The insulating solid sphere in the previous Example 24.5 has the same total charge Q and radius a as the thin shell in the example here. Consider the electric fields due to the sphere (E_sphere), the shell (E_shell), and a point charge Q (E_Q). Rank the strength of the electric fields due to these three charged objects at the same three points ('1' represents the object with the strongest, '2' for the next in strength and so on. For example, you can have the triad {3, 1, 2} as your answer, or {2, 1, 2} if the shell is strongest while the sphere and the point charge have equal strengths.): r greaterthan a a. {1, 1, 2} b. {2, 1, 1} c. {1, 1, 1} d. {2, 2, 1} e. {1, 2, 3} r lesserthan a a. {2,2, 1} b. {1,1,1} c. {2, 3, 1} d. {2,1,1} e.{1, 2, 1}

Answer:

V= 3.55 V

Explanation:

         [tex]V_{rint} = I* r_{int}[/tex]

        [tex]V = V_{b} - V_{rint} = 6.00 V - 0.207A* r_{int}[/tex]

        [tex]r_{int} = \frac{V_{b} - V}{I} = \frac{6.00 V - 5.03V}{0.207A} = 4.7 \Omega[/tex]

         [tex]V = V_{b} - V_{rint} = 6.00 V - 0.523A* 4.7 \Omega = 3.55 V[/tex]

Answer:

[tex]v=177.95m/s[/tex]

Explanation:

First, determine circle's radius  between Earth's pole and the location. This can be calculated as:

[tex]r=R_e_a_r_t_hCos(90\frac{3}{4})\\R_e_a_r_t_h=6.37\times10^6m\\r=6.37\times10^6\times Cos67.5\textdegree\\r=2,437,693.46m\\[/tex]

The angular speed of earth is constant and is :

[tex]w=\frac{2\pi}{T}=\frac{2\pi}{24\times 3600}\\=7.3\times10^{-5}rad/s[/tex]

Velocity is:

[tex]v=wr\\=7.3\times10^{-5}\times 2,437,693.46\\v=177.95m/s[/tex]

Answer: The correct option is B (The Young's modulus of women's ACLS is typically smaller than that of men's, resulting in more stress for the same amount of strain)

Explanation:

Anterior cruciate ligament (ACL) is one of the important ligaments found at the knee joint which helps to stabilise the joint. It connects the femur to the tibia bone at the knee joint.

Anterior cruciate ligament tear is one of the common knee joint injury which is seen in individuals( especially females) involved in sports( example soccer and basketball which involves sudden change in direction causing the knee to rotate inwards)

ACL tear occurs through both contact and non contact mechanisms. The contact mechanism of ACL injury occurs when force is directly applied at the lateral part of the knee while in non contact mechanism,tear occurs when the tibia is externally rotated on the planted foot.

Research has proven that women are prone to have ACL tear than men when competing in similar sports. This disparity exists due to structural differences that pose as risk factors. These includes

- the female ACL size is smaller than the male.

- the ACL of female has a lower modulus if elasticity( that is, less stiff) than in males leading to greater joint mobility than in the male.. therefore the option, (The Young's modulus of women's ACLS is typically smaller than that of men's, resulting in more stress for the same amount of strain) is correct.

Answer:

The current in the primary coil would be [tex]0.5\ A[/tex].

Explanation:

Given the power supplied by a transformer is 60 watts.

And the voltage in the primary coil is 120 Volts.

We need to find the current supply in the primary coil.

We will use the formula

[tex]P=V\times I[/tex]

Where,

[tex]P[/tex] is the power in Watts.

[tex]V[/tex] is the voltage in Volts.

[tex]I[/tex] is the current supply in Ampere.

[tex]I=\frac{P}{V}\\\\I=\frac{60}{120}\\ \\I=0.5\ A[/tex]

So, the current in the primary coil would be [tex]0.5\ A[/tex].

Answer:

[tex]d=2.4\ miles[/tex]

Explanation:

Given:

According to given condition:

[tex]t_w=t_b+\frac{36}{60}[/tex]

where:

[tex]t_w=[/tex] time taken to reach the building by walking

[tex]t_b=[/tex] time taken to reach the building by biking

We know that,

[tex]\rm time=\frac{distance}{speed}[/tex]

so,

[tex]\frac{d}{v_w} =\frac{d}{v_b} +\frac{36}{60}[/tex]

[tex]\frac{d}{3}=\frac{d}{12} +\frac{3}{5}[/tex]

[tex]d=2.4\ miles[/tex]

Answer:

The distance from her apartment to the classroom building is 2.4 miles.

