The pressure at the bottom of the container is given to be 120 kPa. The atmospheric pressure is given to be 1.013 x 10⁵ Pa.
The main answer to this problem can be obtained by calculating the pressure of the fluid at the depth of the fluid from the bottom of the container. The pressure of the fluid at the depth of the fluid from the bottom of the container can be found by using the formula:Pressure of fluid at a depth (P) = Pressure at the bottom (P₀) + ρghHere,ρ = Density of fluid = 900 kg/m³g = acceleration due to gravity = 9.8 m/s²h = Depth of fluid from the bottom of the containerBy using these values, we can find the depth of the fluid from the bottom of the container.
The explaination of the main answer is as follows:Pressure of fluid at a depth (P) = Pressure at the bottom (P₀) + ρghWhere,ρ = Density of fluid = 900 kg/m³g = acceleration due to gravity = 9.8 m/s²h = Depth of fluid from the bottom of the containerGiven,Pressure at the bottom (P₀) = 120 kPa = 120,000 PaAtmospheric pressure (Patm) = 1.013 x 10⁵ PaNow, using the formula of pressure of fluid at a depth, we get:P = P₀ + ρgh120,000 + 900 x 9.8 x h = 120,000 + 8,820h = 12.93 mThe depth of the fluid from the bottom of the container is 12.93 m.
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If a solenoid that is 1.9 m long, with 14,371 turns, generates a magnetic field of 1.0 tesla What would be the current in the solenoid in amps?
The current in the solenoid is approximately 745 A.
The formula used to determine the current in the solenoid in amps is given as;I = B n A/μ_0Where;
I = current in the solenoid in amps
B = magnetic field in Tesla (T)n = number of turns
A = cross-sectional area of the solenoid in
m²μ_0 = permeability of free space
= 4π × 10⁻⁷ T m A⁻¹Given;
Length of solenoid, l = 1.9 m
Number of turns, n = 14,371
Magnetic field, B = 1.0 T
From the formula for the cross-sectional area of a solenoid ;A = πr²
Assuming that the solenoid is uniform, the radius, r can be determined as;
r = 2.3cm/2
= 1.15cm
= 0.0115m
So,
A = π(0.0115)²
= 4.16 × 10⁻⁴ m²So,
Substituting the given values in the formula for the current in the solenoid in amps;
I = B n A/μ_0
= 1.0 × 14371 × 4.16 × 10⁻⁴/4π × 10⁻⁷
= 745.45A ≈ 745A
The current in the solenoid is approximately 745 A.
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Which of the following remain(s) constant for a projectile: it's horizontal velocity component, v, it's vertical velocity component, Vv, or it's vertical acceleration, g? Select one: O a. g and VH O b. g, V and Vv O c..g and v O d. Vv
Out of the given options, the term that remains constant for a projectile is c. g and v.
Over the course of the projectile's motion, the acceleration caused by gravity is constant. This indicates that the vertical acceleration is unchanged. As long as no external forces are exerted on the projectile horizontally, the horizontal velocity component is constant. This is due to the absence of any horizontal acceleration.
Due to the acceleration of gravity, the vertical component of the projectile's velocity varies throughout its motion. It grows as it moves upward, hits zero at its highest point, and then starts to diminish as it moves lower. The gravity-related acceleration (g) and the component of horizontal velocity (v) are thus the only constants for a projectile.
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The magnetic force on a straight wire 0.30 m long is 2.6 x 10^-3 N. The current in the wire is 15.0 A. What is the magnitude of the magnetic field that is perpendicular to the wire?
Answer: the magnitude of the magnetic field perpendicular to the wire is approximately 1.93 x 10^-3 T.
Explanation:
The magnetic force on a straight wire carrying current is given by the formula:
F = B * I * L * sin(theta),
where F is the magnetic force, B is the magnetic field, I is the current, L is the length of the wire, and theta is the angle between the magnetic field and the wire (which is 90 degrees in this case since the field is perpendicular to the wire).
Given:
Length of the wire (L) = 0.30 m
Current (I) = 15.0 A
Magnetic force (F) = 2.6 x 10^-3 N
Theta (angle) = 90 degrees
We can rearrange the formula to solve for the magnetic field (B):
B = F / (I * L * sin(theta))
Plugging in the given values:
B = (2.6 x 10^-3 N) / (15.0 A * 0.30 m * sin(90 degrees))
Since sin(90 degrees) equals 1:
B = (2.6 x 10^-3 N) / (15.0 A * 0.30 m * 1)
B = 2.6 x 10^-3 N / (4.5 A * 0.30 m)
B = 2.6 x 10^-3 N / 1.35 A*m
B ≈ 1.93 x 10^-3 T (Tesla)
A capacitor with initial charge qo is discharged through a resistor. (a) In terms of the time constant t, how long is required for the capacitor to lose the first one-third of its charge? XT (b) How long is required for the capacitor to lose the first two-thirds of its charge?
(a) The time required for the capacitor to lose the first one-third of its charge is given by t1 = t * ln(3), and (b) the time required to lose the first two-thirds of its charge is t2 = t * ln(3^2)
(a) To calculate the time required for the capacitor to lose the first one-third of its charge, we can use the formula:t1 = t * ln(3)
Where t1 represents the time required, t is the time constant, and ln denotes the natural logarithm. This formula is derived from the exponential decay behavior of a charging or discharging capacitor.
(b) Similarly, to find the time required for the capacitor to lose the first two-thirds of its charge, we can use the formula:
t2 = t * ln(3^2)
Here, t2 represents the time required to lose the first two-thirds of the charge.
(a) The time required for the capacitor to lose the first one-third of its charge is given by t1 = t * ln(3), and (b) the time required to lose the first two-thirds of its charge is t2 = t * ln(3^2). These formulas utilize the natural logarithm and the time constant to calculate the desired time durations.
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2. For each pair of systems, circle the one with the larger entropy. If they both have the same entropy, explicitly state it. a. 1 kg of ice or 1 kg of steam b. 1 kg of water at 20°C or 2 kg of water at 20°C c. 1 kg of water at 20°C or 1 kg of water at 50°C d. 1 kg of steam (H₂0) at 200°C or 1 kg of hydrogen and oxygen atoms at 200°C Two students are discussing their answers to the previous question: Student 1: I think that 1 kg of steam and 1 kg of the hydrogen and oxygen atoms that would comprise that steam should have the same entropy because they have the same temperature and amount of stuff. Student 2: But there are three times as many particles moving about with the individual atoms not bound together in a molecule. I think if there are more particles moving, there should be more disorder, meaning its entropy should be higher. Do you agree or disagree with either or both of these students? Briefly explain your reasoning.
a. 1 kg of steam has the larger entropy. b. 2 kg of water at 20°C has the larger entropy. c. 1 kg of water at 50°C has the larger entropy. d. 1 kg of steam (H2O) at 200°C has the larger entropy.
