A 0.1-kilogram block is attached to an initially unstretched spring of force constant k = 40 newtons per meter as shown above. The block is released from rest at time t=0.

What is the amplitude, in meters, of the resulting simple harmonic motion of the block?

A) 1/40m
B) 1/20m
C) 1/4m
D) 1/2m

The given question is incomplete. The complete question is as follows.

An oxygen molecule is adsorbed onto a small patch of the surface of a catalyst. It's known that the molecule is adsorbed on 1 of 36 possible sites for adsorption. Calculate the entropy of this system.

Explanation:

It is known that Boltzmann formula of entropy is as follows.

             s = k ln W

where,   k = Boltzmann constant

              W = number of energetically equivalent possible microstates or configuration of the system

In the given case, W = 36. Now, we will put the given values into the above formula as follows.

                  s = k ln W

                    = [tex]1.38 \times 10^{-23} ln (36)[/tex]        

                    = [tex]4.945 \times 10^{-23} J/K[/tex]

Thus, we can conclude that the entropy of this system is [tex]4.945 \times 10^{-23} J/K[/tex].

The entropy of the given system is [tex]4.954 \times 10^{-23 } \rm\; J/K[/tex]  in which an oxygen molecule is absorbed in one of the 36 possible states.

From the Boltzmann formula of entropy,

[tex]s = k \times ln W[/tex]

Where,  

[tex]k[/tex]= Boltzmann constant = [tex]1.38\times 10^{-23} \rm\; J/K[/tex]

[tex]W[/tex] = Number of energetically equivalent possible microstates of the system = 36

Put the values in the formula  

[tex]s =1.38\times 10^{-23} \times ln (36)\\\\s = 4.954 \times 10^{-23 } \rm\; J/K[/tex]

Therefore, the entropy of the given system is [tex]4.954 \times 10^{-23 } \rm\; J/K[/tex]

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the magnitude of the magnetic torque on the loop when the plane of its area is perpendicular to the magnetic field is approximately [tex]\( 0.47 \, \text{N} \cdot \text{m} \)[/tex].

The magnetic torque [tex]\( \tau \)[/tex] on a current-carrying loop in a uniform magnetic field can be calculated using the formula:

[tex]\[ \tau = N \cdot I \cdot A \cdot B \cdot \sin(\theta) \][/tex]

Where:

- N is the number of turns in the loop (1 in this case, as there is a single loop),

- I is the current flowing through the loop (2.0 A),

- A is the area of the loop (πr² for a circular loop, where \( r \) is the radius),

- B is the magnetic field strength (0.30 T),

- [tex]\( \theta \)[/tex] is the angle between the normal to the loop's plane and the magnetic field (90° in this case, as the loop is perpendicular to the magnetic field).

Substituting the given values:

[tex]\[ \tau = (1) \cdot (2.0 \, \text{A}) \cdot (\pi \times (0.50 \, \text{m})^2) \cdot (0.30 \, \text{T}) \cdot \sin(90°) \][/tex]

[tex]\[ \tau = 2.0 \cdot \pi \cdot (0.50)^2 \cdot 0.30 \][/tex]

[tex]\[ \tau = 2.0 \cdot \pi \cdot 0.25 \cdot 0.30 \][/tex]

[tex]\[ \tau = 0.15 \cdot \pi \][/tex]

[tex]\[ \tau \approx 0.47 \, \text{N} \cdot \text{m} \][/tex]

So, the magnitude of the magnetic torque on the loop when the plane of its area is perpendicular to the magnetic field is approximately [tex]\( 0.47 \, \text{N} \cdot \text{m} \)[/tex].

Therefore, the correct answer choice is [tex]\(\boxed{\text{0.47 N*m}}\)[/tex].

The complete Question is given below:

A flat circular loop of wire of radius 0.50 m that is carrying a 2.0-A current is in a uniform magnetic field of 0.30 T. What is the magnitude of the magnetic torque on the loop when the plane of its area is perpendicular to the magnetic field?

Answer choices.

.41N*m

.00N*m

.47N*m

.58N*m

.52N*m

Answer:

e. 1.2 x 10²³

Explanation:

According to the problem, The current equation is given by:

[tex]I(t)=0.88e^{-t/6\times3600s}[/tex]

Here time is in seconds.

Consider at t=0 s the current starts to flow due to battery and the current stops when the time t tends to infinite.

The relation between current and number of charge carriers is:

[tex]q=\int\limits {I} \, dt[/tex]

Here the limits of integration is from 0 to infinite. So,

[tex]q=\int\limits {0.88e^{-t/6\times3600s}}\, dt[/tex]

[tex]q=0.88\times(-6\times3600)(0-1)[/tex]

q = 1.90 x 10⁴ C

Consider N be the total number of charge carriers. So,

q = N e

Here e is electronic charge and its value is 1.69 x 10⁻¹⁹ C.

