The electrostatic force is the force of attraction or repulsion between electrically charged particles due to their electric charges. The alternative that best represents the ratio Q/q so that the magnitude of the electrostatic force between the two charges is maximum is: Option B. Q/q = 3/2.
The electrostatic force can be attractive when the charges have opposite signs (one positive and one negative), and repulsive when the charges have the same sign (both positive or both negative). The force acts along the line joining the charges and follows the principle of superposition, meaning that the total force on a charge due to multiple charges is the vector sum of the individual forces from each charge.
In electrostatics, the magnitude of the electrostatic force between two charges is given by Coulomb's law:
[tex]F = k * |Q| * |q| / d^2[/tex]
where F is the electrostatic force, k is the electrostatic constant, Q and q are the magnitudes of the charges, and d is the distance between them.
To maximize the electrostatic force, we need to maximize the numerator of the equation (|Q| * |q|). Since the denominator (d²) is fixed, increasing the numerator will result in a larger force.
Among the given options, option b (Q/q = 3/2) represents the largest ratio of Q/q, which means that the magnitude of the charges is larger for Q and smaller for q. This configuration will result in a maximum electrostatic force between the charges. The correct answer is option b (Q/q = 3/2).
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The correct option is (e) Q/q=1/2, that best represents the ratio Q/q so that the magnitude of the electrostatic force between the two parts is maximum is O
Given: From a charge Q is removed q, and then the two are kept at a distance d from each other. We have to indicate the alternative that best represents the ratio Q/q so that the magnitude of the electrostatic force between the two parts is maximum. Now, the electrostatic force between the two charges is given by Coulomb’s law which is: F ∝ (q1q2)/d²where, F is the electrostatic force, q1 and q2 are the magnitude of charges and d is the distance between them. So, if we want to maximize the electrostatic force, then q1 and q2 should be maximum. Therefore, the ratio Q/q should be equal to 1.
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A small particle called a muon is created at the top of the atmosphere when a high energy cosmic ray hits an air molecule. The muon is travelling at v = 2.95 x 108 m/s with respect to the Earth. If a person on the ground observes the muon move for 1.0 ms in his frame of reference, how much time has passed in the frame of reference of the moon?
The time passed in the frame of reference of the moon when a muon is observed on the ground is around 0.998 ms.
The theory of relativity is a theory developed by Albert Einstein, which deals with the relationship between space and time. In physics, it is a theory that describes the effect of gravity on the movement of the objects. The special theory of relativity deals with the physics of objects at a steady speed and describes the way space and time are viewed by observers in different states of motion. The general theory of relativity deals with the physics of accelerating objects and gravity. It describes gravity as an effect caused by the curvature of space-time by massive objects. The time dilation is one of the most significant consequences of the theory of relativity.
Now coming back to the question: A small particle called a muon is created at the top of the atmosphere when a high energy cosmic ray hits an air molecule. The muon is travelling at v = 2.95 x 108 m/s with respect to the Earth. If a person on the ground observes the muon move for 1.0 ms in his frame of reference.
The time dilation formula is as follows:[tex]\[{\Delta}t' = \frac{\Delta t}{\sqrt{1 - \frac{v^2}{c^2}}}\]Where,\[{\Delta}t'\][/tex] is the time in the frame of reference of the moon[tex],\[\Delta t\][/tex] is the time in the frame of reference of the person on Earth, and c is the speed of light in vacuum. From the question,[tex]\[\Delta t = 1.0\text{ ms} = 1.0 \times 10^{-3} \text{ s}\][/tex]. The velocity of the muon,[tex]\[v = 2.95 \times 10^8\text{ m/s}\][/tex]. Hence,[tex]\[{\Delta}t' = \frac{\Delta t}{\sqrt{1 - \frac{v^2}{c^2}}} = \frac{1.0 \times 10^{-3}}{\sqrt{1 - \frac{(2.95 \times 10^8)^2}{(3.0 \times 10^8)^2}}}\][/tex]. Calculating this,[tex]\[{\Delta}t' \approx 0.998\text{ ms}\].[/tex]
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The current in an RL circuit drops from 1.2 A to 13 mA
in the first second following removal of the battery from the
circuit. If L is 11 H, find the resistance R in
the circuit.
We can solve this equation 0.013 - ln(1.2) = 1.2 * e^(-(R/11)) numerically to find the value of resistance R using methods like iteration or numerical solvers. Unfortunately, it is not possible to find the exact value of R analytically.
In an RL circuit, the rate of change of current with respect to time is given by:
di/dt = - (R/L) * i,
where i is the current and R is the resistance.
Given:
Initial current (i_0) = 1.2 A
Final current (i_f) = 13 mA = 0.013 A
Time (t) = 1 second
Inductance (L) = 11 H
We can integrate both sides of the equation to solve for R.
∫(di/i) = - ∫((R/L) * dt)
Integrating both sides, we get:
ln(i) = - (R/L) * t + C,
where C is the constant of integration.
Using the initial condition i = i_0 when t = 0, we can determine the value of C.
ln(i_0) = - (R/L) * 0 + C
ln(i_0) = C
Therefore, the equation becomes:
ln(i) = - (R/L) * t + ln(i_0)
To find R, we need to substitute the given values into the equation and solve for R when i = i_f and t = 1 second.
ln(i_f) = - (R/L) * 1 + ln(i_0)
Taking the exponential of both sides:
i_f = i_0 * e^(-(R/L)) + ln(i_0)
Substituting the given values:
0.013 = 1.2 * e^(-(R/11)) + ln(1.2)
Simplifying the equation:
0.013 - ln(1.2) = 1.2 * e^(-(R/11))
Now, we can solve this equation numerically to find the value of R using methods like iteration or numerical solvers. Unfortunately, it is not possible to find the exact value of R analytically.
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A steel walkway (a=18.4 x 10^-6 mm/mmC) spans the rome walkway . The walkway spans a 170 foot 8.77 inch gap. If the walkway is meant for a temperature range of -32.4 C to 39.4 C how much space needs to be allowed for expansion? Report your answer in inches ..
2048.77 inches space needed to be allowed for expansion
To calculate the expansion space required for a steel walkway that spans a 170 ft 8.77 inch gap.
we need to consider the walkway's coefficient of thermal expansion and the temperature range it's designed for. Using the given coefficient of and the temperature range of -32.4 C to 39.4 C, we can calculate the expansion space required in inches, which turns out to be 2.39 inches.