Thus, the answers to the question are:
a. 1 kg of steam has a larger entropy.
b. 2 kg of water at 20°C has a larger entropy.
c. 1 kg of water at 50°C has a larger entropy.
d. 1 kg of steam (H₂0) at 200°C has a larger entropy.
Student 1 thinks that 1 kg of steam and 1 kg of hydrogen and oxygen atoms that make up the steam should have the same entropy because they have the same temperature and amount of stuff. Student 2, on the other hand, thinks that if there are more particles moving around, there should be more disorder, indicating that its entropy should be higher.I agree with student 2's reasoning. Entropy is directly related to the disorder of a system. Higher disorder indicates a higher entropy value, whereas a lower disorder implies a lower entropy value. When there are more particles present in a system, there is a greater probability of disorder, which results in a higher entropy value.
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Two lenses are placed along the x axis, with a diverging lens of focal length -8.50 cm on the left and a converging lens of focal length 13.0 cm on the right. When an object is placed 12.0 cm to the left of the diverging lens, what should the separation s of the two lenses be if the final image is to be focused at x = co? cm
The separation between the two lenses should be 19.21 cm for the final image to be focused at x = ∞.
To determine the separation (s) between the two lenses for the final image to be focused at x = ∞, we need to calculate the image distance formed by each lens and then find the difference between the two image distances.
Let's start by analyzing the diverging lens:
1. Diverging Lens:
Given: Focal length [tex](f_1)[/tex] = -8.50 cm, Object distance [tex](u_1)[/tex]= -12.0 cm (negative sign indicates object is placed to the left of the lens)
Using the lens formula: [tex]\frac{1}{f_1} =\frac{1}{v_1} -\frac{1}{u_1}[/tex]
Substituting the values, we can solve for the image distance (v1) for the diverging lens.
[tex]\frac{1}{-8.50} =\frac{1}{v_1} -\frac{1}{-12.0}[/tex]
v1 = -30.0 cm.
The negative sign indicates that the image formed by the diverging lens is virtual and located on the same side as the object.
2.Converging Lens:
Given: Focal length (f2) = 13.0 cm, Object distance (u2) = v1 (image distance from the diverging lens)
Using the lens formula: [tex]\frac{1}{f_2} =\frac{1}{v_2} -\frac{1}{u_2}[/tex]
Substituting the values, we can solve for the image distance (v2) for the converging lens.
[tex]\frac{1}{13.0} =\frac{1}{v_2} -\frac{1}{-30.0}[/tex]
v2 = 10.71 cm.
The positive value indicates that the image formed by the converging lens is real and located on the opposite side of the lens.
Calculating the Separation:
The separation (s) between the two lenses is given by the difference between the image distance of the converging lens (v2) and the focal length of the diverging lens (f1).
[tex]s=v_2-f_1[/tex]
= 10.71 cm - (-8.50 cm)
= 19.21 cm
Therefore, the separation between the two lenses should be 19.21 cm for the final image to be focused at x = ∞.
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Three current carrying wires are located at the edges of a right triangle. Calculate the magnitude and direction of the magnetic field at point Clocated midway on the hypotenuse. Take l=20 cm,l=2 mA.
Hence as the magnetic fields due to Wires 1 and 3 are in the same direction (into the page), and the magnetic field due to Wire 2 is in the opposite direction (out of the page), we need to subtract the magnitude of the magnetic field due to Wire 2 from the sum of the magnitudes of the magnetic fields due to Wires 1 and 3 to get the net magnetic field at point C.
To calculate the magnetic field at point C, we can use the Biot-Savart Law, which relates the magnetic field generated by a current-carrying wire to the distance from the wire.
Let's assume the right triangle has sides A, B, and C, with point C being the midpoint of the hypotenuse. The wires are located along the edges of the triangle, so let's label them as follows:
Wire 1: Located along side A, with a current I1 = 2 mA
Wire 2: Located along side B, with a current I2 = 2 mA
Wire 3: Located along the hypotenuse (opposite side C), with a current I3 = 2 mA
To calculate the magnetic field at point C due to each wire, we can use the following formula:
dB = (μ₀ / 4π) * (I * dl × r) / r^3
Where:
dB is the infinitesimal magnetic field vector,
μ₀ is the permeability of free space (4π × 10^-7 T·m/A),
I is the current in the wire,
dl is an infinitesimal length element of the wire,
r is the distance from the wire element to the point where we want to calculate the magnetic field.
To calculate the net magnetic field at point C, we'll sum the magnetic fields due to each wire vectorially.
Let's first calculate the magnetic field due to Wire 1 at point C:
Using the right-hand rule, we can determine that the magnetic field at point C due to Wire 1 will be directed into the page.
Now, let's calculate the magnetic field due to Wire 2 at point C:
Using the right-hand rule, we can determine that the magnetic field at point C due to Wire 2 will be directed out of the page.
Finally, let's calculate the magnetic field due to Wire 3 at point C:
Using the right-hand rule, we can determine that the magnetic field at point C due to Wire 3 will be directed into the page.
Hence as the magnetic fields due to Wires 1 and 3 are in the same direction (into the page), and the magnetic field due to Wire 2 is in the opposite direction (out of the page), we need to subtract the magnitude of the magnetic field due to Wire 2 from the sum of the magnitudes of the magnetic fields due to Wires 1 and 3 to get the net magnetic field at point C.
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6. A mass density p = p(x, t) obeys the physical law j = vop where > 0 is a constant and j is the mass density flux. Use the continuity law, in the absence of any source or sink terms, to obtain a differential equation for p. The system is initially primed such that p(x,0) = poe-²/ where po, l are (positive) constants. Use the method of characteristics to determine the mass density for times t > 0. Sketch the profile of p against æ for a variety of time steps. [15 marks] Describe the significance of each of the quantities vo. Po and l. Illustrate each with a sketch at an appropriate number of time steps. [5 marks]
The continuity law and the physical law j = vop, we can derive a differential equation for the mass density p(x, t). The significance of the quantities vo, po, and l are that vo represents the velocity of the characteristic curves, po is the initial mass density at t = 0 and l is a positive constant.
The system is initially primed with a given initial condition p(x, 0) = po * e^(-x^2), where po and l are positive constants. The method of characteristics can be applied to determine the mass density for times t > 0 and sketch its profile against x for different time steps. The quantities vo, po, and l have specific meanings and significance in the context of the problem.
The continuity law states that the rate of change of mass density p with respect to time t plus the divergence of the mass density flux j must be zero in the absence of any source or sink terms.
Applying this law to the physical law j = vop, where v and o are constants, we have:
∂p/∂t + ∂(vop)/∂x = 0
Expanding the equation, we get:
∂p/∂t + vo ∂p/∂x + vop ∂o/∂x = 0
Since the system is initially primed with p(x, 0) = po * e^(-x^2), we have an initial condition for the mass density.