Explanation:

Given that,

Time  = 36 min

Walking average speed of her = 3 m/h

biking average speed of her = 12 m/h

If she takes n minutes to ride, then if the distance is d miles,

We need to calculate the distance

Using formula of time

[tex]t=t_{1}+t_{2}[/tex]

[tex]t=\dfrac{d}{v_{1}}+\dfrac{d}{v_{2}}[/tex]

Put the value into the formula

[tex]\dfrac{36}{60}=\dfrac{d}{3}-\dfrac{d}{12}[/tex]

[tex]d=\dfrac{36\times12}{60\times3}[/tex]

[tex]d=2.4\ miles[/tex]

Hence, The distance from her apartment to the classroom building is 2.4 miles.

Answer:

The direction of the electric field vector is horizontal and pointing north.

Option (C) is correct option.

Explanation:

Given :

The direction of wave propagation is toward the west.

The direction of magnetic field vector is vertically upward.

According to the theory of electromagnetic wave propagation, the electric field and magnetic field is perpendicular to each other and the direction of propagation is also perpendicular to both electric and magnetic field vector.

⇒   [tex]\vec{E} + \vec{B} = \vec {k}[/tex]

From right hand rule, the fingers goes towards horizontal and pointing north and curl the finger goes towards  vertically upward and thumb will give you the direction of wave propagation toward west.

Hence, the direction of electric field vector is horizontal and pointing north.

The correct direction of the electric field vector in an electromagnetic wave propagating to the west with an upward magnetic field is horizontal and pointing north, following the right-hand rule for perpendicularity and direction of electromagnetic waves.

The subject of this question is the direction of the electric field vector in an electromagnetic wave that is propagating towards the west, with a magnetic field vector that points vertically upward. According to the properties of electromagnetic waves, the electric field (E) and magnetic field (B) are perpendicular to each other and to the direction of wave propagation. Therefore, if the magnetic field is pointing upward and the wave is moving west, the electric field must be pointing horizontally. Since the right-hand rule dictates that E x B gives the direction of wave propagation, and the wave is moving west, the electric field cannot be pointing east or west as it would not satisfy the right-hand rule. Thus, the electric field is either pointing north or south. To determine the correct direction between north and south, we rely on the right-hand rule: the fingers of the right hand point in the direction of E, the curled fingers point towards B, and the thumb points in the direction of the wave propagation (west in this case). If the magnetic field points up, and propagation is to the west, the electric field must be directed to the north. Therefore, the correct answer is C. horizontal and pointing north.

Answer:

B = (4.76 × 10⁻⁷) T

Explanation:

From Biot Savart's law, the magnetic field formula is given as

B = (μ₀I)/(2πr)

B = magnetic field = ?

I = current = 238 mA = 0.238 A

μ₀ = magnetic constant = (4π × 10⁻⁷) H/m

r = 10 cm = 0.1 m

B = [4π × 10⁻⁷ × 0.238)/(2π×0.1)]

B = (4.76 × 10⁻⁷) T

The direction of the magnetic field is in the clockwise direction wrapped around the current-carrying wire.

Hope this Helps!!!

Answer:

a) 2 m/s

b) i) [tex]K.E = 50 (1.5t^2 + 2) ^2\\[/tex]

ii) [tex]F = 3tm[/tex]

Explanation:

The function for distance is [tex]x = 0.5t ^3 + 2t[/tex]

We know that:

Velocity = [tex]v= \frac{d}{dt} x[/tex]

Acceleration = [tex]a= \frac{d}{dt}v[/tex]

To find speed at time t = 0, we derivate the distance function:

[tex]x = 0.5 t^3 + 2t\\v= x' = 1.5t^2 + 2[/tex]

Substitute t = 0 in velocity function:

[tex]v = 1.5t^2 + 2\\v(0) = 1.5 (0) + 2\\v(0) = 2[/tex]

Velocity at t = 0 will be 2 m/s.

To find the function for Kinetic Energy of the box at any time, t.

[tex]Kinetic \ Energy = \frac{1}{2} mv^2\\\\K.E = \frac{1}{2} \times 100 \times (1.5t^2 + 2) ^2\\\\K.E = 50 (1.5t^2 + 2) ^2\\[/tex]

We know that [tex]Force = mass \times acceleration[/tex]

[tex]a = v'(t) = 1.5t^2 + 2\\a = 3t[/tex]

[tex]F = m \times a\\F= m \times 3t\\F = 3tm[/tex]

The speed of the box at time t=0 is 0 m/s. The acceleration, displacement, and velocity functions of the box as a function of time are a(t) = 3t, x(t) = .5t^3 + 2t and v(t) = 1.5t^2 + 2 respectively.

For part (a), the speed of the box at time t=0 can be found by taking the derivative of the position function x(t), which gives us the velocity function v(t). Therefore, v(t) = 1.5t^2 + 2 and v(0) = 0. Thus, the speed of the box at t=0 is 0 m/s.

For part (b), the box's acceleration at any time t can be found by taking the derivative of the velocity function v(t), which gives us the acceleration function a(t). Therefore, a(t) = 3t, the displacement function as a function of time is the original function x(t) = .5t^3 + 2t and the velocity function is as mentioned above, v(t) = 1.5t^2 + 2.

