Answer: tan(θ) = v²/(rg) where g is the acceleration due to gravity(g).
The equation for the tangent(T) of the angle of banking of a banked highway given that traffic is moving at velocity(v) = 8 km/h and the radius(r) of the curve r = 3/8 m is as follows: T of the angle of banking of the highway: tan(θ) = v²/ (rg) where g is the acceleration due to gravity
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Like a baseball bat, a tennis racket has a sweet spot at its center of percussion. If a tennis ball hits this center of percussion, the racket's handle does not accelerate. This is because
A) an impact at the center of percussion exerts no torque about the racket's centerof mass and doesn't cause the racket to undergo angular acceleration.
B) the racket's center of mass accelerates backward while its handle rotatesforward about its center of mass and the two motions cancel one another at the handle.
C) an impact at the center of percussion transfers no momentum to the racket anddoesn't cause the racket to accelerate.
D) the racket's velocity doesn't change when the ball hits its center of percussion
A tennis racket is just like a baseball bat, which has a sweet spot at its center of percussion. When a tennis ball strikes this spot, the racket handle doesn't accelerate. This is because an impact at the center of percussion exerts no torque around the racket's center of mass and does not cause the racket to undergo angular acceleration.
Similar to a baseball bat, a tennis racket has a center of percussion, and when the ball hits that spot, the racket handles do not accelerate. A force or torque applied to an object tends to accelerate the object in the direction of the force or torque. When a tennis ball is hit off-center with a racket, a torque or force is applied to the racket, and it tends to rotate about its center of mass.
As a result, the racket's handle will accelerate.Since the force applied to the tennis ball when it strikes the center of percussion is in line with the racket's center of mass, there is no torque acting on the racket. The racket does not undergo angular acceleration, which is why the handle does not accelerate.
Hence, option A, an impact at the center of percussion exerts no torque about the racket's center of mass and doesn't cause the racket to undergo angular acceleration, is the correct answer.
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A resistor develops 200 J of thermal energy in a time of 10.0s when a current of 1 A is passed through it. If the current is increased to 4 A, what will be the energy (in Joules) developed in 10 s.?
Answer:
[tex]3200\; {\rm J}[/tex].
Explanation:
The power [tex]P[/tex] (rate at which energy is consumed) of an electric circuit is equal to the product of voltage [tex]V[/tex] and current [tex]I[/tex]:
[tex]P = V\, I[/tex].
By Ohm's Law, the current in a resistor is proportional to the voltage in that resistor:
[tex]V = I\, R[/tex],
Where [tex]R[/tex] is the resistance of the resistor.
Substitute the expression for [tex]V[/tex] into the equation for power:
[tex]P = (I\, R)\, I = I^{2}\, R[/tex].
In other words, if resistance stays the same, the rate [tex]P[/tex] at which energy is consumed would be proportional to the square of current.
Hence, when current in this resistor is quadrupled, power consumed would increase to [tex]4^{2} = 16[/tex] times the initial value assuming that resistance stays the same. In the same amount of time, the resistor would now consume:
[tex]16\times 200\; {\rm J} = 3200\; {\rm J}[/tex].
For each problem, draw a diagram showing the relevant physics of the problem, including any vectors. All relevant quantities should be clearly labeled on the diagram. Start from first principles (an equation in the review section of the chapters). Always show your work and/or explain your reasoning. In some cases, the work speaks for itself and requires little to no explanation. For problems with few or no calculations, but sure to clearly explain your reasoning. Answers without work shown or without sufficient relevant explanations will not receive full credit. Be sure to include units. Problem 4 Copper has a work function of 4.70 eV, a resistivity of 1.7 x10 m, and a temperature coefficient of 3.9 x10³ °C -¹. Suppose you have a cylindrical wire of length 2.0 m and diameter 0.50 cm connected to a variable power source; and a separate thin, square plate of copper. (a) (5 points) Draw a clear physics diagram showing each part of the problem. (b) (6 points) At what temperature would the wire have 5 times the resistance that it has at 20 ºC? (c) (3 points) Use Wien's Law (Eq 14-24) to find the peak wavelength of radiation emitted by a wire of this temperature. (d) (6 points) If light at only the wavelength found above were shone onto the copper plate, what would be the maximum kinetic energy of the ejected photoelectrons?
(b) The temperature is 1656°C. (c) The peak wavelength is 1.75 × 10−6 m.
(d) The maximum kinetic energy of the ejected photoelectrons is 2.56 × 10−20 J.
b) Given: Resistivity of copper, p = 1.7 × 10−8 Ω m
Temperature coefficient of resistivity, α = 3.9 × 10−3/°C Work function, W = 4.7 eV Length of the cylindrical wire, l = 2.0 m Diameter of the wire, d = 0.50 cm Temperature, T1 = 20 °C Temperature, T2 = ?
The resistance of the wire at a given temperature T is given by R = pl/A, where A is the cross-sectional area of the wire. Thus, the resistance of the wire at 20°C can be calculated as follows: R1 = pl1/ A1
The resistance of the wire at a temperature T can be written as R2 = pl2/A2, where l2 = l and A2 = πd2/4.
To find the temperature at which the wire has five times the resistance it has at 20°C, we can use the equation R2 = 5R1.
R2 = pl2/ A2 = 5R1 = 5pl1/ A1l2/ A2 = (5/ p)(A1/A2)l1 = (5/ p)(πd2/4)l1/A1l2 = (5/ p)(πd2/4)l1/A1= (5/ p)(π(0.005 m)2/4) (2.0 m)/(π(0.00025 m2)/4)l2 = 0.0049 l1= 0.0049 × 2 = 0.0098 mT2 = T1 + ΔTR2 = pl2/A2 = p(l1 + αΔT)(A2/ A1) = pl1(πd2/4)/(πd12/4) = pld2/d12 = 4pld2πd12T2 = T1 + ΔT = T1 + (R2/R1 − 1)/α = 20 + [(5pl1/ A1)/pl1 − 1]/α= 20 + [5(π(0.005 m)2/4)(2.0 m)/(π(0.00025 m2)/4)/(π(0.005 m)2/4) − 1]/(3.9 × 10−3/°C)= 1656 °C
c) Wien’s law states that the wavelength λ of the peak of the blackbody radiation spectrum is inversely proportional to the absolute temperature T of the object.
Mathematically, this can be expressed as λmaxT = b, where b is a constant equal to 2.898 × 10−3 m·K.
Thus, the peak wavelength of radiation emitted by a wire of temperature T is given by λmax = b/T.
