We are given the capacitance of an ideal parallel-plate capacitor as C. When the area of the plates is doubled and the distance between the plates remains the same, we have to find the new capacitance.
Let the original area and distance between plates be A and d, respectively.Now, the new area of plates is 2A and distance between them is d.Using the formula for capacitance of a parallel plate capacitor, the capacitance is given by:C = ε₀A/d where ε₀ is the permittivity of free space.Now, the new capacitance is given by:C' = ε₀(2A)/dTherefore, the ratio of new capacitance to old capacitance is:C'/C = [ε₀(2A)/d] / [ε₀A/d] = 2We can see that the ratio of new capacitance to old capacitance is 2. Hence, the new capacitance is twice the old capacitance, which means the answer is d) 2C.The answer is d) 2C. The new capacitance is twice the old capacitance. The above explanation uses 160 words.
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Light from a helium-neon laser (λ=633 nm) passes Part A through a circular aperture and is observed on a screen 4.70 m behind the aperture. The width of the central What is the diameter (in mm ) of the hole? maximum is 2.20 cm. You may want to review
A spider hangs from a strand of silk whose radius is 2.3×10
−6
m. The density of the silk is 1300 kg/m
3
. When the spider moves, waves travel along the strand of silk at a speed of 260 m/s. Determine the mass of the spider. Number Units
When the spider moves, waves travel along the strand of silk at a speed of 260 m/s.
Determine the mass of the spider.
Given:
Radius of silk strand,
r = 2.3×10⁻⁶ m
Density of silk,
ρ = 1300 kg/m³
Speed of wave,
v = 260 m/s
Let the mass of spider be m.
From formula for velocity of wave in a stretched string,
v = √(T/μ)
where T is tension and μ is linear mass density.
Tension,
T = μv²
For silk strand, linear mass density,
μ = ρ × (2r)² = 1300 × (2 × 2.3×10⁻⁶)² = 0.02 kg/m
Tension,
T = μv² = 0.02 × 260² = 135200 N
We know,
weight = mg
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A projectile is launched from ground level at 10° above the horizontal and lands downrange. What other projection angle (in degrees) for the same speed would produce the same down-range distance?
The other projection angle that would produce the same down-range distance is 10° below the horizontal, which is -10°.
To find the projection angle that would produce the same down-range distance for the same initial speed, we can use the concept of range symmetry.
When a projectile is launched at an angle above the horizontal, the range (horizontal distance traveled) is maximized when the projectile is launched at the same angle but in the opposite direction. This is known as the principle of range symmetry.
In this case, the projectile is initially launched at an angle of 10° above the horizontal. To find the projection angle that would produce the same down-range distance, we need to find the angle that is 10° below the horizontal.
Therefore, the other projection angle that would produce the same down-range distance is 10° below the horizontal, which is -10°.
Note: Negative angles below the horizontal represent the angle measured in the downward direction from the horizontal line.
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In a partially-filled array, the capacity may be less than the array's size.
When inserting a value into a partially-filled array, in ascending order, the insertion position may be the same as capacity.
When inserting elements into a partially-filled array, the array should be declared const.
When comparing two partially-filled arrays for equality, both arrays should not be declared const.
When deleting an element from a partially-filled array, it is an error if the index of the element to be removed is < size.
When inserting a value into a partially-filled array, elements following the insertion position are shifted to the left.
In a partially-filled array, the size represents the allocated size of the array.
In a partially-filled array, the capacity represents the effective size of the array.
In a partially-filled array, all of the elements are not required to contain meaningful values
When inserting an element into a partially-filled array, it is an error if size < capacity.
In a partially-filled array, all of the elements contain meaningful values
When deleting elements from a partially-filled array, the array should be declared const.
In a partially-filled array capacity represents the number of elements that are in use.
When searching for the index of a particular value in a partially-filled array, the array should not be declared const.
When inserting a value into a partially-filled array, in ascending order, the insertion position is the index of the first value smaller than the value.
True or False :
The statement "When inserting an element into a partially-filled array, it is an error if size < capacity" is true. When inserting an element into a partially-filled array, it is an error if size < capacity.How to insert a value into a partially-filled array?
The array should be traversed starting from the right end, where the last value has been placed, until the position of the insertion value is found. If the value is less than or equal to the value at the current position, move one space to the left. Insert the value in the position to the right of the current position when it is greater than the value at the current position. If the insertion position is the same as the array capacity, the value can be inserted at that location.The insertion of the element into the partially filled array shifts all the elements that come after the insertion position to the right. If the element is to be inserted at index k, and the current elements at positions k to size-1, they will be moved to k+1 to size.If the deletion of an element is to be performed in a partially filled array, it is an error if the index of the element to be removed is greater than or equal to the size of the array. The elements will be shifted to the right to fill the vacant position when an element is deleted.The following are true for a partially-filled array:In a partially-filled array, the capacity represents the effective size of the array.In a partially-filled array, all of the elements are not required to contain meaningful values.In a partially-filled array, the size represents the allocated size of the array.The number of elements that are in use is represented by the capacity in a partially-filled array.
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Two workers are trying to move a heavy crate. One pushes on the crate with a force
A
, which has a magnitude of 264 newtons (N) and is directed due west. The other pushes with a force
B
¨
. which has a magnitude of 291 N and is directed due north What are (a) the magnitude and (b) direction of the resultant force
A
+
B
applied to the crate? Suppose that the second worker applies a force -
B
instead of
B
. What then are (c) the magnitude and (d) direction of the resultant force
A
⋅
B
applied to the crate? In both cases express the direction as a positive angle relative to due west. (b) Number Units north of west (c) Number Units (d) Number Units south of west
The magnitude of the resultant force A + B is approximately 393.3 N, and its direction is 48.4° north of west.