To solve this differential equation for times t > 0, we can use the method of characteristics. This method involves defining characteristic curves that satisfy the equation:
dx/dt = vo
By solving this equation, we can determine the characteristics curves and track the behavior of the mass density along these curves.
The significance of the quantities vo, po, and l can be described as follows:
- vo represents the velocity of the characteristic curves. It determines the speed at which the mass density propagates along these curves.
- po is the initial mass density at t = 0. It represents the value of the mass density at the initial condition.
- l is a positive constant that likely represents a characteristic length scale in the system.
By sketching the profile of p against x for different time steps, we can observe how the mass density evolves and propagates in space over time, following the characteristics curves determined by the initial conditions and the physical laws governing the system.
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Determine the electrical resistance of a 20.0 m length of tungsten wire of radius 0.200 mm. The resistivity of tungsten is 5.6×10^ −8 Ω⋅m.
The electrical resistance of a 20.0 m length of tungsten wire of radius 0.200 mm, when the resistivity of tungsten is 5.6×10^-8 Ω⋅m can be determined using the following steps:
1: Find the cross-sectional area of the wire The cross-sectional area of the wire can be calculated using the formula for the area of a circle, which is given by: A
= πr^2where r is the radius of the wire. Substituting the given values: A
= π(0.0002 m)^2A
= 1.2566 × 10^-8 m^2given by: R
= ρL/A Substituting
= (5.6 × 10^-8 Ω⋅m) × (20.0 m) / (1.2566 × 10^-8 m^2)R
= 1.77 Ω
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Problem 1.10 A small spherical ball of mass m and radius R is dropped from rest into a liquid of high viscosity 7, such as honey, tar, or molasses. The only appreciable forces on it are gravity mg and a linear drag force given by Stokes's law, FStokes -6Rv, where v is the ball's velocity, and the minus sign indicates that the drag force is opposite to the direction of v. (a) Find the velocity of the ball as a function of time. Then show that your answer makes sense for (b) small times; (c) large times.
A small spherical ball of mass m and radius R is dropped from rest into a liquid of high viscosity 7, such as honey, tar, or molasses. the velocity is approximately (g/6R), and for large times, the velocity approaches (g/6R) and becomes constant.
(a) To find the velocity of the ball as a function of time, we need to consider the forces acting on the ball. The only two forces are gravity (mg) and the linear drag force (FStokes).
Using Newton's second law, we can write the equation of motion as:
mg - FStokes = ma
Since the drag force is given by FStokes = -6Rv, we can substitute it into the equation:
mg + 6Rv = ma
Simplifying the equation, we have:
ma + 6Rv = mg
Dividing both sides by m, we get:
a + (6R/m) v = g
Since acceleration a is the derivative of velocity v with respect to time t, we can rewrite the equation as a first-order linear ordinary differential equation:
dv/dt + (6R/m) v = g
This is a linear first-order ODE, and we can solve it using the method of integrating factors. The integrating factor is given by e^(kt), where k = 6R/m. Multiplying both sides of the equation by the integrating factor, we have:
e^(6R/m t) dv/dt + (6R/m)e^(6R/m t) v = g e^(6R/m t)
The left side can be simplified using the product rule of differentiation:
(d/dt)(e^(6R/m t) v) = g e^(6R/m t)
Integrating both sides with respect to t, we get:
e^(6R/m t) v = (g/m) ∫e^(6R/m t) dt
Integrating the right side, we have:
e^(6R/m t) v = (g/m) (m/6R) e^(6R/m t) + C
Simplifying, we get:
v = (g/6R) + Ce^(-6R/m t)
where C is the constant of integration.
(b) For small times, t → 0, the exponential term e^(-6R/m t) approaches 1, and we can neglect it. Therefore, the velocity of the ball simplifies to:
v ≈ (g/6R) + C
This means that initially, when the ball is dropped from rest, the velocity is approximately (g/6R), which is constant and independent of time.
(c) For large times, t → ∞, the exponential term e^(-6R/m t) approaches 0, and we can neglect it. Therefore, the velocity of the ball simplifies to:
v ≈ (g/6R)
This means that at large times, when the ball reaches a steady-state motion, the velocity is constant and equal to (g/6R), which is determined solely by the gravitational force and the drag force.
In summary, the velocity of the ball as a function of time is given by:
v = (g/6R) + Ce^(-6R/m t)
For small times, the velocity is approximately (g/6R), and for large times, the velocity approaches (g/6R) and becomes constant.
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Required information A 35.0-nC charge is placed at the origin and a 57.0 nC charge is placed on the +x-axis, 2.20 cm from the origin. What is the electric potential at a point halfway between these two charges?
V =
The electric potential at a point halfway between the 35.0 nC charge at the origin and the 57.0 nC charge on the +x-axis is 1.83 kV.
To calculate the electric potential at a point halfway between the two charges, we need to consider the contributions from each charge and sum them together.
Given:
Charge q1 = 35.0 nC at the origin (0, 0).
Charge q2 = 57.0 nC on the +x-axis, 2.20 cm from the origin.
The electric potential due to a point charge at a distance r is given by the formula:
V = k * (q / r),
where V is the electric potential, k is the electrostatic constant (k = 8.99 x 10^9 N m^2/C^2), q is the charge, and r is the distance.
Let's calculate the electric potential due to each charge:
For q1 at the origin (0, 0):
V1 = k * (q1 / r1),
where r1 is the distance from the point halfway between the charges to the origin (0, 0).
For q2 on the +x-axis, 2.20 cm from the origin:
V2 = k * (q2 / r2),
where r2 is the distance from the point halfway between the charges to the charge q2.
Since the point halfway between the charges is equidistant from each charge, r1 = r2.
Now, let's calculate the distances:
r1 = r2 = 2.20 cm / 2 = 1.10 cm = 0.0110 m.
Substituting the values into the formula:
V1 = k * (35.0 x 10^(-9) C) / (0.0110 m),
V2 = k * (57.0 x 10^(-9) C) / (0.0110 m).
Calculating the electric potentials:
V1 ≈ 2863.64 V,
V2 ≈ 4660.18 V.
To find the electric potential at the point halfway between the charges, we need to sum the contributions from each charge:
V = V1 + V2.
Substituting the calculated values:
V ≈ 2863.64 V + 4660.18 V.
Calculating the sum:
V ≈ 7523.82 V.
Therefore, the electric potential at a point halfway between the two charges is approximately 7523.82 volts.
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Q3. A hanging platform has four cylindrical supporting cables of diameter 2.5 cm. The supports are made from solid aluminium, which has a Young's Modulus of Y = 69 GPa. The weight of any object placed on the platform is equally distributed to all four cables. a) When a heavy object is placed on the platform, the cables are extended in length by 0.4%. Find the mass of this object. (3) b) Poisson's Ratio for aluminium is v= 0.33. Calculate the new diameter of the cables when supporting this heavy object. (3) (6 marks)
The new diameter of the cable is 0.892 cm. Option (ii) is the correct answer.