Substituting the value of T obtained above, we get λmax = 1.75 × 10−6 m.
d) The maximum kinetic energy of the ejected photoelectrons is given by KE = hf − W, where h is Planck’s constant (6.626 × 10−34 J·s) and f is the frequency of the light.
To find the frequency of the light, we can use the equation λf = c, where c is the speed of light.
Thus, f = c/λmax = 1.712 × 1014 Hz.
Substituting the given value of the work function W and the frequency of the light obtained above, we get KE = hf − W = (6.626 × 10−34 J·s)(1.712 × 1014 Hz) − (4.7 eV)(1.602 × 10−19 J/eV) = 1.01 × 10−19 J - 7.53 × 10−20 J = 2.56 × 10−20 J.
Answer:
(b) The temperature is 1656°C. (c) The peak wavelength is 1.75 × 10−6 m.
(d) The maximum kinetic energy of the ejected photoelectrons is 2.56 × 10−20 J.
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A 13.0 μF capacitor is charged by a 10.0V battery through a resistance R. The capacitor reaches a potential difference of 4.00 V at a time 3.00 s after charging begins. Find R 117.7 x Your response d
The formula to calculate the voltage across a capacitor is given by:
[tex]V = Vf (1 - e^(-t/RC))[/tex].
where, V = Voltage across capacitor
Vf = Final voltage across capacitor
R = Resistance
C = Capacitance of the capacitor
t = time In the given problem, the resistance, R is to be calculated.
Using the given values, we can rearrange the formula to solve for
[tex]R.R = -t/(Cln((V - Vf)/Vf))[/tex]
On substituting the values, we get,
[tex]R = -3.00 s/(13.0 μF ln((10.0 V - 4.00 V)/4.00 V))= 117.7 Ω[/tex]
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A large chunk of ice with mass 12.0 kg falls from a roof 5.32 m above the ground. Ignoring air resistance, what is the speed of the ice when it reaches the ground?
a. 12.5 mls
b. 12.1 mls
c. 10.8 mls
d. 7.67 m/s
we have ignored the air resistance, this is the exact velocity of the ice when it reaches the ground. Hence, the correct option is (b) 11.5 m/s.
Mass of the ice = 12.0 kg
Height of the fall, h = 5.32 m
The final velocity of the ice, v = ?
Let's use the formula for the velocity of an object falling under the influence of gravity,
v=√2gh
Here, g = acceleration due to gravity = 9.8 m/s²
We can substitute the given values in the above formula to find the velocity of the ice as:
v = √2 × 9.8 m/s² × 5.32 mv
= √(2 × 9.8 m/s² × 5.32 m)≈ 11.5 m/s
Resistance refers to the opposition that a substance or a medium offers to the flow of an electrical current. Resistance is measured in Ohms (Ω).
In physics, resistance is a measure of how much current is opposed by an object, material, or circuit component. Resistance, like its reciprocal, conductance, is a scalar quantity.
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The velocity v, in meters per second, is given as a function of time t, in seconds, by v(t) = -0.605t^2 + 2.11t - 8.15 What is the acceleration at time t = 3.47 s? Number ______ m/s^2
The acceleration at time t = 3.47 seconds is -2.077 m/s². Rounded to the nearest hundredth, this is -0.605 m/s².
The acceleration at time t = 3.47 seconds is -0.605 m/s². Given, the velocity v, in meters per second, is given as a function of time t, in seconds, by the equation:v(t) = -0.605t² + 2.11t - 8.15 The acceleration is the derivative of velocity.
Therefore, we can differentiate v(t) with respect to time t to obtain acceleration a(t).
Differentiating v(t) with respect to time t: a(t) = v'(t) = d/dt (-0.605t² + 2.11t - 8.15)
Now, the derivative of -0.605t² is -1.21t, the derivative of 2.11t is 2.11, and the derivative of -8.15 is zero.
Therefore, the acceleration a(t) is given by:a(t) = -1.21t + 2.11
The acceleration at time t = 3.47 seconds:a(3.47) = -1.21(3.47) + 2.11a(3.47) = -4.187 + 2.11a(3.47) = -2.077 m/s²
Therefore, the acceleration at time t = 3.47 seconds is -2.077 m/s². Rounded to the nearest hundredth, this is -0.605 m/s².
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Briefly explain the concepts of reference direction, reference
polarity, and passive reference configuration.
Reference DirectionIn electronic circuits, current is the flow of charge. Electrons flow from the negative end of a battery to the positive end, as we've seen. However, the directions of voltage and current are not the same. The voltage in a circuit, for example, might be supplied by a battery. The positive end of the battery is at a higher voltage than the negative end, according to the battery's polarity.
The reference direction in a circuit is the direction of current flow chosen to define the polarity of the voltage and is denoted by an arrow.Reference PolarityThe reference polarity of a circuit is the direction in which the current flows. The reference polarity, unlike the reference direction, can be reversed by flipping the direction of current flow. For example, if we switch the positive and negative connections on the battery,
the reference polarity of the circuit is reversed. The voltage and current in the circuit are still present, but their polarities are reversed.Passive Reference ConfigurationA passive reference configuration is a system in which there is no net gain of energy or power, but in which an input signal causes a response. In this configuration, a sensor, such as a thermocouple, generates a voltage in response to an external stimulus, such as temperature. The voltage produced is in direct proportion to the temperature, and the sensor's output is measured with an instrument such as a voltmeter or oscilloscope.The passive reference configuration is utilized in all kinds of electronic circuits, from thermometers and thermostats to electronic filter design and control systems.
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A box moves 10\,\tex 10 m horizontally when force F=20\,\text N F = 20 N is applied at an angle \theta=30\degree . What is the work done on the box by FF during the displacement? 173 J 0-173 J 200 J -200 J
When a force of 20 N is applied at an angle of 30 degree to a box and it moves 10 m horizontally, the work done on the box by F during the displacement is 173 J. Work is defined as the energy transferred when a force is applied to an object and causes it to move in the direction of the force.
The formula to calculate work done is: W = F * d * cosθ where, W is work done F is the force applied d is the distance over which the force is appliedθ is the angle between the force and the displacement of the object W = 20 * 10 * cos30°= 173 J
The work done on the box by F during the displacement is 173 J.
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Consider the motion of an object modeled with ideal projectile motion (neglecting air resistance). The trajectory of the object can be derived from basic physics and is given by the formula: \( y=x \t
The formula for the trajectory of an object modeled with ideal projectile motion is y = xtanθ – (gx²) / 2v²cos²θ.