N = q/e

Substitute the suitable values in the above equation.

[tex]N= \frac{1.9\times10^{4} }{1.69\times10^{-19}}[/tex]

N = 1.2 x 10²³

Answer:

[tex]4.725 m/s^{2}[/tex]

Explanation:

We know that from Newton's second law of motion, F=ma hence making acceleration the subject then [tex]a=\frac {F}{m}[/tex]  where a is acceleration, F is force and m is mass

Also making mass the subject of the formula [tex]m=\frac {F}{a}[/tex]

For [tex]m1= \frac {F}{13.5}[/tex] and [tex]m2=\frac {F}{3.5}[/tex] hence [tex]F=(m2-m1)a= (\frac {F}{3.5}-\frac {F}{13.5})a=0.2116402116\\\frac {1}{a}=0.2116402116\\a=4.725 m/s^{2}[/tex]

Answer with Explanation:w

a.We are given that

Potential difference, V=48 V

[tex]R_1=24\Omega[/tex]

[tex]R_2=96\Omega[/tex]

Equivalent resistance when R1 and R2 are connected in series

[tex]R_{eq}=R_1+R_2[/tex]

Using the formula

[tex]R_{eq}=24+96=120\Omega[/tex]

We know that

[tex]I=\frac{V}{R_{eq}}=\frac{48}{120}=0.4 A[/tex]

In series combination, current passing through each resistor is  same and potential difference across each resistor is different.

Power, P=[tex]I^2 R[/tex]

Using the formula

Power,[tex]P_1=I^2R_1=(0.4)^2\times 24=3.84 W[/tex]

Power, [tex]P_2=I^2 R_2=(0.4)^2(96)=15.36 W[/tex]

b.

In parallel combination, potential difference remains same across each resistor and current passing through each resistor is different..

Current,[tex]I=\frac{V}{R}[/tex]

Using the formula

[tex]I_1=\frac{V}{R_1}=\frac{48}{24}=2 A[/tex]

[tex]I_2=\frac{V}{R_2}=\frac{48}{96}=0.5 A[/tex]

[tex]P_1=\frac{V^2}{R_1}=\frac{(48)^2}{24}=96 W[/tex]

[tex]P_2=\frac{V^2}{R_2}=\frac{(48)^2}{96}=24 W[/tex]

When two resistors are in series, the current through each is the same and is calculated by dividing the total voltage by the total resistance. The power through each resistor is the current squared times the resistance of each resistor. When resistors are in parallel, the total resistance decreases and the power increases. The current remains the same.

When the 24-ohm and 96-ohm resistors are connected in series, the total resistance can be calculated using the formula R = R1 + R2. Here, R1 is the resistance of the first resistor (24 ohms) and R2 is the resistance of the second resistor (96 ohms). R equals 120 ohms. The current, I, is calculated using Ohm's Law, I = V / R. Therefore, the current flowing through the circuit is I = 48.0 V / 120 Ω = 0.4 A. The power, P, through each resistor is calculated using the formula P = I^2 * R. Therefore, for the 24-ohm resistor, P is (0.4 A)^2 * 24 Ω = 3.84 W, and for the 96-ohm resistor, P is (0.4 A)^2 * 96 Ω = 15.36 W. When the resistors are connected in parallel, the total resistance is calculated using the formula 1/R = 1/R1 + 1/R2. The current through each resistor remains the same (0.4 A) and the power for each resistor can be calculated in the same way as described above.

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Answer:

-3413 ft/s2

Explanation:

We need to know the velocity with which he landed on the snow.

He 'dropped' from 512 feet. This is the displacement. His initial velocity is 0 and the acceleration of gravity is 32 ft/s2.

We use the equation of mition

[tex]v^2 = u^2 + 2as[/tex]

v and u are the initial and final velocities, a is the acceleration and s is the displacement. Putting the appropriate values

[tex]v^2 = 0^2 + 2\times32\times512[/tex]

[tex]v = \sqrt{2\times32\times512} = 128\sqrt{2}[/tex]

This is the final velocity of the fall and becomes the initial velocity as he goes into the snow.

In this second motion, his final velocity is 0 because he stops after a displacement of 4.8 ft. We use the same equation of motion but with different values. This time, [tex]u=128\sqrt{2}[/tex], v = 0 and s = 4.8 ft.

[tex]0^2 = (128\sqrt{2})^2 + 2a\times4.8[/tex]

[tex]a = -\dfrac{2\times128^2}{2\times4.8} = -3413[/tex]

Note that this is negative because it was a deceleration, that is, his velocity was decreasing.