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Answer:

ΔS = - 3.74 × 10⁻²³ J/K = - 3.7 × 10⁻²³ to 2 s.f

Explanation:

The change in entropy for a system with changing allowable Microsystems is given as

ΔS = K In (W/W₀)

K = Boltzmann's constant = 1.381 × 10⁻²³ J/K

W₀ = initial number of microstates

To calculate this, how many ways can 2 atoms occupy 16 available microstates with order important?

That is, ¹⁶P₂ = 16!/(16 - 2)! = 16 × 15 = 240 microstates.

W = the number of microstates for Chlorine atom when Bromine atom desorps = 16 microstates.

ΔS = K In (W/W₀)

ΔS = (1.381 × 10⁻²³) In (16/240)

ΔS = (1.381 × 10⁻²³) × 2.7081

ΔS = - 3.74 × 10⁻²³ J/K

Entropy change is positive when an atom desorbs from a surface and drifts away, allowing for more freedom of movement and increasing the system's entropy.

Entropy change is a measure of disorder in a system. When an atom desorbs from a surface and drifts away, the change in entropy is positive as it increases the freedom of movement of the atom. This occurs because there are more possible locations for the atom to occupy, leading to an increase in entropy.

Answer: 5cm

Explanation: Since the radius of curvature is 10cm, the focal length of the mirror (f) is

f = r/2

Where r is the radius of curvature.

Since r = 10cm, f = 10/2 = 5cm.

To produce a parallel light rays of a flash light, it means the the image will be at infinity this making the image distance to be infinite.

From the mirror formulae

1/u + 1/v = 1/f

Where u = object distance =?, v = image distance = infinity and f = focal length = 5cm.

Let us substitute the parameters, we have that

1/u + 1/∞ = 1/5

1/∞ = 0

Hence 1/u = 1/5

u = 5cm.

Hence the object needs to be placed nearly 5cm to the mirror

Final answer:

The light bulb should be placed at the focal length of the concave mirror, which is 5 cm, to produce near-parallel light rays in a flashlight.

Explanation:

The distance between the light bulb and a concave mirror to produce a beam of near-parallel light rays in a flashlight is most nearly the focal length of the mirror. Since the mirror's radius of curvature (R) is 10 cm, using the formula R = 2f, we can calculate the focal length (f). Dividing the radius of curvature by 2, we get f = R/2 = 10 cm / 2 = 5 cm. Therefore, the light bulb should be placed approximately 5 cm from the mirror to achieve near-parallel rays.

Answer:

e. it is anywhere inside (the force is zero everywhere)

Explanation:

The relation between the force and electric field is given as follows

[tex]\vec{F} = \vec{E}q[/tex]

where q is the charge inside, and E is the electric field inside the balloon created by the charge on the surface.

By Gauss' Law, the electric field inside the balloon created by the charges on the surface (excluding the charge q, since the electric field of the same charge cannot apply a force on the same charge) is zero.

[tex]\int \vec{E}d\vec{a} = \frac{Q_{enc}}{\epsilon_0}\\E4\pi r^2 = 0\\E = 0[/tex]

Since the external electric field inside the sphere is zero, then the force on the point charge is zero everywhere.

It is anywhere inside (the force is zero everywhere).

The electrical field on the surface of the charged sphere is calculated by applying Coulomb law;

[tex]E = \frac{Qr}{4\pi \varepsilon _0R^3}[/tex]

Electric force is calculated as follows;

F = Eq

The electric field inside the charged sphere is zero.

F = 0 x q = 0

Thus, we can conclude that, it is anywhere inside (the force is zero everywhere).

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Answer:

Part (a) current in the wire is 1.144 A

Part (b) the drift velocity of electrons in the wire is 1.028 x 10⁻⁴ m/s

Explanation:

Given;

diameter d  = 1.02 mm

current density J = 1.40×10⁶ A/m²

number of electron = 8.5×10²⁸ electrons

Part (a) Current in the wire

I = J×A

Where A is area of the wire;

[tex]A = \frac{\pi d^2}{4} \\\\A = \frac{\pi (1.02X10^{-3})^2}{4} = 8.1723 X10^{-7} m^2[/tex]

I = 1.40 x 10⁶ x 8.1723 x 10⁻⁷

I = 1.144 A

Part (b) the drift velocity of electrons in the wire

[tex]V = \frac{J}{nq} = \frac{1.4X10^6}{8.5X10^{28} X 1.602X10^{-19}} = 1.028 X10^{-4} m/s[/tex]

We were given the

diameter = 1.02 mm

current density = 1.40×10⁶ A/m²

number of electron = 8.5×10²⁸ electrons

We can use the formula:

I = J×A

where I is current, J is density and A is area.