The expansion space required for the steel walkway can be calculated using the following formula:
ΔL = L * α * ΔT
Where ΔL is the change in length of the walkway, L is the original length (in this case, the length of the gap the walkway spans), α is the coefficient of thermal expansion, and ΔT is the temperature difference.
[tex]ΔL = 170 ft 8.77 in * (18.4 \times 10^-6 mm/mmC) * (39.4 C - (-32.4 C))[/tex]
Converting the length to inches and the temperature difference to Fahrenheit and Simplifying this expression, we get
ΔL=170ft8.77in∗(18.4×10 − 6mm/mmC)∗(39.4C−(−32.4C))
Therefore, the expansion space required for the steel walkway is 2.39 inches. This means that the gap the walkway spans should be slightly larger than its original length to allow for thermal expansion and prevent buckling or distortion.
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A 1.0 kg ball is dropped from the roof of a building 40 meters
tall. Ignoring air resistance, what is the approximate time of
fall
The approximate time of fall for a 1.0 kg ball dropped from a 40-meter tall building, ignoring air resistance, is approximately 2.86 seconds.
To determine the approximate time of fall for a ball dropped from a height of 40 meters, we can use the kinematic equation for free fall:
h = (1/2) × g × t²
where:
h is the height (40 meters),g is the acceleration due to gravity (approximately 9.8 m/s²),t is the time of fall.Rearranging the equation to solve for t:
t = sqrt((2 × h) / g)
Substituting the given values:
t = sqrt((2 × 40) / 9.8)
t = sqrt(80 / 9.8)
t ≈ sqrt(8.16)
t ≈ 2.86 seconds
Therefore, the approximate time of fall for the 1.0 kg ball is approximately 2.86 seconds when ignoring air resistance.
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Think and Solve 10. A 3.0 cm-tall candle light is located 60.0 em from a thin converging lens with a focal length of 20.0 cm. A. Sketch a ray diagram to locate the image. B. Calculate the image distance
The ray diagram of a thin converging lens is shown below
The image distance is 15 cm.
A) Ray diagram to locate the image:The ray diagram of a thin converging lens is shown below. The candle's height is represented as an arrow, and the diverging rays are drawn using arrows with vertical lines at the top. A lens that is thin and converging converges the light rays, as shown in the diagram. Image is formed on the opposite side of the lens from the object.
B) Calculation of the image distance:
Height of candle, h0 = 3.0 cm
Object distance, u = -60.0 cm (since the object is on the left side of the lens)
Focal length, f = 20.0 cm
Image distance, v = ?
Formula: 1/f = 1/v - 1/u
Substituting the values,
1/20 = 1/v - 1/-60.
1/v = 1/20 + 1/60 = (3 + 1)/60 = 1/15
v = 15 cm
Therefore, the image distance is 15 cm.
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Write the complete decay equation for the given nuclide in the complete 4xy notation. Refer to the periodic table for values of Z. A decay of 210 Po, the isotope of polonium in the decay series of 238U that was discovered by the Curies.
The complete decay equation for the given nuclide, 210Po, in the complete 4xy notation is:
210Po → 206Pb + 4He
Polonium-210 (210Po) is an isotope of polonium that undergoes alpha decay as part of the decay series of uranium-238 (238U). In alpha decay, an alpha particle (consisting of two protons and two neutrons) is emitted from the nucleus of the parent atom.
In the case of 210Po, the parent atom decays into a daughter atom by emitting an alpha particle. The daughter atom formed in this process is lead-206 (206Pb), and the emitted alpha particle is represented as helium-4 (4He).
The complete 4xy notation is used to represent the nuclear reactions, where x and y represent the atomic numbers of the daughter atom and the emitted particle, respectively. In this case, the complete decay equation can be written as:
210Po → 206Pb + 4He
This equation shows that 210Po decays into 206Pb by emitting a 4He particle. It is important to note that the sum of the atomic numbers and the sum of the mass numbers remain conserved in a nuclear decay reaction.
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Question 10. As the baseball is being caught, it's speed goals from 32 to 0 m/s in about 0.008 seconds. It's mass is 0.145 kg. ( Take the direction the baseball is thrown to be positive.) (a) what is the baseball acceleration in m/s2? ----m/s2 What is the baseball's acceleration in g's? -- -g What is the size of the force acting on it? ----N
The baseball's acceleration is -4000 m/s² (-408.16 g) and the force acting on it is -580 N.
The baseball's acceleration can be calculated using the given information. It can be expressed in m/s² and also converted to g's. The force acting on the baseball can also be determined. To calculate the baseball's acceleration, we can use the formula:
Acceleration = (Change in Velocity) / Time
Given that the initial velocity (u) is 32 m/s, the final velocity (v) is 0 m/s, and the time (t) is 0.008 seconds, we can calculate the acceleration.
Acceleration = (0 - 32) m/s / 0.008 s
Acceleration = -4000 m/s²
The negative sign indicates that the acceleration is in the opposite direction of the initial velocity. To express the acceleration in g's, we can use the conversion factor:
1 g = 9.8 m/s²
Acceleration in g's = (-4000 m/s²) / (9.8 m/s² per g)
Acceleration in g's = -408.16 g
The negative sign signifies that the acceleration is directed opposite to the initial velocity and is decelerating.
To determine the size of the force acting on the baseball, we can use Newton's second law of motion:
Force = Mass × Acceleration
Given that the mass (m) of the baseball is 0.145 kg and the acceleration is -4000 m/s², we can calculate the force.
Force = 0.145 kg × (-4000 m/s²)
Force = -580 N
Hence, the baseball's acceleration is -4000 m/s² (-408.16 g) and the force acting on it is -580 N. The negative sign indicates the direction of the force and acceleration in the opposite direction of the initial velocity.
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7 Part 3 of 3 166 points eBook Hint Pant References ! Required information An arrangement of two pulleys, as shown in the figure, is used to lift a 54.8 kg crate a distance of 2.96 m above the starting point. Assume the pulleys and rope are ideal and that all rope sections are essentially vertical Pkg where P 54.8. What length of rope must be pulled to lift the crate 2.96 m?
The length of the rope that must be pulled to lift the crate 2.96 m when an arrangement of two pulleys is used to lift a 54.8 kg crate a distance of 2.96 m above the starting point can be calculated as follows:The arrangement of two pulleys shown in the figure can be considered as a combination of two sets of pulleys, each having a single movable pulley and a fixed pulley.
In this arrangement, the rope passes through two sets of pulleys, such that each section of the rope supports half of the weight of the load.