Answer:

0.308 m/s2 at an angle of 13.5° below the horizontal

Explanation:

The parallel acceleration to the roadway is the tangential acceleration on the rise.

The normal acceleration is the centripetal acceleration due to the arc. This is given by

[tex]a_N = \dfrac{v^2}{r} = \dfrac{36^2}{500}=0.072[/tex]

The tangential acceleration, from the question, is

[tex]a_T = 0.300[/tex]

The magnitude of the total acceleration is the resultant of the two accelerations. Because these are perpendicular to each other, the resultant is given by

[tex]a^2 =a_T^2 + a_N^2 = 0.300^2 + 0.072^2[/tex]

[tex]a = 0.308[/tex]

The angle the resultant makes with the horizontal is given by

[tex]\tan\theta=\dfrac{a_N}{a_T}=\dfrac{0.072}{0.300}=0.2400[/tex]

[tex]\theta=13.5[/tex]

Note that this angle is measured from the horizontal downwards because the centripetal acceleration is directed towards the centre of the arc

Final answer:

The magnitude of the force exerted on the right cube by the middle cube, when three identical cubes accelerate together on a frictionless surface, is calculated using Newton's second law (F = ma) and is found to be 16.0 Newtons.

Explanation:

The student's question pertains to Newton's second law of motion and the concept of force and acceleration. The problem involves three identical cubes on a frictionless surface accelerating due to a force applied to the first cube. To find the magnitude of the force exerted on the right cube by the middle cube, we use the formula F = ma, where F is the force, m is the mass, and a is the acceleration.

Since the cubes are identical and accelerate together, each 4.0-kg cube has an acceleration of 4.0 m/s². Therefore, the force exerted by one cube on another can be found by multiplying one cube's mass by the given acceleration:

The force exerted on the right cube by the middle cube is 16.0 Newtons.

Answer:

The frequency is 1.3 kHz.

Explanation:

Given that,

Capacitance of the capacitor, [tex]C=1\ \mu F=10^{-6}\ C[/tex]

Inductance of the inductor, [tex]L=15\ mH=15\times 10^{-3}\ H[/tex]

We need to find the frequency when the inductive reactance equal the capacitive reactance such that :

[tex]X_c=X_L[/tex]

[tex]2\pi fL=\dfrac{1}{2\pi fC}[/tex]

[tex]f=\dfrac{1}{2\pi \sqrt{LC} }[/tex]

[tex]f=\dfrac{1}{2\pi \sqrt{15\times 10^{-3}\times 10^{-6}} }[/tex]

f = 1299.49 Hz

[tex]f=1.29\times 10^3\ Hz[/tex]

or

[tex]f=1.3\ kHz[/tex]

So, the frequency is 1.3 kHz. Therefore, the correct option is (d).

Explanation:

Below is an attachment containing the solution.

To calculate the current, we first convert the mass of gold deposited to moles and then use the equivalence of one mole of gold requiring one faraday of charge. We calculate the total charge transferred and then find the average current by dividing this charge by the total time in seconds.

To find the current in the cell during the period when 4.00 × 10⁻³ kg of gold was deposited on the negative electrode, we need to calculate the total charge that resulted in the deposition of gold. First, we will convert the mass of gold to moles using the molar mass of gold, which is approximately 197 g/mol. Since gold ions carry one unit of positive charge, one mole of gold ions will require one faraday (96,485 C) to be reduced and deposited as gold metal.

After calculating the number of moles of gold, we can then determine the number of moles of electrons that moved through the cell using the equivalence of moles of electrons to moles of gold deposited. Multiplying this number by the charge per mole of electrons (1 faraday), we get the total charge moved. To find the current, we divide the total charge by the total time in seconds, and this gives us the average current over the 2.73 hours.

Answer:

a) 138 ft

b) 4.62 s

c) 1.375 s

d) 168.25 ft

Explanation:

The height of a rock (thrown from the top of a bridge) above the level of water surface as it varies with time when thrown is given in the question as

h = f(t) = -16t² + 44t + 138

with t in seconds, and h in feet

a) The bridge's height above the water.

At t=0 s, the rock is at the level of the Bridge's height.

At t = 0,

h = 0 + 0 + 138 = 138 ft

b) How many seconds after being thrown does the rock hit the water?

The rock hits the water surface when h = 0 ft. Solving,

h = f(t) = -16t² + 44t + 138 = 0

-16t² + 44t + 138 = 0

Solving this quadratic equation,

t = 4.62 s or t = -1.87 s

Since time cannot be negative,

t = 4.62 s

c) How many seconds after being thrown does the rock reach its maximum height above the water?

