Between this and the next assignment, we want to get a better under- standing of how light interacts with the eye. Here are two questions to get us started, focused on diffraction (i.e., the spreading of light when it passes through a narrow opening). A. To regulate the intensity of light reaching our retinas, our pupils1 change diameter anywhere from 2 mm in bright light to 8 mm in dim light. Find the angular resolution of the eye for 550 nm wavelength light at those extremes. In which light can you see more sharply, dim or bright

Answer:

0.763 m

Explanation:

Intensity I = power P ÷ area A of exposure (spherical area of propagation)

I = P/A

A = P/I

Power = 10.0 W

Intensity = 1.39 W/m^2

A = 10/1.39 = 7.19 m^2

Area A = 4¶r^2

7.19 = 4 x 3.142 x r^2

7.19 = 12.568r^2

r^2 = 7.19/12.568 = 0.57

r = 0.753 m

Answer:

The wavelength of incident light is [tex]1.38x10^{-6}m[/tex]

Explanation:

The physicist Thomas Young established, through his double slit experiment, a relation between the interference (constructive or destructive) of a wave, the separation between the slits, the distance between the two slits to the screen and the wavelength.

[tex]\Lambda x = L\frac{\lambda}{d} [/tex]  (1)

Where [tex]\Lambda x[/tex] is the distance between two adjacent maxima, L is the distance of the screen from the slits, [tex]\lambda[/tex] is the wavelength and d is the separation between the slits.  

The values for this particular case are:

[tex]L = 2.60m[/tex]

[tex]d = 0.230mm[/tex]

[tex]\Lambda x = 1.57cm[/tex]

Then, [tex]\lambda[/tex] can be isolated from equation 1

[tex]\lambda = \frac{d \Lambda x}{L}[/tex]  (2)

However, before equation 2 can be used, it is necessary to express [tex]\Lambda x[/tex] and d in units of meters.

[tex]\Lambda x= 1.57cm \cdot \frac{1m}{100cm}[/tex] ⇒ [tex]0.0157m[/tex]

[tex]d = 0.230mm \cdot \frac{1m}{1000mm}[/tex] ⇒ [tex]2.3x10^{-4}m[/tex]

Finally, equation 2 can be used.

[tex]\lambda = \frac{(2.3x10^{-4}m)(0.0157m}{(2.60m)}[/tex]

[tex]\lambda = 1.38x10^{-6}m[/tex]

Hence, the wavelength of incident light is [tex]1.38x10^{-6}m[/tex]

Answer:horizontal motion and vertical motion

Explanation:projectile motion is a combination of both vertical and horizontal motion

Answer:

C. Horizontal and Vertical

Explanation:

edge

Answer:

(b) da/√2​

Explanation:

Detailed explanation and calculation is shown in the image below

Final answer:

The electric field inside an infinite slab with a constant volume charge density is found using Gauss's law, resulting in an expression where the electric field is directly proportional to both the distance from the midplane and the charge density, and inversely proportional to the permittivity of free space.

Explanation:

Finding the Electric Field Inside an Infinite Slab Using Gauss's Law

To find the electric field strength inside an infinite slab of charge lying in the xy-plane and having a uniform volume charge density (ρ), we employ Gauss's law. Gauss's law states that the net electric flux through a closed surface is equal to the charge enclosed by that surface divided by the permittivity of free space (ε0). For an infinite slab of thickness 2z0, positioned between z = -z0 and z = +z0, we choose a Gaussian surface in the form of a rectangular box (pillbox) that extends symmetrically above and below the xy-plane. This choice is motivated by the symmetry of the slab and the desire to have an electric field that is either parallel or perpendicular to the faces of the box.

The charge enclosed by the Gaussian surface is given by Q = ρA(2z), where A is the cross-sectional area of the box parallel to the xy-plane and 2z is the extent of the box in the z-direction within the slab. Applying Gauss's law, the electric flux through the box is Ψ = EA = Q/ε0, where E is the magnitude of the electric field inside the slab and is directed along the z-axis. Simplifying, we find E = ρz/ε0. It follows that the electric field strength inside the slab, for -z0 ≤ z ≤ z0, is directly proportional to the distance z from the midplane and to the volume charge density ρ, and inversely proportional to the permittivity of free space ε0.

Using Gauss's law, the electric field strength inside the infinite slab of charge is found to be E = (ρ * z) / ε0.