The tension in the rope supporting the load is equal to the weight of the load, which is given by T = m × g, where m = 54.8 kg is the mass of the crate and g = 9.81 m/s² is the acceleration due to gravity.
Hence, the tension in each section of the rope supporting the load is equal to T/2 = (m × g)/2.
The length of rope pulled to lift the crate a distance of 2.96 m is equal to the vertical displacement of the load, which is equal to the vertical displacement of each section of the rope. Since the rope is essentially vertical, the displacement of each section of the rope is equal to the displacement of the load, which is given by Δy = 2.96 m.
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Maxwell calculated what the speed of light would have to be in order to obey which law?
A. Universal Law of Gravitation
B. Special theory of relativity C. Law of Conservation of Matter D. Law of Conservation of Energy
Maxwell calculated the speed of light to satisfy the requirements of B. the special theory of relativity.
In his work on electrodynamics, James Clerk Maxwell developed a set of equations that described the behavior of electromagnetic waves. These equations predicted the existence of electromagnetic waves that traveled at a particular speed.
Maxwell realized that the speed of these waves matched the speed of light, suggesting a fundamental connection between light and electromagnetism. This led to the development of the special theory of relativity by Albert Einstein, who recognized that the speed of light in a vacuum is constant and is the maximum attainable speed in the universe.
Therefore, Maxwell's calculations were crucial in formulating the theory of relativity, which revolutionized our understanding of space, time, and the fundamental laws of physics. Option B is the correct answer.
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A sample of lead has a mass of 36 kg and a density of 11.3 x 103 kg/mº at 0 degree Celcius. Given the average linear expansion coefficient of lead 29 x 10-K-1 (a) What is the density of lead at 90 degree Celcius? (in SI units) (b) What is the mass of the sample of lead at 90 degree Celcius? (in Sl units)
a. The density of lead at 90 degrees Celsius in SI units is [tex]36 kg / (V0 + (36 kg / (11.3 x 10^3 kg/m³) * (29 x 10^-6 K^-1) * 363.15 K)[/tex]
b. Mass of the lead sample at 90 degrees Celsius is ρ * (V0 + ΔV)
To solve this problem, we can use the formula for volumetric expansion to find the new density and mass of the lead sample at 90 degrees Celsius.
(a) Density of lead at 90 degrees Celsius:
The formula for volumetric expansion is:
[tex]ΔV = V0 * β * ΔT[/tex]
where ΔV is the change in volume, V0 is the initial volume, β is the coefficient of linear expansion, and ΔT is the change in temperature.
We can rearrange the formula to solve for the change in volume:
[tex]ΔV = V0 * β * ΔT[/tex]
[tex]ΔV = (m / ρ0) * β * ΔT[/tex]
where m is the mass of the sample and ρ0 is the initial density.
The new volume V is given by:
[tex]V = V0 + ΔV[/tex]
The new density ρ can be calculated as:
ρ = m / V
Substituting the expression for ΔV:
[tex]ρ = m / (V0 + (m / ρ0) * β * ΔT)[/tex]
m = 36 kg
[tex]ρ0 = 11.3 x 10^3 kg/m³[/tex]
[tex]β = 29 x 10^-6 K^-1[/tex]
[tex]ΔT = (90 - 0) = 90 degrees Celsius[/tex]
Converting ΔT to Kelvin:
[tex]ΔT = 90 + 273.15 = 363.15 K[/tex]
Substituting the values:
[tex]ρ = 36 kg / (V0 + (36 kg / (11.3 x 10^3 kg/m³) * (29 x 10^-6 K^-1) * 363.15 K)[/tex]
Calculating this expression will give us the density of lead at 90 degrees Celsius in SI units.
(b) Mass of the lead sample at 90 degrees Celsius:
To find the mass at 90 degrees Celsius, we can use the equation:
[tex]m = ρ * V[/tex]
Substituting the values:
[tex]m = ρ * (V0 + ΔV)[/tex]
We already calculated ρ and ΔV in part (a).
Calculating this expression will give us the mass of the lead sample at 90 degrees Celsius in SI units.
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A small block of mass M is placed halfway up on the inside of a frictionless, circular loop of radius R, as shown. The size of the block is very small compared to the radius of the loop. Determine an expression for the minimum downward speed v min
with which the block must be released in order to guarantee that it will make a full circle. Incorrect
The block must be released with vmin = √(2gR/5) in order to guarantee that it will make a full circle.
A small block of mass M is placed halfway up on the inside of a frictionless, circular loop of radius R. At the top of the loop, the entire energy of the block is equal to its potential energy at A or its kinetic energy at the bottom of the loop. Thus, mgh = 1/2mv²+mg2Rg = v²/2v = √(2gR). Let Minimum velocity required to just complete the circle = v1.Now consider point B from which the block will start the circular motion.
In order to just complete the circle, the minimum velocity required by the block at point B is due to the conservation of energy as follows. v1²/2 = mgh - mg3Rg/2v1²/2 = mg(R - 3R/2)R = 5v1²/2g⇒ v1 = √(2gR/5). Minimum velocity required at B to just complete the circle = v1 = √(2gR/5).
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A guitar string is vibrating at its 2nd overtone or 3rd fundamental mode of vibration. The note produced by the string is 587.33 Hz. The speed of the wave on the string is 350 m/s. What is the length of the string? 0.596 m 0.894 m 111 m 1.68 m
The length of the string is 0.894 m.
To find the length of the string, given that a guitar string is vibrating at its 2nd overtone or 3rd fundamental mode of vibration and the note produced by the string is 587.33 Hz and that the speed of the wave on the string is 350 m/s, we will use the formula;Speed = wavelength x frequency
For a string with fixed ends, the fundamental frequency is given by;f = (nv/2L)where n = 1, 2, 3...L = length of the string v = speed of wave on the string
The second overtone or third fundamental mode means that n = 3L = (nv/2f) => L = (3v/2f)Substituting the given values;L = (3 × 350)/(2 × 587.33)L = 0.894 m.Therefore, the length of the string is 0.894 m. Therefore, the option that correctly answers the question is 0.894 m.
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The length of the guitar string when it's vibrating at its 2nd overtone or 3rd fundamental mode of vibration is 0.596 m.
The fundamental frequency of a string depends on its length and speed. The equation for the frequency of a string with length L and wave speed v is f = v/2L where f is the frequency in hertz, v is wave speed in meters per second, and L is length in meters.
The string is vibrating at the 2nd overtone or 3rd fundamental mode, which means there are 3 nodes and 2 antinodes. In this case, the frequency is given as 587.33 Hz and the wave speed is 350 m/s.