At maximum height or at the maximum of any function, the derivative of that function with respect to the independent variable is equal to 0.

At maximum height,

(dh/dt) = f'(t) = (df/dt) = 0

h = f(t) = -16t² + 44t + 138

(dh/dt) = (df/dt) = -32t + 44 = 0

32t = 44

t = (44/32)

t = 1.375 s

d) What is the rock's maximum height above the water?

The maximum height occurs at t = 1.375 s,

Substituting this for t in the height equation,

h = f(t) = -16t² + 44t + 138

At t = 1.375 s, h = maximum height = H

H = f(1.375) = -16(1.375²) + 44(1.375) + 138

H = 168.25 ft

Hope this Helps!!!

The velocity of the ball just before it hits the ground, thrown upward from 2 meters with an initial velocity of 10 m/s, can be calculated using kinematic equations and is approximately 11.8 m/s.

To determine the velocity of the ball just before it hits the ground, we can use kinematic equations. One equation that relates initial velocity, acceleration due to gravity, and final velocity is:

v² = u² + 2as

Where:

In this case, the ball is tossed upward so we consider the acceleration due to gravity as negative (-9.8 m/s²). The displacement, in this case, is 2 m (the height from which the ball is thrown).

Insert the known values into the equation:

v² = (10 m/s)² + 2 × (-9.8 m/s²) × (-2 m)

The negative signs cancel for the displacement and acceleration due to the upward throw and the downward acceleration, which will give us a positive number.

v² = 100 + (19.6 × 2)

v² = 100 + 39.2

v² = 139.2

v = √139.2

v ≈ 11.8 m/s

Therefore, the velocity of the ball just before it hits the ground is approximately 11.8 m/s.

Answer:

13.875 T

Explanation:

Parameters given:

Length of solenoid, L = 2.5 cm = 0.025 m

Radius of solenoid, r = 0.75 cm = 0.0075 m

Number of turns, N = 25 turns

Current, I = 1.85 A

Magnetic field, B, is given as:

B = (N*r*I) /L

B = (25 * 0.0075 * 1.85)/0.025

B = 13.875 T

Explanation:

Below is an attachment containing the solution.

Answer:

(b) 4.775 kN

Explanation:

see the attached file

Answer:

dB = (-5 × 10⁻⁷k) T

Magnitude of dB = (-5 × 10⁻⁷) T; magnitude is actually (5 × 10⁻⁷) T in the mathematical sense of what magnitude is, but this question instructs to include the negative of the direction of dB is negative.

Direction is in the negative z-direction as evident from the sign on dB's vector notation.

Explanation:

From Biot Savart's relation, the magnetic field is given by

dB = (μ₀I/4πr³) (dL × r)

μ₀ = (4π × 10⁻⁷) H/m

I = 5.0 A

r = (2î) m

Magnitude of r = 2

dL = (4j)

(dL × r) is the vector product of both length of current carrying wire vector and the vector position of the point where magnetic field at that point is needed.

(dL × r) = (4j) × (2î)

​|i j k|

|0 4 0|

|2 0 0|

(dL × r) = (0î + 0j - 8k) = (-8k)

(μ₀I/4πr³) = (4π × 10⁻⁷ × 5)/(4π×2³)

(μ₀I/4πr³) = (6.25 × 10⁻⁸)

dB = (μ₀I/4πr³) (dL × r) = (6.25 × 10⁻⁸) × (-8k)

dB = (-5 × 10⁻⁷k) T

Magnitude of dB = (-5 × 10⁻⁷) T; magnitude is actually (5 × 10⁻⁷) T in the mathematical sense of what magnitude is, but this question instructs to include the negative of the direction of dB is negative.

Direction is in the negative z-direction as evident from the sign on dB's vector notation.

Hope this Helps!!!

When the distance is 4 m, the magnetic field strength is 2.5 x 10⁻⁷ T.

When the distance is 2 m, the magnetic field strength is 5 x 10⁻⁷ T.

The magnitude of magnetic field at any distance from a wire is determined by applying Biot-Savart law,

[tex]B = \frac{\mu_o I}{2\pi r}[/tex]

Where;

r is the distance from the conductor

When the distance is 4 m, the magnetic field strength is calculated as;

[tex]B = \frac{(4\pi \times 10^{-7}) \times5 }{2\pi \times 4} \\\\B = 2.5 \times 10^{-7} \ T[/tex]

When the distance is 2 m, the magnetic field strength is calculated as;

[tex]B = \frac{(4\pi \times 10^{-7} \times 5}{2\pi \times 2} \\\\B = 5 \times 10^{-7} \ T[/tex]

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Explanation:

Thermodynamic Laws -

Standard Electronic potential  -

Aerobic grow is much more efficient at making ATP because of the presence of oxygen the cycles in the respiration are carried out at an efficient rate which forces the cell to undergo a much large amount of ATP production.