To find the electric field strength inside an infinite slab of charge with uniform volume charge density ρ, we will use Gauss's law.

The slab extends from z = -z₀ to z = z₀ in the z-direction.

Step-by-Step Solution:

The electric field strength inside the slab, for -z0 ≤ z ≤ z0, is given by:

E = (ρ * z) / ε₀

Answer: 3.60*10^-4 s

Explanation:

Given

Mass of bullet, m = 26 g = 0.026 kg

Initial speed of bullet, u = 1000 m/s

Length of target, s = 35 cm = 0.35 m

Mass of target, M = 400 kg

Final speed of bullet, v = 950 m/s

Using equation of motion

v² = u² + 2as, making a subject of formula, we have

a = (v² - u²) / (2*s)

a = 950² - 1000² / 2 * 0.35

a = 902500 - 1000000 / 0.7

a = -97500 / 0.7

The acceleration = - 1.39*10^5 m/s² ( it is worthy of note that the acceleration is negative)

now, using another equation of motion, we have

v = u + a*t

we know our a, so we make t subject of formula

time t = (v-u) / a

t = (950 - 1000) / -1.39*10^5

t = -50 / -1.39*10^5

t = 3.60*10^-4 s

Complete Question

The complete question is shown on the first uploaded image

Answer:

The maximum emf is [tex]\epsilon_{max}= 26.8 V[/tex]

The emf induced at t = 1.00 s is [tex]\epsilon = 24.1V[/tex]

The maximum rate of change of magnetic flux is   [tex]\frac{d \o}{dt}|_{max} =26.8V[/tex]

Explanation:

    From the question we are told that

        The number of turns is N = 44 turns

          The length of the coil is  [tex]l = 15.0 cm = \frac{15}{100} = 0.15m[/tex]

          The width of the coil is  [tex]w = 8.50 cm =\frac{8.50}{100} =0.085 m[/tex]

          The magnetic field is  [tex]B = 745 \ mT[/tex]

          The angular speed is [tex]w = 64.0 rad/s[/tex]

Generally the induced emf is mathematically represented as

        [tex]\epsilon = \epsilon_{max} sin (wt)[/tex]

 Where [tex]\epsilon_{max}[/tex] is the maximum induced emf and this is mathematically represented as

            [tex]\epsilon_{max} = N\ B\ A\ w[/tex]

Where [tex]\o[/tex] is the magnetic flux

            N is the number of turns

             A is the area of the coil which is mathematically evaluated as

             [tex]A = l *w[/tex]

        Substituting values

           [tex]A = 0.15 * 0.085[/tex]

               [tex]= 0.01275m^2[/tex]

substituting values into the equation for  maximum induced emf

         [tex]\epsilon_{max} = 44* 745 *10^{-3} * 0.01275 * 64.0[/tex]

                 [tex]\epsilon_{max}= 26.8 V[/tex]

 given that the time t = 1.0sec

substituting values into the equation for induced emf  [tex]\epsilon = \epsilon_{max} sin (wt)[/tex]

      [tex]\epsilon = 26.8 sin (64 * 1)[/tex]

        [tex]\epsilon = 24.1V[/tex]

   The maximum induced emf can also be represented mathematically as

              [tex]\epsilon_{max} = \frac{d \o}{dt}|_{max}[/tex]

  Where  [tex]\o[/tex] is the magnetic flux and [tex]\frac{d \o}{dt}|_{max}[/tex] is the maximum rate at which magnetic flux changes the value of the maximum rate of change of magnetic flux is

         [tex]\frac{d \o}{dt}|_{max} =26.8V[/tex]

Answer:

Car body rise on its suspension by 0.0309 m

Explanation:

We have given mass of the car m = 1500 kg

Mass of each person = 90 kg

Speed of the car [tex]v=20km/hr=20\times \frac{5}{18}=5.555m/sec[/tex]

Distance traveled by car d = 3.7 m

So time period  [tex]T=\frac{distance}{speed}=\frac{4}{5.55}=0.72sec[/tex]

Frequency [tex]f=\frac{1}{T}=\frac{1}{0.72}=1.388Hz[/tex]

Angular frequency is [tex]\omega =2\pi f=2\times 3.14\times 1.388=8.722rad/sec[/tex]

Angular frequency is equal to [tex]\omega =\sqrt{\frac{k}{m}}[/tex]