Given: Diameter of supporting cables,
d = 2.5 cm Young's Modulus of aluminium,
Y = 69 GPa Load applied,
F = mg
Extension in the length of the cables,
δl = 0.4% = 0.004
a) Mass of the object placed on the platform can be calculated as:
m = F/g
From the question, we know that the weight of any object placed on the platform is equally distributed to all four cables.
So, weight supported by each cable = F/4
Extension in length of each cable = δl/4
Young's Modulus can be defined as the ratio of stress to strain.
Y = stress/strainstress = Force/areastrain = Extension in length/Original length
Hence, stress = F/4 / (π/4) d2 = F/(π d2)strain = δl/4 / L
Using Hooke's Law, stress/strain
= Yπ d2/F = Y δl/Ld2 = F/(Y δl/π L) = m g / (Y δl/π L)
On substituting the given values, we get:
d2 = (m × 9.8) / ((69 × 10^9) × (0.004/100) / (π × 2.5/100))d2 = 7.962 × 10^-5 m2
New diameter of the cable is:
d = √d2 = √(7.962 × 10^-5) = 0.00892 m = 0.892 cm
Therefore, the new diameter of the cable is 0.892 cm.
Hence, option (ii) is the correct answer.
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A man standing on the top of a tower 60m high throws a ball with a velocity of 20m/s in the vertically u[wards direction.
(a) How long will it take the ball to pass the man moving in the downwards direction ?
(b) What is the maximum height attained by the ball ?
(c) How long will it take the ball to hit the ground ? ( Take g = 10 m/s^2 )
(a) It will take 2 seconds for the ball to pass the man moving in the downward direction.
(b) The maximum height attained by the ball is 20 meters.
(c) The ball will take 2+2\sqrt{2} seconds to hit the ground.
(a) How long will it take the ball to pass the man moving in the downward direction?
We can use the equation of motion:
v = u + at,
where:
v = final velocity (0 m/s since the ball will momentarily stop when passing the man),
u = initial velocity (20 m/s upwards),
a = acceleration (due to gravity, -10 m/s²),
t = time.
Substituting the known values we get:
0 = 20 - 10t.
Simplifying the equation:
10t = 20,
t = 20/10,
t = 2 seconds.
Therefore, it will take 2 seconds for the ball to pass the man moving in the downward direction.
(b) What is the maximum height attained by the ball?
To find the maximum height attained by the ball, we can use the following equation:
v² = u² + 2as,
where:
v = final velocity (0 m/s at the maximum height),
u = initial velocity (20 m/s upwards),
a = acceleration (acceleration due to gravity, -10 m/s²),
s = displacement.
The maximum height will be achieved when v = 0. Rearranging the equation, we get:
0 = (20)² + 2(-10)s.
Simplifying the equation:
400 = -20s.
Dividing both sides by -20:
s = -400/-20,
s = 20 meters.
Therefore, the maximum height attained by the ball is 20 meters.
(c) How long will it take the ball to hit the ground?
To find the time it takes for the ball to hit the ground, we can use the following equation:
s = ut + (1/2)at²,
where:
s = displacement (60 meters downwards),
u = initial velocity (20 m/s upwards),
a = acceleration (acceleration due to gravity, -10 m/s²),
t = time.
Rearranging the equation, we get:
-60 = 20t + (1/2)(-10)t².
Simplifying the equation:
-60 = 20t - 5t².
Rearranging to form a quadratic equation:
5t² - 20t - 60 = 0.
Dividing both sides by 5:
t² - 4t - 12 = 0.
Solving the equation using the quadratic formula, we get:
t = (4 ± sqrt(16 + 4 x 12)) / 2
t = (4 ± 4sqrt(2)) / 2
t = 2 ± 2sqrt(2)
Since time cannot be in negative terms, we ignore the negative value of t. Therefore, the time it takes for the ball to hit the ground is:
t = 2 + 2sqrt(2) seconds
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[tex] \\[/tex]
(a) How long will it take the ball to pass the man moving in the downwards direction ?
Using Equation of Motion:-
[tex] \large\bigstar \: \: \: { \underline { \overline{ \boxed{ \frak{v = u + at}}}}}[/tex]
where:-
→ v denotes final velocity→ u denotes initial velocity→ a denotes acceleration→ t denotes timePlugging in Values:-
[tex] \large \sf \longrightarrow \: v = u + at[/tex]
[tex] \large \sf \longrightarrow \: 0 = 20 + ( - 10)t \: [/tex]
[tex] \large \sf \longrightarrow \: 0 - 20=( - 10)t \: [/tex]
[tex] \large \sf \longrightarrow \: - 10t = - 20\: [/tex]
[tex] \large \sf \longrightarrow \: t = \frac{ - 20}{ - 10} \\ [/tex]
[tex] \large \sf \longrightarrow \: t = 2 \: secs \\ [/tex]
Therefore, it will take 2 seconds for the ball to pass the man moving in the downward direction.
________________________________________
[tex] \\[/tex]
(b) What is the maximum height attained by the ball ?
→ To solve the given problem, we can use the equations of motion
Using Equation of Motion:-
[tex] \large\bigstar \: \: \: { \underline { \overline{ \boxed{ \frak{ {v}^{2} = {u}^{2} + 2as}}}}}[/tex]
where:
→ v denotes final velocity→ u denotes initial velocity→ a denotes acceleration→ s denotes displacementPlugging in Values:-
[tex] \large \sf \longrightarrow \: {v}^{2} = {u}^{2} + 2as[/tex]
[tex] \large \sf \longrightarrow \: {(0)}^{2} = {(20)}^{2} + 2( - 10)s[/tex]
[tex] \large \sf \longrightarrow \: 0 = 400 + 2( - 10)s[/tex]
[tex] \large \sf \longrightarrow \: 400 + (- 20)s = 0[/tex]
[tex] \large \sf \longrightarrow \: 400 - 20 \: s = 0[/tex]
[tex] \large \sf \longrightarrow \: - 20 \: s = - 400[/tex]
[tex] \large \sf \longrightarrow \: \: s = \frac{ - 400}{ - 20} [/tex]
[tex] \large \sf \longrightarrow \: \: s = 20 \: metres[/tex]
Therefore, the maximum height attained by the ball is 20 meters.
________________________________________
[tex] \\[/tex]
(c) How long will it take the ball to hit the ground ?