Projectile motion is a type of motion experienced by objects that are launched into the air and are subject to gravity and air resistance. In ideal projectile motion, the air resistance is neglected, and only the force of gravity is considered. The trajectory of the object is given by the formula:
y = xtanθ – (gx²) / 2v²cos²θ where y is the height of the object, x is the horizontal distance traveled by the object, θ is the angle of projection, v is the initial velocity of the object, and g is the acceleration due to gravity. When the object is launched at an angle of 45 degrees, the horizontal distance traveled by the object is equal to the vertical distance traveled by the object. Therefore, the maximum range of the projectile is achieved at an angle of 45 degrees.
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1. When the phase emf waveform of an ac machine is improved by using distributed or short-pitch windings, is the emf waveform of each conductor in the coils also improved? 2. How should we connect the coil groups corresponding to different poles in series for 3-phase double-layer windings? And explain the reason.
1. Yes, when the phase emf waveform of an ac machine is improved by using distributed or short-pitch windings, the emf waveform of each conductor in the coils is also improved.
2. And explain the reason. In order to connect the coil groups corresponding to different poles in series for 3-phase double-layer windings, we need to consider the following things: Series connection of the coil groups can be done in two ways: one is simplex and the other is multiplex.
In the simplex lap winding, two groups of coils (one group for each phase) are connected in series per pole. As a result, the number of paths is equal to the number of poles.In the multiplex lap winding, the coils are connected in series to form multiple paths. A multiplex lap winding with q paths has q/2 coil groups per phase.
The reason for connecting the coil groups corresponding to different poles in series for 3-phase double-layer windings is to generate a rotating magnetic field. The rotating magnetic field is created because each phase of the winding is offset by 120 electrical degrees with respect to each other. This causes the magnetic field produced by one phase to interact with the other two phases, creating a rotating magnetic field.
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Suppose a planet in our solar system has an orbital period of 7
years. What would be its average distance from the sun (length of
its semimajor axis)?
Suppose a planet in our solar system has an orbital period of 7 years, iits average distance from the sun (length of
its semimajor axis) would approximately 3.03 astronomical units.
If a planet has an orbital period of 7 years, the length of its semimajor axis can be determined using Kepler's third law. Kepler's third law states that the square of the orbital period is proportional to the cube of the average distance between the planet and the sun. This can be expressed as T^2 ∝ a^3, where T is the orbital period and a is the average distance from the sun. Solving for a, we get a = (T^2 * k)^(1/3), where k is a constant.
Using the value of T as 7 years, we can find the length of the semimajor axis. Plugging in the values, we get a = (7^2 * k)^(1/3).
To determine the value of k, we can use the fact that the semimajor axis of Earth's orbit is approximately 1 astronomical unit (AU).
This means that (1^2 * k)^(1/3) = 1 AU, or k = 1 AU^3. Substituting this value of k, we get a = (7^2 * 1 AU^3)^(1/3) = 3.03 AU.
Therefore, the average distance of the planet from the sun is approximately 3.03 astronomical units.
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Which of the following is NOT a disadvantage of Wind Energy? Wind turbines are very tall and each takes a small plot of land. The force of the high blades is capable of harming wildlife. They are noisy. Large wind farms are needed to provide entire communities with enough electricity
The disadvantage of wind energy is that wind turbines can be noisy and the force of high blades can harm wildlife.
The disadvantages of wind energy include potential noise pollution caused by wind turbines and the risk of harm to wildlife due to the force of high blades. However, it is important to note that wind turbines being tall and occupying small plots of land are not considered disadvantages but rather requirements for efficient wind energy generation.
Additionally, large wind farms are needed to generate enough electricity to meet the demands of entire communities, which can present challenges in terms of land availability and infrastructure. Despite these drawbacks, wind energy remains a valuable and sustainable source of renewable energy, contributing to reducing greenhouse gas emissions and mitigating climate change.
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Biological fluid mechanics, please answer all questions or at
least as much as possible
(a) The governing principles in fluid mechanics are described analyticaly by the conservation laws for mass, momentum, and energy. These can be stated either in integral form when applied to an extend
Biological fluid mechanics is a rapidly growing field of study that uses the principles of fluid mechanics to understand the behavior of fluids in biological systems. This includes the study of blood flow, mucus transport, and the swimming of microorganisms.
The field is essential for understanding the functioning of many biological systems and has led to new insights into the behavior of living organisms.
Biological fluid mechanics is a multidisciplinary field that draws on the expertise of engineers, physicists, biologists, and mathematicians.
As the field continues to develop, we can expect to see new applications in fields such as medicine, environmental science, and robotics.
Here are some of the specific applications of biological fluid mechanics:
Medicine: Biofluid mechanics can be used to design new medical devices, such as artificial heart valves and catheters.
Environmental science: Biofluid mechanics can be used to understand the transport of pollutants in water and air.
Robotics: Biofluid mechanics can be used to design robots that can swim or fly like animals.
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A 500 N cube of density rho = 1800 kg/m3 falls through water at a
constant speed
U. Determine U if the cube falls with an orientation to minimize
the drag force. Hint: don’t
forget buoyancy.
Determine U if the cube falls with an orientation to minimize the drag force, we need to use buoyancy. The formula for the buoyant force is given by Fb = ρVg.
V is the volume of the object displaced by the water, ρ is the density of the liquid (water), and g is the acceleration due to gravity. We can use this formula to find the weight of the cube in water.
Let W be the weight of the cube in air, then the weight of the cube in water is given by W - Fb. The buoyant force Fb is given by
Fb = ρVg
= (1800 kg/m³)(0.125 m³)(9.81 m/s²)
= 2212.5 N.
The weight of the cube in air is given by
W = mg
= (500 N)/(9.81 m/s²)
= 50.91 kg.
The weight of the cube in water is given by W - Fb = 50.91 kg - 2212.5 N = -2161.59 N.
We can set these two forces equal to each other and solve for U:
FD = W - Fb(1/2)ρCU²A
= W - FbU
= sqrt((2(W - Fb))/(ρCA))
Plugging in the values, we get
U = sqrt((2((50.91 kg)(9.81 m/s²) - 2212.5 N))/(1000 kg/m³)(0.25 m²)(0.8))
≈ 1.44 m/s.
The cube falls at a constant speed of 1.44 m/s when oriented to minimize the drag force.
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For a tidal range at a particular place with 2 tides daily of 10 m, and the surface tidal energy harnessing plant of 9 km², if the specific gravity of water is 1025.18 kg/m³, determine the total energy potential per day of the plant. [8]
The total energy potential per day of the plant is 4.4 * 10¹³ J i.e.