[tex]8.722 =\sqrt{\frac{k}{1500}}[/tex]

k = 114109.92 N/m

Now weight of total persons will be equal to spring force

[tex]4mg=kx[/tex]

[tex]4\times 90\times 9.8=114109.92\times x[/tex]

x = 0.0309 m

Answer:

Perpendicular

Explanation:

write the angle between them as a

cosine theoreme

[tex]0.6^{2} =1.8^{2} +2.4^{2}-2*1.8*2.4*cos(a)[/tex]

cos(a)=(3.24+5.76-0.6)/(2*1.8*2.4)

cos(a)=1

a=90°

To find the arrangement of two vectors with magnitudes of 1.8 m and 2.4 m so that their sum is 0.6 m, we need to consider vector addition. The magnitude of the resultant vector is 4.2 m. One possible arrangement is to align the vectors in opposite directions, cancelling out each other's effects and resulting in a net sum of zero.

To find the arrangement of two vectors with magnitudes of 1.8 m and 2.4 m, so that their sum is 0.6 m, we need to understand vector addition. The sum of two vectors can be found by aligning the vectors head to tail and drawing a line connecting the head of the first vector to the tail of the second vector. The resulting vector, called the resultant vector, is the sum of the two vectors.

In this case, let's call the first vector A with magnitude 1.8 m and the second vector B with magnitude 2.4 m. To find the arrangement where their sum is 0.6 m, we can set up the equation: A + B = 0.6. Since the magnitudes are given, we can rearrange the equation to solve for the magnitude of the resultant vector: |A| + |B| = |0.6|. Substituting the given values, we get: 1.8 + 2.4 = 0.6. Simplifying the equation, we find that the magnitude of the resultant vector is 4.2 m.

Now, to find the arrangement, we need to consider the direction of the vectors. Since the sum of the two vectors is not zero, their directions cannot be directly opposite. Therefore, we need to arrange them in a way that their individual directions cancel out each other to result in a net sum of zero. One possible arrangement is to align the vectors such that they form a straight line in opposite directions. In this case, A and B would have the same magnitude but opposite directions, cancelling out each other's effects and resulting in a net sum of zero.

Answer:

a). 675J

b). 337.5J

c). 1012.5J

Explanation:

M = 6.0kg

V = 15.0m/s

a). Translational energy

E = ½ *mv²

E = ½ * 6 * 15²

E = 675J

b). Rotational kinetic energy K.E(rot) = Iw²

But moment of inertia of a cylinder (I) = ½Mr²

I = ½mr²

V = wr, r = v / w

K.E(rot) = ¼ mv²

K.E(rot) = ¼* 6 * 15²

K.E(rot) = 337.5J

Total energy of the system = K.E(rot) + Translational energy = 337.5 + 675

T.E = 1012.5J

Answer:

[tex]f = 0.806\,hz[/tex], [tex]T = 1.241\,s[/tex]

Explanation:

The problem can be modelled as a vertical mass-spring system exhibiting a simple harmonic motion. The spring constant is:

[tex]k = \frac{970\,N}{0.03\,m}[/tex]

[tex]k = 32333.333\,\frac{N}{m}[/tex]

The angular frequency is:

[tex]\omega = \sqrt{\frac{32333.333\,\frac{N}{m} }{1258.879\,kg} }[/tex]

[tex]\omega = 5.068\,\frac{rad}{s}[/tex]

The frequency and period of oscillations are, respectively:

[tex]f = \frac{5.068\,\frac{rad}{s} }{2\pi}[/tex]

[tex]f = 0.806\,hz[/tex]

[tex]T = \frac{1}{0.806\,hz}[/tex]

[tex]T = 1.241\,s[/tex]

Answer:

Explanation:

Ez = (5.2 V/m)

Magnitude of electric field = 5.2 V/m

Magnitude of magnetic field be B then

Magnitude of electric field  / Magnitude of magnetic field = c , c is velocity of light

5.2 / B = 2.998 x 10⁸

B = 5.2 / 2.998 x 10⁻⁸

= 1.73 x 10⁻⁸ T.

b ) E X B = direction of velocity of light , E is electric vector , B is magnetic V.

E is along z - axis , velocity is along x -axis  , then magnetic field must be in   - Y direction.

c ) E and B  are in phase so when E is in positive z axis , directio of magnetic field must be in  -  y direction.

Answer:

2.837% less than actual value.