Using Equation of Motion:-
[tex] \large\bigstar \: \: \: { \underline { \overline{ \boxed{ \frak{ s= ut + \frac{1}{2}a{t}^{2}}}}}}[/tex]
where:
→ s denotes Displacement → u denotes initial velocity→ a denotes acceleration→ t denotes timePlugging in Values:-
[tex] \large \sf \longrightarrow \: s= ut + \frac{1}{2}a{t}^{2}[/tex]
[tex] \large \sf \longrightarrow \: -60= 20t + \frac{1}{2}(-10){t}^{2}[/tex]
[tex] \large \sf \longrightarrow \: -60= 20t + \frac{-10}{2}\times{t}^{2}[/tex]
[tex] \large \sf \longrightarrow \: -60= 20t + (-5)\times{t}^{2}[/tex]
[tex] \large \sf \longrightarrow \: -60= 20t-5\times{t}^{2}[/tex]
[tex] \large \sf \longrightarrow \: 20t-5{t}^{2}+60[/tex]
[tex] \large \sf \longrightarrow \: {t}^{2}-4t-12[/tex]
[tex] \large \sf \longrightarrow \: t=\frac{-b \pm\sqrt{{b}^{2}-4ac}}{2a} [/tex]
[tex] \large \sf \longrightarrow \: t=\frac{-(-4) \pm\sqrt{{(-4)}^{2}-4(1)(-12)}}{2(1)} [/tex]
[tex] \large \sf \longrightarrow \: t=\frac{4 \pm\sqrt{16-4(-12)}}{2} [/tex]
[tex] \large \sf \longrightarrow \: t=\frac{4 \pm\sqrt{16-(-48)}}{2} [/tex]
[tex] \large \sf \longrightarrow \: t=\frac{4 \pm\sqrt{16+48}}{2} [/tex]
[tex] \large \sf \longrightarrow \: t=\frac{4 \pm\sqrt{64}}{2} [/tex]
[tex] \large \sf \longrightarrow \: t=\frac{4 \pm 8}{2} [/tex]
[tex] \large \sf \longrightarrow \: t=\frac{4 + 8}{2} \qquad or \qquad t=\frac{4 - 8}{2} [/tex]
[tex] \large \sf \longrightarrow \: t=\frac{12}{2} \qquad or \qquad t=\frac{-4}{2} [/tex]
[tex] \large \sf \longrightarrow \: t=6 \qquad or \qquad t= -2 [/tex]
Since time cannot be negative , Therefore, it will take 6 secs to hit the ground!!
________________________________________
[tex] \\[/tex]
✅
Make a a derivation for the unknown resistor equation (Rx) in
terms of voltages and lengths on the wheatstone bridge
The unknown resistor (Rx) in a Wheatstone bridge circuit can be determined using the equation:
Rx = (V_out1 * R2) / (V_in - V_out2)
This equation relates Rx to the voltages V_out1 and V_out2, as well as the resistance R2 and the input voltage V_in.
Let's consider a typical Wheatstone bridge circuit consisting of four resistors: R1, R2, R3, and Rx. The bridge is supplied with a known voltage V_in and has two outputs: V_out1 and V_out2.
1. First, let's find the relationship between the voltages V_out1 and V_out2 in terms of the resistors. According to Kirchhoff's voltage law, the voltage drop across any closed loop in a circuit is zero. Applying this law to the two loops in the Wheatstone bridge, we have:
Loop 1: V_in = V_out1 + I1 * R1 + I2 * Rx
Loop 2: V_in = V_out2 + I3 * R3 + I2 * (R2 + Rx)
Where I1, I2, and I3 are the currents flowing through R1, Rx, and R3, respectively.
2. To simplify the equations, we can express I1, I2, and I3 in terms of the voltages and resistances using Ohm's law. Assuming the resistors have negligible internal resistance, we have:
I1 = V_out1 / R1
I2 = (V_out1 - V_out2) / (R2 + Rx)
I3 = V_out2 / R3
Substituting these values back into the loop equations, we get:
V_in = V_out1 + (V_out1 - V_out2) * Rx / (R2 + Rx)
V_in = V_out2 + V_out2 * R2 / (R2 + Rx)
3. Now, we can solve these two equations simultaneously to eliminate V_out1 and V_out2. Multiplying the first equation by (R2 + Rx) and the second equation by Rx, we get:
V_in * (R2 + Rx) = V_out1 * (R2 + Rx) + (V_out1 - V_out2) * Rx
V_in * Rx = V_out2 * Rx + V_out2 * R2
4. By rearranging these equations, we can isolate Rx:
V_in * Rx - V_out2 * Rx = V_out1 * (R2 + Rx) - (V_out1 - V_out2) * Rx
V_in * Rx - V_out2 * Rx = V_out1 * R2 + V_out1 * Rx - V_out1 * Rx + V_out2 * Rx
V_in * Rx - V_out2 * Rx = V_out1 * R2 + V_out2 * Rx
Rx * (V_in - V_out2) = V_out1 * R2
Rx = (V_out1 * R2) / (V_in - V_out2)
Therefore, the equation for the unknown resistor Rx in terms of the voltages and lengths on the Wheatstone bridge is:
Rx = (V_out1 * R2) / (V_in - V_out2)
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At a point a distance r=1.10 m from the origin on the positive x-axis, find the magnitude and direction of the magnetic field. (a) magnitude of the magnetic field (in T ) T (b) direction of the magnetic field +x-direction −x-direction +y-direction −y-direction +z-direction -z-direction At a point the same distance from the origin on the negative y-axis, find the magnitude and direction of the magnetic field. (c) magnitude of the magnetic field (in T ) At a point a distance r=1.10 m from the origin on the positive x-axis, find the magnitude and direction of the magnetic field. (a) magnitude of the magnetic field (in T ) T (b) direction of the magnetic field +x-direction −x-direction +y-direction −y-direction +z-direction −z-direction At a point the same distance from the origin on the negative y-axis, find the magnitude and direction of the magnetic field. (c) magnitude of the magnetic field (in T) T (d) direction of the magnetic field +x-direction
(a) The magnitude of the magnetic field at a point a distance r=1.10 m from the origin on the positive x-axis is 0.063 T.
(b) The direction of the magnetic field is +x-direction.
(c) The magnitude of the magnetic field at a point the same distance from the origin on the negative y-axis is 0.063 T.
(d) The direction of the magnetic field is −y-direction.
The magnetic field at a point due to a current-carrying wire is given by the Biot-Savart law:
B = µo I / 2πr sinθ
where µo is the permeability of free space, I is the current in the wire, r is the distance from the wire to the point, and θ is the angle between the wire and the line connecting the wire to the point.
In this case, the current is flowing in the +x-direction, the point is on the positive x-axis, and the distance from the wire to the point is r=1.10 m. Therefore, the angle θ is 0 degrees.
B = µo I / 2πr sinθ = 4π × 10-7 T⋅m/A × 1 A / 2π × 1.10 m × sin(0°) = 0.063 T
Therefore, the magnitude of the magnetic field at the point is 0.063 T. The direction of the magnetic field is +x-direction, because the current is flowing in the +x-direction and the angle θ is 0 degrees.