440 quadrillion joules of energy per day.
The total energy potential per day of the plant can be calculated using the following formula:
Total energy potential = (2 * tidal range * surface area * specific gravity * acceleration due to gravity) / 2
where:
tidal range is the difference between the high tide and low tide, in meters
surface area is the area of the tidal energy harnessing plant, in square meters
specific gravity of water is the ratio of the density of water to the density of air, in kg/m³
acceleration due to gravity is the acceleration caused by the Earth's gravity, in m/s²
In this case, we have:
tidal range = 10 m
surface area = 9 km² = 9 * 10⁶ m²
specific gravity of water = 1025.18 kg/m³
acceleration due to gravity = 9.81 m/s²
Substituting these values into the formula, we get:
Total energy potential = (2 * 10 m * 9 * 10⁶ m²* 1025.18 kg/m³*9.81 m/s²)/ 2 Total energy potential = 4.4 * 10¹³ J
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Pls. Solve them both pls pls
(2) Write the matrix state equation for the circuit shown below.
Exercise (1) Write the matrix state-variable equation for the above circuit.
(1) For the given circuit shown below, the matrix state-variable equation is given as:[tex]X = [ V1, V2, iL ]'Q = [ Vi, iL ]'[/tex]where ' denotes transpose of matrix.Now, to get the state-variable equation, we have to apply KVL to the loops of the circuit. Applying KVL to the given circuit,
we get the following equations:Loop 1: Vi - V1 - L * diL/dt - R1 * iL = 0Loop 2: V1 - V2 - R2 * iL = 0Differentiating both the above equations with respect to time, we get:Loop 1: dVi/dt - dV1/dt - L * d²iL/dt² - R1 * diL/dt = 0Loop 2: dV1/dt - dV2/dt - R2 * diL/dt = 0Now, using matrices, the above equations can be represented as:For loop 1: [ dV1/dt, diL/dt, dVi/dt ] = [ R1/L, -1/L, -1/L ] * [ V1, iL, Vi ]For loop
we have to first identify the state variables and write their first and second derivatives. The state variables are:iC, charge stored on the capacitorV2, voltage across the capacitorDifferentiating the above state variables with respect to time, we get:diC/dt = iL - C * dV2/dt... (1)dV2/dt = 1/C * iC... (2)Now, to write the matrix state equation, we can represent equation (1) and (2) in matrix form as:dX/dt = [ -1/RC, -1/R;1/C, 0 ] * X + [ 1, 0 ] * VwhereX = [ iC, V2 ]'V = [ V1 ]'Rearranging the above equation, we get:dX/dt = AX + BUwhere[tex]X = [ iC, V2 ]'U = [ V1 ]'Y = [ V2 ]'A = [ -1/RC, -1/R;1/C, 0 ]B = [ 1, 0 ]C = [ 0, 1 ]D = [ 0 ][/tex]Therefore, the matrix state equation for the given circuit is:dX/dt = [ -2, -1;-2, 0 ] * X + [ 1 ] * V1U = [ 0, 1 ] * X + [ 0 ]
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Solve the formula for one variable.
Solve for F: C=5/9(F-32); If C= 25°C
Solve for E IF P=; IF M=4KG AND P =100KGM/S
Solve for L IF T=2 AND IF G=9.8 M/S^2 AND T=2 S
Solve for K: IF T=2PI AND IF M=3.0KG AND T +9.0S
Solve for y2: 1/2MV2/1+MGY1=1/2MV2/2+MGY2
(PLEASE ANWSER THEM ALL, THANK YOU SO MUCH)
The formula for one variable F is 77°C, E = 25 kg/ms², L = 19.6 m,
The solution for each of the given problems is shown below:
Solve for F: C = 5/9(F-32); If C= 25°C
We have C = 5/9(F-32); If C= 25°C
Now, we can substitute C with the given value of 25°C.
therefore: 25 = 5/9(F - 32)
Now, we can solve for F.
Therefore: F - 32 = (9/5) × 25F - 32 = 45F = 45 + 32F = 77°C.
So, the answer is F = 77°C.
Solve for E IF P=; IF M=4KG AND P =100KG/MS
The formula is given as P = M × E
Therefore: E = P/M
Substituting the values: E = 100/4E = 25 kg/ms²
So, the answer is E = 25 kg/ms².
Solve for L IF T=2 AND IF G=9.8 M/S² AND T=2S
The formula is given as L = 1/2GT²
Substituting the values: L = 1/2(9.8)(2²)L = 1/2(9.8)(4)L = 19.6 m
So, the answer is L = 19.6 m.
Solve for K:
IF T=2PI AND IF
M=3.0KG AND T +9.0S
The formula is given as K = 2π/T × (Mg + F)
Given, T = 2π, M = 3 kg, and T + 9 s
We have to find F.
Substituting the given values:
T = 2π = 6.28 s
M = 3 kg
F = K × T/(2π) - MgF = K × 6.28/(2π) - 3 × 9.8F = K × 2 - 29.4
Therefore, the answer is F = (K × 2) - 29.4
Solve for y2: 1/2MV²/1+MGY₁=1/2MV²/2+MGY₂
We have to solve for y2.
So, we need to use the given formula and isolate y2.
Therefore: 1/2MV²/1+MGY₁=1/2MV²/2+MGY₂
Multiplying both sides by
(2 + MGY₂): 1/2MV²(2 + MGY₂)/(1+MGY₁) = 1/2MV²
Dividing both sides by 1/2MV²: (2 + MGY₂)/(1+MGY₁) = 1
Now, cross-multiply to get rid of the denominators:
2 + MGY₂ = 1 + MGY₁MGY₂ - MGY₁ = 1 - 2MY₂(G - Y₁) = (1/2V²)Y₂ = (1/2V²)(G - Y₁)
Therefore, the answer is Y₂ = (1/2V²)(G - Y₁).
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Excited H atoms give off radiation in the infrared region known by the balman series. It results when electrons fall from higher energy levels to n=5. Calculate the energy and the frequency of the lowest energy line in the series.
ν = ΔE / h
Now, substitute the appropriate values and calculate the result.
To calculate the energy and frequency of the lowest energy line in the Balmer series for hydrogen atoms transitioning from higher energy levels to n=5, we can use the Rydberg formula:
1/λ = [tex]R_H[/tex] * (1/n₁² - 1/n₂²)
where λ is the wavelength of the emitted light, R_H is the Rydberg constant for hydrogen (approximately 1.097 × [tex]10^7 m^{-1}[/tex]), n₁ is the initial energy level, and n₂ is the final energy level.