A = π d²

        4

  = π (1.02ₓ 10⁻³)² = 8.1723 x 10⁻⁷

              4

I = J×A

I = 1.40 x 10⁶ x 8.1723 x 10⁻⁷

I = 1.144 A

V = J/ nq

    =   1.4 ₓ 10⁶ / (8.5ₓ 10²⁸ₓ 1.602ₓ 10⁻¹⁹)

   = 1.028ₓ 10⁻⁴ m/s

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Answer:

The distance is 709.5 m.

Explanation:

Given that,

Speed = 150 m/s

Distance = 110 m

Suppose, How far short of the target should it drop the package?

We need to calculate the time

Using equation of motion

[tex]s=ut+\dfrac{1}{2}gt^2[/tex]

[tex]t^2=\dfrac{2s}{g}[/tex]

Where, g = acceleration due to gravity

t = time

Put the value into the formula

[tex]t=\sqrt{\dfrac{2\times110}{9.8}}[/tex]

[tex]t=4.73\ sec[/tex]

We need to calculate the distance

Using formula of distance

[tex]d= vt[/tex]

Put the value into the formula

[tex]d=150\times4.73[/tex]

[tex]d=709.5\ m[/tex]

Hence, The distance is 709.5 m.

Answer:

Please find attached file for complete answer solution and explanation of same question.

Explanation:

Complete Question:

A volley ball is hit directly toward the ceiling in a gymnasium with a ceiling height of 10 m. If the initial vertical velocity is 13 m/s and the release height is 1.8 m will the ball hit the ceiling?

Answer:

The ball will hit the ceiling

Explanation:

Given;

Initial vertical Velocity U = 13 m/s

Height of the ceiling = 10 m

Released height of the volley ball = 1.8 m

Height traveled by the volley ball, is calculated as follows;

[tex]V^2 =U^2 -2gH[/tex]

where;

V is final vertical velocity

[tex]2gH =U^2\\\\H = \frac{U^2}{2g} = \frac{(13)^2}{2(9.8)} = 8.62 m[/tex]

Remember this ball was released from 1.8 m height and it traveled 8.62 m.

Total distance traveled = 1.8 + 8.62 = 10.42 m

Therefore, the ball will hit the ceiling

4.45 * 10¹⁴ J is transferred to get this mass of aluminum from 20°C to its melting point, 660⁰C.

The quantity of heat required to change the temperature of a substance is given by:

Q = mcΔT

Where Q is the heat, m is the mass of the substance, ΔT is the temperature change = final temperature - initial temperature. c is the specific heat capacity

m = 1.7 billion pounds = 77 * 10⁷ kg, ΔT = 660 - 20 = 640°C, c = 903 J/kg•K

Hence:

Q = 77 * 10⁷ kg *  903 J/kg•K * 640°C

Q = 4.45 * 10¹⁴ J

4.45 * 10¹⁴ J is transferred to get this mass of aluminum from 20°C to its melting point, 660⁰C.

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The energy required to heat 1.7 billion pounds of aluminum from 20 degrees Celsius to 660 degrees Celsius is approximately 4.398 × 10^17 Joules.

The thermal energy transferred, or heat, to raise the temperature of a substance is given by the formula q=mcΔT where 'm' is the mass, 'c' is the specific heat capacity, and 'ΔT' is the change in temperature. For aluminum, the specific heat capacity is 0.897 Joules per gram per degree Celsius (J/g°C).

First, we need to convert 1.7 billion pounds of aluminum into grams since the specific heat value is in grams. There are about 453,592.37 grams in a pound, so this gives us about 7.711 × 10^14 grams of aluminum.

The change in temperature (ΔT) is the final temperature minus the initial temperature, or 660 degrees Celsius - 20 degrees Celsius, which equals 640 degrees Celsius.

So, to find the total energy required, we use the formula and substitute the known values: q=(7.711 × 10^14 g)*(0.897 J/g°C)*(640°C), which equals approximately 4.398 × 10^17 Joules.

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Explanation:

According to the law of conservation of energy, work done by the force is as follows.

        [tex]W_{F} = F Cos (30^{o}) \times 1.5[/tex]

                   = 64.95 J

Now, gain in potential energy is as follows.

                P.E = mgh

                      = [tex]2 \times 9.8 \times 1.5[/tex]

                      = 29.4 J

Gain in potential energy will be as follows.

           = [tex]\frac{1}{2}kx^{2}_{2} - \frac{1}{2}kx^{2}_{1}[/tex]

           = [tex]\frac{1}{2} \times 30 N/m \times [(2.5 - 1.5)^{2} - (2 - 1.5)^{2}][/tex]

           = 11.25

As,

          [tex]W_{f} = u_{1} + u_{2} + \frac{1}{2}mv^{2}[/tex]

          [tex]\frac{1}{2}mv^{2} = W_{f} - u_{1} - u_{2}[/tex]  

                   = 64.95 J - 29.4 - 11.25

                   = 24.3

              [tex]v^{2} = \frac{24.3 \times 2}{2}[/tex]

                  v = 4.92 m/s

Therefore, we can conclude that relative velocity at point B is 4.92 m/s.  