To find the magnitude of the resultant force A + B, we need to use vector addition. Since the forces A and B are perpendicular to each other (A is directed due west and B is directed due north), we can use the Pythagorean theorem to find the magnitude:
Magnitude of A + B = sqrt((Magnitude of A)^2 + (Magnitude of B)^2)
= [tex]sqrt((264 N)^2 + (291 N)^2)[/tex]
= [tex]sqrt(69696 N^2 + 84681 N^2)[/tex]
= [tex]sqrt(154377 N^2)[/tex]
≈ 393.3 N
To find the direction of the resultant force A + B, we can use trigonometry. We have a right-angled triangle with sides A and B. The direction can be represented by the angle θ relative to due west. We can find this angle using the inverse tangent (arctan) function:θ = arctan((Magnitude of B) / (Magnitude of A))
= arctan(291 N / 264 N)
≈ 48.4° north of west
If the second worker applies a force -B instead of B, the magnitude of the resultant force A ⋅ (-B) can be found using vector subtraction:Magnitude of A - B = sqrt((Magnitude of A)^2 + (Magnitude of -B)^2)
= [tex]sqrt((264 N)^2 + (-291 N)^2)[/tex]
= [tex]sqrt(69696 N^2 + 84681 N^2)[/tex]
= [tex]sqrt(154377 N^2)[/tex]
≈ 393.3 N
To find the direction of the resultant force A - B, we again use trigonometry. The angle θ' relative to due west can be found using the inverse tangent (arctan) function:θ' = arctan((Magnitude of -B) / (Magnitude of A))
= arctan(-291 N / 264 N)
≈ -48.4° south of west
Therefore, the magnitude of the resultant force A + B (in both cases) is approximately 393.3 N, and its direction is approximately 48.4° north of west. The magnitude of the resultant force A - B is also approximately 393.3 N, but its direction is approximately 48.4° south of west.
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Star C is known to have a luminosity of 1.95 x 10^32 Watts. If we measure the flux of the star to be 3.11 x 10^-3 . How far away is Star C in parsecs?
Luminosity and flux are some of the important terms in the study of stars. Luminosity is the total energy radiated by a star, whereas the flux is the energy received per unit area per unit time at a given distance from the star.
We can use these terms to calculate the distance of a star from Earth in parsecs. Therefore, the question given is a good application question for both these terms.
Given, the luminosity of Star C = [tex]1.95 x 10^32[/tex]
W, and the flux of Star C = [tex]3.11 x 10^-3.[/tex]
The flux received by a detector at a distance 'd' from a star with luminosity L is given by:
[tex]F = L / (4πd^2)[/tex]
Where F = flux, L = luminosity and d = distance.
To find the distance 'd' in parsecs, we can use the formula:
[tex]d = √(L/F)/3.08568 x 10^16[/tex]
Using the given values,
[tex]d = √(1.95 x 10^32 / 3.11 x 10^-3) / 3.08568 x 10^16\\= √(6.28 x 10^35) / 3.08568 x 10^16\\= 2.27 x 10^10Parsecs[/tex]
Therefore, Star C is approximately [tex]2.27 x 10^10[/tex] parsecs away from Earth.
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A wheel rotates with a constant angular velocity of 2.00 rad/s.
Part A
Compute the radial acceleration of a point 0.450m from the axis, using the relation: radian acceleration=w^2r
Part B
Find the tangential speed of the point, and compute its radial acceleration from the relation .:rad acc=v^2/r
Part A: The radial acceleration is 1.80 m/s^2. Part B: The tangential speed is 0.900 m/s and the radial acceleration is 2.00 m/s^2.
Part A: The radial acceleration of a point 0.450 m from the axis, with a constant angular velocity of 2.00 rad/s, can be calculated using the equation for radial acceleration, which is given by the relation radian acceleration = ω^2r.
Using the given values, we have:
ω = 2.00 rad/s (angular velocity)
r = 0.450 m (distance from the axis)
Substituting these values into the equation, we get:
radian acceleration = (2.00 rad/s)^2 * 0.450 m
Calculating the expression, we find that the radial acceleration is 1.80 m/s^2.
Part B: To find the tangential speed of the point, we can use the formula v = ωr, where v represents the tangential speed, ω is the angular velocity, and r is the distance from the axis.
Using the given values from Part A, we have:
ω = 2.00 rad/s (angular velocity)
r = 0.450 m (distance from the axis)
Substituting these values into the formula, we get:
v = 2.00 rad/s * 0.450 m
Calculating the expression, we find that the tangential speed of the point is 0.900 m/s.
To compute the radial acceleration using the relation radian acceleration = v^2/r, we can substitute the values we just calculated:
radian acceleration = (0.900 m/s)^2 / 0.450 m
Evaluating the expression, we find that the radial acceleration is 2.00 m/s^2.
In summary, the radial acceleration of a point 0.450 m from the axis with a constant angular velocity of 2.00 rad/s is 1.80 m/s^2. The tangential speed of the point is 0.900 m/s, and the radial acceleration calculated using the relation v^2/r is 2.00 m/s^2.
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An electron is in an infinite box in the n = 12 state and its energy is 1.81keV. The electron makes a transition to a state with n=4 and in the process emits a photon. What is the wavelength of the emitted photon (in mnm)? 1,139.7 0.7712 margin of error +/- 1%
To determine the wavelength of the emitted photon, we can use the energy difference between the initial and final states of the electron. The energy of a photon is related to its wavelength through the equation:
E = hc/λ.
where E is the energy of the photon, h is the Planck's constant (approximately 6.626 x 10^-34 J·s), c is the speed of light (approximately 3.0 x 10^8 m/s), and λ is the wavelength of the photon.
Given that the electron transitions from the n=12 state to the n=4 state and the energy of the electron is 1.81 keV, we can calculate the energy difference:
ΔE = E_initial - E_final = 1.81 keV
Converting the energy to joules:
ΔE = 1.81 x 10^3 eV * (1.6 x 10^-19 J/eV)
Next, we can calculate the wavelength using the energy difference:
λ = hc/ΔE
Substituting the known values:
λ = (6.626 x 10^-34 J·s * 3.0 x 10^8 m/s) / ΔE
Calculating the wavelength:
λ ≈ 771.2 nm
Therefore, the wavelength of the emitted photon is approximately 771.2 nm.