In this case, we have n₁ = higher energy level and n₂ = 5.
First, we need to determine the energy difference between the initial energy level and n=5. The energy difference (ΔE) can be calculated using the formula:
ΔE =[tex]E_{initial} - E_{final}[/tex]
= -13.6 eV / n₁² - (-13.6 eV / 5²)
Next, we convert the energy difference to joules:
ΔE (in joules) = ΔE (in eV) * 1.6 × [tex]10^{-19 }[/tex]J/eV
Finally, we can calculate the frequency (ν) using the equation:
ν = ΔE / h
where h is the Planck's constant (approximately 6.63 ×[tex]10^{-34 }[/tex]J·s).
Let's calculate the values:
ΔE = (-13.6 eV / n₁²) - (-13.6 eV / 5²)
= (-13.6 eV / n₁²) - (-13.6 eV / 25)
ΔE (in joules) = ΔE (in eV) * 1.6 × [tex]10^{-19}[/tex] J/eV
ν = ΔE / h
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How does the time of fall relate to the weight (mg) of the coffee filters? What happens to the time of fall if you double the mass of falling filters? Explain
The time of fall of an object is not directly related to its weight (mg), but rather to the acceleration due to gravity (g) and the distance it falls.
In the case of coffee filters, assuming they have a similar shape and size, the weight (mg) will be proportional to the mass (m) of the filters.
Doubling the mass of the falling filters will not have a direct effect on the time of fall if we assume that air resistance is negligible. According to the equation for the time of fall, which is derived from the
kinematic equations:
Time = √((2 * distance) / g)
The mass of the falling object does not appear in this equation. Therefore, doubling the mass will not change the time of fall if other factors such as distance and acceleration due to gravity remain constant.
However, in real-world scenarios, where air resistance is present, the time of fall can be affected by the mass of the falling filters. Increased mass can lead to increased air resistance, which can slow down the filters and increase the time of fall. This effect becomes more significant as the mass and size of the falling object increase.
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If the needle on the pressure gauge is fluctuating, read and record the valve located:
Select one:
a. at the lowest extreme.
b. where the needle appears to stay the longest.
c. in the center between the high and low extremes.
d. at the highest extreme.
A fluctuating needle could indicate a variety of issues, including mechanical or electrical problems with the gauge, an issue with the system being measured, or environmental variables affecting the measurement. When a needle is fluctuating, it can be difficult to determine the correct reading. If the needle on the pressure gauge(GP) is fluctuating, read and record the valve located in the center between the high and low extremes.
What is the pressure gauge?A pressure gauge is a device that determines and measures the pressure(P) of a gas or liquid in a closed container. A pressure gauge measures pressure by means of a bourdon tube(BT), which is a mechanical system. When pressure is put on it, it deforms. This deformation is calculated by a system of gears and springs and displayed on a dial.
What are the types of gauges?The following are some of the most common types of pressure gauges: Manometer(Mr) is a kind of pressure gauge that works by comparing the pressure of a liquid in a U-shaped tube to the pressure of the gas being measured, which compresses the liquid. Piezometer(Pr) is a form of pressure gauge that works by measuring the weight of the liquid in a container, which is proportional to the pressure being measured. Bourdon Tube: The most common type of pressure gauge is the bourdon tube. It works by comparing the pressure of a gas or liquid in a chamber to a spring inside a tube. Wheel Gauge is a kind of pressure gauge that works by converting pressure into a rotary motion. This rotary motion is measured by a series of gears, which then display the pressure.
What is a fluctuating needle?
A fluctuating needle(FN) is a needle that is not steady on a gauge or instrument.
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Sisyphus is doomed to push a wooden crate up a ramp for all eternity. Sisyphus has a mass of 80.0 kg. If he exerts 450 N on the crate parallel to the ramp, which makes an angle of 35.0° with the horizontal, then find the total work he does in pushing it 830 m. Make sure to include the work he does on the crate and his body to get up the ramp.
If he exerts 450 N on the crate parallel to the ramp, which makes an angle of 35.0° with the horizontal, then 630,406 J is the total work he does in pushing it 830 m.
The amount of energy that is transmitted to or from an item is measured as work in physics. It is described as being the result of the force applied to an object and the length of time it is applied. Due to the fact that work is a scalar quantity, it has simply magnitude and no direction. Depending on the force's direction and the object's displacement, work might be positive or negative. In the SI system of units, joules (J) are used to represent work.
work = force x distance x cos(θ)
work{crate}= 450 N x 830 m x cos(35.0°)
work{crate} = 310,335 J
work = force x distance x sin(θ)
work{body} = (80.0 kg x 9.81 m/s^2) x (830 m x sin(35.0°))
work{body} = 320,071 J
work{total}= work_crate + work_body
work{total} = 310,335 J + 320,071 J
work{total} = 630,406 J
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13. 5. You are watching a bat fly out from the bottom of a well. The bat flies in a helical path so that its position vector is given by
r
=5cos(
3
2π
t)
^
+5sin(
3
2π
t)
^
+4t
k
^
. The origin x=0,y=0,z=0 is fixed at the center of the well, and the z-axis is directed upward from the bottom of the well. Note that t=0 when the bat is at the bottom of the well. The well is of depth 20 m. How long does it take before the bat exits the well? Please give your answer in s. 3.12
It takes 5 seconds for the bat to come out of the well.
Given the position vector of a bat as r = 5cos(3/2πt)i + 5sin(3/2πt)j + 4tk, we have to calculate the time taken by the bat to come out of the well. The depth of the well is given to be 20 m. So, let's start with the solution.
The position vector of the bat is given by r = 5cos(3/2πt)i + 5sin(3/2πt)j + 4tk.
In this equation, the position vector of the bat r is the sum of three vectors: r = r_1 + r_2 + r_3, where r_1 = 5cos(3/2πt)i, r_2 = 5sin(3/2πt)j and r_3 = 4tk.
The bat is coming out of the well so we have to calculate the time it takes for the bat to come out of the well. For this, we will set the value of z equal to 20.
The position vector of the bat at the mouth of the well is: r = 5cos(3/2πt)i + 5sin(3/2πt)j + 20k
We need to solve this equation for t, which will give us the time taken by the bat to come out of the well.
Equating z-coordinate to 20: 20 = 4t⇒ t = 5 seconds
Therefore, it takes 5 seconds for the bat to come out of the well.
Therefore, the correct option is (d) 5 seconds.