Answer:

a. Increases

Explanation:

By the definition we know that the acceleration is the rate of change in velocity and here we have acceleration component in the direction of motion of the block.

Mathematically:

when the body is moving down:

[tex]v=u+gt[/tex]

where:

[tex]v=[/tex] final velocity of the block

[tex]u=[/tex] initial velocity of the block

[tex]g=[/tex] acceleration due to gravity

[tex]t=[/tex] time of observation during the instance of motion

As we know that kinetic energy is given as:

[tex]KE=\frac{1}{2} \times m.v^2[/tex]

where:

[tex]m=[/tex] mass of the block which remains constant (macroscopically)

[tex]v=[/tex] velocity of the block (which increases here as the body descends)

Answer:

[tex]w=694.575\ m[/tex]

Explanation:

Given:

velocity of the sound, [tex]v=343\ m.s^{-1}[/tex]

time lag in echo form one wall of the valley, [tex]t= 1.55\ s[/tex]

time lag in echo form the other wall of the valley, [tex]t'=2.5\ s[/tex]

distance travelled by the sound in the first case:

[tex]d=v.t[/tex]

[tex]d=343\times 1.55[/tex]

[tex]d=531.65\ m[/tex]

Since this is the distance covered by the sound while going form the source to the walls and then coming back from the wall to the source so the distance of the wall form the source will be half of the distance obtained above.

[tex]s=\frac{d}{2}[/tex]

[tex]s=\frac{531.65}{2}[/tex]

[tex]s=265.825\ m[/tex]

distance travelled by the sound in the second case:

[tex]d'=v.t'[/tex]

[tex]d'=343\times 2.5[/tex]

[tex]d'=857.5\ m[/tex]

Since this is the distance covered by the sound while going form the source to the walls and then coming back from the wall to the source so the distance of the wall form the source will be half of the distance obtained above.

[tex]s'=\frac{d'}{2}[/tex]

[tex]s'=\frac{857.5}{2}[/tex]

[tex]s'=428.75\ m[/tex]

Now the width of valley:

[tex]w=s+s'[/tex]

[tex]w=265.825+428.75[/tex]

[tex]w=694.575\ m[/tex]

To determine the width of the valley with vertical walls using echo timings.

To find the width of the valley:

Calculations:

Distance to first wall = 343 m/s * 1.55 s = 531.85 m

Distance to second wall = 343 m/s * 2.5 s = 857.5 m

Width of the valley: 857.5 m - 531.85 m = 325.65 m

Answer:

Which stars are coming toward us? Which are moving away?

The Star A and B are moving toward the observer and Star C and D away from the observer.

Which star is moving fastest relative to us?

Star A is moving fastest relative to us.

What are the speeds of Star B and Star C?

The speed of the star B is 986842m/s and the speed of star C is  740131m/s.

Explanation:

Which stars are coming toward us? Which are moving away?  

Spectral lines will be shifted to the blue part of the spectrum if the source of the observed light is moving  toward the observer, or to the red part of the spectrum when is moving away from the observer (that is known as the Doppler effect).

The wavelength at rest is 121.6 nm ([tex]\lambda_{0} = 121.6nm[/tex])

[tex]Redshift: \lambda_{measured}  >  \lambda_{0} [/tex]

[tex]Blueshift: \lambda_{measured}  <  \lambda_{0} [/tex]

Then, for this particular case it is gotten:

Star A: [tex]\lambda_{measured} = 120.5nm[/tex]

Star B: [tex]\lambda_{measured} = 121.2nm[/tex]

Star C: [tex]\lambda_{measured} = 121.9nm[/tex]

Star D: [tex]\lambda_{measured} = 122.9nm[/tex]

Star A:

[tex]Blueshift: 120.5nm  <  121.6nm [/tex]

Star B:

[tex]Blueshift: 121.2nm  <  121.6nm [/tex]

Star C:

[tex]Redshift: 121.9nm  >  121.6nm [/tex]

Star D:

[tex]Redshift: 122.9nm  >  121.6nm [/tex]

Therefore, according to the approach above. The Star A and B are moving toward the observer and Star C and D away from the observer.

Due to that shift the velocity of the star can be determined by means of Doppler velocity.

[tex]v = c\frac{\Delta \lambda}{\lambda_{0}}[/tex] (1)

Where [tex]\Delta \lambda[/tex] is the wavelength shift, [tex]\lambda_{0}[/tex] is the wavelength at rest, v is the velocity of the source and c is the speed of light.