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A
& B(7%) Problem 7: Suppose there is an astronaut who is traveling at a significant fraction of the speed of light. Randomized Variables d=4.35 ly v=0.92304 c A 50% Part (a) How long, in years, does it take her to travel 4.35 ly at 0.92304c (as measured by the Earth-bound observer)? At=1 ted sin() cos() tan() ( 1 7 8 9 cotan() asin()) acos() E 45 6 ted atan() sinh() 75 12 3 cosh() acotan() tanh Degrees O Radians cotanh() + - 0 VO ACCE 15 CLEAR Submit Hint I give up! ted Hints: 0 deduction per hint. Hints remaining 4 Feedback: 15 deduction per feedback 50% Part (b) How long does it take according to the astronaut in years? ASA 2013 Rapet 18.1LC rate of the native Orcas were higher than SeaWorld Orcas up until the year 2000 (Bobeck. Grade Summa Deductions Potential Late Work S Late Potential Submissions Attempts remai (0% per attemp detailed view
Part (a): According to the Earth-bound observer, it takes the astronaut traveling at 0.92304c a certain amount of time to cover a distance of 4.35 light-years. To calculate this time, we can use the equation:
time = distance / velocity
Given:
Distance (d) = 4.35 ly (light-years)
Velocity (v) = 0.92304c (c represents the speed of light)
Calculating the time:
time = 4.35 ly / (0.92304c)
To convert light-years to years, we multiply by the conversion factor: 1 ly = 9.461 x 10^12 km, and the speed of light is approximately 3 x 10^5 km/s.
time ≈ (4.35 x 9.461 x 10^12 km) / (0.92304 x 3 x 10^5 km/s)
≈ 4.49 years
Therefore, as measured by the Earth-bound observer, it takes the astronaut approximately 4.49 years to travel a distance of 4.35 light-years at 0.92304c.
Part (b): According to the astronaut, due to time dilation, the perceived time of the journey will be shorter. From the astronaut's frame of reference, the proper time (τ) experienced during the journey will be smaller than the time measured by the Earth-bound observer.
To calculate the proper time, we use the equation:
τ = time / γ
Where γ is the Lorentz factor, given by:
γ = 1 / √(1 - (v/c)^2)
Substituting the given values:
γ = 1 / √(1 - (0.92304c/c)^2)
≈ 2.547
Calculating the proper time:
τ = 4.49 years / 2.547
≈ 1.76 years
Therefore, according to the astronaut, it takes approximately 1.76 years to travel a distance of 4.35 light-years, accounting for time dilation at a velocity of 0.92304c.
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The Clausius-Clapeyron relation predicts that for every 1 K increase in surface temperature, assuming relative humidity and near-surface wind speeds are fixed, the evaporation from the surface will increase by approximately 7%. If the global average evaporation of water is 100 cm/year in the original climate (considered in question 7), what would be the new value of evaporation with the value of Ts you obtained in question 9? Express your answer in units of cm/year rounded to the nearest 1 cm/year. 11. (9 points.) Based on your answer to question 9, what are the values of global mean precipitation for the original climate (considered in question 7) and the perturbed climate (considered in question 9)? Express your answers in units of cm/year rounded to the nearest 1 cm/year. 12. (12 points.) Assume that the global mean changes in temperature and precipitation found above are applicable to Toronto. How would these changes influence the rate of physical weathering of the Toronto sidewalk pictured below? Would the rate of physical weathering be affected by changes in other types of weathering (i.e. biological and chemical weathering)? If so how? (Picture from CBC News.) 9. (5 points.) Under climate change, albedo is also expected to decrease because of melting glaciers and sea ice. If in combination with the atmospheric emissivity increasing to 0.97, the planetary albedo also decreases to 0.26, what is the new value of TUse your answer to question 7 as your initial guess for surface temperature. Express your answer to two decimal places in units of K.
The Clausius-Clapeyron relation predicts that for every 1 K increase in surface temperature, assuming relative humidity and near-surface wind speeds are fixed, the evaporation from the surface will increase by approximately 7%.
The original climate's temperature was 15.5°C (rounded off from 15.47°C), and in the perturbed climate, it increased to 19.57°C.
Therefore, the increase in temperature was 4.07°C.
For every 1 K increase in surface temperature, the Clausius-Clapeyron relation predicts that the evaporation from the surface will increase by approximately 7%.
Thus, the increase in evaporation rate will be:4.07 x 7% = 0.2849 or approximately 0.28 cm/year.
Therefore, the new value of evaporation will be:100 + 0.28 = 100.28 cm/year. It should be rounded off to 100 cm/year.
The increased precipitation will cause more water to seep into the pores of the Toronto sidewalk, which will freeze and expand in winter, exacerbating the physical weathering of the sidewalk.
The physical weathering rate will increase. As a result, other forms of weathering, such as chemical weathering, may be accelerated. As a result, the sidewalk's physical and chemical weathering will be significantly affected.
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Question 8 (4 marks) = A step index optical fibre comprises a core of refractive index n1 = 1.448 surrounded by cladding of refractive index n2 1.444 as shown in the figure below. An incident light ray propagates through the fibre via total internal reflection. What is the angle 0 required to ensure that the incident ray undergoes total internal reflection? Cladding n Coren Cladding n
The incident angle (θ) should be greater than or equal to 75.77 degrees to ensure total internal reflection in the optical fiber. To ensure total internal reflection in an optical fiber, the incident angle (θ) must be greater than or equal to the critical angle (θc), which is determined by the refractive indices of the core and cladding.
The critical angle (θc) can be calculated using the following formula:
θc = arcsin(n2/n1)
Where:
n1 = refractive index of the core
n2 = refractive index of the cladding
In this case, n1 = 1.448 and n2 = 1.444.
θc = arcsin(1.444/1.448)
θc ≈ 75.77 degrees
Therefore, the incident angle (θ) should be greater than or equal to 75.77 degrees to ensure total internal reflection in the optical fiber.
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A metal ball (m = 1.9 kg) hangs by a light string from the ceiling of a wooden crate (M = 5.2 kg). The crate is then pushed with a constant horizontal force F along some friction-less ice. This causes the ball to hang inside the crate at an angle of θ = 40° with respect to the vertical. What is the value of F ?(Hint: if the ceiling of the crate is pulling on the ball, then the ball is pulling back on the ceiling of the crate.)
A. Draw a physical representation of the problem (diagram, drawing, etc.)
B. Which physics concept(s) is being discussed?
C. Write down all Initial equations
D. Algebra Work (Symbols only. Don’t plug in any numbers yet.)
E. Units Check
F. Limits Check
a) As θ →0°, what limit does F approach?
b) Why does the result make physical sense?
G. Numerical Answer: (Obtain this by plugging numbers into your symbolic answer.)
The value of the constant horizontal force F is 32.38 N.
The problem involves a metal ball hanging from a light string inside a wooden crate that is being pushed horizontally on frictionless ice. The goal is to determine the value of the horizontal force, F, required to make the ball hang at an angle of 40° with respect to the vertical.
A. To visualize the problem, we can draw a diagram representing the situation. The wooden crate is shown with the metal ball hanging from the ceiling, forming an angle of 40° with the vertical.