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You're working for the summer with an ornithologist who knows you've studied physics. She asks you for a noninvasive way to measure birds' masses. You propose using a bird feeder in the shape of a 47-cm- diameter disk of mass 388 g, suspended by a wire with torsional constant 5.4 N.m/rad. Two birds land on opposite sides and the feeder goes into torsional oscillation at 2.3 Hz. Assuming the birds have the same mass, calculate the mass of a single bird. Please report your mass in grams to 1 decimal place.
To find the mass of a single bird, we will use the torsional constant formula: The mass of a single bird is approximately 8.2 grams. The torsional constant formula is τ = κθ = Iαω, where:τ is torque, κ is the torsional constant,
θ is the angle of twist,
I is the moment of inertia,
α is the angular acceleration, and
ω is the angular velocity.
The formula can be written as:
κ = I (2π/T)^2.
Let's solve for the mass of the bird using the given formula:
κ = torsional constant = 5.4 N·m/rad
ω = angular velocity = 2π × f = 2 × 3.14 × 2.3 Hz = 14.44 rad/s
Diameter of feeder, d = 47 cm = 0.47 m
Mass of feeder, m = 388 g = 0.388 kg
The moment of inertia of the feeder is given by:
I = (1/2)mr²,
where r is the radius of the feeder.
r = d/2 = 0.47/2 = 0.235 m
I = (1/2)(0.388 kg)(0.235 m)²
I = 0.004 kg·m²
The mass of the bird can be calculated as:
Mass of bird = (κ/ω²I) - m
Mass of bird = ((5.4 N·m/rad)/(14.44 rad/s)²(0.004 kg·m²)) - 0.388 kg
Mass of bird = 0.0082 kg = 8.2 g
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Throttling range = 5 v DC, Kp = 2kW/ V DC
Write the equation relating heater output to sensed temperature for the controller of the answer above in the thermostat output voltage decreases linearly with temperature between 90F (32C) and 60F (16C) for the nominal thermostat set-point of 75F (24C)
Ans: Q = 1/3 (kW/F) (75 - Tsensed) + 5 kW
Q= = 1/3 kW/°C × (75°C - Tsensed) + 5 kW. The output power equation can be obtained by using the following expression: Q = Kp (Vset - Vt) Where, Q = Output power, Kp = Proportional gain, Vset = Set-point temperature in volts, Vt = Sensed temperature in volts
Thermostat output voltage decreases linearly with temperature between 90F (32C) and 60F (16C) for the nominal thermostat set-point of 75F (24C)To convert F to C, use the following expression: T(°C) = (T(°F) - 32) × 5/9, Temperature range can be converted as follows: 90°F = 32.2°C, 60°F = 15.6°C, 75°F = 23.9°C
Then, the voltage range can be calculated as follows:
V90 = 5 - (32.2 - 60) × (5/30)
= 3.14 V
V60 = 5 - (15.6 - 60) × (5/30)
= 4.16 V
For any sensed voltage, Vt = (5/30) × (Tsensed - 60) + 4.16 V
Plugging this into the output power equation and simplifying it, Q = Kp (Vset - [(5/30) × (Tsensed - 60) + 4.16 V])
Q = Kp (Vset - (5/30) × (Tsensed - 60) - 4.16 V)Q
= 2 kW/V DC × (5 V DC - (5/30) × (Tsensed - 60°C) - 4.16 V)Q
= 1/3 kW/°C × (75°C - Tsensed) + 5 kW
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Two point charges are located on the -axis of a coordinate system: q1 = 1.0 nC is at x = +2.0 cm, and q2 is at x = +4.0 cm. What is the total electric force exerted by q1 and q2 on a charge q3 = 5.0 nC at x = 0?
what is
F1-3
F2on3
F3
HELP ASAP
Two point charges are located on the x-axis of a coordinate system: ql = -15.0 nC is at x = 2.0 m, q2 = +20.0 nC is at x = 6.0 m, and q3 = 5.0 nC at x = 0. What is the net force experienced by q3? ?
reqd
F1on3
F2on3
F3
Given data;Charge of ql = -15.0 nC,Charge of q2 = +20.0 nCCharge of q3 = 5.0 nCDistance of ql from q3 = 2.0 mDistance of q2 from q3 = 6.0 m Distance of q3 from the axis = 0Net force experienced by q3 is calculated using Coulomb's law and vector addition principles.
Coulomb's law for electric force F on q3 between ql and
[tex]q3F1on3 = (1/4πε₀) (qlq3/r13²)[/tex]
where, r13 = 2 m (distance of ql from q3)
ε₀ is a constant having the value [tex]8.854 x 10^-12 C²/Nm²[/tex]
Putting the values, we get;
F1on3 = ([tex]1/4πε₀) (qlq3/r13²)[/tex]
=[tex](1/4πε₀) (-15.0 × 10^-9 C × 5.0 × 10^-9 C / 2.0²)[/tex]
= - 100.6 N
(force experienced by q3 due to ql)Coulomb's law for electric force F on q3 between q2 and q3F2on3 = [tex](1/4πε₀) (q2q3/r23²)[/tex]
where, r23 = 6 m (distance of q2 from q3)ε₀ is a constant having the value [tex]8.854 x 10^-12 C²/Nm²[/tex]
Putting the values, we get;
[tex]F2on3 = (1/4πε₀) (q2q3/r23²)[/tex]
=[tex](1/4πε₀) (+20.0 × 10^-9 C × 5.0 × 10^-9 C / 6.0²)[/tex]
= + 6.24 N (force experienced by q3 due to q2)The net force on q3 is;
F3 = F1on3 + F2on3
= - 100.6 N + 6.24 N
= - 94.36 N
The net force experienced by q3 is 94.36 N and it is directed towards ql.
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A person exposed to fast neutrons receives a radiation dose of 300 rem on part of his hand, affecting 25 g of tissue. The RBE of these neutrons is 10. How many rad did he receive?
Given that a person exposed to fast neutrons receives a radiation dose of 300 rem on part of his hand, affecting 25 g of tissue and the RBE of these neutrons is 10. We need to find the number of rads he received.
RBE stands for relative biological effectiveness, which is a comparative expression of the ability of radiation to produce a biological reaction. RBE is used as a multiplying factor to calculate the equivalent dose, measured in Sieverts (Sv), that would be produced by an equal amount of absorbed dose by a type of radiation other than X-rays or gamma rays.