Therefore, the length of the string can be found using the equation f = v/2L, which can be rearranged to give L = v/2f.
Substituting in the given values, we get:
L = 350/(2 x 587.33) = 0.298 m
Since there are three segments of the string, the length of each segment is 0.298 m / 3 = 0.099 m. So the total length of the string is L = 0.099 m x 2 + 0.298 m = 0.596 m.
The length of the guitar string when it's vibrating at its 2nd overtone or 3rd fundamental mode of vibration is 0.596 m.
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Atan air show the tirectly toward the stands at a speed of 1100 / min 140 on a day when the down to what Frequency received by the bar (h) What frequency in re do they receive as the plane files directly away from them
At an air show a jet flies directly toward the stands at a speed of 1100 / min emitting a frequency of 3500 Hz, on a day when the speed of sound is 342 m/s, frequency received by the observers when the jet flies directly toward the stands is approximately 3326 Hz. b) the frequency received is approximately 3703 Hz.
(a) To determine the frequency received by the observers when the jet flies directly toward the stands, the concept of Doppler effect is used.
The formula for the apparent frequency observed (f') when a source is moving towards an observer is given by:
f' = (v + v₀) / (v + [tex]v_s[/tex]) × f
Where:
f' is the observed frequency
v is the speed of sound
v₀ is the velocity of the observer
[tex]v_s[/tex]is the velocity of the source
f is the emitted frequency
In this case, the speed of sound (v) is 342 m/s, the velocity of the observer (v₀) is 0 (as they are stationary), the velocity of the source ([tex]v_s[/tex]) is 1100 m/min (which needs to be converted to m/s), and the emitted frequency (f) is 3500 Hz.
Converting the velocity of the source to m/s:
1100 m/min = 1100 / 60 m/s ≈ 18.33 m/s
Now, the observed frequency (f'):
f' = (v + v₀) / (v + v_s) × f
= (342 m/s + 0 m/s) / (342 m/s + 18.33 m/s) × 3500 Hz
Calculating the value:
f' ≈ (342 m/s / 360.33 m/s) × 3500 Hz
≈ 0.949 × 3500 Hz
≈ 3326 Hz
Therefore, the frequency received by the observers when the jet flies directly toward the stands is approximately 3326 Hz.
(b) When the plane flies directly away from the observers, the formula for the apparent frequency observed (f') is slightly different:
f' = (v - v₀) / (v - [tex]v_s[/tex]) × f
Using the same values as before, the observed frequency (f') when the plane flies directly away:
f' = (v - v₀) / (v - [tex]v_s[/tex] × f
= (342 m/s - 0 m/s) / (342 m/s - 18.33 m/s) × 3500 Hz
Calculating the value:
f' ≈ (342 m/s / 323.67 m/s) × 3500 Hz
≈ 1.058 × 3500 Hz
≈ 3703 Hz
Therefore, the frequency = is approximately 3703 Hz.
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complete question is below
a) At an air show a jet flies directly toward the stands at a speed of 1100 / min emitting a frequency of 3500 Hz, on a day when the speed of sound is 342 m/s. What frequency is received by the observers? (b) What frequency do they receive as the plane flies directly away from them?
When an atom of 215Po decays it releases an ________ particle, which is actually an atomic nucleus with ________ protons as well as ________ neutrons. The daughter atom has an atomic number of 82. The Name of the daughter atom is ________.
An atom of 215Po decays by releasing an alpha particle, which is actually an atomic nucleus with 2 protons as well as 2 neutrons. The daughter atom has an atomic number of 82. The name of the daughter atom is lead (Pb).
Polonium-215 (215Po) decays by alpha decay, where an alpha particle is emitted. An alpha particle consists of two protons and two neutrons, which means it has an atomic number of 2 (since protons determine the atomic number) and a mass number of 4 (sum of protons and neutrons).
When an alpha particle is emitted during the decay of 215Po, the resulting daughter atom will have an atomic number that is two less than that of the parent atom. Given that 215Po has an atomic number of 84, the daughter atom will have an atomic number of 82.
Therefore, when an atom of 215Po decays, it releases an alpha particle, which is an atomic nucleus with 2 protons and 2 neutrons. The daughter atom produced has an atomic number of 82 and is known as lead (Pb).
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2. Tides+Gravity (32 points): a. At what distance would the Moon have to be for you to weigh 0.01% less when it is directly overhead? [Hint: refer to your homework solutions). b. How high would typical ocean tide heights be if the Moon were that close? c. Calculate the Moon's orbital period at the distance you found in part a. d. If the Moon's period were given by your answer to part c, would you expect tidal forces to cause its orbit to become larger or smaller over time? Why?
a. To determine the distance at which the Moon would have to be for you to weigh 0.01% less when it is directly overhead, we can use the concept of tidal forces. Tidal forces are inversely proportional to the cube of the distance between two objects.
Let's assume your weight when the Moon is not directly overhead is W. To calculate the distance (d) at which you would weigh 0.01% less, we can use the formula:
W - 0.0001W = (GMm)/d^2
Where:
G is the gravitational constant (6.67430 × 10^-11 m^3 kg^-1 s^-2)
M is the mass of the Moon (7.349 × 10^22 kg)
m is your mass (assumed to be constant)
d is the distance between you and the Moon
Simplifying the equation:
0.9999W = (GMm)/d^2
d^2 = (GMm)/(0.9999W)
d = sqrt((GMm)/(0.9999W))
Substituting the appropriate values and using the fact that your mass (m) cancels out, we can calculate the distance (d).
b. To calculate the typical ocean tide heights if the Moon were that close, we can use the concept of tidal bulges. Tidal bulges are created due to the gravitational pull of the Moon on the Earth's oceans. The height of the tide is determined by the difference in gravitational attraction between the near side and far side of the Earth.
The typical ocean tide heights can vary depending on various factors such as the specific location, geography, and other astronomical influences. However, we can generally assume that if the Moon were closer, the tidal bulges would be significantly higher.
c. To calculate the Moon's orbital period at the distance found in part a, we can use Kepler's Third Law of Planetary Motion, which states that the square of the orbital period (T) is proportional to the cube of the average distance (r) between the Moon and the Earth.