Explanation:

Based on given information let's calculate our value.

S = Vxt = 331m/s x 5s = 1655m, that is the total distance that sound would travel in 5 seconds.

1mile = 1609.34meters.

percentage error is.

[tex]\frac{actual-calculated}{actual} *100 = \frac{1609.34-1655}{1609.34} *100 = -2.83%[/tex]

negative indicates less than actual value.

The rule of thumb that states the lightning bolt was one mile away for every five seconds between seeing the flash and hearing the thunder is not very accurate. The actual distance the lightning bolt would be approximately 3.19 miles away, which results in a percent error of approximately 219%. The rule tends to underestimate the distance to the lightning bolt.

The "rule of thumb that many people follow" during a thunder and lightning storm is based on the fact that light travels much faster than sound. When you see a flash of lightning, the sound wave created by the thunder associated with the lightning bolt takes more time to reach the observer than the light from the flash.

According to the rule of thumb, we estimate one mile per five seconds because sound travels at a speed of approximately 331 meters per second. However, to calculate the actual distance in miles, you would multiply the time (in seconds) by the speed of sound and convert to miles (1 meter = 0.00062137 miles). This gives an actual distance of about 0.00063741 miles/second. Therefore, for every second delay between the lightning and the thunder, the lightning bolt would be about 0.00063741 miles away.

So, if we see a flash of lightning and hear the thunder 5 seconds later, according to the accurate calculation, the lightning bolt was just over 3.19 miles away (5 seconds * 0.00063741 miles/second). That's a sizeable difference from the one-mile estimate given by the rule of thumb. To find the percent error, we subtract the accepted value from the experimental value, divide by the accepted value, and multiply by 100. That gives us a percent error of approximately 219%. So the rule of thumb is not particularly accurate.

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Find the given attachments

Answer:

The solution to the question above is explained below:

Explanation:

(a) The work function of the surface is:

The work function of a metal, Φ, it's the minimum amount of energy required to remove electron from the conduction band and remove it to outside the metal. It is typically exhibited in units of eV (electron volts) or J (Joules). Work Function, is the minimum thermodynamic work.

hf = hc /λ = φ + Kmax = φ + 1 /2 mev ²max

where,   φ=work function of a metal

               eV=electron volts

              J= Joules

             λ=the Plank constant 6.63 x 10∧-34 J s

              f = the frequency of the incident light in hertz

              ∧= signifies raised to the power in the solution

Kmax= the maximum kinetic energy of the emitted electrons in joules

φ= ( hc /λ -1/2mev ²max= 6.63 × 10∧-34Js × 3.00 × 10∧8 m/s ÷ 625 × 10∧-9) -

 (1/2 × 9.11 × 10∧-31 kg × 4.60 × 10∧5 m/s) = 2.21 × 10∧-19 J

ans= 1.38 eV

(b) The cutoff frequency for this surface is:

The cutoff frequency is the minimum frequency that is required for the emission of electrons from a metallic surface at which energy flowing through the metallic surface begins to be reduced  rather than passing through.

Light at the cutoff frequency only barely supplies enough energy to overcome the work function. The value of the cutoff frequency is in unit hertz (Hz)

hfcut = φ

fcut = φ /h

ans= 334 THz

Answer:

It made landfall.

Explanation:

On land there is more friction than in open water, so it slowed down the hurricane.

Using the analytical one-term approximation method, we can determine how long an egg should be kept in boiling water to reach a specific temperature at its center.

In this problem, we are given the initial and final temperatures of an egg, as well as its diameter, the heat transfer coefficient, and the thermal conductivity and diffusivity of water. We are asked to find how long the egg should be kept in boiling water in order for its center temperature to reach a certain value.

To solve this problem, we can use the analytical one-term approximation method, which involves calculating the Biot number and the dimensionless temperature profile. By equating the temperature at the center of the egg to the desired final temperature, we can solve for the time required.