When dealing with other forms of ionizing radiation, the concept of RBE is essential to calculate equivalent doses. In this case, the individual was exposed to fast neutrons, which have an RBE of 10. Therefore the equivalent dose is calculated as:
Dose equivalent (rem) = Absorbed dose (rad) x Quality Factor
Since RBE is a quality factor for neutron radiation, the equivalent dose can be determined as:
E = 300 rem (dose equivalent) = 25g tissue (absorbed dose) x 10 (RBE)
Therefore, the absorbed dose in rads can be calculated by using the formula;
Dose equivalent (rem) = Absorbed dose (rad) x Quality Factor
From this formula, we can rearrange and find the absorbed dose as follows;
Absorbed dose (rad) = Dose equivalent (rem) / Quality Factor
Given that the individual received a radiation dose of 300 rem, the absorbed dose can be calculated as:
Absorbed dose (rad) = 300 rem / 10 = 30 rad
Hence, the individual received 30 rad. Therefore, the correct option is D.
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A 200 g piece of ice at 0.00 °C is placed in 200 g of liquid water at 100 °C. When the system reaches equilibrium, the temperature is 10 °C. Find the change in entropy of the universe during this process.
The change in entropy of the universe during this process is -729.2 JK⁻¹. Total entropy change of the universe is calculated as ΔSuniverse = ΔSsurroundings + ΔSsystem
Given data; Mass of ice, m₁ = 200 g, Mass of liquid water, m₂ = 200 g, Temperature of ice, T₁ = 0 °C, Temperature of liquid water, T₂ = 100 °C, Temperature at equilibrium, T = 10 °C, The specific heat capacity of ice, cs₁ = 2.09 J/(gK)
The specific heat capacity of water, cs₂ = 4.18 J/(gK)
The latent heat of fusion of water, L = 333 J/g
The change in entropy of the universe during this process is; To find the change in entropy of the universe, we need to find the entropy change of the surroundings and the entropy change of the system. If we sum up the entropy change of the system and the surroundings, we will get the entropy change of the universe, i.e.
ΔSuniverse = ΔSsurroundings + ΔSsystem
Entropy change of the surroundings;
The water at 100 °C will lose heat to the surroundings until it reaches 10 °C. This will be an irreversible process, as it cannot be done without losing some energy as heat to the surroundings. The heat lost by the hot water, Q₂ = m₂ cs₂ (T₂ - T)
= 200 x 4.18 x (100 - 10)
= 75324 J
The heat gained by the surroundings, Qsurroundings = -Q₂
= -75324 J
As the process is irreversible, the entropy change of the surroundings can be calculated as; ΔSsurroundings = Qsurroundings/Tsurroundings = -75324/293
= -257.03 JK-1
Entropy change of the system;
The heat gained by the ice, Q₁= m₁L + m₁cs₁(T - T₁)
= 200 x 333 + 200 x 2.09 x (10 - 0)
= 133460 J
The system will lose heat to the surroundings until it reaches equilibrium, which is an irreversible process. The entropy change of the system can be calculated as;
ΔSsystem = -ΔQsystem/T
= -133460/283
= -472.17 JK⁻¹
Total entropy change of the universe;ΔSuniverse = ΔSsurroundings + ΔSsystem
= -257.03 + (-472.17)
= -729.2 JK⁻¹
Therefore, the change in entropy of the universe during this process is -729.2 JK⁻¹.
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A uniform wave traveling in a medium with Er1=4 is normally incident upon a second medium with Er2=2.25. both media are non magnetic and non conductive the electric field of the incident wave is Ei(z,t)=x10cos(2pi x 10^10t-kz) (V/m)
A) find the phase velocities in the two media, respectively
B) find the wavelengths in the two media
C) find the reflection and transmission coefficients and the standing wave ratio (S)
a) The phase velocity is 2c / 3
b) The wavelengths of the two media are λ₁ = λ₀ / 2 and λ₂ = λ(2/3) λ₀
c) The reflection and transmission coefficients are -1/7 and 4/7 respectively with standing wave ratio S = 1/4.
Given data:
A)
The phase velocity of a wave in a medium is given by v = c / √(εr), where c is the speed of light in vacuum and εr is the relative permittivity of the medium.
For the first medium with εr₁ = 4, the phase velocity is v₁ = c / √(εr₁) = c / √(4) = c / 2.
For the second medium with εr₂ = 2.25, the phase velocity is v₂ = c / √(εr₂) = c / √(2.25) = c / 1.5 = 2c / 3.
B)
The wavelength of a wave in a medium is given by λ = v / f, where λ is the wavelength, v is the phase velocity, and f is the frequency of the wave.
In the first medium:
λ₁ = v₁ / f = (c / 2) / 10¹⁰ = c / (2 x 10¹⁰) = λ₀ / 2, where λ₀ is the wavelength in vacuum.
In the second medium:
λ₂ = v₂ / f = (2c / 3) / 10¹⁰ = (2/3) (c / 10¹⁰) = (2/3) λ₀.
C)
The reflection coefficient (R) and transmission coefficient (T) can be calculated using the formulas:
R = (Z₂ - Z₁) / (Z₂ + Z₁),
T = 2Z₂ / (Z₂ + Z₁),
S = |R / T|,
where Z₁ and Z₂ are the characteristic impedances of the two media, respectively.
Since both media are non-magnetic and non-conductive, the characteristic impedance is given by Z = √(μr / εr), where μr is the relative permeability of the medium.
For the first medium with εr₁ = 4 and μr₁ = 1, Z₁ = √(μr₁ / εr₂) = √(1 / 4) = 1/2.
For the second medium with εr₂ = 2.25 and μr₂ = 1, Z₂ = √(μr₂ / εr₂) = √(1 / 2.25) = 2/3.
Using these values, we can calculate the reflection coefficient:
R = (Z₂ - Z₁) / (Z₂ + Z₁) = (2/3 - 1/2) / (2/3 + 1/2) = -1/7.
The transmission coefficient is given by:
T = 2Z₂ / (Z + Z₁) = 2(2/3) / (2/3 + 1/2) = 4/7.
So, the standing wave ratio (S) is the absolute value of the reflection coefficient divided by the transmission coefficient:
S = |R / T| = |-1/7 / (4/7)| = 1/4.
Hence, the standing wave ratio S = 1/4.
