A loop of wire with cross-sectional area 2 m2 is inserted into a uniform magnetic field with initial strength 2 T. The field is parallel to the axis of the loop. The field begins to grow with time at a rate of 2 Teslas per hour. What is the magnitude of the induced EMF in the loop of wire

Answer:

L = 130 decibels

Explanation:

The computation of the sound intensity level in decibels is shown below:

According to the question, data provided is as follows

I = sound intensity = 10 W/m^2

I0 = reference level = [tex]1 \times 10-12 W/m^2[/tex]

Now

Intensity level ( or Loudness)is

[tex]L = log10 \frac{I}{10}[/tex]

[tex]L = log10 \frac{10}{1\times 10^{-12}}[/tex]

[tex]L = log10 \times 1013[/tex]

[tex]= 13 \times 1 ( log10(10) = 1)[/tex]

Therefore  

L = 13 bel

And as we know that

1 bel = 10 decibels

So,

The  Sound intensity level is

L = 130 decibels

Answer:

1ft per second

Explanation:

Physics is on my side!!!!!!!!!!

Answer:

τ = 0.26 N.m

Explanation:

First we find the moment of inertia of the wheel, by using the following formula:

I= mr²

where,

I = Moment of Inertia = ?

m = mass of wheel = 2.3 kg

r = radius of wheel = 50 cm/2 = 25 cm = 0.25 m

Therefore,

I = (2.3 kg)(0.25 m)²

I = 0.115 kg.m²

Now, we find the angular acceleration of the wheel:

α = (ωf - ωi)/t

where,

α = angular acceleration = ?

ωf = final angular velocity = (120 rpm)(2π rad/1 rev)(1 m/60 s) = 12.56 rad/s

ωi = Initial Angular Velocity = 0 rad/s

t = time = 5.5 s

Therefore,

α = (12.56 rad/s - 0 rad/s)/(5.5 s)

α = 2.28 rad/s²

Now, the torque is given as:

Torque = τ = Iα

τ = (0.115 kg.m²)(2.28 rad/s²)

τ = 0.26 N.m

Answer:

[tex]v_{2}=3.5 m/s[/tex]

Explanation:

Using the conservation of energy we have:

[tex]\frac{1}{2}mv^{2}=mgh[/tex]

Let's solve it for v:

[tex]v=\sqrt{2gh}[/tex]

So the speed at the lowest point is [tex]v=7 m/s[/tex]

Now, using the conservation of momentum we have:

[tex]m_{1}v_{1}=m_{2}v_{2}[/tex]

[tex]v_{2}=\frac{1*7}{2}[/tex]

Therefore the speed of the block after the collision is [tex]v_{2}=3.5 m/s[/tex]

I hope it helps you!

Answer:

Acceleration of the asteroid relative to the spacecraft = 2ε[tex]E^{2}[/tex]A/m

Explanation:

The maximum electric field in the beam = 2E

cross-sectional area of beam = A

The intensity of an electromagnetic wave with electric field is

I = cε[tex]E_{0} ^{2}[/tex]/2

for [tex]E_{0}[/tex] = 2E

I = 2cε[tex]E^{2}[/tex]    ....equ 1

where

I is the intensity

c is the speed of light

ε is the permeability of free space

[tex]E_{0}[/tex]  is electric field

Radiation pressure of an electromagnetic wave on an absorbing surface is given as

P = I/c

substituting for I from above equ 1. we have

P = 2cε[tex]E^{2}[/tex]/c = 2ε[tex]E^{2}[/tex]    ....equ 2

Also, pressure P = F/A

therefore,

F = PA    ....equ 3

where

F is the force

P is pressure

A is cross-sectional area

substitute equ 2 into equ 3, we have

F = 2ε[tex]E^{2}[/tex]A

force on a body = mass x acceleration.

that is

F = ma

therefore,

a = F/m

acceleration of the asteroid will then be

a = 2ε[tex]E^{2}[/tex]A/m

where m is the mass of the asteroid.

