The minimum frequency to extract an electron is D)
Explanation:
The equation for the photoelectric effect is:
where
(hf) is the energy of the incident photon, where
is the Planck constant
f is the photon frequency
is the work function of the material
is the maximum kinetic energy of the ejected electron
The minimum frequency of the light needed to extract an electron fro mthe surface of the material can be found by requiring that the maximum kinetic energy of the photoelectron is zero:
So we get
For silver, the work function is
Solving for f, we find the minimum frequency:
Learn more about photoelectric effect:
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Answer:
The distance the piece travel in horizontally axis is
L=3.55m
Explanation:
Now the angular velocity is the blade speed so:
assuming no air friction effects affect blade piece:
time for blade piece to fall to floor
Now is the same time the piece travel horizontally
blade piece travels HORIZONTALLY = (24.5)(0.397) = 9.73 m ANS
Answer:
1027.2 m
Explanation:
t = Time taken
u = Initial velocity
v = Final velocity
s = Displacement
a = Acceleration due to gravity = 32.2 ft/s
The height the tomato would fall is 450+577.2 = 1027.2 m
Answer:
x = 0.0685 m
Explanation:
In this exercise we can use the relationship between work and energy conservation
W = ΔEm
Where the work is
W = F x
The energy can be found in two points
Initial. Just when the block with its spring spring touches the other spring
Em₀ = K = ½ m v²
Final. When the system is at rest
=
= ½ k₁ x² + ½ k₂ x²
We can find strength with Newton's second law
∑ F = F - fr
Axis y
N- W = 0
N = W
The friction force has the equation
fr = μ N
fr = μ W
The job
W = (F – μ W) x
We substitute in the equation
(F - μ W) x = ½ m v² - (½ k₁ x² + ½ k₂ x²)
½ x² (k₁ + k₂) + (F - μ W) x - ½ m v² = 0
We substitute values and solve
½ x² (20 + 40) + (15 -0.2 2) x - ½ (2/32) 6² = 0
x² 30 + 14.4 x - 1,125 = 0
x² + 0.48 x - 0.0375 = 0
We solve the second degree equation
x = [-0.48 ±√(0.48 2 + 4 0.0375)] / 2
x = [-0.48 ± 0.617] / 2
x₁ = 0.0685 m
x₂ = -0.549 m
The first result results from compression of the spring and the second torque elongation.
The result of the problem is x = 0.0685 m
Answer:
0.0984
Explanation:
From the first diagram attached below; a free flow diagram shows the interpretation of this question which will be used to solve this question.
From the diagram, the horizontal component of the force is:
Replacing 42° for θ and 87.0° for
On the other hand, the vertical component is ;
Replacing 42° for θ and 87.0° for
However, resolving the vector, let A be the be the component of the mutually perpendicular directions.
The magnitude of the two components is shown in the second attached diagram below and is now be written as A cos θ and A sin θ
The expression for the frictional force is expressed as follows:
Where;
is said to be the coefficient of the friction
N = the normal force
Similarly the normal reaction (N) = mg - F sin θ
Replacing . The normal reaction can now be:
By balancing the forces, the horizontal component of the force equals to frictional force.
The horizontal component of the force is given as follows:
Making the subject of the formular in the above equation; we have the following:
Replacing the following values: i.e
m = 73 Kh
g = 9.8 m/s²
Then:
Thus, the coefficient of friction is = 0.0984