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(a) During a thermodynamic cycle gas undergoes three different processes beginning at an initial state where pr-1.5 bar, V₁ =2.5 m³ and U₁=61 kJ. The processes are as follows: (i) Process 1-2: Compression with pV= constant to p2 = 3 bar, U₂ = 710 kJ 3 (ii) Process 2-3: W2-3 = 0, Q2-3-200 kJ, and (iii) Process 3-1: W3-1 = +100 kJ. Determine the heat interactions for processes 1-2 and 3-1 i.e. Q1-2 and Q3-1. (b) A and B are two reversible Carnot engines which are connected in series working between source temperature of 1500 K and sink temperature of 200 K, respectively. Carnot engine A gets 2000 kJ of heat from the source (maintained at temperature of 1500 K) and rejects heat to second Carnot engine i.e. B. Carnot engine B takes the heat rejected by Carnot engine A and rejects heat to the sink maintained at temperature 200 K. Assuming Carnot engines A and B have same thermal efficiencies, determine: a. Amount of heat rejected by Carnot engine B b. Amount of work done by each Carnot engines i.e. A and B c. Assuming Carnot engines A and B producing same amount of work, calculate the amount of heat received by Carnot B and d. Thermal efficiency of Carnot engines A and B, respectively. c) A flat plate of area = 0.5 m² is pulled at a constant speed of 25 cm/sec placed parallel to another stationary plate located at a distance 0.05 cm. The space between two plates is filled with a fluid of dynamic viscosity =0.004 Ns/m². Calculate the force required to maintain the speed of the plate in the fluid.
The force required to maintain the speed of the plate in the fluid is 0.02 N.
(a) For process 1-2, which is compression with pV = constant, it is an isothermal process. The heat interaction for this process, Q1-2, can be determined using the equation Q1-2 = U2 - U1, where U2 and U1 are the initial and final internal energies, respectively. Substituting the given values, Q1-2 = 710 kJ - 61 kJ = 649 kJ.
For process 3-1, the work done, W3-1, is positive, indicating that work is done on the system. Since the gas is returning to its initial state, the change in internal energy, ΔU, must be zero. Therefore, the heat interaction for process 3-1, Q3-1, is given by Q3-1 = -W3-1 = -100 kJ.
(b) In a series connection of two Carnot engines with the same thermal efficiencies, the heat rejected by engine A is equal to the heat received by engine B. Given that engine A receives 2000 kJ of heat, the amount of heat rejected by engine B is also 2000 kJ.
The work done by each Carnot engine is equal to the heat absorbed from the source. Therefore, both engine A and engine B do 2000 kJ of work.
Assuming both engines produce the same amount of work, the heat received by engine B is also 2000 kJ.
The thermal efficiency of a Carnot engine is given by η = 1 - (Tc/Th), where Tc is the temperature of the cold reservoir (sink) and Th is the temperature of the hot reservoir (source).
In this case, the temperatures are given as 200 K and 1500 K, respectively. Therefore, the thermal efficiency of both Carnot engines A and B is η = 1 - (200/1500) = 0.867.
(c) To calculate the force required to maintain the speed of the plate in the fluid, we can use the formula for viscous drag force: F = η * A * v / d, where η is the dynamic viscosity of the fluid, A is the area of the plate, v is the velocity of the plate, and d is the distance between the plates.
Substituting the given values, η = 0.004 Ns/m², A = 0.5 m², v = 25 cm/sec = 0.25 m/sec, and d = 0.05 cm = 0.0005 m, we can calculate the force as follows:
F = (0.004 Ns/m²) * (0.5 m²) * (0.25 m/sec) / (0.0005 m) = 0.02 N
Therefore, the force required to maintain the speed of the plate in the fluid is 0.02 N.
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Object 1 has a mass of 30,000kg. Object 2 has a mass of 50,000kg. Object 3 has a mass of 75,000kg. Object 2 is 3m to the right of Object 1. Object 3 is 5m to the right of Object 2. What is the net force acting on Object 3 due to Objects 1 and 2?
A cat of mass 10kg is standing on the end of a ceiling fan blade of 0.75m rotating at 2.3rad/s. What is the minimum coefficient of static friction between the cat and the fan blade?
A rotisserie chicken rotates at 0.25rev/s. When the power is shut off it takes the rotisserie chicken 3rev to come to a full stop. What is the angular acceleration of the rotisserie chicken, assuming the acceleration is constant?
A circular saw rotates at a rate of 25rad/s. A setting is changed to make the rotation rate increase at a rate of 0.5rad/s^2. What is the angular speed of the blade after 1.5s?
The angular speed of the blade after 1.5s is 26.25 rad/s.
1. The net force acting on Object 3 due to Objects 1 and 2The net force acting on Object 3 due to Objects 1 and 2 is as follows. Let us first calculate the gravitational force between object 1 and object 3.
The formula used to calculate gravitational force is F = (Gm1m2) / d2G is the gravitational constant, m1 and m2 are the masses of two objects, and d is the distance between the centers of the two objects
.F = (6.67 x 10-11) [(30,000 kg) (75,000 kg) / (5 m)2]
F = 6.0 x 10-6 N
Now, let's calculate the gravitational force between object 2 and object 3.
F = (6.67 x 10-11) [(50,000 kg) (75,000 kg) / (2 m)2]
F = 2.5 x 10-5 N
The direction of the gravitational force between Object 3 and Object 1 is to the right, while the direction of the gravitational force between Object 3 and Object 2 is to the left.
Fnet = F3,2 + F3,1
Fnet = (2.5 x 10-5 N) - (6.0 x 10-6 N)
Fnet = 1.9 x 10-5 N (to the left)
2. Minimum coefficient of static friction between the cat and the fan blade. The minimum coefficient of static friction between the cat and the fan blade is given by μs = v2 / rg
where v = 2.3 rad/s (angular velocity of the blade)
r = 0.75 m (radius of the fan blade)g = 9.8 m/s2 (acceleration due to gravity)
m = 10 kg (mass of the cat)μs = v2 / rgμs = (2.3 rad/s)2 / (0.75 m)(9.8 m/s2)
μs = 0.21 (approximately)3. Angular acceleration of the rotisserie chicken, assuming the acceleration is constant The angular acceleration of the rotisserie chicken, assuming the acceleration is constant is given by the formula:
α = (ωf - ωi) / twhere ωi = 0.25 rev/s (initial angular velocity)ωf = 0 rev/s (final angular velocity)
t = 3 rev / (0.25 rev/s) (time taken to come to a full stop)
α = (ωf - ωi) / tα
= (0 - 0.25 rev/s) / (3 rev / (0.25 rev/s))
α = - 0.02 rev/s2 (negative sign indicates deceleration)4. Angular speed of the blade after 1.5sThe angular speed of the blade after 1.5s is given by the formula:ωf = ωi + αt
where ωi = 25 rad/s (initial angular velocity)α = 0.5 rad/s2 (angular acceleration)t = 1.5 sωf = ωi + αtωf = 25 rad/s + (0.5 rad/s2) (1.5 s)ωf = 26.25 rad/s (approximately)
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