To calculate the velocity of the collar as it passes position B, we need to consider the forces acting on the collar and use Newton's second law of motion. The collar is attached to a light spring, so the force exerted by the spring can be calculated using Hooke's law. The net force acting on the collar is the sum of the force exerted by the spring and the constant 50-N force.

To calculate the velocity of the collar as it passes position B, we need to consider the forces acting on the collar and use Newton's second law of motion. The collar is attached to a light spring, so the force exerted by the spring can be calculated using Hooke's law. The net force acting on the collar is the sum of the force exerted by the spring and the constant 50-N force. We can equate this net force to the mass of the collar times its acceleration. Solving for the acceleration gives us the magnitude of the velocity as it passes position B.

Using Hooke's law, the force exerted by the spring can be calculated as:

F = k * x

where F is the force, k is the stiffness of the spring, and x is the displacement of the collar from its equilibrium position. Since the collar is attached to a light spring, we can assume that the displacement of the spring is negligible. Therefore, the force exerted by the spring is zero.

The net force is then equal to the constant 50-N force:

Net force = 50 N

Applying Newton's second law, we have:

Net force = mass * acceleration

Solving for acceleration gives us:

Acceleration = Net force / mass = 50 N / 2 kg = 25 m/s^2

Since velocity is the derivative of displacement, we can integrate the acceleration with respect to time to find the velocity:

v = a * t

where v is the velocity, a is the acceleration, and t is the time.

Since the collar is released from rest at position A, the time taken to reach position B can be determined using the equation of motion:

s = u*t + (1/2)*a*t^2

where s is the displacement, u is the initial velocity, a is the acceleration, and t is the time.

Since the collar starts from rest, the initial velocity is zero. Solving for t gives us:

t = sqrt((2*s) / a) = sqrt((2*1.5 m) / 25 m/s^2) = 0.7746 s

Finally, substituting the values of acceleration and time into the equation for velocity gives us:

v = a * t = 25 m/s^2 * 0.7746 s = 19.365 m/s

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Answer:

 v = 0.0147 m / s

Explanation:

For this exercise let's use energy conservation

Starting point. Fully stretched spring

            Em₀ = Ke = ½ k (x-x₀)²

Final point. Unstretched position

          Emf = K = ½ m v²

          Emo = Emf

         ½ k (x- x₀)² = ½ m v²

           v = √m/k    (x-x₀)

Let's calculate

            v = √(0.022 / 0.5)      (0.26-0.19)

            v = 0.0147 m / s

The speed of the mass at the mean position is 0.333 m/s

The potential energy stored in a fully stretched spring

PE = ½ kx²

where x is the stretch of the spring  = 26 -19 = 7 cm = 0.07 m

At the mean position, where x = 0, the PE stored in sprig is zero,

So according to the law of conservation of energy total energy must remain conserved so all the energy is converted into kinetic energy KE of the mass

KE = ½ mv²

where m is the mass and v is the velocity

½ kx² = ½ mv²

where k is the spring constant = 0.5 N/m

and m is the mass = 0.022 kg

[tex]v=\sqrt{\frac{k}{m} } x[/tex]

[tex]v=\sqrt{\frac{0.5}{0.022} } 0.07[/tex]

v = 0.333 m/s

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Answer:

Atomic Size and Mass:

convert given density to kg/m^3 = 8900kg/m^3 2) convert to moles/m^3 (kg/m^3 * mol/kg) = 150847 mol/m^3 (not rounding in my actual calculations) 3) convert to atoms/m^3 (6.022^23 atoms/mol) = 9.084e28 atoms/m^3 4) take the cube root to get the number of atoms per meter, = 4495309334 atoms/m 5) take the reciprocal to get the diameter of an atom, = 2.2245e-10 m/atom 6) find the mass of one atom (kg/mol * mol/atoms) = 9.7974e-26 kg/atom Young's Modulus: Y=(F/A)/(dL/L) 1) F=mg = (45kg)(9.8N/kg) = 441 N 2) A = (0.0018m)^2 = 3.5344e-6 m^2 3) dL = 0.0016m 4) L = 2.44m 5) Y = 1.834e11 N/m^2 Interatomic Spring Stiffness: Ks,i = dY 1) From above, diameter of one atom = 2.2245e-10 m 2) From above, Y = 1.834e11 N/m^2 3) Ks,i = 40.799 N/m (not rounding in my actual calculations) Speed of Sound: v = ωd 1) ω = √(Ks,i / m,a) 2) From above, Ks,i = 40.799 N/m 3) From above, m,a = 9.7974e-26 kg 4) ω=2.0406e13 N/m*kg 5) From above, d=2.2245e-10 m 6) v=ωd = 4539 m/s (not rounding in actual calculations) Time Elapsed: 1) length sound traveled = L+dL = 2.44166 m 2) From above, speed of sound = 4539 m/s 3) T = (L+dL)/v = 0.000537505 s