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a. The period (T) of the motion is [tex]\(2\pi\)[/tex] seconds, and the spring constant (k) is [tex]\(m\omega^2\) where \(m\) is the mass, and \(\omega\)[/tex] is the angular frequency. For the given problem, [tex]\(T = 2\pi\) seconds and \(k = \frac{m}{\pi^2}\).[/tex]

b. i. The velocity function [tex]\(v(t)\) is given by \(v(t) = -A\omega\sin(\omega t + \phi_0)\).[/tex]

ii. Evaluating the constant parameters:

[tex]\(A = 0.4\ m\) (maximum displacement),[/tex]

[tex]\(\omega = \frac{2\pi}{T} = 1\ \text{rad/s}\),[/tex]

[tex]\(\phi_0 = -\frac{\pi}{2}\) (phase angle).[/tex]

c. Disagree. The block doesn't travel 40 cm in the first [tex]\(\pi\)[/tex] seconds. The correct initial speed [tex]\(v_0\) is found using \(v_0 = A\omega\), so \(v_0 = 0.4\ m \times 1\ \text{rad/s} = 0.4\ \text{m/s}\).[/tex]

a. The period of the motion [tex](\(T\))[/tex] is the time taken for one complete oscillation. For simple harmonic motion, [tex]\(T = 2\pi/\omega\), where \(\omega\)[/tex] is the angular frequency. In this case, [tex]\(T = 2\pi\)[/tex] seconds. The spring constant [tex](\(k\))[/tex] is related to the angular frequency by [tex]\(k = m\omega^2\), where \(m\)[/tex] is the mass. Substituting [tex]\(T\) into the formula for \(\omega\), we find \(k = \frac{m}{\pi^2}\).[/tex]

b. i. The velocity function [tex]\(v(t)\)[/tex] is the derivative of the displacement function [tex]\(x(t)\). For \(x(t) = A\cos(\omega t + \phi_0)\), \(v(t) = -A\omega\sin(\omega t + \phi_0)\).[/tex]

ii. To fully describe the motion, we find [tex]\(A\), \(\omega\), and \(\phi_0\). \(A\)[/tex] is the amplitude, given as 0.4 m. [tex]\(\omega\)[/tex] is calculated from the period, resulting in 1 rad/s. [tex]\(\phi_0\)[/tex] is the phase angle, set to [tex]\(-\frac{\pi}{2}\)[/tex] to match the initial condition.

c. The statement is incorrect. The block does not travel 40 cm in the first [tex]\(\pi\)[/tex] seconds. The initial speed [tex](\(v_0\))[/tex] can be found using [tex]\(v_0 = A\omega\), which yields \(0.4\ m \times 1\ \text{rad/s} = 0.4\ \text{m/s}\).[/tex]

Answer:

Explanation:

Moment of inertia of wheel = 1/2 x mR²  , m is mass and R is radius of wheel

= .5 x 9 x .4²

= .72 kg m²

Torque created on wheel by string = T x r , T is tension and r is radius of wheel .

13 x .4 = 5.2 N m

angular acceleration α = torque / moment of inertia

= 5.2 / .72

= 7.222 rad /s²

a ) final angular speed = α x t , α is angular acceleration , t is time.

=  7.222  x .72

= 5.2 rad /s

b )

θ = 1/2 α t² , θ  is angle turned , t is time

= .5 x 7.222 x .72²

= 1.872 rad

average angular speed = θ / t

= 1.872 / .72

= 2.6 rad /s

c )

angle turned = 1.872 rad ( discussed above )

d )

length of string coming off

=  angle rotated x radius of wheel

= 1.872 x .4

= .7488 m .

74.88 cm

The final angular speed of the wheel is 5.2 radians/s. The average angular speed is 0.52 radians/s. The wheel turned through an angle of 0.3478 radians and 0.1391 m of string came off the wheel.

To find the final angular speed, we can use the equation ω = φt + 0.5αt^2, where ω is the final angular speed, φ is the initial angular speed (which is 0 since the wheel starts from rest), α is the angular acceleration, and t is the time. We are given that the force applied to the wheel is 13 N for 0.72 s.

Using the equation F = mα, we can rearrange it as α = F/m, where F is the force and m is the mass of the wheel. Plugging in the values, we get α = 13/9. Now we can substitute the values into the first equation and solve for ω: ω = (0)(0.72) + 0.5(13/9)(0.72)^2 = 5.2 radians/s.

To find the average angular speed, we use the formula ωavg = φ + (1/2)αt, where ωavg is the average angular speed. Since the initial angular speed φ is 0, we can simplify the equation to ωavg = (1/2)αt. Plugging in the values, we get ωavg = (1/2)(13/9)(0.72) = 0.52 radians/s.