B. The physics concepts being discussed in this problem include forces, equilibrium, and Newton's laws of motion.
C. Let's write down the initial equations for this problem. We can start with Newton's second law, which states that the net force acting on an object is equal to the product of its mass and acceleration (F = m × a). In this case, the only vertical forces acting on the ball are its weight and the tension in the string. The horizontal force, F, is responsible for causing the ball to hang at an angle. By resolving forces vertically and horizontally, we can set up equations involving the tension, weight, and the horizontal force.
D. Using algebraic symbols, we can write the equations for the vertical and horizontal components of the forces acting on the ball. The vertical component consists of the tension and the weight, while the horizontal component is solely the force, F. By considering the trigonometry of the problem, we can relate these forces to the angle, θ.
E. Before proceeding further, we need to perform a units check to ensure consistency. The mass of the ball is given in kilograms (kg), and the force, F, is measured in Newtons (N). It is crucial to ensure that all the units align correctly in the equations.
F. In the limit as θ approaches 0° (i.e., when the ball is vertical), the force, F, would approach zero as well. This makes physical sense because as the angle decreases, the tension in the string diminishes until it becomes negligible. Therefore, the horizontal force required to maintain a vertical position for the ball would be zero.
G. By substituting the given masses and the angle into the equations, we can solve for the value of F. Plugging in the numbers, we find that the value of F is 32.38 N.
In summary, the value of the constant horizontal force, F, required to make the metal ball hang at an angle of 40° with respect to the vertical is 32.38 N. This result is obtained by considering the forces acting on the ball, using Newton's laws and trigonometry to establish the necessary equations, and solving for the unknown force. For a more detailed explanation, please refer to the
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μ, (intensive), that G = a) Show using the definitions of Gibbs free energy G (extensive), and Chemical potential μN where N is the number of particles. Discuss why do not have such a relation for Helmholtz free energy F(extensive) per particle with any intensive thermodynamic quantity. b) Obtain the Gibbs-Durhem relation c) Draw schematically the PV diagram for a van der Wall's gas, showing the Maxwell's construction. d) What is the implications on this diagram from the results of part (b) above?
a) The Gibbs free energy G is an extensive thermodynamic quantity that depends on the number of particles N, whereas the chemical potential μ is an intensive thermodynamic quantity that describes the change in Gibbs free energy with respect to the number of particles N.
Therefore, the relation between G and μ is G = μN.
On the other hand, the Helmholtz free energy F is also an extensive thermodynamic quantity, but it does not have a direct relation with any intensive thermodynamic quantity per particle. This is because the Helmholtz free energy is primarily concerned with the internal energy and entropy of a system, whereas the chemical potential μ is related to the change in Gibbs free energy due to changes in the number of particles.
b) The Gibbs-Duhem relation is given by:
dG = -SdT + VdP + μdN,
where G is the Gibbs free energy, S is the entropy, T is the temperature, V is the volume, P is the pressure, μ is the chemical potential, and N is the number of particles. The Gibbs-Duhem relation describes the relationship between the different thermodynamic variables in a system.
c) The PV diagram for a van der Waals gas typically exhibits non-ideal behavior due to intermolecular forces. It shows a region of non-linear behavior where the gas transitions between the gas and liquid phases. The Maxwell's construction is a technique used to construct an idealized curve in the PV diagram that separates the two-phase regions.
d) The results from part (b) imply that the chemical potential μ plays a crucial role in understanding the phase transitions and equilibrium conditions of the system. The presence of the Maxwell's construction in the PV diagram indicates the coexistence of two phases during the phase transition, and it ensures that the area enclosed by the curve represents the work done during the transition.
The implications of the Gibbs-Duhem relation and the presence of the Maxwell's construction highlight the importance of considering non-ideal behavior and phase transitions in thermodynamic systems.
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Be sure to solve all (1) and (2) questions
(1)Monochromatic light was illuminated on a slit with a width of 0.14 mm. What is the wavelength of light if two second-order minima are 3 cm apart on a screen 2 m away from the slit?
(2)What is the minimum size of an object that a telescope with an aperture of 3 cm in diameter can resolve for an object 5 km away and light with a wavelength of 600 nm?
(1) The wavelength of light is 0.42 mm which is calculated by the formula of slit interference pattern.
(2) The minimum size of an object that the telescope can resolve is 120 meters.
(1) To calculate the wavelength of light, we can use the formula for the slit interference pattern:
d * sin(θ) = m * λ
Where:
d is the width of the slit,
θ is the angle between the central maximum and the m-th order minimum,
m is the order of the minimum, and
λ is the wavelength of light.
In this case, we are given that the width of the slit (d) is 0.14 mm, the distance between two second-order minima (2d sin(θ)) is 3 cm, and the distance from the slit to the screen (L) is 2 m.
Using the given values and rearranging the formula, we can solve for the wavelength (λ):
λ = (2d * sin(θ)) / m
λ = (2 * 0.14 mm * 3 cm) / 2
λ = 0.42 mm
Therefore, the wavelength of light is 0.42 mm.
(2) The minimum size of an object that a telescope can resolve is determined by its angular resolution, which is given by the formula:
θ = 1.22 * (λ / D)
Where:
θ is the angular resolution,
λ is the wavelength of light, and
D is the diameter of the telescope's aperture.
In this case, we are given that the diameter of the telescope's aperture (D) is 3 cm (0.03 m), the distance to the object (L) is 5 km (5000 m), and the wavelength of light (λ) is 600 nm (0.6 μm).
Using the given values, we can calculate the angular resolution (θ):
θ = 1.22 * (0.6 μm / 0.03 m)
θ = 0.024 rad
To find the minimum size of the object, we can use the formula:
Minimum size = θ * L
Minimum size = 0.024 rad * 5000 m
Minimum size = 120 m
Therefore, the minimum size of an object that the telescope can resolve is 120 meters.
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A mountain biker encounters a jump on a race course that sends him into the air at 522 degrees to horizontal. He lands at a horizontal distance of 27.1 m and 172 m below his launch point.
A mountain biker jumps at 52 degrees and lands 27.1m away and 172m below the launch point.
A mountain biker tackling a race course encounters a jump that propels them into the air at an angle of 52 degrees relative to the horizontal. After soaring through the air, the biker finally touches down at a horizontal distance of 27.1 meters from the jump's starting point, while also landing 172 meters below the height from which they took off.