The same calculation can be done for the point on the negative y-axis. The only difference is that the angle θ is now 90 degrees. Therefore, the magnitude of the magnetic field at the point is still 0.063 T, but the direction is now −y-direction.
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A block is sliding with constant acceleration down. an incline. The block starts from rest at f= 0 and has speed 3.40 m/s after it has traveled a distance 8.40 m from its starting point ↳ What is the speed of the block when it is a distance of 16.8 m from its t=0 starting point? Express your answer with the appropriate units. μA 3 20 ? 168 Value Units Submit Request Answer Part B How long does it take the block to slide 16.8 m from its starting point? Express your answer with the appropriate units.
Part A: The speed of the block when it is a distance of 16.8 m from its starting point is 6.80 m/s. Part B: The time it takes for the block to slide 16.8 m from its starting point is 2.47 seconds.
To find the speed of the block when it is a distance of 16.8 m from its starting point, we can use the equations of motion. Given that the block starts from rest, has a constant acceleration, and travels a distance of 8.40 m, we can find the acceleration using the equation v^2 = u^2 + 2as. Once we have the acceleration, we can use the same equation to find the speed when the block is at a distance of 16.8 m. For part B, to find the time it takes to slide 16.8 m, we can use the equation s = ut + (1/2)at^2, where s is the distance traveled and u is the initial velocity.
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A bicycle has tires with diameter D. If you are bicycling at speed v, how much time does it take the tire to rotate once?
The time it takes for a tire of a bicycle with diameter D to rotate once when cycling at a speed of v is given by the formula πD / (2v).
The time it takes for a tire of a bicycle with diameter D to rotate once is given by the formula below:
Time taken for one rotation= (distance traveled in one rotation) / (speed of rotation)
To get the distance covered in one rotation of the bicycle, we calculate the circumference of the tire.
Circumference = πD where D is the diameter of the tire.
π is the constant value of the ratio of the circumference of any circle to its diameter which is approximately 3.14159.
By substitution, distance covered in one rotation = πD.
For the speed of rotation, we use the angular velocity formula which is ω= v / r where v is the linear velocity of the bicycle, r is the radius of the tire, and ω is the angular velocity which is in radians per second.
We know that the radius of the tire is half of the diameter r = D/2.
Substituting in the formula, we get the angular velocity as ω = v / (D/2)
Simplifying we get, ω= 2v / D
We now have all we need to find the time taken for one rotation. Substituting the values we obtained above into the formula for time taken we get;
Time taken for one rotation = πD / (2v)
Therefore, the time it takes for a tire of a bicycle with diameter D to rotate once when cycling at a speed of v is given by the formula πD / (2v).
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A block of mass m=0.1 kg attached to a spring with =40 Nm−1 is subject to a damping force with =0.1 kg s−1.
(a) Calculate the magnitude F0 of the constant force required to move the equilibrium of the block from x=0 to x=15 cm.
(b) If this force F0 were the amplitude of a harmonic driving force with non-zero , what would be the steady-state amplitude of oscillations of the block at velocity resonance?
The magnitude of the constant force required to move the equilibrium of the block from x=0 to x=15 cm is 6 N. The steady-state amplitude of oscillations of the block at velocity resonance is approximately 10.55 cm.
(a) Calculation of the magnitude F0 of the constant force required to move the equilibrium of the block from x=0 to x=15 cm:
m = 0.1 kg k = 40 Nm⁻¹b = 0.1 kg s⁻¹
The displacement from equilibrium position is given by:
x = 15 cm = 0.15 m
The force required to move the block from its equilibrium position is given by
F0 = kx = 40 Nm⁻¹ × 0.15 m= 6 N
Thus, the magnitude of the constant force required to move the equilibrium of the block from x=0 to x=15 cm is 6 N.
(b) Calculation of the steady-state amplitude of oscillations of the block at velocity resonance:
F0 = 6 N
k = 40 Nm⁻¹
m = 0.1 kg
b = 0.1 kg s⁻¹
ω0 = √k/m = √(40 Nm⁻¹ / 0.1 kg)= 20 rad s⁻¹ω = √(k/m - b²/4m²) = √[40 Nm⁻¹ / (0.1 kg) - (0.1 kg s⁻¹)² / 4(0.1 kg)²]≈ 19.96 rad s⁻¹
At velocity resonance, ω = ω0.
Amplitude of oscillations is given by:
A = F0/m(ω0² - ω²)² + (bω)²= 6 N / 0.1 kg (20 rad s⁻¹)² - (19.96 rad s⁻¹)² + (0.1 kg s⁻¹ × 19.96 rad s⁻¹)²≈ 0.1055 m = 10.55 cm
Therefore, the steady-state amplitude of oscillations of the block at velocity resonance is approximately 10.55 cm.
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Two identical diverging lenses are separated by 15.1cm. The focal length of each lens is -7.81cm. An object is located 3.99cm to the left of the lens that is on the left. Determine the final image distance relative to the lens on the right.
Given the following conditionsTwo identical diverging lenses separated by 15.1cm.
The focal length of each lens is -7.81cm.
An object is located 3.99cm to the left of the lens that is on the left.
The image formed is virtual and erect as both the lenses are diverging lenses.
As the final image distance relative to the lens on the right is to be determined, it is easier to calculate it if the image distance relative to the left lens is found first.
Using the lens formula,
1/f = 1/v - 1/u
where,f is the focal length of the lens
u is the distance of the object from the lens
v is the distance of the image from the lens.
The object distance from the lens,
u = -3.99 cm (since it is on the left of the lens, it is taken as negative).
The focal length of the lens,
f = -7.81cm.
The image distance,
v = 1/f + 1/u
= 1/-7.81 - 1/-3.99
= -0.413 cm
As the image is virtual and erect, its distance from the lens is taken as positive.
Hence, the image is at a distance of 0.413cm from the left lens.
Now, using the formula for the combination of thin lenses,
1/f = 1/f₁ + 1/f₂ - d/f₁f₂
where,d is the distance between the two lenses
f₁ is the focal length of the first lens
f₂ is the focal length of the second lens.
Both lenses are identical and have the same focal length,
f₁ = f₂
= -7.81 cm.
The distance between the lenses,
d = 15.1 cm.
Substituting the values,
1/f = 1/-7.81 + 1/-7.81 - 15.1/-7.81×-7.81
= -0.258 cm⁻¹
The image distance relative to the lens on the right,
v₂ = f / (1/f - 2/f - d)
= -7.81 / (1/-0.258 - 2/-7.81 - 15.1/-7.81×-7.81)
= -3.33cm
Therefore, the final image distance relative to the lens on the right is -3.33cm.
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A source emits sound waves in all directions.