To find the angle through which the wheel turned, we can use the equation θ = φt + 0.5αt^2. Since the initial angular speed φ is 0, the equation simplifies to θ = 0.5αt^2. Plugging in the values, we get θ = 0.5(13/9)(0.72)^2 = 0.3478 radians.

To find how much string came off the wheel, we can use the formula s = rθ, where s is the length of string and r is the radius of the wheel. Plugging in the values, we get s = (0.4)(0.3478) = 0.1391 m.

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Answer:

Remember that Kinetic energy is a scalar quantity and it only depends on the speed and not necessary not the angle

Thus,Since the masses and the speed are same for both A and B, the initial kinetic energy of A and B are same.

b]

The difference or variation in gravitational potential energy is again a scalar quantity and so as long as the initial speed is same, the change in gravitational potential energy will also be the same [though they may not occur at the same horizontal position].

therefore, from the ground to the highest point of both A and B, both will have same potential energy.

Also The energy in part (a) differs from part (b),

In part (a) energy mention is kinetic energy that depends on mass and velocity of particle whereas in part (b) energy is potential energy that depends on mass and the position with reference of ground. Potential energy is a state function but kinetic energy is not.

Answer: they are the same

Explanation:

The instantaneous rate of change of the force between two masses with respect to distance is given by the derivative of Newton's Law of Universal Gravitation, resulting in [tex]dF/dd = -2G(m1*m2)/d^3.[/tex]

The question is asking for the instantaneous rate of change of the force between the two masses with respect to the distance. This can be found by taking the derivative of Newton's Law of Universal Gravitation.

The gravitational force, F, is defined by the equation[tex]F = G(m1*m2)/d^2.[/tex]Taking the derivative of this function with respect to d, gives us [tex]dF/dd = -2G(m1*m2)/d^3.[/tex] This equation represents how the force changes with a small change in distance.

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Answer:

4117.65 N

Explanation:

Speed of ball, u = 126 km/h = 35 m/s

Mass of ball, m = 160 g = 0.16 kg

Time interval, t = 1.36 ms = 0.00136 s

We can calculate the force as a measure of the momentum of the ball:

F = P/t

Momentum, P, is given as:

P = mv

Therefore:

F = (mv) / t

F = (0.16 * 35) / (0.00136)

F = 4117.65 N

The force imparted to the two glove d hands of the inexperienced catcher is 4117.65 N.

Answer:

The average force on the target is proportional to:

- The number of projectiles hitting the target.

- The mass of the projectiles.

- If the time increases or decreases

Explanation:

This is a problem that applies momentum and the amount of movement. Where this principle can be explained by the following equation:

m*v1 + Imp1_2 = m*v2

where:

∑F *Δt = Imp1_2 = impulse. [N*s]

m*v1  = mass by velocity before the impact [kg*m/s]

m*v2  = mass by velocity after the impact [kg*m/s]

When a problem includes two or more particles, each particle it can be considered separately and equation is written for every particle.

We clear the expression of force in the equation:

∑F *Δt  = m*v2 - m*v1

In this equation if we have a different number of particles, given by the value n, we see that the equation is proportional to the number of particles

∑F *Δt  = n*m*v2 - n*m*v1

Therefore the average force on the target is proportional to the number of projectiles hitting the target.

The Force F is also increased or decreased if the mass of the projectiles is changed. Therefore it is also proportional to the mass of the projectiles.

The Force F also changes if the time increases or decreases.

Complete Question

The complete question is shown on the first uploaded image

Answer:

The answer is

     [tex]T_2 = 1.008[/tex] % higher than [tex]T_1[/tex]

    [tex]T_2 = 0.99[/tex] % lower than [tex]T_1[/tex]

Explanation:

   From the question we are told that

         The first string has a frequency of   [tex]f_1 = 230 Hz[/tex]

          The period of the beat is  [tex]t_{beat} = 0.99s[/tex]

Generally the frequency of the beat is

             [tex]f_{beat} = \frac{1}{t_{beat}}[/tex]

  Substituting values

            [tex]f_{beat} = \frac{1}{0.99}[/tex]

                   [tex]= 1.01 Hz[/tex]

From the question

        [tex]f_2 - f_1 = f_{beat}[/tex]   for  [tex]f_2[/tex]  having a  higher tension

So

       [tex]f_2 - 230 = 1.01[/tex]

               [tex]f_2 = 231.01Hz[/tex]

 From the question

            [tex]\frac{f_2}{f_1} = \sqrt{\frac{T_2}{T_1} }[/tex]