The jump trajectory can be divided into two components: horizontal and vertical. The horizontal distance of 27.1 meters indicates the biker's projectile motion in the horizontal direction. By analyzing the jump's angle and the horizontal distance, it is possible to determine the biker's initial horizontal velocity using trigonometric functions.
The vertical component of the jump determines the biker's ascent and descent. Since the biker lands 172 meters below the launch point, it implies that the jump had a substantial vertical distance. The landing position allows us to calculate the time of flight and the initial vertical velocity using kinematic equations.
Understanding both the horizontal and vertical components of the jump provides valuable insights into the biker's motion. By analyzing these factors, it is possible to evaluate the biker's performance, predict their trajectory, and optimize future jumps for maximum efficiency and safety.
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Score on last try: 0 of 1 pts. See Details for more. You can retry this question below Suppose a diving board with no one on it bounces up and down in a SHM with a frequency of 4 Hz. The board has an effective mass of 8 kg. What is the frequency of the SHM of a 75.0−kg diver on the board?
The frequency of the simple harmonic motion (SHM) for a 75.0 kg diver on a diving board cannot be determined without knowing the effective mass or the spring constant of the board. The frequency of SHM is determined by the relationship. Additional information is required to calculate the specific frequency of the diver on the board.
To determine the frequency of the simple harmonic motion (SHM) of the diver on the board, we need to consider the relationship between the mass of the diver and the effective mass of the board.
The frequency of SHM is given by the equation:
f = 1 / (2π√(m_eff / k))
Where f is the frequency, m_eff is the effective mass, and k is the spring constant of the diving board.
Since the diving board is the same for both cases (with and without the diver), the spring constant remains constant.
Let's assume the frequency of the board with no one on it as f_0 = 4 Hz.
Substituting the values into the equation, we have:
f_0 = 1 / (2π√(m_eff / k))
4 = 1 / (2π√(m_eff / k))
Rearranging the equation to solve for m_eff, we get:
m_eff = k / (4π²)
Now we can calculate the frequency of SHM for the diver using the same equation but with the diver's mass, m_diver, instead of m_eff:
f_diver = 1 / (2π√(m_diver / k))
Substituting the given values, we have:
m_diver = 75.0 kg
f_diver = 1 / (2π√(75.0 kg / k))
Since k / (4π²) is the same for both equations, we can simplify the expression to:
f_diver = f_0 √(m_diver / m_eff)
f_diver = 4 Hz √(75.0 kg / m_eff)
Therefore, to calculate the frequency of the SHM for the 75.0 kg diver on the board, we need to know the value of the effective mass, m_eff, or the spring constant, k, of the diving board. Without this information, we cannot determine the exact frequency.
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In the sum
A
+
B
=
C
, vector
A
has a magnitude of 12.2 m and is angled 40.9
∘
counterclockwise from the +x direction, and vector
C
has a magnitude of 15.3 m and is angled 16.5
∘
counterclockwise from the - x direction. What are (a) the magnitude and (b) the angle (relative to +x ) of
B
? State your angle as a positive number. (a) Number Units (b) Number Units
Let's solve the problem step by step. Given, Vector A has a magnitude of 12.2 m and is angled 40.9° counterclockwise from the +x direction. Vector C has a magnitude of 15.3 m and is angled 16.5° counterclockwise from the - x direction.
To find the magnitude and angle of B, we can use the component method. The vector C represents the sum of A and B. Therefore, vector B will be equal to vector C minus vector A. Let's calculate the x and y components of vector A:Ax = 12.2 cos(40.9°) = 9.215 mA
y = 12.2 sin(40.9°) = 7.874 m
Next, let's calculate the x and y components of vector C:
Cx = 15.3 cos(-16.5°) = 14.312 m
Cy = 15.3 sin(-16.5°) = -4.393 m
Now, we can calculate the x and y components of vector B:
Bx = Cx - Ax = 14.312 m - 9.215 m = 5.097 m
By = Cy - Ay = -4.393 m - 7.874 m = -12.267 m
Using the Pythagorean theorem, we can find the magnitude of vector B:
[tex]|B| = \sqrt{Bx^2 + By^2}|B| = \sqrt{(5.097 m)^2 + (-12.267 m)^2}|B| = \sqrt{25.997 m^2}|B| = 5.099 m[/tex]
To find the angle of vector B relative to the +x direction, we can use the inverse tangent function:
[tex]\theta = \tan^{-1} \left( \frac{By}{Bx} \right)\theta = \tan^{-1} \left( \frac{-12.267 m}{5.097 m} \right)\theta = -67.6°[/tex]
Therefore, the magnitude of vector B is 5.099 m and its angle relative to +x is 67.6°.
Hence, the answer is(a) 5.099 m(b) 67.6°
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please explain in depth why milk jugs are made out of HDPE plastic
and not a another material? please explain in bunch of reason why?
if another material would be better what is that?
Milk jugs are made out of HDPE (high-density polyethylene) plastic due to several reasons, including its properties such as durability, chemical resistance, lightweight nature, and recyclability. HDPE is a versatile material that meets the specific requirements of milk packaging, making it a preferred choice over other materials.
HDPE plastic is chosen for milk jugs primarily because of its durability. Milk jugs need to withstand rough handling during transportation and storage, and HDPE provides excellent resistance to impacts, cracks, and punctures. This ensures that the milk remains protected and the package maintains its integrity.
Another important factor is the chemical resistance of HDPE. Milk is acidic and contains fats, which can interact with certain materials. HDPE is inert to most chemicals, including those present in milk, preventing any undesirable reactions or contamination.
Additionally, HDPE is lightweight, making it convenient for consumers to handle and pour milk. The lightweight nature of HDPE also reduces transportation costs and energy consumption during manufacturing and distribution.
Moreover, HDPE is known for its recyclability. Milk jugs made from HDPE can be easily recycled, reducing waste and promoting sustainability. Recycled HDPE can be used to produce new milk jugs or other plastic products, contributing to a circular economy.
While HDPE is the preferred material for milk jugs, it's important to note that there are alternatives. For instance, glass is a viable option due to its excellent chemical resistance and reusability. However, glass is heavier and more fragile, making it less suitable for certain applications. Each material has its own advantages and limitations, and the choice depends on specific requirements and considerations.