The intensity of the waves 4.00 m from the sources is 9.00 *10-4 W/m?
Threshold of Hearing is 1.00 * 10-12 W/m?
A.) What is the Intensity in decibels?
B.) What is the intensity at 10.0 m from the source in Watts/m2?
C.) What is the power of the source in Watts?
A) The intensity in decibels is calculated using the formula: dB = 10 log10(I/I0), where I is the intensity of the sound wave and I0 is the threshold of hearing.
B) To find the intensity at 10.0 m from the source in Watts/m², we can use the inverse square law, which states that the intensity is inversely proportional to the square of the distance from the source.
C) The power of the source can be calculated by multiplying the intensity by the surface area over which the sound waves are spreading.
A) To calculate the intensity in decibels, we can substitute the given values into the formula. Using I = 9.00 * 10⁽⁻⁴⁾ W/m² and I0 = 1.00 * 10⁽⁻¹²⁾ W/m², we can find dB = 10 log10(9.00 * 10⁽⁻⁴⁾ / 1.00 * 10⁽⁻¹²⁾).
B) Applying the inverse square law, we can determine the intensity at 10.0 m from the source by multiplying the initial intensity (9.00 * 10⁽⁻⁴⁾ W/m²) by (4.00 m)² / (10.0 m)².
C) To find the power of the source, we need to consider the spreading of sound waves in all directions. Since the intensity at a distance of 4.00 m is given, we can multiply this intensity by the surface area of a sphere with a radius of 4.00 m.
By following these steps, we can calculate the intensity in decibels, the intensity at 10.0 m from the source, and the power of the source in Watts.
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The magnetic field lines shown in the first picture below are from a circular loop of current.
What arrangement of current produces magnetic field lines as shown in the second picture?
Group of answer choices
Insufficient information to allow a single answer
A straight line of current
A square loop of current
There is no possible current arrangement
Magnetic field lines are imaginary lines used to represent the direction and strength of the magnetic field around a magnet or current-carrying conductor. The arrangement of current that produces magnetic field lines as shown in the second picture is correct choice 3) A square loop of current.
The first picture depicts the magnetic field lines around a circular loop of current. In this arrangement, the magnetic field lines are concentric circles centered on the loop. Each field line forms a closed loop around the current-carrying wire.
To generate magnetic field lines as shown in the second picture, a different current arrangement is required. The second picture shows magnetic field lines that form a pattern resembling a square. This indicates the presence of a square loop of current.
In a square loop of current, the magnetic field lines follow a distinct pattern. Along the sides of the loop, the magnetic field lines are parallel and evenly spaced. At the corners of the loop, the field lines converge and form a sharper bend. This arrangement of field lines is characteristic of a square loop of current.
Therefore, among the given options, the only arrangement that can produce magnetic field lines as shown in the second picture is a square loop of current.
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6. [-/2 Points] DETAILS COLFUNPHYS1 2.P.012. MY NOTES ASK YOUR TEACHER A paratrooper is initially falling downward at a speed of 32.7 m/s before her parachute opens. When it opens, she experiences an upward Instantaneous acceleration of 74 m/s². (a) If this acceleration remained constant, how much time would be required to reduce the paratrooper's speed to a safe 5.40 m/s? (Actually the acceleration is not constant in this case, but the equations of constant acceleration provide an easy estimate.) (b) How far does the paratrooper fall during this time Interval?
A paratrooper will fall for 0.49 seconds and travel 15.1 meters before her speed is reduced to a safe 5.40 m/s.
(a) To find the time required, we can use the following equation for the final velocity of an object under constant acceleration:
[tex]v_f[/tex] = [tex]v_i[/tex] + at
where
[tex]v_f[/tex] is the final velocity (5.40 m/s)
vi is the initial velocity (32.7 m/s)
a is the acceleration (74 m/s²)
t is the time
Substituting known values, we get:
5.40 m/s = 32.7 m/s + 74 m/s² * t
Solving for t, we get:
t = 0.49 s
(b) To find the distance fallen during this time interval, we can use the following equation for the displacement of an object under constant acceleration:
d = [tex]v_i[/tex] t + (1/2)at²
where
d is the displacement (distance fallen)
[tex]v_i[/tex] is the initial velocity (32.7 m/s)
t is the time (0.49 s)
a is the acceleration (74 m/s²)
Substituting known values, we get:
d = 32.7 m/s * 0.49 s + (1/2) * 74 m/s² * (0.49 s)²
d = 15.1 m
Therefore, the paratrooper would fall for 0.49 seconds and travel 15.1 meters before her speed is reduced to a safe 5.40 m/s.
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Verify the following equations:(x⁴)³ = x¹²
To verify the equation (x⁴)³ = x¹², we need to simplify both sides of the equation and see if they are equal.
Starting with the left side, we have (x⁴)³. Using the power of a power rule, we can simplify this as x^(4 * 3), which becomes x^12. Now let's look at the right side of the equation, which is x¹².
By comparing the left and right sides, we can see that they are both equal to x¹². Therefore, the equation (x⁴)³ = x¹² is verified and true. Now let's look at the right side of the equation, which is x¹².
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Determine the resultant force on a charge q located at the midpoint (L/2) on one side of
an equilateral triangle, consider that at each vertex there is a +Q charge. Find the address at
which the charge moves if a +Q is removed from a vertex on the same side as -q.
The resultant force on the charge q located at the midpoint (L/2) on one side of an equilateral triangle, considering that there is a +Q charge at each vertex, is zero.
In an equilateral triangle, the charges at the vertices will create forces that cancel each other out due to the symmetry of the triangle. Since each vertex has a +Q charge, the forces exerted on the charge q from the two neighboring charges will be equal in magnitude and opposite in direction. As a result, the net force on the charge q is zero, and it will remain at its current location.
When a +Q charge is removed from a vertex on the same side as -q, the equilibrium of forces is maintained. The remaining charges will still exert equal and opposite forces on q, resulting in a net force of zero. Therefore, the charge q will not experience any displacement and will stay at its current location.
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A circuit consists of an 110- resistor in series with a 5.0-μF capacitor, the two being connected between the terminals of an ac generator. The voltage of the generator is fixed. At what frequency is the current in the circuit one-half the value that exists when the frequency is very large? Note: The ac current and voltage are rms values and power is an average value unless indicated otherwise
The peak value of the current supplied by the generator is approximately 2.07 Amperes.
To determine the peak value of the current supplied by the generator, we can use the relationship between voltage, current, and inductance in an AC circuit.
The peak current (I_peak) can be calculated using the formula:
I_peak = V_rms / (ω * L),
where:
V_rms is the root mean square (RMS) value of the voltage (in this case, 9.0 V),
ω is the angular frequency of the AC signal (in radians per second), and
L is the inductance of the inductor (in henries).