Answer:

a) yes

b) no

c) yes

d)Cart 2 with mass [tex]\frac{M}{3}[/tex]   is expected to be more faster

e) u₂ = 48 m/s

Explanation:

a) the all out linear momentum of an arrangement of particles of Cart 1 not followed up on by external forces is constant.

b) the linear momentum of Cart 2 will be acted upon by external force by Cart 1 with mass M, thereby it's variable and the momentum is not conserved

c) yes, the momentum is conserved because no external force acted upon it and both Carts share the same velocity after the reaction

note: m₁u₁ + m₂u₂ = (m₁ + m₂)v

d) Cart 2 with mass [tex]\frac{M}{3}[/tex] will be faster than Cart 1 because Cart 2 is three times lighter than Cart 1.

e) Given

m₁=  M

u₁ = 16m/s

m₂ =[tex]\frac{M}{3}[/tex]

u₂ = ?

from law of conservation of momentum

m₁u₁= m₂u₂

M× 16 = [tex]\frac{M}{3}[/tex] × u₂(multiply both sides by 3)

therefore, u₂ = [tex]\frac{3(M .16)}{M}[/tex] ("." means multiplication)

∴u₂ = 3×16 = 48 m/s

Answer:

 θ₁ = 0.04º , θ₂ = 0.00118º

Explanation:

The equation that describes the diffraction pattern of a network is

             d sin θ = m λ

where the diffraction order is, in this case they indicate that the order

m = 1

           θ = sin⁻¹ (λ / d)

Trfuvsmod ls inrsd fr ll red s SI units

           d = 12000 line / inc (1 inc / 2.54cm) = 4724 line / cm

the distance between two lines we can look for it with a direct proportions rule

If there are 4724 lines in a centimeter, the distance for two hundred is

            d = 2 lines (1 cm / 4724 line) = 4.2337 10⁻⁴ cm

let's calculate the angles

λ = 300 10-9 m

            θ₁ = sin⁻¹ (300 10-9 / 4,2337 10-4)

            θ₁ = sin⁻¹ (7.08 10-4)

            θ₁ = 0.04º

λ = 5000

          θ₂ = sin-1 (500 10-9 / 4,2337 10-4)

          θ₂ = 0.00118º

Answer:

Explanation:

Power of electrical circuit = I² R where I is current and R is resistance

Putting the given data

1.64 x 10⁵ = 12² x R

R = 1.139 x 10³ ohm

= 1139 ohm .

Answer:

r=1140ohms

Explanation: plato family

Answer:

Since the angular acceleration of the objects will be proportional to the torque (due to gravity) acting on them and they will all experience the same torque their accelerations will be inversely proportional to their moments of inertia:

I disk = 1/2 M R^2

I sphere = 2/5 M R^2

I shell = 2/3 M R^2

Thus the sphere will experience the greatest angular acceleration and reach the bottom first, and then be followed by the disk and the shell.

By conservation of energy they will all have the same kinetic energy when they reach the bottom of the ramp.

(a) The ranking of the objects in order of how they will finish the race is

solid sphere > disk > hollow spherical shell

(b) The ranking of the objects in order of kinetic energy is

solid sphere > disk > hollow spherical shell

The moment of inertia of each object is calculated as follows;

The angular momentum of the objects is calculated as follows;

[tex]L =I \omega \\\\\omega = \frac{L}{I}[/tex]

The object with the least moment of inertia is will have the highest speed.

The ranking of the objects in order of how they will finish the race;

solid sphere > disk > hollow

The kinetic energy of the objects is calculated as follows;

[tex]K.E = \frac{1}{2} I \omega ^2[/tex]

The ranking of the objects in order of kinetic energy;

solid sphere > disk > hollow

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Answer:

B

Explanation:

ANSEWER :B IN ROWS ONLY

Answer:

0.80 c

Explanation:

The computation of speed is shown below:-

Here, The speed of the captain ship A report for speed of the ship B which is

[tex]S = \frac{S_A + S_B}{1 + \frac{(S_AS_B)}{c^2} }[/tex]

where

[tex]S_A[/tex] indicates the speed of the ship A

[tex]S_B[/tex] indicates the speed of the ship B

and

C indicates the velocity of life

now we will Substitute 0.40c for A and 0.60 for B in the equation which is

[tex]S = \frac{0.40c + 0.60c}{1 + \frac{(0.40c)(0.60c)}{c^2} }[/tex]

after solving the above equation we will get

0.80 c

So, The correct answer is 0.80c

Answer:

The mass is  [tex]m =6.4*10^{-28} \ kg[/tex]

Explanation:

From the question we are told that

   The  speed of the charge is  [tex]v = 1.0 *10^{6} \ m/s[/tex]

    The  magnetic field is  [tex]B = 0.20 \ T[/tex]

     The radius is [tex]r = 0.02 \ m[/tex]

      The value of the charge is  [tex]e = 1.60 *10^{-19} \ C[/tex]

The centripetal acting on the charge moving in the circular orbit is mathematically represented as

        [tex]F_c = \frac{mv^2}{r }[/tex]

Now this centripetal force is due to the force exerted on the charge by the magnetic field on the charge which is mathematically represented as

     [tex]F_m = qv B sin\theta[/tex]

At the maximum of this magnetic force [tex]\theta = 90 ^o[/tex]

So  

     [tex]F_m = e v B sin(90)[/tex]

      [tex]F_m = e v B[/tex]

Now given that it is this  magnetic force that is causing the circular motion we have that

       [tex]F_c = F_m[/tex]

=>     [tex]\frac{mv^2}{r } = ev B[/tex]

=>     [tex]m = \frac{e * B * r }{v }[/tex]

substituting values

       [tex]m = \frac{ 1.60 *10^{-19} * 0.20 * 0.020 }{1.0*10^{6} }[/tex]

     [tex]m =6.4*10^{-28} \ kg[/tex]

Answer:

I believe the answer is in fact section (VW) on the line where the electric field result will be zero.

Explanation:

The direction of the electric field due to a positive charge is away from it and the direction of the electric field due to a negative one is towards it.

Answer:

In collision between equal-mass objects, each object experiences the same acceleration, because of equal force exerted on both objects.

Explanation:

In a collision two objects, there is a force exerted on both objects that causes an acceleration of both objects. These forces that act on both objects are equal in magnitude and opposite in direction.

Thus, in collision between equal-mass objects, each object experiences the same acceleration, because of equal force exerted on both objects.

Answer:

The direction of electric field and equipotential line at the same point are always PERPENDICULAR TO THE ELECTRIC FIELD.

Explanation:

Equipotential surface is a three dimensional part of equipotential lines.

Equipotential lines are a type of contour lines that is use to trace lines that have the same altitude on the map and the altitude is the electric potential.

Equipotential lines are always perpendicular to electric potential because the lines creates three dimension equipotential surface.

The direction of the electric field and equipotential line at the same point is always perpendicular.

The electric field and the electric potential both are dependent on distance. As we move farther from the source generating the electric field, the electric field strength, as well as the electric potential strength, decreases.

The electric field is inversely proportional to the square of the distance from the source, while the electric potential is inversely proportional to the distance itself.

The equipotential surface is a surface on which every point is at the same distance from the source so that each point is at the same potential.

Now, we can make an equipotential line joining these points. Since it is fixed at a surface, we can not move farther or closer to the source, because there will be a change in the distance and the potential will change.

So these lines are always perpendicular to the lines representing the electric field, which travel towards or away from the source

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Answer:

109.32 N/m

Explanation:

Given that

Mass of the hung object, m = 8 kg

Period of oscillation of object, T = 1.7 s

Force constant, k = ?

Recall that the period of oscillation of a Simple Harmonic Motion is given as

T = 2π √(m/k), where

T = period of oscillation

m = mass of object and

k = force constant if the spring

Since we are looking for the force constant, if we make "k" the subject of the formula, we have

k = 4π²m / T², now we go ahead to substitute our given values from the question

k = (4 * π² * 8) / 1.7²

k = 315.91 / 2.89

k = 109.32 N/m

Therefore, the force constant of the spring is 109.32 N/m

Complete question is;

(a) A light, rigid rod of length, l = 1.00 m joins two particles, with masses m = 4.00 kg and m, = 3.00 kg, at its ends. The combination rotates in the xy-plane about a pivot through the center of the rod (see figure below). Determine the angular momentum of the system about the origin when the speed of each particle is 6.4 m/s. (Enter the magnitude to at least two decimal places in kg. m/s.)