[tex]v = c(\frac{\lambda_{measured}- \lambda_{0}}{\lambda_{0}})[/tex]

Which star is moving fastest relative to us?

Case for the Star A:

[tex]v = (3x10^{8}m/s)(\frac{121.6nm-120.5nm}{121.6nm})[/tex]

[tex]v = 2713815m/s[/tex]

Case for the Star B:

[tex]v = (3x10^{8}m/s)(\frac{121.6nm - 121.2nm}{121.6nm})[/tex]

[tex]v = 986842m/s[/tex]

Hence, Star A is moving fastest relative to us.

What are the speeds of Star B and Star C?

Case for the Star C:

[tex]v = (3x10^8m/s)(\frac{(121.9nm - 121.6nm}{121.6nm})[/tex]

[tex]v = 740131m/s[/tex]

Therefore, The speed of the star B is 986842m/s and the speed of star C is  740131m/s.

Final answer:

Stars with shift towards shorter wavelengths (Star A and B) are moving toward Earth, while those with shift towards longer wavelengths (Star C and D) are moving away, with Star D moving the fastest. The speeds of Star B and Star C can be calculated using the Doppler effect formula. Star A is blue-shifted the most, indicating it is moving towards us the fastest.

Explanation:

The Doppler Effect on Spectral Lines

The observed changes in the wavelength of spectral lines from hydrogen transitions can be explained by Doppler shift, which is the change in frequency or wavelength of a wave in relation to an observer who is moving relative to the wave source. Stars showing a shorter wavelength than the rest wavelength are moving towards us (blue-shifted), while those with a longer wavelength are moving away from us (red-shifted).

For star A with an observed wavelength of 120.5 nm, the shift is towards the blue, indicating it is moving towards us. Star B, with an observed wavelength of 121.2 nm, is also moving towards us but at a slower speed. Star C and Star D, having observed wavelengths of 121.9 nm and 122.9 nm respectively, display a red shift, meaning they are moving away from us. Among these stars, Star D is the one moving away the fastest.

To calculate the velocity of Star B and Star C with respect to Earth, we can use the Doppler effect formula for light:

[tex]v = c × (λ_{observed} - λ_{rest}) / λ_{rest}[/tex]

Where v is the velocity of the star, c is the speed of light, [tex]λ_{observed}[/tex] is the observed wavelength, and [tex]λ_{rest}[/tex] is the rest wavelength of the emission line. By plugging in the values and solving for v, we can determine the velocity for each star.

Answer:

0.1111 W/m²

Explanation:

If all other parameters are constant, sound intensity is inversely proportional to the square of the distance of the sound. That is,

I ∝ (1/r²)

I = k/r²

Since k can be the constant of proportionality. k = Ir²

We can write this relation as

I₁ × r₁² = I₂ × r₂²

I₁ = 0.25 W/m²

r₁ = 16 m

I₂ = ?

r₂ = 24 m

0.25 × 16² = I₂ × 24²

I₂ = (0.25 × 16²)/24²

I₂ = 0.1111 W/m²

The sound intensity at a distance of 28 m from the generator will be "0.1111 W/m²".

According to the question,

Distance, r₁ = 16 m

                r₂ = 28 m

Sound intensity, I₁ = 0.25 W/m²

We know the relation,

→ I ∝ ([tex]\frac{1}{r^2}[/tex])

or,

  I ∝ [tex]\frac{k}{r^2}[/tex]

Now,

→ I₁ × r₁² = I₂ × r₂²

By substituting the values,

0.25 × (16)² = I₂ × (24)²

                I₂ = [tex]\frac{0.25\timers (16)^2}{(24)^2}[/tex]

                   = 0.1111 W/m²

Thus the above answer is correct.

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Answer:

observer see the leading edges of the two ships pass each other at time 0.136 s

Explanation:

given data

spaceship length = 100 m

speed of 0.700 Co = [tex]0.700\times 3 \times 10^8[/tex]  m/s

distance d = 58,000 km = 58000 × 10³ m

solution

as here distance will be half because both spaceship travel with same velocity

so they meet at half of distance

Distance Da = [tex]\frac{d}{2}[/tex]   ............1

Distance Da = [tex]\frac{58000\times 10^3}{2}[/tex]  

Distance Da = 29 ×[tex]10^{6}[/tex] m

and

time at which observer see leading edge of 2 spaceship pass

Δ time = [tex]\frac{Da}{v}[/tex]   ..........2

Δ time = [tex]\frac{29 \times 10^6}{0.700\times 3 \times 10^8}[/tex]

Δ time = 0.136 s

Answer:

The time at which the observer see the leading edges of the two ships pass each other is 0.138 sec.