Answer:

The scale reading at the top = 565.8N

The scale reading at the bottom = 610.44N

Explanation:

We are given:

t = 32seconds

R = 9.7meters

mass (m) = 60Kg

We take g as gravitational field = 9.8

Therefore, to find the scale reading (N) at the top, let's use the formula:

[tex] N_t = m (g - w^2 R) [/tex]

Where w = 2π/t

w = 2π/32 = 0.197

Substituting the figures into the equation, we have

[tex] N = 60 (9.8 - 0.197^2 * 9.7) [/tex]

N = 60 (9.8 - 0.37)

N = 60 * 9.43

Na = 565.8N

To find scalar reading at the bottom, we use;

[tex] N_b = m(g + w^2 R) [/tex]

= 60 (9.8 + 0.37)

= 60 * 10.17

[tex] N_b = 610.44 [/tex]

Answer:

The scale reading at the top is [tex]z_{top} = 565.6\mu N[/tex]

The scale reading at the bottom is [tex]z_{bottom} = 610.356\ N[/tex]

Explanation:

From the question

       The radius is [tex]r = 9.7 m[/tex]

       The period is [tex]T = 32sec[/tex]

      The mass is [tex]m =60kg[/tex]

Generally the mathematical representation for angular velocity of the wheel is

                  [tex]\omega = \frac{2 \pi}{T}[/tex]

                    [tex]= \frac{2*3.142}{32}[/tex]

                    [tex]= 0.196 \ rad/sec[/tex]

The velocity at which the point scale move can be obtained as

                     [tex]v = r\omega[/tex]

                        [tex]= 9.7* 0.196[/tex]

                       [tex]= 1.9 m/s[/tex]

Considering the motion of the 60kg mass as shown on the first and second uploaded image

Let the z represent the reading on the scale which is equivalent to the normal force acting on the mass.

          Now at the topmost the reading of the scale would be

                       [tex]mg - z_{top} =\frac{mv^2}{r} =m\omega^2r[/tex]

Where mg is the gravitational force acting on the mass and [tex]\frac{mv^2}{r}[/tex] is the centripetal force keeping the mass from spiraling out of the circle

Now making z the subject of the formula

                    [tex]z_{top} = mg - \frac{mv^2}{r}[/tex]

                       [tex]= m(g- \frac{v^2}{r})[/tex]

                       [tex]= 60(9.8 - \frac{1.9^2}{9.7} )[/tex]

                      [tex]= 565.6\mu N[/tex]

Now at the bottom the scale would be

                      [tex]z_{bottom}-mg = \frac{mv^2}{r} = m \omega^2r[/tex]

This is because in order for the net force to be in the positive y-axis (i.e for the mass to keep moving in the Ferris wheel) the Normal force must be greater than the gravitational force.  

Making  z the subject

                  [tex]z_{bottom}= mg +m\omega^2r[/tex]

                  [tex]z =m(g+\omega^2r)[/tex]

                  [tex]z= 60(9.8 + (0.196)^2 *(9.7))[/tex]

                     [tex]= 610.356\ N[/tex]

Explanation:

Below is an attachment containing the solution .

Answer:

The speed of the speeder is [tex]8.348x10^6m/s[/tex].

Explanation:

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).

That shift can be used to find the velocity of the object (in this case the speeder) by means of the 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_{0}-\lambda_{measured}}{\lambda_{0}})[/tex]

For this case [tex]\lambda_{measured}[/tex] is equal to 564.2 nm and [tex]\lambda_{0}[/tex] is equal to 575.9 nm.

[tex]v = (3x10^8m/s)(\frac{575.9 nm - 564.2 nm}{564.2 nm)})[/tex]

[tex]v = 8.348x10^6m/s[/tex]

Hence, the speed of the speeder is [tex]8.348x10^6m/s[/tex].

The question involves calculating the speed of a car based on the Doppler shift of light from yellow to green. The formula for Doppler shift of light is utilized to determine the relative velocity, but the practicality of such an effect for a moving car is negligible.

The question relates to the concept of the Doppler Effect for light, where the observed wavelength of light emitted by a source changes due to relative motion between the source and the observer. In this case, to calculate how fast the speeder would have to be traveling for the Doppler shift to change the color of a yellow light (575.9 nm) to green (564.2 nm), we can use the Doppler shift formula for light:

f' = f (c + v) / (c - v), where:

Since frequency is inversely proportional to wavelength (f = c / λ), the formula can be rearranged in terms of wavelength. Solving for v when the source is moving towards the observer gives us the expression:

v = c (λ0 - λ) / λ, where λ0 is the original wavelength and λ is the observed wavelength.

The speed of the car can thus be calculated accordingly. However, the effect of Doppler shift at such speeds is so small that it would not account for the perceptual change from yellow to green in a real-world scenario.