(b) What If? What would be the new angular momentum of the system (in kg. m/s) if each of the masses were instead a solid sphere 15.0 cm in diameter? (Round your answer to at least two decimal places.)

Answer:

A) L = 22.4 kg.m²/s and it's direction will be along the positive(+ve) z-axis

B) L = 3.36 kg.m²/s

Explanation:

The image is missing, so i have attached it.

Formula for the moment of Inertia would be; I = mr²

m1 = 4 kg

m2 = 3 kg

r = 1/2 = 0.5 m

So, sum of moment of inertia for the 2 masses would be;

I = (4 × 0.5²) + (3 × 0.5²)

I = 1.75 kg.m²

Now, angular velocity is given by the formula;

ω = v/r

We are given v = 6.4 m/s

So;

ω = 6.4/0.5

ω = 12.8 rad/s

Now, let's find angular momentum.

Angular momentum; L = Iω

L = 1.75 × 12.8

L = 22.4 kg.m²/s

Now, using the right hand rule, the direction will be along the positive(+ve) z-axis.

B) Now, the new diameter is 15 cm = 0.15 m

Thus,

radius;r = 0.15/2 = 0.075 m

Similar to a above;

I = (4 × 0.075²) + (3 × 0.075²)

I = 0.039375 kg.m²

ω = v/r

We are given v = 6.4 m/s

ω = 6.4/0.075

ω = 85.33 rad/s

Angular momentum; L = Iω

L = 0.039375 × 85.33

L = 3.36 kg.m²/s

The Complete question is;

(a) A light, rigid rod of length, l = 1.00 m joins two particles, with masses m = 4.00 kg and m, = 3.00 kg, at its ends. The combination rotates in the xy-plane about a pivot through the center of the rod (see figure below). Determine the angular momentum of the system about the origin when the speed of each particle is 6.4 m/s. (Enter the magnitude to at least two decimal places in kg. m/s.)

(b) What If? What would be the new angular momentum of the system (in kg. m/s) if each of the masses were instead a solid sphere 15.0 cm in diameter? (Round your answer to at least two decimal places.) Image check below.

A) L is = 22.4 kg.m²/s and it's direction will be along the positive(+ve) z-axis

B) L is = 3.36 kg.m²/s

We are applying the Formula for the moment of Inertia would be; I = mr²

Then, m1 = 4 kg

After that, m2 is = 3 kg

Now, r = 1/2 = 0.5 m

So, When the sum of the moment of inertia for the 2 masses would be;

Then, I = (4 × 0.5²) + (3 × 0.5²)

After that, I = 1.75 kg.m²

Now, when the angular velocity is given by the formula;

Then, ω = v/r

We are given v is = 6.4 m/s

Then, ω = 6.4/0.5

After that, ω = 12.8 rad/s

Now, let's find the angular momentum.

Then, the Angular momentum; L = Iω

L is = 1.75 × 12.8

Theregore, L = 22.4 kg.m²/s

Now, we are using the right-hand rule, the direction will be along the positive(+ve) z-axis.

B) Now, wehn the new diameter is 15 cm = 0.15 m

Thus, radius;r = 0.15/2 = 0.075 m

Then, Similar to a above;

After that, I = (4 × 0.075²) + (3 × 0.075²)

Now, I = 0.039375 kg.m²

Then, ω = v/r

We are given v = 6.4 m/s

ω is = 6.4/0.075

ω is = 85.33 rad/s

When the Angular momentum; L = Iω

Then, L = 0.039375 × 85.33

Therefore, L = 3.36 kg.m²/s

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Answer:

9.53 m

Explanation:

The computation of shortest organ pipe with both ends open that will resonate at this frequency is shown below:-

[tex]\lambda = \frac{velocity}{frequency}[/tex]

[tex]= \frac{343}{18}[/tex]

= 19.06 m

Now the

Shortest organ pipe  with both ends open is

=  [tex]\frac{\lambda}{2}[/tex]

[tex]= \frac{19.06}{2}[/tex]

= 9.53 m

Basically we applied the above formulas so that first we easily determined the shortest organ pipe for both ends at this frequency

Answer:

10.2 lbs

Explanation:

m=F/g

m=100N/9.8

m=10.2040816 lbs

The weight of the object in pounds will be 220.46 pounds m/s².