Explanation:

Given that,

Length = 100 m

Speed = 0.700 c

Distance = 58000 km

The distance should be halved because the spaceships both travel the same speed.

So they will meet at the middle of the distance

We need to calculate the distance

Using formula for distance

[tex]d'=\dfrac{d}{2}[/tex]

Put the value into the formula

[tex]d'=\dfrac{58000}{2}[/tex]

[tex]d'=29000\ km[/tex]

We need to calculate the time at which the observer see the leading edges of the two ships pass each other

Using formula of time

[tex]\Delta t=\dfrac{d}{V}[/tex]

Put the value into the formula

[tex]\Delta t=\dfrac{29\times10^{6}}{0.700\times3\times10^{8}}[/tex]

[tex]\Delta t=0.138\ sec[/tex]

Hence, The time at which the observer see the leading edges of the two ships pass each other is 0.138 sec.

Answer:

1. increase

2. remain the same

3. increases

4. decreases

5. remain the same

6. increases

7. decreases

8. remain the same

Explanation:

a. the formula for the capacitance of a capacitor relating the capacitor and the dielectric material is express as

[tex]C=e_oA/d[/tex]........equation 1

also the capacitance and the charge is related as

Q=CV.......equation 2

from equation 1 as the dielectric material is introduced, the capacitance increases, the charge also increases

2. from the equation as the dielectric material is introduced, the capacitance increases, the electric potential also remain the same

3. from

[tex]C=e_oA/d[/tex]........equation 1

we conclude that the capacitance increases

4. the voltage between the plates decreases

5. the charge remain the same because capacitance is constant

6. the capacitance increases

7. the electric potential decreases

8. remain the same

Answer 1: the charge on the plates will increase

Explanation: placing a dielectric between two charged plate increases its capacitance

C = Q/V,

If the plates remain connected then the voltage remains the same.

Therefore for an increase in capacitance charge will increase.

Answer 2: electric field potential remains the same.

Explanation: if the plates are disconnected, charge on plates remains contant while voltage varies with change in distance, electric field intensity remains constant and this is proportional to the electric potential energy.

Answer 3: capacitance increases

Explanation: introducing a dielectric between two plates causes opposite charges to be induced on the faces of the dielectric. This also reduces the p.d across the capacitor.

Answer 4: voltage remains constant.

Explanation: A connected plate has a constant voltage across its field.

Answer 5: charge remains contant.

Explanation: capacitance will increase with introduction of dielectric, p.d across the plates will drop, the charge will remain constant.

Answer 6: capacitance increases

Explanation: placing a dielectric between plates always increase the capacitance.

Answer 7: electric potential energy falls.

Answer 8: voltage between plates decreases

Answer:

Torque = 0.47 Nm

Explanation:

Torque = BIAsin∅

Since the plane is parallel to the magnetic field, ∅ = 90⁰

sin 90 = 1

Magnetic field, B = 0.30 T

current, I = 2.0 A

Radius, R = 0.50 m

A = πR²

A = π(0.5)² = 0.785 m²

Torque = 0.3 * 2 * 0.785

Torque = 0.47 Nm

Answer:

The magnetic torque when the plane of the loop is parallel to the magnetic field is zero.

Explanation:

Given;

radius of wire, r = 0.50 m

strength of magnetic field, B = 0.3 T

current in the wire, I = 2.0 A

Dipole moment, μ = I x A

where;

A is the area of the circular loop = πr² = π(0.5)² = 0.7855 m²

Dipole moment, μ = 2A x 0.7855m² = 1.571 Am²

magnetic torque, τ = μBsinθ

when the plane of the loop is parallel to the magnetic field, θ = 0

τ = 1.571 Am² x 0.3sin0

τ = 0

Therefore, the magnetic torque when the plane of the loop is parallel to the magnetic field is zero.

Answer:

B

Explanation:

Newton's third law of motion states that to every action there is equal an opposite reaction. Momentum is always conserved provided there is no net force on the body. Considering the experiment: the momentum is conserved as expected but the  kinetic energy is not conserved meaning that the collision is not elastic; some energy is converted into internal energy. When the collision is elastic the total kinetic energy before will equal total kinetic energy after and when the body stick together, they move with a common velocity and that described a perfectly inelastic collision.  5J ≠ 4J

Final answer:

The scenario describes an inelastic collision because while the momentum is conserved, the kinetic energy decreases from 5J to 4J, indicating that not all kinetic energy is conserved in the collision.