         [tex]\frac{T_2}{T_1} = \frac{f_2^2}{f_1^2}[/tex]

Substituting values

         [tex]\frac{T_2}{T_1} = \frac{(231.01)^2}{(230)^2}[/tex]

      [tex]T_2 = 1.008[/tex] % higher than [tex]T_1[/tex]

    For [tex]f_2[/tex] having a lower tension

           [tex]f_1 - f_2 = f_{beat}[/tex]

  So

       [tex]230 - f_2 = 1.01[/tex]

            [tex]f_2 = 230 -1.01[/tex]

                  [tex]= 228.99[/tex]

  From the question

            [tex]\frac{f_2}{f_1} = \sqrt{\frac{T_2}{T_1} }[/tex]

         [tex]\frac{T_2}{T_1} = \frac{f_2^2}{f_1^2}[/tex]

    Substituting values

         [tex]\frac{T_2}{T_1} = \frac{(228.99)^2}{(230)^2}[/tex]

      [tex]T_2 = 0.99[/tex] % lower than [tex]T_1[/tex]        

Answer:

false  b) a = v²(radial) / r  and e)

Explanation:

Let's review given statement separately

a) centripetal acceleration

       a = v² / r

linear and angular velocity are related

     v = w r

we substitute

       a = w²r

this acceleration is directed to the center of the circle, so the vector must be negative

        a = - w r2

the bold are vector

True this statement

b) the magnitude is the scalar value

     a = v² / r

where v is the tangential velocity, not the radial velocity, so this statement is

False

c) This is true

      a = v²/ r

this speed is tangential

d) Newton's second law is

         F = m a

if the acceleration is centripetal

         F = m (- v² / r)

we substitute

         F = m (- s² / R)

the statement is true

e) when the car turns to the left, the objects have to follow in a straight line, which is why

you need a force toward the center of the circle to take the curve.

     Consequently there is no outward force

This statement is false

Answer: 0.5 m/s

Explanation:

Given

Speed of the sled, v = 0.55 m/s

Total mass, m = 96.5 kg

Mass of the rock, m1 = 0.3 kg

Speed of the rock, v1 = 17.5 m/s

To solve this, we would use the law of conservation of momentum

Momentum before throwing the rock: m*V = 96.5 kg * 0.550 m/s = 53.08 Ns

When the man throws the rock forward

rock:

m1 = 0.300 kg

V1 = 17.5 m/s, in the same direction of the sled with the man

m2 = 96.5 kg - 0.300 kg = 96.2 kg

v2 = ?

Law of conservation of momentum states that the momentum is equal before and after the throw.

momentum before throw = momentum after throw

53.08 = 0.300 * 17.5 + 96.2 * v2

53.08 = 5.25 + 96.2 * v2

v2 = [53.08 - 5.25 ] / 96.2

v2 = 47.83 / 96.2

v2 = 0.497 ~= 0.50 m/s

Complete Question

A satellite in geostationary orbit is used to transmit data via electromagnetic radiation. The satellite is at a height of 35,000 km above the surface of the earth, and we assume it has an isotropic power output of 1 kW (although, in practice, satellite antennas transmit signals that are less powerful but more directional).

Imagine that the satellite described in the problem introduction is used to transmit television signals. You have a satellite TV reciever consisting of a circular dish of radius R which focuses the electromagnetic energy incident from the satellite onto a receiver which has a surface area of 5 cm2.

How large does the radius R of the dish have to be to achieve an electric field vector amplitude of 0.1 mV/m at the receiver?

For simplicity, assume that your house is located directly beneath the satellite (i.e. the situation you calculated in the first part), that the dish reflects all of the incident signal onto the receiver, and that there are no losses associated with the reception process. The dish has a curvature, but the radius R refers to the projection of the dish into the plane perpendicular to the direction of the incoming signal.

Give your answer in centimeters, to two significant figures.