We have an object on Earth whose weight is 100 N.

We have to determine its weight in pounds.

Pounds is used to represent the mass of the body.

According tot the question -

Weight on earth = 100 N = 100 Kg . m/s²

1 Kg = 2.2046 Pounds

Therefore, the weight on earth in pounds will be = 100 x 2.2046 pounds m/s² = 220.46 pounds m/s².

Hence, the weight of the object in pounds will be 220.46 pounds m/s².

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Answer:

"Energy deficiency, no coal-burning, no-cost mining pollution" is the correct answer.

Explanation:

Answer:

The new angular speed is [tex]w = 6 \ rev/s[/tex]

Explanation:

From the  question we are told that

      The angular velocity of the spin is  [tex]w_o = 3 \ rev/s[/tex]

       The  original moment of inertia is  [tex]I_o[/tex]

        The new moment of inertia is  [tex]I =\frac{I_o}{2}[/tex]    

Generally angular momentum is mathematically represented as

      [tex]L = I * w[/tex]

Now according to the law of conservation of momentum, the initial momentum is equal to the final momentum hence the angular momentum is constant so

         [tex]I * w = constant[/tex]

=>       [tex]I_o * w _o = I * w[/tex]

where w is the new angular speed  

  So  

          [tex]I_o * 3 = \frac{I_o}{2} * w[/tex]

=>        [tex]w = \frac{3 * I_o}{\frac{I_o}{2} }[/tex]

=>         [tex]w = 6 \ rev/s[/tex]

Answer:

x=22.57 m

Explanation:

Given that

35 m in W of S

angle = 40 degrees

25 m in east

From the diagram

The angle

[tex]\theta=90-40=50^o[/tex]

From the triangle OAB

[tex]cos40^o=\frac{35^2+25^2-x^2}{2\times 35\times 25}[/tex]

[tex]1340.57=35^2+25^2-x^2[/tex]

x=22.57 m

Therefore the answer of the above problem will be 22.57 m

Complete Question:

A 0.50-kg ball that is tied to the end of a 1.5-m light cord is revolved in a horizontal plane, with the cord making a 30° angle with the vertical.

(a) Determine the ball’s speed. (b) If, instead, the ball is revolved so that its

speed is 3.7 m/s, what angle does the cord make with the vertical?

(Check attached image for the diagram.)

Answer:

(a) The ball’s speed, v = 2.06 m/s

(b) The angle the cord makes with the vertical is 50.40⁰

Explanation:

If the ball is revolved in a horizontal plane, it will form a circular trajectory,

the radius of the circle, R = Lsinθ

where;

L is length of the string

The force acting on the ball is given as;

F = mgtanθ

This above is also equal to centripetal force;

[tex]mgTan \theta = \frac{mv^2}{R} \\\\Recall, R = Lsin \theta\\\\mgTan \theta = \frac{mv^2}{Lsin \theta}\\\\v^2 = glTan \theta sin \theta\\\\v = \sqrt{glTan \theta sin \theta} \\\\v = \sqrt{(9.8)(1.5)(Tan30)(sin30)} \\\\v = 2.06 \ m/s[/tex]

(b) when the speed is 3.7 m/s

[tex]v = \sqrt{glTan \theta sin \theta} \ \ \ ;square \ both \ sides\\\\v^2 = glTan \theta sin \theta\\\\v^2 = gl(\frac{sin \theta}{cos \theta}) sin \theta\\\\v^2 = \frac{gl*sin^2 \theta}{cos \theta} \\\\v^2 = \frac{gl*(1- cos^2 \theta)}{cos \theta}\\\\gl*(1- cos^2 \theta) = v^2cos \theta\\\\(9.8*1.5)(1- cos^2 \theta) = (3.7^2)cos \theta\\\\14.7 - 14.7cos^2 \theta = 13.69cos \theta\\\\14.7cos^2 \theta + 13.69cos \theta - 14.7 = 0 \ \ \ ; this \ is \ quadratic \ equation\\\\[/tex]