Explanation:

When examining collisions in physics, an elastic collision is one in which both momentum and kinetic energy are conserved, whereas an inelastic collision is one where momentum is conserved but kinetic energy is not. Given that in the scenario the total momentum of the system remains the same before and after the collision, that part of the conservation law is satisfied in both cases. However, since the kinetic energy of the system decreases from 5J to 4J, this means that some of the kinetic energy has been transformed into other forms of energy, like heat or sound, which typically happens during an inelastic collision.

Therefore, the correct answer is (b): This describes an inelastic collision (and it could NOT be elastic) since the total kinetic energy of the system is not the same before and after the collision. An elastic collision would have required that the kinetic energy also remain constant.

Answer:

(a) strikes the plane at the same time as the other body

Explanation:

Two bodies are falling with negligible air resistance, side by side, above a horizontal plane near Earth's surface. If one of the bodies is given an additional horizontal acceleration during its descent, it strikes the plane at the same time as the other body

Answer:

Velocity at 64 mm is 0.532 m/s

Maximum displacement = 0.082 m or 82 mm

Explanation:

The maximum displacement or amplitude is determined by the applied force from Hooke's law

[tex]F = kA[/tex]

[tex]A=\dfrac{F}{k}=\dfrac{14 \text{ N}}{170 \text{ N/m}}=0.082 \text{ m}[/tex]

The velocity at at any point, x, is given by

[tex]v=\sqrt{\dfrac{k}{m}(A^2 - x^2)}[/tex]

m is the mass of the load, here the cylinder.

In fact, the expression [tex]\sqrt{\dfrac{k}{m}}[/tex] represents the angular velocity, [tex]\omega[/tex].

Substituting given values,

[tex]v=\sqrt{\dfrac{170}{1.5}(0.082^2 - 0.065^2)} = 0.532 \text{ m/s}[/tex]

Explanation:

It is known that the relation between speed and distance is as follows.

               velocity = [tex]\frac{distance}{time}[/tex]

As it is given that velocity is 6 m/s and distance traveled by the bear is (d + 29). Therefore, time taken by the bear is calculated as follows.

         [tex]t_{bear} = \frac{(d + 29)}{6 m/s}[/tex] ............. (1)

As the tourist is running in a car at a velocity of 4.2 m/s. Hence, time taken by the tourist is as follows.

              [tex]t_{tourist} = \frac{d}{4.2}[/tex] ............. (2)

Now, equation both equations (1) and (2) equal to each other we will calculate the value of d as follows.

              [tex]t_{bear} = t_{tourist}[/tex]

       [tex]\frac{(d + 29)}{6 m/s}[/tex] = [tex]\frac{d}{4.2}[/tex]

                   4.2d + 121.8 = 6d

                         d = [tex]\frac{121.8}{1.8}[/tex]

                            = 67.66

Thus, we can conclude that the maximum possible value for d is 67.66.

Answer: 9.59° and 350.41°

Explanation: The formulae that relates the force F exerted on a moving charge q with velocity v in a magnetic field of strength B is given as

F =qvB sin x

Where x is the angle between the strength of magnetic field and velocity of the charge.

q = 1.609×10^-19 C

v = 4×10³ m/s

B = 1.25 T

F = 1.40×10^-16 N

By substituting the parameters, we have that

1.40×10^-16 = 1.609×10^-19 × 4×10³ × 1.25 × sinx

sin x = 1.40×10^-16/ 1.609×10^-19 × 4×10³ × 1.25

sin x = 1.40×10^-16 /8.045*10^(-16)

sin x = 0.1666

x = 9.59°

The value of sin x is positive in first and fourth quadrant.

Hence to get the second value of x, we move to the 4th quadrant of the trigonometric quadrant which is 360 - x

Hence = 360 - 9.59 = 350.41°

Final answer:

The angle between the velocity of the electron and the magnetic field is approximately 6.27° or 173.73°.

Explanation:

To find the angle between the velocity of the electron and the magnetic field, we can use the formula:

F = q(vsinθ)B

Where F is the magnetic force, q is the charge of the electron, v is the velocity of the electron, θ is the angle between the velocity and the magnetic field, and B is the magnetic field strength.

In this case, the magnetic force is given as 1.40 × 10^-16 N, the charge of an electron is 1.6 × 10^-19 C, the velocity of the electron is 4.00 × 10³ m/s, and the magnetic field strength is 1.25 T.

Plugging in these values, we can solve for θ:

1.40 × 10^-16 N = (1.6 × 10^-19 C)(4.00 × 10³ m/s)(sinθ)(1.25 T)

Solving for sinθ:

sinθ = (1.40 × 10^-16 N) / [(1.6 × 10^-19 C)(4.00 × 10³ m/s)(1.25 T)]

sinθ ≈ 0.109

Taking the inverse sine of 0.109, we find that θ ≈ 6.27° or θ ≈ 173.73°.