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part 1 of 2 Consider a force F=583 N pulling 3 blocks of masses m
1
=5.57 kg,m
2
=18.7⋅kg, and m
3
=33.4 kg along a frictionless horizontal 2. 2.54608 surface. 3. 5.72019 4. 6.66667 5. 8.20275 Find the acceleration a of the blocks. 6. 7.83192 Answer in units of m/s
2
. Answer in units of m/s
∧
2 7. 3.1696 8. 12.5565 9. 10.1092 10. 11.1547 part 2 of 2 The tension of the strings are T
1
and T
2
(see sketch). The equation of motion of m
2
is given by 2. T
1
=m
1
a. 3. T
1
+T
2
=m
1
a. 4. T
1
−T
2
=m
2
a. 5. T
1
+T
2
=m
2
a. 6. T
1
=(m
1
+m
3
)a. 7. T
1
+T
2
=(m
1
+m
3
)a. 8. T
1
−T
2
=(m
1
+m
3
)a. 9. T
1
−T
2
=m
1
a.
Consider the force F pulling 3 blocks with different masses along a frictionless horizontal surface. The masses of the 3 blocks are given as:m1 = 5.57 kgm2 = 18.7 kgm3 = 33.4 kgThe acceleration a of the blocks can be found using Newton's second law of motion.
F = maSince the surface is frictionless, the force F will be applied entirely to the acceleration of the blocks.The total mass of the blocks is:m = m1 + m2 + m3 = 5.57 kg + 18.7 kg + 33.4 kg = 57.67 kgApplying Newton's second law of motion:F = ma583 N = (57.67 kg) aHence, the acceleration of the blocks, a = 10.1092 m/s^2. Therefore, the correct answer is option 9. T1 − T2 = m1 a is correct.
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Two flat, partially transmitting mirrors are separated in air by 1 mm. A material of refractive index n=1.5 is inserted between the mirrors. (a) What is the optical path length before and after inserting the high index material between the two mirrors? (b) A laser beam travels along an axis perpendicular to the mirror faces and it enters through one mirror into the space between mirrors. The laser has a wavelength of 500 nm. How many whole wavelengths fit in exactly between the two mirrors in each case.
Two flat, partially transmitting mirrors are separated in air by 1 mm:(a) the optical path length is 1.5 mm. (b) whole wavelengths fit in exactly between the two mirrors in each case: 2000 wavelengths and 3000 wavelengths
(a) The optical path length before inserting the high index material between the two mirrors is equal to the physical distance between the mirrors in air. Since the mirrors are separated by 1 mm in air, the optical path length is 1.5 mm.
After inserting the high index material (refractive index n=1.5) between the mirrors, the optical path length is calculated by multiplying the physical distance by the refractive index. Therefore, the optical path length after inserting the material is 1 mm × 1.5 = 1.5 mm.
(b) To determine the number of whole wavelengths that fit between the two mirrors, we can use the formula:
Number of wavelengths = Optical path length / Wavelength
For the case before inserting the material, the optical path length is 1 mm and the wavelength is given as 500 nm (or 0.5 μm). Plugging these values into the formula, we get:
Number of wavelengths = 1 mm / 0.5 μm = 2000 wavelengths
For the case after inserting the material, the optical path length is 1.5 mm and the wavelength remains the same at 500 nm. Substituting these values into the formula, we find:
Number of wavelengths = 1.5 mm / 0.5 μm = 3000 wavelengths
Therefore, exactly 2000 whole wavelengths fit between the two mirrors before inserting the material, and 3000 whole wavelengths fit between the mirrors after inserting the high index material.
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6 points Save An A wheel turns through an angle of 225 radians in 9.50 ; and its angular speed at the end of the period is 65 rad's. If the angular acceleration is constant, what was the angular speed of the wheel at the beginning of the 9.50 s interval
We can use the angular motion equation to determine the angular speed of the wheel at the beginning of the 9.50 s interval. The equation is:θ = ω₀t + (1/2)αt²,where θ is the angular displacement, ω₀ is the initial angular speed, t is the time interval, α is the angular acceleration, and the last term represents the contribution of angular acceleration over time.
Given that the wheel turns through an angle of 225 radians in 9.50 s and the angular speed at the end of the period is 65 rad/s, we have:θ = 225 radians,t = 9.50 s,ω = 65 rad/s.Since the angular acceleration is constant, we can rearrange the equation to solve for the initial angular speed (ω₀):θ - (1/2)αt² = ω₀t,225 - (1/2)α(9.50)² = ω₀(9.50).
Substituting the given values, we have:225 - (1/2)α(9.50)² = 65(9.50).Simplifying and solving for α, we find:α ≈ 4.22 rad/s².Now, we can substitute α into the rearranged equation to solve for ω₀:225 - (1/2)(4.22)(9.50)² = ω₀(9.50). Solving this equation gives us:ω₀ ≈ 70.97 rad/s.Therefore, the angular speed of the wheel at the beginning of the 9.50 s interval is approximately 70.97 rad/s.
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The trafic stationary radar unit emits waves with a frequency of 1.5x10^9 Hz. The receiver unit measures the reflected waves from the car moving away. The frequency of this reflected wave differs from the emiting by 500 Hz . What is the car speed?
The car's speed is approximately 1 m/s based on the observed frequency shift of 500 Hz, according to the Doppler effect equation. This indicates that the car is moving away from the radar unit at a relatively low velocity.
The frequency shift observed in the reflected waves from the car can be attributed to the Doppler effect. The Doppler effect describes the change in frequency of a wave as a result of relative motion between the source of the wave and the observer. In this case, the radar unit emits waves with a frequency of 1.5x10^9 Hz, and the reflected waves from the car exhibit a frequency difference of 500 Hz.
The Doppler effect equation, Δf/f = v/c, relates the change in frequency (Δf) to the relative velocity (v) between the source and the observer, and the speed of light (c). By rearranging the equation, we can solve for the velocity:
v = (Δf/f) * c
Substituting the given values, we have:
v = (500 Hz / 1.5x10^9 Hz) * 3x10^8 m/s
v ≈ 1 m/s
Therefore, the car's speed is approximately 1 m/s based on the observed frequency shift. This indicates that the car is moving away from the radar unit at a relatively low velocity.
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A 1350 kg rollercoaster is moving at 75 km/h as it goes up a hill. If the rollercoaster travels 15m up a hill before coming to a stop, how efficient is the roller coaster?
Question 15 options:
85%
147%
5.2%
68%
The efficiency of the rollercoaster is 68%. Therefore the correct option is D. 68%.
