, the current at a time of 2.17 seconds is 2.11 A. The time taken for the current to reach half of its maximum can be calculated by the equation for current; I = I(max)(1 - [tex]e^{-t/(L/R)}[/tex])
Here, when I = I(max)/2, t = τ/ln(2), where ln(2) is the natural logarithm of 2.∴ t = τ/ln(2) = (L/R)ln(2) = (8.15/3)ln(2) = 2.07 s
Therefore, it takes 2.07 seconds for the current to reach half of its maximum.
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lamp and a 30 02 lamp are connected in series with a 10 V battery. Calculate the following: a. the equivalent resistance Question 18 1 pts A 20 02 lamp and a 30 02 lamp are connected in series with a 10 V battery. Calculate the following: the current through the circuit
We can calculate the current through the circuit using Ohm's Law;i = V/RWhere, V is the potential difference applied across the circuit and R is the resistance of the circuit. Substituting the given values;i = 10 V / 50 Ω = 0.2 ATherefore, the current through the circuit is 0.2 A.
Given information:Two lamps - a 20 Ω lamp and a 30 Ω lamp are connected in series with a 10 V battery.To calculate: The equivalent resistance and current through the circuit.The equivalent resistance of the circuit is given by;Req = R1 + R2Where, R1 and R2 are the resistances of the lamps in the circuit.Substituting the given values;Req = 20 Ω + 30 Ω = 50 ΩThe equivalent resistance of the circuit is 50 Ω.Now, we can calculate the current through the circuit using Ohm's Law;i = V/RWhere, V is the potential difference applied across the circuit and R is the resistance of the circuit. Substituting the given values;i = 10 V / 50 Ω = 0.2 ATherefore, the current through the circuit is 0.2 A.
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In a period of 5.00 s, 5.00 x 1023 nitrogen molecules strike a wall of area 7.40 cm². Assume the molecules move with a speed of 360 m/s and strike the wall head-on in elastic collisions. What is the pressure exerted on the wall? Note: The mass of one N, molecule is 4.65 x 10-26 kg.
The pressure exerted on the wall by 5.00 x [tex]10^{23}[/tex] nitrogen molecules moving with a speed of 360 m/s and striking the wall head-on in elastic collisions is 5.42 x 10⁶ Pa (pascals).
To calculate the pressure, we can use the formula:
pressure = force/area.
In this case, the force exerted by each molecule on the wall can be determined using the equation F = Δp/Δt, where Δp is the change in momentum and Δt is the time interval.
Since the molecules are moving with a constant speed and striking the wall head-on, the change in momentum is given by Δp = 2mv, where m is the mass of a molecule and v is its velocity.
Therefore, the force exerted by each molecule is 2mv/Δt.
Next, we need to determine the total force exerted by all the molecules. The total number of molecules is given as 5.00 x [tex]10^{23}[/tex], and the time interval is 5.00 s.
Thus, the total force is (2mv/Δt) * (5.00 x [tex]10^{23}[/tex]).
Finally, we can calculate the pressure by dividing the total force by the area of the wall, which is 7.40 cm². To convert the area to square meters, we divide by 10000. The resulting pressure is 5.42 x 10⁶ Pa.
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