T^2 ∝ r^3
Since we found the new distance (d) in part a, we can set up the following proportion:
(T_new)^2 / (T_earth)^2 = (d_new)^3 / (d_earth)^3
Solving for T_new:
T_new = T_earth * sqrt((d_new)^3 / (d_earth)^3)
Where T_earth is the current orbital period of the Moon (approximately 27.3 days).
d. If the Moon's orbital period were given by the answer in part c, we would expect tidal forces to cause its orbit to become larger over time. This is because the tidal forces exerted by the Earth on the Moon cause a transfer of angular momentum, which results in a gradual increase in the Moon's orbital distance. This phenomenon is known as tidal acceleration.
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You place a crate of mass 37.6 kg on a frictionless 4.77-meter-long incline.
You release the crate from rest, and it begins to slide down, eventually
reaching the bottom 1.69 s after you released it. What is the angle of the
incline?
The angle of the incline is approximately 16.65 degrees.
To find the angle of the incline, we can use the kinematic equations and the principles of motion along an inclined plane.
Given:
Mass of the crate (m) = 37.6 kg
Length of the incline (s) = 4.77 m
Time taken to reach the bottom (t) = 1.69 s
Acceleration due to gravity (g) = 9.8 m/s²
Let's consider the motion of the crate along the incline.
Using the equation for displacement along an inclined plane:
s = (1/2) * g * t²
We can rearrange this equation to solve for g:
g = (2 * s) / t²
Substituting the given values:
g = (2 * 4.77 m) / (1.69 s)²
g ≈ 2.8 m/s²
The acceleration due to gravity (g) acting parallel to the incline is given by:
g_parallel = g * sin(θ)
where θ is the angle of the incline.
Rearranging the equation, we can solve for sin(θ):
sin(θ) = g_parallel / g
sin(θ) = g_parallel / 9.8 m/s²
Substituting the value of g_parallel:
sin(θ) = 2.8 m/s² / 9.8 m/s²
sin(θ) ≈ 0.2857
To find the angle θ, we can take the inverse sine (sin⁻¹) of both sides:
θ = sin⁻¹(0.2857)
θ ≈ 16.65°
Therefore, the angle of the incline is approximately 16.65 degrees.
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A 2.860 kg, 60.000 cm diameter solid ball initially spins about an axis that goes through its center at 5.100 rev/s. A net torque of 1.070 N.m then makes the ball come to a stop. The average net power of the net torque acting on the ball as it stops the ball, in Watts and to three decimal places, is
The average net power exerted on the solid ball as it comes to a stop is approximately 5.457 Watts. This is calculated using the formula for power and considering the given net torque and initial angular velocity .
To calculate the average net power exerted on the solid ball as it comes to a stop, we need to use the formula for power and consider the angular acceleration of the ball. The net torque and the initial angular velocity are given. The formula for power is given by:
Power = Torque * Angular velocity
First, we need to calculate the angular acceleration of the ball using the formula: Torque = Moment of inertia * Angular acceleration
The moment of inertia of a solid ball can be calculated using the formula: Moment of inertia = (2/5) * Mass * Radius²
Given:
Mass of the ball (m) = 2.860 kg
Diameter of the ball (d) = 60.000 cm
Initial angular velocity (ω) = 5.100 rev/s
Net torque (τ) = 1.070 N.m
Radius (r) = d/2 = 60.000 cm / 2 = 30.000 cm = 0.30000 m
Moment of inertia (I) = (2/5) * m * r²
= (2/5) * 2.860 kg * (0.30000 m)²
= 0.1029 kg.m²
Angular acceleration (α) = τ / I
= 1.070 N.m / 0.1029 kg.m²
≈ 10.395 rad/s²
Now, we can calculate the average net power:
Average net power = Torque * Angular velocity
= 1.070 N.m * 5.100 rev/s
= 5.457 W (to three decimal places)
Hence, the average net power exerted on the ball as it comes to a stop is approximately 5.457 Watts.
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5. What kinetic energy must an electron have in order to have a de Broglie wavelength of 1 femtometer? 18pts) 6. The average temperature of a blackhole is 1.4 x 10-14K. Assuming it is a perfect black body, a)What is the wavelength at which the peak occurs in the radiation emitted by a blackhole? 16pts b)What is the power per area emitted by a blackhole? [6pts!
5. The kinetic energy of an electron with a de Broglie wavelength of 1 femtometer is approximately 1.097 x 10^-16 J.
6. The peak wavelength in the radiation emitted by a black hole is approximately 2.07 x 10^-11 meters, with a power per unit area of approximately 2.53 x 10^-62 W/m^2.
5. To determine the kinetic energy of an electron with a de Broglie wavelength of 1 femtometer, we can use the de Broglie wavelength equation:
λ = h / p
where λ is the wavelength, h is the Planck's constant (approximately 6.626 x 10^-34 J·s), and p is the momentum of the electron.
Since the momentum of an electron is given by:
p = √(2mE)
where m is the mass of the electron (approximately 9.11 x 10^-31 kg) and E is the kinetic energy of the electron, we can rearrange the equations and substitute the values to solve for E:
λ = h / √(2mE)
E = h^2 / (2mλ^2)
E = (6.626 x 10^-34 J·s)^2 / (2 * 9.11 x 10^-31 kg * (1 x 10^-15 m)^2)
E ≈ 1.097 x 10^-16 J
6a.
The wavelength at which the peak occurs in the radiation emitted by a black hole can be calculated using Wien's displacement law:
λpeak = (2.898 x 10^-3 m·K) / T
where λpeak is the peak wavelength, T is the temperature of the black hole in Kelvin, and 2.898 x 10^-3 m·K is Wien's constant.
λpeak = (2.898 x 10^-3 m·K) / (1.4 x 10^-14 K)
λpeak ≈ 2.07 x 10^-11 m
6b.
The power per unit area emitted by a black hole can be calculated using the Stefan-Boltzmann law:
P/A = σT^4
where P/A is the power per unit area, σ is the Stefan-Boltzmann constant (approximately 5.67 x 10^-8 W/(m^2·K^4)), and T is the temperature of the black hole in Kelvin.
P/A = (5.67 x 10^-8 W/(m^2·K^4)) * (1.4 x 10^-14 K)^4
P/A ≈ 2.53 x 10^-62 W/m^2
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3. [-/2 Points] DETAILS OSUNIPHYS1 3.4.P.048. MY NOTES ASK YOUR TEACHER PRACTICE ANOTHER A particle has a constant acceleration of 7.0 m/s. (Due to the nature of this problem, do not use rounded intermediate values in your calculations-including answers submitted in Wesign) (a) If its initial velocity is 2.7 m/s, at what time (ins after t-0) is its displacement 6.0 m (b) What is its speed at that time (in m/s)? m/s Additional Materials Reading Submit Answer
The value of acceleration is 7.0 m/s². (a) We have to find out the time taken by the particle to reach 6.0 m displacement with the initial velocity of 2.7 m/s.(b) Find the velocity of the particle when it is displaced by 6 m.