To convert the given frequency (690 Hz) to angular frequency (ω), we can use the formula:
ω = 2πf,
where:
f is the frequency.
Substituting the values into the formula, we have:
ω = 2π * 690 Hz ≈ 4,335.48 rad/s.
Now, let's calculate the peak current:
I_peak = (9.0 V) / (4,335.48 rad/s * 10 × 10^(-3) H).
Simplifying the expression:
I_peak ≈ 2.07 A.
Therefore, the peak value of the current supplied by the generator is approximately 2.07 Amperes.
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Select the correct answer. Why does a solid change to liquid when heat is added? A. The spacing between particles decreases. B. Particles lose energy. C. The spacing between particles increases. D. The temperature decreases.
Answer:
The right answer is c because when we heat solid object the molecule will start lose attraction on object
Explanation:
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Problem mos teple have (2.000 1.00 Listamentum his particle points (A) 20+ 0.20 2008 + 100 (96200 + 2007 D) (0.0208 +0.010729 32. Find the gula momentum of the particle about the origin when its position vector is a (1 508 +1.50pm 2 points) (A) (0.15k)kg-mals (B) (-0.15k)kg-m/s ((1.50k)kg-m/s D) (15.0k)kg-m/s
The correct answer is (A) (0.15k)kg-m/s.
The angular momentum of a particle about the origin is given by:
L = r × p
Where, r is the position vector of the particle, p is the particle's linear momentum, and × is the cross product.
In this case, the position vector is given as:
r = (1.50i + 1.50j) m
The linear momentum of the particle is given as:
p = mv = (1.50 kg)(5.00 m/s) = 7.50 kg m/s
The cross product of r and p can be calculated as follows:
L = r × p = (1.50i + 1.50j) × (7.50k) = 0.15k kg m/s
Therefore, the angular momentum of the particle about the origin is (0.15k) kg m/s. So the answer is (A).
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"Two converging lenses with the same focal length of 10 cm are 40
cm apart. If an object is located 15 cm from one of the lenses,
find the final image distance of the object.
a. 0 cm
b. 5 cm
c. 10 cm
d 15 cm
The final image distance of the object, if the object is located 15 cm from one of the lenses is 6 cm. So none of the options are correct.
To determine the final image distance of the object in the given setup of two converging lenses, we can use the lens formula:
1/f = 1/di - 1/do
Where: f is the focal length of the lens, di is the image distance, do is the object distance.
Given that both lenses have the same focal length of 10 cm, we can consider them as a single lens with an effective focal length of 10 cm. The lenses are 40 cm apart, and the object distance (do) is 15 cm.
Using the lens formula, we can rearrange it to solve for di:
1/di = 1/f + 1/do
1/di = 1/10 cm + 1/15 cm
= (15 + 10) / (10 * 15) cm⁻¹
= 25 / 150 cm⁻¹
= 1 / 6 cm⁻¹
di = 1 / (1 / 6 cm⁻¹) = 6 cm
Therefore, the final image distance of the object is 6 cm. So, none of the options are correct.
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A parallel plate capacitor, in which the space between the plates is empty, has a capacitance of Co= 1.5μF and it is connected to a battery whose voltage is V = 2.7V and fully charged. Once it is fully charged, it is disconnected from the battery and without affecting the charge on the plates, the space between the plates is filled with a dielectric material of = 10.7. How much change occurs in the energy of the capacitor (final energy minus initial energy)? Express your answer in units of mJ (mili joules) using two decimal places.
The change in energy of the capacitor is 51.93 μJ (microjoules), which can be expressed as 0.05193 mJ (millijoules) when rounded to two decimal places.
To calculate the change in energy of the capacitor, we need to find the initial energy and the final energy and then take the difference.
The initial energy of the capacitor can be calculated using the formula E_initial = (1/2)C_oV^2, where C_o is the initial capacitance and V is the voltage. In this case, C_o = 1.5 μF and V = 2.7V. Plugging in these values, we get E_initial = (1/2)(1.5 μF)(2.7V)^2.
So, Initial energy, E_initial = (1/2)C_oV^2
Substituting C_o = 1.5 μF and V = 2.7V:
E_initial = (1/2)(1.5 μF)(2.7V)^2
E_initial = 6.1575 μJ (microjoules)
After the space between the plates is filled with a dielectric material, the capacitance changes. The new capacitance can be calculated using the formula C' = εC_o, where ε is the dielectric constant. In this case, ε = 10.7. Therefore, the new capacitance is C' = 10.7(1.5 μF).
So, New capacitance, C' = εC_o
Substituting ε = 10.7 and C_o = 1.5 μF:
C' = 10.7(1.5 μF)
C' = 16.05 μF
The final energy of the capacitor can be calculated using the formula E_final = (1/2)C'V^2, where C' is the new capacitance and V is the voltage. Plugging in the values, we get E_final = (1/2)(10.7)(1.5 μF)(2.7V)^2.
So, Final energy, E_final = (1/2)C'V^2
Substituting C' = 16.05 μF and V = 2.7V:
E_final = (1/2)(16.05 μF)(2.7V)^2
E_final = 58.0833 μJ (microjoules)
To find the change in energy, we subtract the initial energy from the final energy: ΔE = E_final - E_initial.
Therefore, Change in energy (ΔE):
ΔE = E_final - E_initial
ΔE = 58.0833 μJ - 6.1575 μJ
ΔE = 51.9258 μJ (microjoules)
So, the energy change is 51.9258 μJ or 0.05193 mJ.
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"A 68.0 kg skater moving initially at 3.57 m/s on rough
horizontal ice comes to rest uniformly in 3.99 s due to friction
from the ice.
What force does friction exert on the skater?
The force does friction exert on the skater is 107 N. The magnitude of the frictional force. f = 60.86 N
What is friction?Friction is the force exerted between two objects when they come in contact with each other, which resists motion. The magnitude of the frictional force is determined by the nature of the surfaces in contact and the normal force acting perpendicular to the surfaces.
values are,m = 68.0 kg
u = 3.57 m/s
s = 3.99 s
Formula used: v = u + at
u = initial velocity
v = final velocity
a = acceleration
t = time taken to come to rest
s = distance moved by the object
a = (-u)/t = (-3.57)/3.99
= -0.895 m/s²
This acceleration is considered negative because it acts opposite to the direction of velocity of the object. Here the velocity is in the positive direction and so acceleration is in the negative direction.
Forces acting on the object:
Weight of the object, W = m*g,
where g is acceleration due to gravity = 9.8 m/s²
Normal force acting on the object, N
Frictional force acting on the object, f
Here, f = m × a, according to second law of motion.
f = m × a
= 68.0 × (-0.895)
= -60.86 N
The negative sign indicates that the frictional force acts opposite to the direction of velocity of the object.
Therefore, we must use the magnitude of the frictional force.f = 60.86 N The force does friction exert on the skater is 107 N.
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