Answer:

[tex]c. 5cm \times 8cm[/tex]

Explanation:

The dimensions [tex]5cm\times 8cm[/tex] have the highest cross-sectional area combination of [tex]40cm^2[/tex].

-Resistance reduces with an increase in cross sectional area.

-[tex]Reason-[/tex]Electrons have alarger area to flow through.

Answer:

a) 201

b) 0

Explanation:

note:

solution is attached in word form due to error in mathematical equation. furthermore i also attach Screenshot of solution in word due to different version of MS Office please find the attachment

For the time interval from 0 to 2, sine wave reaches to zero for 201 times. Hence the current equals to zero for 201 times.

No charge transported through the light in the first second.

Given that, the current flowing through the bulb is [tex]I(t)=114 sin (100\pi t) \;\rm A[/tex].

The general equation of the current is,

[tex]I(t) =Asin(2\pi ft)[/tex]

So the frequency can be calculated as,

[tex]2\times \pi\times f\times t = 100\times \pi[/tex]

[tex]f =50 \;\rm Hz[/tex]

Hence the frequency of the sine wave is 50 Hz.

For the time interval from 0 to 2, the number of zero for the sine wave is,

[tex]No.\;of\; zero = (2\times50\times2 )+1[/tex]

[tex]No.\;of\;zero=201[/tex]

So, For the time interval from 0 to 2, sine wave reaches to zero for 201 times. Hence the current equals to zero for 201 times.

The charge can be calculated  by the formula given below.

[tex]Q(t) = \int\limits^{t_1}_{t_2} {I(t)} \ dt[/tex]

[tex]Q(t)=\int\limits^1_0 {114sin(100\pi t)} \ dt[/tex]

[tex]Q(t) = \dfrac {-114cos(100\pi t)}{100\pi}[/tex]

[tex]Q(t) = \dfrac {-114cos(100\pi \times 1)}{100\pi}-\dfrac {-114cos(100\pi \times0)}{100\pi}[/tex]

[tex]Q(t)=0[/tex]

Hence, no charge transported through the light in the first second.

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Answer a) impulse is 1360 kg.m/s

Explanation: impulse is impact force times the time of impact

I = 3400 * 0.4 = 1360kg.m/s

Answer b) final velocity is 10.1m/s

Explanation: impulse is the change of momentum

I = m(v-u)

V and u are final and initial velocities respectively.

1360 = 200 (v - 3.3)

1360 = 200v - 660

V = (1360+660)÷200

V = 10.1m/s

Q2 answer is: astronaut has KE approximately 208 times that of the truck

Explanation :

KE = 0.5mv^2

For truck

KE = 11000 * 33.3^2 = 12197790J

For astronaut

KE = 42 * 7777.7^2 = 2540689926J

Comparing

2540689926/12197790 = 208.2

NB: speed has been converted to m/s by multiplying with 0.28 I.e 1000/3600

Answer:

8.46 N/C

Explanation:

Using Gauss law

[tex]E=\frac {kQ}{r^{2}}[/tex]

Gauss's Law states that the electric flux through a surface is proportional to the net charge in the surface, and that the electric field E of a point charge Q at a distance r from the charge

Here, K is Coulomb's constant whose value is [tex]9\times 10^{9} Nm^{2}/C^{2}[/tex]

r = 0.43 + 0.106 = 0.536 m

[tex]E=\frac {9\times 10^{9}\times 0.270\times 10^{-9}}{0.536^{2}}=8.4581755402094007\approx 8.46 N/C[/tex]

The magnitude of the electric field at a point 0.106 m outside a solid metal sphere with a radius of 0.430 m and a net charge of 0.270 nC is approximately 892 N/C, to three significant figures.

The subject of your question is Physics, specifically focussing on electrostatics and the calculation of the electric field outside a charged sphere. The formula for the electric field (E) due to a point charge is given by Coulomb's Law, which is E = kQ/r^2, where 'Q' is the charge, 'r' is the distance from the charge, and 'k' is Coulomb's constant, approximately 8.99 x 10^9 N.m^2/C^2. Since the electric field due to a uniformly distributed spherical charge behaves as if all the charge is concentrated at the center, you can use this formula for the magnitude of the electric field outside the sphere.

Substituting the provided values (converted to appropriate units), we find E = (8.99 x 10^9 N.m^2/C^2 x 0.270 x 10^-9 C)/(0.536 m)^2, which gives E approximately equal to 892 N/C to three significant figures.

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Since there is a meeting of the cables at their midpoints, it is therefore understood that the force on them is the same but in the opposite direction, this to maintain the static balance between the two.

This can also be corroborated by applying the right hand rule for the force, at which depends of the magnetic field. The net force is zero because the cable segment to the left of the vertical cable feels an opposite force in the direction of the cable segment to the right.

Then the forces cancel.