We know that, acceleration is defined as the rate of change of velocity with time which is denoted as,a = Δv / ΔtHere, Δv = change in velocity and Δt = change in time. The particle has a constant acceleration of 7.0 m/s².We have to find out the time taken by the particle to reach 6.0 m displacement with the initial velocity of 2.7 m/s. (a)
We know that,
Displacement (s) = ut + 1/2 at²where
u = initial velocity,t = time taken to reach 6.0 m displacement.
a = acceleration,
ands = displacement
At s = 6.0 m,
u = 2.7 m/s
t= ?
a = 7.0 m/s²
We can find the time taken by substituting the above values in the formula,
6.0 m = 2.7 m/s × t + 1/2 × 7.0 m/s² × t²6t² + 5.4t - 12 = 0
On solving the above equation, we get,t = 0.935 s (approx)
Thus, the time taken by the particle to reach 6.0 m displacement with the initial velocity of 2.7 m/s is 0.935 s.
(b)We know that,Final velocity (v)² = u² + 2as
Here, u = 2.7 m/s,
s = 6.0 m, and
a = 7.0 m/s²
Therefore, the velocity of the particle when it is displaced by 6.0 m is 13 m/s.
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A 45 cm long wire has a radias of 2 mm, the resistivity of the metal 65x10- mis connected with a volts battery. How much current will pass through the wire? Express your answer in Amperes !
When a 45 cm long wire having a radius of 2 mm, the resistivity of the metal 65x10-8 Ωm is connected with a volts battery, then the current passing through the wire is 1.83 Amperes (A).
The resistance of a wire depends on its resistivity, length, and cross-sectional area.
The formula for the resistance of a wire is R = ρL/A
where,
R is the resistance
ρ is the resistivity
L is the length of the wire
A is the cross-sectional area of the wire.
The current through a wire is given by I = V/R
where, I is the current, V is the voltage, and R is the resistance.
R = ρL/AR = (ρL)/πr²
I = V/R = Vπr²/(ρL)
I = (1 V)π(0.002 m)²/(65×10⁻⁸ Ω·m)(0.45 m)
I = 1.83 A
Therefore, the current passing through the wire is 1.83 Amperes (A).
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An energy of 0.17J is stored atop the metal sphere of
a Van de Graaff generator. A spark carrying 1.0 microcoulomb (10-6
C) discharges the sphere. Find the sphere's potential relative to
the ground.
The potential of the sphere relative to the ground is 170,000 volts.
When the spark discharges the sphere, it releases an electric charge of 1.0 microcoulomb (10-6 C). The potential energy stored in the sphere can be converted to electrical potential energy using the formula PE = qV, where PE is the potential energy, q is the charge, and V is the potential. Rearranging the formula, we have V = PE / q. Substituting the given values, the potential of the sphere relative to the ground is 0.17 J / (1.0 × 10-6 C) = 170,000 volts. Therefore, the potential of the metal sphere relative to the ground is 170,000 volts.
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A deuteron (the nucleus of an isotope of hydrogen) has a mass of 3.34x10-27 kg and a charge of 1.60 10-19 C. The deuteron travels in a circular path with a radius of 720 mm in a magnetic field with a magnitude of 2.80 T Find the speed of the deuteron
The speed of the deuteron is approximately 3.43 * 10^6 m/s.
To find the speed of the deuteron traveling in a circular path in a magnetic field, we can use the equation for the centripetal force:
[tex]F = q * v * B[/tex]
where:
F is the centripetal force,
q is the charge of the deuteron,
v is the speed of the deuteron,
and B is the magnitude of the magnetic field.
The centripetal force is:
[tex]F = m * (v^2 / r)[/tex]
where:
m is the mass of the deuteron,
v is the speed of the deuteron,
and r is the radius of the circular path.
Setting the centripetal force equal to the magnetic force, we have:
[tex]F = m * (v^2 / r)[/tex]
Rearranging the equation, we can solve for the speed (v):
[tex]v = (q * B * r) / m[/tex]
Plugging in the values:
[tex]q = 1.60 * 10^(-19) C[/tex]
B = 2.80 T
r = 720 mm = 0.72 m
[tex]m = 3.34 * 10^(-27) kg[/tex]
[tex]v = (1.60 * 10^(-19) C * 2.80 T * 0.72 m) / (3.34 * 10^(-27) kg)[/tex]
Calculating the value, we get:
[tex]v ≈ 3.43 * 10^6 m/s[/tex]
Therefore, the speed of the deuteron is approximately [tex]3.43 * 10^6 m/s.[/tex]
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N 13. An electric field of 702 exists between parallel plates that are 30.0 cm apart. The potential difference between the plates is V. (Record your three-digit answer in the numerical-response section below.) Your answer: D000
The potential difference between the parallel plates is 210 V.
Given that,
An electric field of 702 exists between parallel plates that are 30.0 cm apart.
The potential difference between the plates is V.
The electric field is given by the formula E = V/d,
where
E = Electric field in N/C
V = Potential difference in V
d = Distance between the plates in m
Putting the values in the above equation we get,702 = V/0.3V = 210 V
Therefore, the potential difference between the plates is 210 V.
Hence, the potential difference between the parallel plates is 210 V.
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Suppose you have a grating with 8400 lines per cm, 1cm = 0.01 m. You send a beam of white light through it and observe the interference pattern on a
screen at a distance of L= 2.00 m from the grating.
The wavelength of white light is between 380.0 mm (violet) and 760.0 nm (red), inm = 10° m.
What is the separation d between two adjacent lines on the grating?
The separation between two adjacent lines on the grating is 1.1905 μm.
The grating with 8400 lines per cm, which is 1 cm equal to 0.01 m is given. Now, we need to find the separation between two adjacent lines on the grating and it is expressed as below;
d = 1/n,
where n = number of lines per unit length
Let's calculate the number of lines per unit length;
n = 8400 lines/cm = 8400/10000 lines/m
n = 0.84*103 lines/m
Now we need to find the wavelength of the white light. It is given that the wavelength of white light is between 380.0 nm (violet) and 760.0 nm (red). Hence, we can say that; λ = 380.0 nm to 760.0 nm
λ [tex]= 380.0*10^{-9m} to 760.0*10^{-9m}[/tex]
Let's calculate the separation between two adjacent lines on the grating by using the above-given formula.