Answer:

 The radius  of  the dish is [tex]R = 18cm[/tex]

Explanation:

  From the question we are told that

     The radius of the orbit is  = [tex]R = 35,000km = 35,000 *10^3 m[/tex]

    The power output of the power is  [tex]P = 1 kW = 1000W[/tex]

   The electric vector amplitude is given as [tex]E = 0.1 mV/m = 0.1 *10^{-3}V/m[/tex]

    The area of thereciever  is   [tex]A_R = 5cm^2[/tex]

Generally the intensity of the dish is mathematically represented as

         [tex]I = \frac{P}{A}[/tex]

Where A is the area orbit which is a sphere so this is obtained as

          [tex]A = 4 \pi r^2[/tex]

              [tex]= (4 * 3.142 * (35,000 *10^3)^2)[/tex]

              [tex]=1.5395*10^{16} m^2[/tex]

  Then substituting into the equation for intensity

          [tex]I_s = \frac{1000}{1.5395*10^{16}}[/tex]

            [tex]= 6.5*10^ {-14}W/m2[/tex]

 Now the intensity received by the dish can be mathematically evaluated as

              [tex]I_d = \frac{1}{2} * c \epsilon_o E_D ^2[/tex]

  Where c is thesped of light with a constant value  [tex]c = 3.0*10^8 m/s[/tex]

              [tex]\epsilon_o[/tex] is the permitivity of free space  with a value  [tex]8.85*10^{-12} N/m[/tex]

              [tex]E_D[/tex] is the electric filed on the dish

So  since we are to assume to loss then the intensity of the satellite is equal to the intensity incident on the receiver dish

      Now making the eletric field intensity the subject of the formula

                  [tex]E_D = \sqrt{\frac{2 * I_d}{c * \epsilon_o} }[/tex]

substituting values

                 [tex]E_D = \sqrt{\frac{2 * 6.5*10^{-14}}{3.0*10^{8} * 8.85*10^{-12}} }[/tex]

                       [tex]= 7*10^{-6} V/m[/tex]

The incident power on the dish is what is been reflected to the receiver

                [tex]P_D = P_R[/tex]

Where [tex]P_D[/tex] is the power incident on the dish which is mathematically represented as

              [tex]P_D = I_d A_d[/tex]

                   [tex]= \frac{1}{2} c \epsilon_o E_D^2 (\pi R^2)[/tex]

And  [tex]P_R[/tex] is the power incident on the dish which is mathematically represented as

                 [tex]P_R = I_R A_R[/tex]

                       [tex]= \frac{1}{2} c \epsilon_o E_R^2 A_R[/tex]

Now equating the two

                [tex]\frac{1}{2} c \epsilon_o E_D^2 (\pi R^2) = \frac{1}{2} c \epsilon_o E_R^2 A_R[/tex]

   Making R the subject we have

                   [tex]R = \sqrt{\frac{E_R^2 A_R}{\pi E_D^2} }[/tex]

Substituting values

                   [tex]R = \sqrt{\frac{(0.1 *10^{-3})^2 * 5}{\pi (7*10^{-6})^ 2} }[/tex]

                     [tex]R = 18cm[/tex]

Answer:

They are called absorption lines

Explanation:

Absorption lines are defined as dark lines or lines having reduced intensity, on an ongoing spectrum. A typical example is noticed in the spectra of stars, where gas existing in the outer layers of the star absorbs some of the light from the underlying thermal blackbody spectrum.

A typical stellar spectrum includes dark lines called absorption lines.

A typical stellar spectrum includes a number of deep indentations in which the intensity abruptly falls and then rises. These deep indentations are called absorption lines. Absorption lines are dark lines in a spectrum that correspond to specific wavelengths of light that have been absorbed by elements in the star's outer layers.

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Final answer:

To find the total length of the wire in a 65-turn square coil subjected to a changing magnetic field, apply Faraday's law of induction to calculate the magnetic flux change and then determine the side length of the coil. Multiply the coil's perimeter by the number of turns to obtain the total length.

Explanation:

The student's question pertains to electromagnetic induction in a coil exposed to a changing magnetic field. To solve for the total length of the wire, we can use Faraday's law of induction, which states that the induced emf (electromotive force) in a coil is proportional to the rate of change of magnetic flux through the coil. Given an induced emf of 80.0 mV and a change in magnetic field from 200 µT to 600 µT over 0.400 s, the change in magnetic flux φ can be calculated.

Since the coil is square and positioned at a 30.0° angle to the magnetic field, the effective area A for inducing emf can be determined using the cosine of the angle and the side length of the square, assuming all sides are equal. With the number of turns (N) being 65, we can apply Faraday's law to find the magnetic flux and subsequently the side length of the square. The total length of the wire is simply the perimeter of the square (4 times the side length) multiplied by the number of turns (N).