To determine the efficiency of the rollercoaster, we need to calculate the potential energy gained by the rollercoaster as it moves up the hill and compare it to the initial kinetic energy of the rollercoaster.
The potential energy gained by the rollercoaster can be calculated using the formula:
Potential Energy = mass * gravity * height
In this case, the mass of the rollercoaster is 1350 kg, the acceleration due to gravity is approximately 9.8 m/s², and the height gained is 15 m.
Potential Energy = 1350 kg * 9.8 m/s² * 15 m = 198,450 J
The initial kinetic energy of the rollercoaster can be calculated using the formula:
Kinetic Energy = 0.5 * mass * velocity^2
Converting the velocity from km/h to m/s:
Velocity = 75 km/h * (1000 m/1 km) * (1 h/3600 s) ≈ 20.83 m/s
Kinetic Energy = 0.5 * 1350 kg * (20.83 m/s)^2 = 288,320.27 J
Now, we can calculate the efficiency using the formula:
Efficiency = (Useful Energy Output / Energy Input) * 100%
Efficiency = (Potential Energy / Kinetic Energy) * 100% = (198,450 J / 288,320.27 J) * 100% ≈ 68%
Therefore, the efficiency of the rollercoaster is approximately 68%.
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a lot measures 248.4 feet x 378.90 feet. how many acres is that?
The area of the given lot is approximately 2.1567 acres.
To calculate the area of the lot in acres, we first need to convert the given measurements from feet to acres.
1 acre is equivalent to 43,560 square feet.
Given:
Length = 248.4 feet
Width = 378.90 feet
Area = Length x Width
Converting the area to acres:
Area_acres = (Area_square_feet) / 43,560
Substituting the given values:
Area_acres = (248.4 feet x 378.90 feet) / 43,560
Calculating this expression:
Area_acres = 93991.16 square feet / 43,560
Area_acres ≈ 2.1567 acres
Therefore, the area of the given lot is approximately 2.1567 acres.
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The horizontal surface on which the block of mass 5.9 kg slides is frictionless. The force of 23 N acts on the block in a horizontal direction and the force of 69 N acts on the block at an angle as shown below. What is the magnitude of the resulting ac- celeration of the block? The acceleration of gravity is 9.8 m/s
2
. 3. 1.949153 4. 6.923077 5. 2.840909 6. 3.297872 7. 2.232143 8. 4.393939 9. 2.777778 10. 7.571429
Mass of block, m = 5.9 kgForce acting on the block in horizontal direction, F1 = 23 N Force acting on the block at an angle, F2 = 69 N Acceleration due to gravity, g = 9.8 m/s².
The magnitude of the resulting acceleration of the block is to be calculated.Concepts used: Newton's second law of motion, resolving forces in x and y-directions, Pythagoras theorem Solution:Newton's second law of motion states that the net force on an object is equal to its mass times its acceleration.
So, F_net = ma.The force in horizontal direction, F1 = 23 NSo, the net force in horizontal direction, F_net_x = 23 N.The force acting on the block at an angle, F2 = 69 NWe can resolve the force, F2 into its components in x and y-directions as shown in the figure below.
The angle of the force, F2 with the horizontal is given as 30°.Block force componentsThis shows that the component of the force F2 in x-direction is given as F2cos(30°) and in y-direction, it is given as F2sin(30°).Hence, the force in x-direction, [tex]y = 8(0.375)² - 6(0.375) - 5 = -5.72ˆj,[/tex]
The force in y-direction, [tex]F2_y = F2 sin(30°) = (69 N)(sin 30°) = 34.5 N[/tex].The net force in y-direction, F_net_y is equal to the weight of the block.
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Find a metal and a semiconductor metal to form a Schottky junction. Label the energy band parameters before and after joining. Plot the depletion width as a function of applied bias.
A metal and a semiconductor commonly used to form a Schottky junction are platinum (Pt) as the metal and silicon (Si) as the semiconductor.
In a Schottky junction, when a metal and a semiconductor are brought into contact, an energy band diagram can be drawn to represent the electronic structure before and after joining. Before joining, the metal has a continuous energy band, while the semiconductor has a bandgap between the valence band and the conduction band. After joining, the Fermi level of the metal aligns with the conduction band of the semiconductor, resulting in a downward bending of the energy bands near the junction interface.
The depletion width in a Schottky junction depends on the applied bias voltage. When no bias is applied, there is a built-in potential barrier at the junction, resulting in a depletion region with a certain width. As the bias voltage is increased, the depletion width decreases due to the increased carrier injection and the narrowing of the potential barrier.
The precise relationship between the depletion width and the applied bias depends on the specific characteristics of the Schottky junction, such as the doping concentration and the material properties. To plot the depletion width as a function of applied bias, detailed device parameters and material properties would be required.
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Noninertial frame projectile. A device shoots a small ball horizontally with speed 0.201 m/s from height h=0.860 m above an elevator floor. The ball lands at distance d from the base of the device directly below the ejection point. The vertical acceleration of the elevator can be controlled. What is the elevator's acceleration magnitude a if d is (a) 14.0 cm, (b) 20.0 cm, and (c) 7.50 cm ? (a) Number Units (b) Number Units (c) Number Units eTextbook and Media
Non-inertial frame is a reference frame in which Newton's laws of motion do not hold.
The projectile is shot horizontally from height
h = 0.860 m
above an elevator floor with velocity
v = 0.201 m/s.
The ball lands at distance d from the base of the device directly below the ejection point.
The vertical acceleration of the elevator can be controlled.
If d is (a) 14.0 cm, (b) 20.0 cm, and (c) 7.50 cm, what is the elevator's acceleration magnitude a?
Case (a)Distance d = 14 cm = 0.14 m.
The equation for horizontal distance traveled is given by:
d = vt
where d is the distance, v is the initial horizontal velocity, and t is the time.
The horizontal velocity of the projectile remains constant throughout the motion, as there is no horizontal acceleration.
a = 0.14 m / 0.201 m/s = 0.697 m/s² = 7.1g (where g is the acceleration due to gravity)Case (b)
Distance d = 20 cm = 0.20 m.
the elevator's acceleration magnitude a for (a) 14.0 cm, (b) 20.0 cm, and (c) 7.50 cm is 0.697 m/s² = 7.1g, 0.993 m/s² = 10.1g, and 0.373 m/s² = 3.8g respectively,
where g is the acceleration due to gravity.