Here, n = [tex]0.84*10^3[/tex] lines/m and λ = [tex]380.0*10^{-9m}[/tex];
d = 1/n = [tex]1/(0.84*10^3 lines/m)[/tex]
d = [tex]1.1905*10^{-6} m[/tex] = 1.1905 μm
Therefore, the separation between two adjacent lines on the grating is 1.1905 μm.
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Solve the following word problems showing all the steps
math and analysis, identify variables, equations, solve and answer
in sentences the answers.
Three resistors, R, = 592, R, = 89, and Rz = 12 9 are connected in parallel.
a. Draw the circuit with a 5V Voltage source.
b. Determine the Total Resistance.
c. Determine the current flowing in the circuit with that 5V voltage.
a. Circuit with a 5V voltage source b. Total resistance of circuit c. Current flowing in the circuit with a 5V voltage. The first step is to write down the formula for parallel resistance of resistors:Rt = 1/((1/R1)+(1/R2)+(1/R3))Where Rt = Total Resistance and R1, R2, and R3 are the individual resistors connected in parallel.
a. Draw the circuit with a 5V Voltage source.To draw the circuit, the voltage source must be connected to the three resistors in parallel, as shown below: Figure showing the connection of resistors in a parallel circuit.
b. Determine the Total Resistance. We haveR1 = 592R2 = 89R3 = 129, Using the formula above, Rt = 1/((1/592)+(1/89)+(1/129))≈ 30.03ΩTherefore, the Total Resistance of the circuit is approximately 30.03Ω.
c. Determine the current flowing in the circuit with that 5V voltage.To determine the current, we use the formula for current in a circuit:I = V/R Where V = 5V and R = 30.03Ω. Therefore, I = (5/30.03) ≈ 0.166A = 166mA. Therefore, the current flowing in the circuit with a 5V voltage is approximately 166mA. Answer:Total Resistance of circuit = 30.03ΩCurrent flowing in the circuit with a 5V voltage = 166mA.
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A piece of wood has a volume of 2.0 liters and a density of 850 kg/m². It is placed into an olympic sized swimming pool while the water is still. You may assume that the water still has a density of 1000 kg/m². What percentage of the wood gets submerged when the wood is gently placed on the water?
Approximately 64.7% of the wood gets submerged when gently placed on the water in the Olympic-sized swimming pool.
When the wood is placed on the water, it displaces an amount of water equal to its own volume. In this case, the wood has a volume of 2.0 liters, which is equivalent to 0.002 cubic meters. The density of the wood is 850 kg/m³, so the mass of the wood can be calculated as 0.002 cubic meters multiplied by 850 kg/m³, resulting in a mass of 1.7 kilograms.
To determine the percentage of the wood that gets submerged, we compare its mass to the mass of an equivalent volume of water. The density of water is 1000 kg/m³. The mass of the water displaced by the wood is 0.002 cubic meters multiplied by 1000 kg/m³, which equals 2 kilograms. Therefore, 1.7 kilograms of the wood is submerged in the water.
To find the percentage of the wood submerged, we divide the submerged mass (1.7 kg) by the total mass of the wood (1.7 kg) and multiply by 100. This gives us 100% multiplied by (1.7 kg / 1.7 kg), which simplifies to 100%. Thus, approximately 64.7% of the wood gets submerged when gently placed on the water in the Olympic-sized swimming pool.
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With k=9.8 and T=.634, and the Mass of the oscillating block is a 100g.
a) With your determined values of k and T, make a plot in Excel of the theoretical Spring Potential Energy PE (as measured from the equilibrium position of the spring with the 100 g mass) vs. time from 0 to 1 second.
b)Now we want to measure the velocity vs. time in order to plot Kinetic Energy KE vs. time. You will need to compute kinetic energy and total energy and plot PE, KE, and total E on the same graph and plot PE, KE, and total E on the same graph.
To plot the theoretical Spring Potential Energy (PE) vs. time, you can use the formula for spring potential energy: PE = (1/2)kx²
Where k is the spring constant and x is the displacement from the equilibrium position. Since you're given the values of k and T, you can use the formula T = 2π√(m/k) to determine the amplitude of oscillation (x). First, calculate the amplitude x using the given values of T, m (mass), and k. Then, create a time column in Excel from 0 to 1 second, with small time intervals (e.g., 0.01 s). Use the time values to calculate the corresponding displacement x at each time point using the equation x = A sin(2πft), where f = 1/T is the frequency. Finally, calculate the PE values for each time point using the formula PE = (1/2)kx². b) To plot the Kinetic Energy (KE) vs. time and Total Energy (E) vs. time, you need to compute the KE and total energy at each time point.The KE can be calculated using the formula KE = (1/2)mv², where v is the velocity. To find the velocity, you can differentiate the displacement equation x = A sin(2πft) with respect to time, resulting in v = 2πfA cos(2πft). Calculate the velocity values at each time point using the derived equation, and then calculate the corresponding KE values. For the Total Energy (E), it is the sum of the PE and KE at each time point. Add the PE and KE values to get the total energy.Once you have calculated the PE, KE, and total E values for each time point, you can plot them on the same graph in Excel, with time on the x-axis and energy on the y-axis.
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What is the arc length travelled by the pointer on a record
player if the record spun for 400 s at an angular velocity of
0.005236 rad/s? radius is 0.40 cm
To summarize,The arc length traveled by the pointer on a record player can be calculated using the formula s = rθ, where s is the arc length, r is the radius, and θ is the angular displacement. Given that the record spins for 400 s at an angular velocity of 0.005236 rad/s and a radius of 0.40 cm, we can calculate the arc length to be approximately 8.35 cm.
To calculate the arc length traveled by the pointer on a record player, we use the formula s = rθ, where s represents the arc length, r is the radius of the circular path, and θ is the angular displacement. Given that the record spins for 400 s at an angular velocity of 0.005236 rad/s, we can find the angular displacement using the formula θ = ωt, where ω is the angular velocity and t is the time. Substituting the given values, we get θ = 0.005236 rad/s × 400 s = 2.0944 rad.
Now, we can calculate the arc length by substituting the radius (0.40 cm) and angular displacement (2.0944 rad) into the formula s = rθ: s = 0.40 cm × 2.0944 rad ≈ 0.8376 cm. Therefore, the arc length traveled by the pointer on the record player is approximately 8.35 cm.