Therefore the correct answer is C. Therefore the net force on each wire is zero

Answer:

a) [tex]F_H=776.952\ N[/tex]

b) [tex]F_g=706.32\ N[/tex]

c) [tex]v=5.4249\ m.s^{-1}[/tex]

d) [tex]KE=1059.48\ J[/tex]

Explanation:

Given:

a)

Now the force of lift by the helicopter:

Here the lift force is the resultant of the force of gravity being overcome by the force of helicopter.

[tex]F_H-F_g=m.a[/tex]

where:

[tex]F_H=72\times 0.981+72\times9.81[/tex]

[tex]F_H=776.952\ N[/tex]

b)

The gravitational force on the astronaut:

[tex]F_g=m.g[/tex]

[tex]F_g=72\times 9.81[/tex]

[tex]F_g=706.32\ N[/tex]

d)

Since the astronaut has been picked from an ocean we assume her initial velocity to be zero, [tex]u=0\ m.s^{-1}[/tex]

using equation of motion:

[tex]v^2=u^2+2a.h[/tex]

[tex]v^2=0^2+2\times 0.981\times 15[/tex]

[tex]v=5.4249\ m.s^{-1}[/tex]

c)

Hence the kinetic energy:

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

[tex]KE=0.5\times 72\times 5.4249^2[/tex]

[tex]KE=1059.48\ J[/tex]

Answer:

Explanation:

mass of helicopter, m = 72 kg

height, h = 15 m

acceleration, a = g/10

(a) Work done by the force

Work, W = force due to helicopter x distance

W = m x ( g + a) x h

W = 72 ( 9.8 + 0.98) x 15

W = 11642.4 J

(b) Work done by the gravitational force

W = - m x g x h

W = - 72 x 9.8 x 15

W = - 10584 J

(c) Kinetic energy = total Work done

K = 11642.4 - 10584

K = 1058.4 J

(d) Let the speed is v.

K = 0.5 x m v²

1058.4 = 0.5 x 72 x v²

v = 5.42 m/s

Now the force of lift by the helicopter:

where:

force by the helicopter

force of gravity

b)

The gravitational force on the astronaut:

d)

Since the astronaut has been picked from an ocean we assume her initial velocity to be zero,

using equation of motion:

c)

Hence the kinetic energy:

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Explanation:

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The magnitude of the magnetic force experienced by the bottom side of the rectangular coil, placed in a uniform magnetic field and carrying a current, is 21.16 N.

The subject of this question relates to the interaction of a current-carrying wire in a magnetic field, a fundamental concept in physics. In this particular setup, the magnetic force on each segment of the rectangular coil can be determined by the formula: F = I (L × B), where F is the magnetic force, I is the current, L is the length of the wire and B is the magnetic field. But in this instance, we're specifically interested in the force exerted on the bottom side of the loop, for which the magnetic field and current are perpendicular to each other.

Therefore, the force is given by F = ILB. By substituting the given values into the equation—the length of the bottom side (b = 0.46 m), the magnitude of the current (I = 10 A), and the strength of the magnetic field (B = 4.60 T)—we obtain: F = (10 A)(0.46 m)(4.60 T) = 21.16 N.

So, the magnitude of the magnetic force on the bottom side of the loop is 21.16 N.

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Answer:

[tex]k=13\ m[/tex]

Explanation:

Given:

From the given information by the laws of reflection we can deduce the distance of the first reflection of the back of the head of person in the rear mirror.

Distance of the first reflection of the back of the head in the rear mirror from the object head:

[tex]y'=2\times y[/tex]

[tex]y'=7\ m[/tex] is the distance of the image from the object back head.

Now the total distance of this image from the front mirror:

[tex]z=y'+x[/tex]

[tex]z=7+3[/tex]

[tex]z=10\ m[/tex]

So, the total distance of the image of the back of the head in the front mirror from the person will be:

[tex]k=x+z[/tex]

[tex]k=3+10[/tex]

[tex]k=13\ m[/tex]

Final answer:

The back of the head appears to be 16.00 meters away due to multiple reflections between two parallel mirrors 6.50 meters apart, when your head is positioned 3.00 meters from the nearer mirror.

Explanation:

The question revolves around a flat mirror problem in physics where multiple reflections between two parallel mirrors are considered. When a person looks into a flat mirror, the image of any object (like the back of the head) appears to be the same distance behind the mirror as the object is in front of it. So if your head is 3.00 meters away from the nearer mirror, the first image of the back of your head will appear 3.00 meters behind that mirror.

However, since there are two mirrors, this first image will then act as an object for the second, farther mirror, creating a new image. The additional distance to this second image will be twice the distance between the two mirrors. So, the total apparent distance will be the distance to the first image plus 6.50 meters times 2, which is 16.00 meters (3.00+6.50+6.50 = 16.00 meters). Therefore, the back of your head appears to be 16.00 meters away.