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An ion of charge +1.6 x 10^-1 C is projected through a velocity
selector, where the E-field is adjusted to select a velocity of 1.5
x 10^6 m/s at 3 x 10^8 V/m. What is the magnetic field field?
The magnetic field required in the velocity selector is 200 T (tesla).
To determine the magnetic field required in the velocity selector, we can use the formula for the Lorentz force experienced by a charged particle:
F = q * (E + v x B)
Where:
F is the force experienced by the ion,
q is the charge of the ion (+1.6 x 10^-1 C),
E is the electric field (3 x 10^8 V/m),
v is the velocity of the ion (1.5 x 10^6 m/s),
B is the magnetic field we need to determine.
Since the electric field is adjusted to select a specific velocity, the force experienced by the ion should be zero in the direction perpendicular to the velocity. Therefore, we can set the perpendicular component of the Lorentz force to zero:
0 = q * (E + v x B)_perpendicular
The cross product of the velocity and magnetic field vectors can be expressed as:
v x B = |v| * |B| * sin(θ)
Where θ is the angle between the velocity and magnetic field vectors.
Since we want the force to be zero, sin(θ) must be zero, which means that θ is either 0° or 180°. In this case, we assume that the angle between the velocity and magnetic field vectors is 180° (opposite direction). Therefore, sin(θ) = -1.
Plugging in the values and solving for B:
0 = q * (E + |v| * |B| * sin(180°))_perpendicular
0 = q * (E - |v| * |B|)
Solving for |B|:
|B| = E / |v|
Substituting the given values:
|B| = (3 x 10^8 V/m) / (1.5 x 10^6 m/s)
|B| = 200 T
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A certain parallel plate capacitor consists of two plates, each with area of 200 cm ^2 , separated by a 0.40−cm air gap: a. Compute its capacitance b. If the capacitor is connected across a 500 V source, find the charge, the energy stored, and the strength of electric field between the plates. c. If a liquid with a dielectric constant of 2.6 is poured between the plates to fill the air gap, how much additional charge will flow on the capacitor from the 500 V source?
The capacitance of the parallel plate capacitor can be calculated using the formula C = ε₀A/d, where C is the capacitance, ε₀ is the permittivity of free space, A is the area of the plates, and d is the distance between the plates.
To compute the capacitance of the parallel plate capacitor, we can use the formula C = ε₀A/d, where ε₀ is the permittivity of free space (approximately 8.85 x 10^-12 F/m), A is the area of the plates (given as 200 cm^2, which is equivalent to 0.02 m^2), and d is the distance between the plates (given as 0.40 cm, which is equivalent to 0.004 m). Substituting the values into the formula, we can calculate the capacitance.
If the capacitor is connected across a 500 V source, we can calculate the charge stored, the energy stored, and the strength of the electric field between the plates. The charge can be determined using the formula Q = CV, where Q is the charge, C is the capacitance, and V is the voltage. The energy stored can be calculated using the formula E = (1/2)CV^2, where E is the energy stored. The strength of the electric field between the plates can be obtained using the formula E = V/d, where E is the electric field and d is the distance between the plates.
If a liquid with a dielectric constant of 2.6 is poured between the plates to fill the air gap, the capacitance of the capacitor will increase. The additional charge that will flow on the capacitor can be calculated using the formula ΔQ = Q(dielectric - 1), where ΔQ is the additional charge, Q is the initial charge, and dielectric is the dielectric constant of the liquid. Substituting the values, we can determine the additional charge.
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A worker pushes a m= 2.00 kg bin a distance d=3.00 m along the floor by a constant force of magnitude F = 25.0 N directed at an angle 0 = 25.0° below the horizontal as shown in the figure. The coefficient of kinetic friction between the bin and the floor is k = 0.15. = WI a) Determine the total work done on the bin? b) Determine the final velocity of the bin, assuming it starts at rest?
a) The total work done on the bin is approximately 71.98 Joules. b) The final velocity of the bin, assuming it starts at rest, is approximately 8.49 m/s.
a) To determine the total work done on the bin, we need to consider the work done by the applied force and the work done against friction.
The work done by the applied force can be calculated using the formula:
Work = Force * Displacement * cos(θ)
where Force is the magnitude of the applied force, Displacement is the distance moved, and θ is the angle between the force and the displacement.
Given that the force magnitude is F = 25.0 N, the displacement is d = 3.00 m, and the angle θ = 25.0° below the horizontal, we can calculate the work done by the applied force:
Work_applied = 25.0 N * 3.00 m * cos(25.0°)
Work_applied ≈ 63.16 J
Next, we need to determine the work done against friction. The work done against friction can be calculated using the formula:
Work_friction = Force_friction * Displacement
where Force_friction is the force of friction and is given by the product of the coefficient of kinetic friction (k) and the normal force (N). The normal force is equal to the weight of the object, which can be calculated as N = mass * gravity.
The force of friction is given by:
Force_friction = k * N
Substituting the values, we have:
Force_friction = 0.15 * (2.00 kg * 9.8 m/[tex]s^{2}[/tex])
Force_friction ≈ 2.94 N
Finally, we can calculate the work done against friction:
Work_friction = 2.94 N * 3.00 m
Work_friction ≈ 8.82 J
The total work done on the bin is the sum of the work done by the applied force and the work done against friction:
Total work = Work_applied + Work_friction
Total work ≈ 63.16 J + 8.82 J
Total work ≈ 71.98 J
b) To determine the final velocity of the bin, we can use the work-energy theorem, which states that the work done on an object is equal to its change in kinetic energy.
The work done on the bin is equal to the total work calculated in part (a), which is 71.98 J. The change in kinetic energy of the bin is equal to the final kinetic energy minus the initial kinetic energy. Assuming the bin starts at rest, the initial kinetic energy is zero.
Therefore, we have:
Work = Final kinetic energy - Initial kinetic energy
71.98 J = (0.5) * mass * [tex]final velocity^{2}[/tex] - 0
Simplifying the equation, we can solve for the final velocity:
71.98 J = (0.5) * 2.00 kg * [tex]final velocity^{2}[/tex]
[tex]final velocity^{2}[/tex] = (2 * 71.98 J) / 2.00 kg
≈ 71.98 [tex]m^{2}[/tex]/[tex]s^{2}[/tex]
≈ [tex]\sqrt{71.98m^{2} s^{2} }[/tex]
≈ 8.49 m/s
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