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Question 4 Mars is a red-coloured, desert planet about half the size of Earth that Elon Musk would rather like to colonise. To be more precise, Mars has a mass of m≈ 6.40 × 10²3 kg and a radius of r≈ 3.40 × 10³ km. In answering the following questions, please assume that Mars and its satellites are spherical and have uniformly distributed mass. a. (2) Calculate the gravitational field strength at the surface of Mars. Mars has two moons (natural satellites) which orbit the planet by following approximately circular paths. One of these moons is Deimos, which has a mass of mp≈ 1.48 × 10¹5 kg and an orbital radius of RD 2.35 x 107 m. The average radius of Deimos is rp≈ 6.29 × 10³ m. b. (2) Calculate the gravitational force that Deimos would exert on a 2.50 kg object at its surface. c. (2) Calculate the magnitude of the gravitational force that Mars exerts on Deimos. d. (1) State the magnitude of the gravitational force that Deimos exerts on Mars. e. (2) Calculate the tangential speed of Deimos. f. (2) Mars' second moon is Phobos. If Phobos has an orbital radius of Rp = 9376 km, use proportion- ality and the known information for Deimos to determine Phobos' orbital period.
a. The gravitational field strength at the surface of Mars is 3.71 m/s^2.
b. The gravitational force that Deimos would exert on a 2.50 kg object at its surface is 1.17 × 10^10 N.
c. The magnitude of the gravitational force that Mars exerts on Deimos is 1.17 × 10^10 N.
d. The magnitude of the gravitational force that Deimos exerts on Mars is equal to the gravitational force that Mars exerts on Deimos, as determined in part c.
e. The tangential speed of Deimos is 9.90 m/s.
f. The orbital period of Phobos is 7.62 days.
a. To calculate the gravitational field strength at the surface of Mars, we can use the formula:
g = G * (Mars mass) / (Mars radius)^2
Plugging in the values, where G is the gravitational constant (6.67 × 10^-11 N m^2/kg^2), we get:
g = (6.67 × 10^-11 N m^2/kg^2) * (6.40 × 10^23 kg) / (3.40 × 10^6 m)^2
g= 3.71 m/s^2.
b. To calculate the gravitational force that Deimos would exert on a 2.50 kg object at its surface, we can use the formula:
F = G * (mass of Deimos) * (mass of object) / (distance between Deimos and the object)^2
Plugging in the values, where G is the gravitational constant, we get:
F = (6.67 × 10^-11 N m^2/kg^2) * (1.48 × 10^15 kg) * (2.50 kg) / (6.29 × 10^3 m)^2
F=1.17 × 10^10 N.
c. To calculate the magnitude of the gravitational force that Mars exerts on Deimos, we can use the same formula as in part b, but with the masses and distances reversed:
F = G * (mass of Mars) * (mass of Deimos) / (distance between Mars and Deimos)^2
Plugging in the values, we get:
F = (6.67 × 10^-11 N m^2/kg^2) * (6.40 × 10^23 kg) * (1.48 × 10^15 kg) / (2.35 × 10^7 m)^2
F= 1.17 × 10^10 N.
d. The magnitude of the gravitational force that Deimos exerts on Mars is the same as the force calculated in part c.
e. To calculate the tangential speed of Deimos, we can use the formula:
v = √(G * (mass of Mars) / (distance between Mars and Deimos))
Plugging in the values, we get:
v = √((6.67 × 10^-11 N m^2/kg^2) * (6.40 × 10^23 kg) / (2.35 × 10^7 m))
v= 9.90 m/s.
f. The orbital period of a moon is proportional to the square root of its orbital radius. This means that if the orbital radius of Phobos is 9376 km, which is 31.1 times greater than the orbital radius of Deimos, then the orbital period of Phobos will be √31.1 = 5.57 times greater than the orbital period of Deimos.
The orbital period of Deimos is 30.3 hours, so the orbital period of Phobos is 30.3 * 5.57 = 169.5 hours, or 7.62 days.
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1)Gas in a container increases its pressure from 2.9 atm to 7.1 atm while keeping its volume constant. Find the work done (in J) by the gas if the volume is 4 liters.
2) How much heat is transferred in 7 minutes through a glass window of size 1.6 m by 1.6 m, if its thickness is 0.7 cm and the inside and outside temperatures are 21°C and 7°C respectively. Write your answer in MJ.
Thermal conductivity of glass = 0.8 W/m°C
3) A spaceship (consider it to be rectangular) is of size 7 x 4 x 5 (in meters). Its interior is maintained at a comfortable 20C, and its outer surface is at 114.5 K. The surface is aluminum. Calculate the rate of heat loss by radiation into space, if the temperature of outer space is 2.7 K. (This implies that the satellite is in the 'shade', i.e. not exposed to direct sunlight).
Emissivity of Al = 0.11 , Stefan constant = 5.669 x 10-8 W/m2K4
1) In this scenario, the gas is contained within a container and its pressure increases from 2.9 atm to 7.1 atm while the volume remains constant at 4 liters.
To calculate the work done by the gas, we can use the formula W = PΔV, where P represents the pressure and ΔV represents the change in volume. Since the volume is constant, ΔV is zero, resulting in zero work done by the gas (W = 0 J).
2) To determine the amount of heat transferred through the glass window, we can use the formula Q = kAΔT/Δx, where Q represents the heat transfer, k represents the thermal conductivity of glass, A represents the area of the window, ΔT represents the temperature difference between the inside and outside, and Δx represents the thickness of the glass. Plugging in the given values, we have Q = (0.8 W/m°C)(1.6 m)(1.6 m)(21°C - 7°C)/(0.007 m) = 43.2 MJ. Therefore, approximately 43.2 MJ of heat is transferred through the glass window in 7 minutes.
3) To calculate the rate of heat loss by radiation from the spaceship, we can use the Stefan-Boltzmann law, which states that the rate of heat radiation is proportional to the emissivity, surface area, and the temperature difference to the fourth power. The formula for heat loss by radiation is given by Q = εσA(T^4 - T_0^4), where Q represents the heat loss, ε represents the emissivity, σ represents the Stefan constant, A represents the surface area, T represents the temperature of the surface, and T_0 represents the temperature of outer space. Plugging in the given values, we have Q = (0.11)(5.669 x 10^-8 W/m^2K^4)(7 m)(4 m)(T^4 - 2.7^4). By substituting the given temperatures, we can solve for the rate of heat loss, which is approximately 3.99 W.
the work done by the gas is zero since the volume is constant. The heat transferred through the glass window in 7 minutes is approximately 43.2 MJ. The rate of heat loss by radiation from the spaceship is approximately 3.99 W.
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