[tex]Cos\theta = \frac{13.69\sqrt{13.69^2 -(-4*14.7*14.7)} }{14.7} \\\\Cos \theta = 0.6374\\\\\theta = Cos^{-1}(0.6374)\\\\\theta = 50.40 ^o[/tex]

Therefore, the angle the cord makes with the vertical is 50.40⁰

Answer:

The wavelength is  [tex]\lambda = 6.28 *10^{-7}=628 nm[/tex]

The frequency is  [tex]f = 4.78 Hz[/tex]

Explanation:

From the question we are told that  

      The slit distance is [tex]d = 0.048 \ mm = 4.8 *0^{-5}\ m[/tex]

       The distance from the screen is  [tex]D = 6.50 \ m[/tex]

       The distance between fringes is  [tex]Y = 8.5 \ cm = 0.085 \ m[/tex]

Generally the distance between the fringes for a two slit interference is  mathematically represented as

           [tex]Y = \frac{\lambda * D}{d}[/tex]

=>       [tex]\lambda = \frac{Y * d }{D}[/tex]

substituting values      

           [tex]\lambda = \frac{0.085 * 4.8*10^{-5} }{6.50 }[/tex]

           [tex]\lambda = 6.27 *10^{-7}=628 nm[/tex]

Generally the frequency of the light is mathematically represented as

          [tex]f = \frac{c}{\lambda }[/tex]

where  c is  the speed of light with  values  

         [tex]c = 3.0 *10^{8} \ m/s[/tex]

substituting values  

      [tex]f = \frac{3.0*10^8}{6.28 *10^{-7}}[/tex]

      [tex]f = 4.78 Hz[/tex]

Answer and Explanation:

There is no probability of obtaining such a circuit of closed track current carrying wire whose field of magnitude displays i.e.  [tex]B \alpha \frac{1}{r^2}[/tex]

The magnetic field is a volume of vectors

And [tex]\phi\ bds = 0[/tex]. This ensures isolated magnetic poles or magnetic charges would not exit

Therefore for a closed path,  we never received magnetic field that followed the [tex]B \alpha \frac{1}{r^2}[/tex] it is only for the simple current-carrying wire for both finite or infinite length.

Answer:

A: An upward force balances the downward force of gravity on the skydiver.

Explanation:

on edge! hope this helps!!~ (⌒▽⌒)☆

Answer:

A. pressure is distributed uniformly throughout the fluid and the area of the plunger is much larger than the area of the opening.

Explanation:

Pressure is the force acting per unit area.  Also, pressure is transmitted undiminished to every of the fluid under pressure, so the same pressure at the plunger will be transmitted to the small opening. Since the opening area is small, the force required to force the caulk out of the opening under pressure will have to be very large at the plunger to be sufficient to force the caulk out of the small opening area.

Answer:

The angular momentum of the crate is [tex]M_{C} V_{1} d[/tex]

Explanation:

mass of the crate = [tex]M_{C}[/tex]

speed of forklift = [tex]V_{1}[/tex]

The distance between the center of the mass and the point A = d

Recall that the angular moment is the moment of the momentum.

[tex]L = P*d[/tex]    ..... equ 1

where L is the angular momentum,

P is the momentum of the system,

d is the perpendicular distance between the crate and the point on the axis about which the momentum acts. It is equal to d from the image

Also, we know that the momentum P is the product of mass and velocity

P = mv      ....equ 2

in this case, the mass = [tex]M_{C}[/tex]

the velocity = [tex]V_{1}[/tex]

therefore, the momentum P = [tex]M_{C}[/tex][tex]V_{1}[/tex]

we substitute equation 2 into equation 1 to give

[tex]L = M_{C} V_{1} d[/tex]

Answer:

474.34 m

Explanation:

From the question,

E = kq/r²................. Equation 1

Where E = Electric Field, k = coulomb's constant, q = Charge, r = distance.

Make r the subject of the equation

r = √(kq/E)............ Equation 2

Given: q = 50 nC = 50×10⁻⁹ C, E = 0.002 N/C

Constant: k = 9×10⁹ Nm²/C².

Substitute these values into equation 2

r = √(50×10⁻⁹×9×10⁹/0.002)

r = √(450/0.002)

r = √(225000)

r = 474.34 m