(a) The speed of the ice cube is given by v = √(gR)
(c) If R is made two times larger, the required speed will decrease by a factor of √2
(d) the time required for each revolution will remain constant.
(a) The speed of the ice cube can be found using the equation for centripetal acceleration: v = √(gR), where v is the speed, g is the acceleration due to gravity, and R is the radius of the circle.
(b) No piece of data is unnecessary for the solution.
(c) If R is made two times larger, the required speed will decrease by a factor of √2. This is because the speed is inversely proportional to the square root of the radius.
(d) The time required for each revolution will stay constant. The time period of revolution is determined by the speed and radius, and since the speed changes proportionally with the radius, the time remains constant.
(e) The answers to parts (c) and (d) are not contradictory. While the speed decreases with an increase in radius, the time required for each revolution remains constant. This is because the decrease in speed is compensated by the larger circumference of the circle, resulting in the same time taken to complete one revolution.
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The complete question is:
A basin surrounding a drain has the shape of a circular cone opening upward, having everywhere an angle of 35.0° with the horizontal. A 25.0-g ice cube is set sllding around the cone without friction in a horizontal circle of radlus R. (a) Find the speed the ice cube must have as a function of R. (b) Is any piece of data unnecessary for the solution? Select-Y c)Suppose R is made two times larger. Will the required speed increase, decrease, or stay constant? Selectv If it changes, by what factor (If it does not change, enter CONSTANT.) (d) Will the time required for each revolution increase, decrease, or stay constant? Select If it changes, by what factor? (If it does not change, enter CONSTANT.) (e) Do the answer to parts (c) and (d) seem contradictory? Explain.
you blow across the open mouth of an empty test tube and produce the fundamental standing wave in the 14.0-cmcm-long air column in the test tube, which acts as a stopped pipe. the speed of sound in air is 344 m/sm/s.
When you blow across the open mouth of an empty test tube, you create a standing wave in the 14.0 cm-long air column inside the tube. This column of air acts as a stopped pipe. The speed of sound in air is given as 344 m/s. the frequency of the fundamental standing wave in the test tube is 614.3 Hz.
To find the frequency of the fundamental standing wave in the test tube, we can use the formula:
frequency = speed of sound / wavelength
Since the test tube is acting as a stopped pipe, we know that the length of the air column is equal to a quarter of the wavelength of the fundamental standing wave.
So, the wavelength of the fundamental standing wave in the test tube is four times the length of the air column, which is 4 * 14.0 cm = 56.0 cm.
Now, we can substitute the values into the formula:
frequency = 344 m/s / 56.0 cm
Before we can continue, we need to convert the wavelength from centimeters to meters:
56.0 cm = 0.56 m
Now, we can substitute the values and solve for the frequency:
frequency = 344 m/s / 0.56 m = 614.3 Hz
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4.45 mol of an ideal gas is expanded from 431 k and an initial pressure of 4.20 bar to a final pressure of 1.90 bar, and cp,m=5r/2. calculate w for the following two cases:
In both cases, the work done by the gas is 15244.6 J.
To calculate the work done by the gas in the two cases, we need to use the ideal gas law and the equation for work done in an expansion.
The ideal gas law is given by:
PV = nRT
The equation for work done in an expansion is given by:
w = -ΔnRT
Let's calculate the work done in each case.
Case 1:
Initial pressure (P1) = 4.20 bar
Final pressure (P2) = 1.90 bar
Number of moles (n) = 4.45 mol
Temperature (T) = 431 K
To calculate the work done, we need to find the change in moles (Δn):
Δn = n2 - n1
Δn = 0 - 4.45
Δn = -4.45 mol
Substituting the values into the equation for work done:
w = -ΔnRT
w = -(-4.45)(8.314 J/(mol·K))(431 K)
w = 15244.6 J
Therefore, in case 1, the work done by the gas is 15244.6 J.
Case 2:
Initial pressure (P1) = 4.20 bar
Final pressure (P2) = 1.90 bar
Number of moles (n) = 4.45 mol
Temperature (T) = 431 K
To calculate the work done, we need to find the change in moles (Δn):
Δn = n2 - n1
Δn = 0 - 4.45
Δn = -4.45 mol
Substituting the values into the equation for work done:
w = -ΔnRT
w = -(-4.45)(8.314 J/(mol·K))(431 K)
w = 15244.6 J
Therefore, in case 2, the work done by the gas is also 15244.6 J.
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One can calculate work done during isobaric or reversible adiabatic expansion of an ideal gas using thermodynamics principles, the ideal gas law, given values for pressure, volume, and mole quantity, and the specific heat capacity at constant pressure.
Explanation:This problem is about thermodynamics and ideal gases. It can be solved by utilizing the first law of thermodynamics and the ideal gas law, along with the definition of isobaric, or constant pressure process.
The quantity w represents the work done by or on the system. In thermodynamics, work done by an expansion is generally considered to be negative. First, we need to convert our pressure to the same units as R (the ideal gas constant), which in this case is joules, so 1 bar = 100000 Pa.
The work done (w) during an isobaric process is given by w=-P(delta)V, where delta V is the volume change. Finding V1 is done using the ideal gas law equation PV=nRT. Because the process is isobaric, P, n, and R are all constant, simplifying the equation. Solving it, we then substitute back in the values we determined into the isobaric work equation.
The situation is more complex with cp,m=5r/2, which signifies a reversible adiabatic process. In this case, the work done by the system is described by a more complicated equation, which includes an integration over volume and requires knowledge of calculus.
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