Suppose a disk drive has the following characteristics:

1. Four surfaces
2. 1,024 tracks per surface
3. 128 sectors per track
4. 512 bytes/sector
5. Track-to-track seek time of 5ms
6. Rotational speed of 5,000rpm 1.

Required:
a. What is the capacity of the drive?
b. What is the access time?

Answer:

Changes of state. The kinetic theory of matter can be used to explain how solids, liquids and gases are interchangeable as a result of increase or decrease in heat energy. ... If it is cooled the motion of the particles decreases as they lose energy.13 Nov 2000

Explanation:

Answer:

(b) electrons will not be ejected

Explanation:

Determine the number of photons ejected by 10 W red laser pointer.

The wavelength (λ) of red light is  700 nm = 700 x 10⁻⁹ m

Energy of a photon is given as;

[tex]E = \frac{hc}{\lambda}[/tex]

where;

h is Planck's constant, = 6.626 x 10⁻³⁴ J/s

c is speed of light, = 3 x 10⁸ m/s

[tex]E = \frac{6.626*10^{-34} *3*10^8}{700 X 10^{-9}} \\\\E = 2.8397 *10^{-19} \ J/photon[/tex]

The number of photons emitted by 10 W red laser pointer

10 W = 10 J/s

[tex]Number \ of \ photons = 10(\frac{ J}{s}) * \frac{1}{2.8397*10^{-19}} (\frac{photon}{J} ) = 3.522 *10^{19} \ photons/s[/tex]

Determine the number of photons ejected by 5 W red green pointer

The wavelength (λ) of green light is  500 nm = 500 x 10⁻⁹ m

[tex]E = \frac{hc}{\lambda} = \frac{6.626*10^{-34} *3*10^8}{500*10^{-9}} = 3.9756 *10^{-19} \ J/photon[/tex]

The number of photons emitted by 5 W green laser pointer

5 W = 5 J/s

[tex]Number \ of \ photons = \frac{5J}{s} *\frac{photon}{3.9756*10^{-19}J} = 1.258 *10^{19} \ Photons/s[/tex]

The number of photons emitted by 10 W red laser pointer is greater than the number of photons emitted by 5 W green laser pointer.

Thus, 5 W green laser pointer will not be able to eject electron from the same metal.

The correct option is "(b) electrons will not be ejected"

Answer:

x = 46.54m

Explanation:

In order to find the length of the incline you use the following formula:

[tex]x=v_ot+\frac{1}{2}at^2[/tex]      (1)

vo: initial speed of the soccer ball = 0 m/s

t: time

a: acceleration

You first use the the fact that the ball traveled 22 m in 2.2 s. Whit this information you can calculate the acceleration a from the equation (1):

[tex]22m=\frac{1}{2}a(2.2s)^2\\\\a=9.09\frac{m}{s^2}[/tex]      (2)

Next, you calculate the distance traveled by the ball for t = 3.2 s (one second later respect to t = 2.2s). The values of the distance calculated is the lenght of the incline:

[tex]x=\frac{1}{2}(9.09m/s^2)(3.2s)^2=46.54m[/tex]       (3)

The length of the incline is 46.54 m

Answer:

a) vo = 14m/s

b) v = 14m/s

c) t = 2.85s

d) t = 0.829s

e) v =  22.12 m/s

Explanation:

a) To find the initial velocity of the ball yo use the following formula:

[tex]h_{max}=\frac{v_o^2}{2g}[/tex]         (1)

hmax:  maximum height reached by the ball but measured from the point at which the ball is thrown = 25.0m - 15.0m = 10.0m

vo: initial velocity of the ball = ?

g: gravitational acceleration = 9.8m/s^2

You solve the equation (1) for vo and replace the values of the other parameters:

[tex]v_o=\sqrt{2gh_{max}}}=\sqrt{2(9.8m/s^2)(10.0m)}=14\frac{m}{s}[/tex]

The initial velocity of the ball is 14m/s

b) To find the velocity of the ball when it is at the same position as the initial point where it was thrown, you can use the following formula:

[tex]v^2=2gh_{max}\\\\v=\sqrt{2gh_{max}}[/tex]        

as you can notice, v = vo = 14m/s

The velocity of the ball is 14 m/s

c) The flight time of the ball is given by twice the time the ball takes to reach the maximum height. You use the following formula:

[tex]t=2\frac{v_o}{g}=2\frac{14m/s}{9.8m/s^2}=2.85s[/tex]             (3)

The time is 2.85s

d) To find the time the ball takes to arrive to the ground after the ball passes the same height at which is was thrown, you can use the following formula:

[tex]y=y_o-v_ot-\frac{1}{2}gt^2[/tex]          (4)

y: 0 m (ball just after it impact the ground)

yo: initial position = 15.0 m

vo: in)itial velocity of the ball = 14m/s    

t: time

You replace the values of the parameters in the equation (4) and obtain a quadratic formula:

[tex]0=15.0-14t-\frac{1}{2}(9.8)t^2\\\\[/tex]

You use the quadratic formula to find the roots t:

[tex]t_{1,2}=\frac{-(-14)\pm\sqrt{(-14)^2-4(4.9)(15)}}{2(-4.9)}\\\\t_{1,2}=\frac{14\pm22.13}{-9.8}\\\\t_1=0.829s\\\\t_2=-2.19s[/tex]

you choose the positive values because is has physical meaning

The time the ball takes to arrive to the ground is 0.829s

e) The final velocity is:

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

[tex]v=14m/s+(9.8m/s^2)(0.829s)=22.12\frac{m}{s}[/tex]

The final velocity is 22.14 m/s

Answer:

17 m/s

Explanation:

Given:

Tension = 600 N

Mass of object, M= 12 kg

Radius, r = 5.78 m

Required:

Find the speed the rod will break

Here, the motor is continuously increased. To find the speed the rod will break (speed of centripetal force), we have:

Tension = Centripetal force

Where centripetal force = [tex] \frac{mv^2}{r} [/tex]

Therefore,

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

Make v subject of the formula:

[tex] v = \sqrt{\frac{T*r}{m}} [/tex]

[tex] = \sqrt{\frac{600*5.78}{12}} [/tex]

[tex] = \sqrt{\frac{3468}{12} [/tex]

[tex] = \sqrt{289} [/tex]

[tex] = 17 m/s [/tex]

Speed the rod will break is 17 m/s.

Answer:

The electric force is  [tex]F = 11.9 *10^{-9} \ N[/tex]

Explanation:

From the question we are told that

    The  Bohr radius at ground state is  [tex]a_o = 0.529 A = 0.529 ^10^{-10} \ m[/tex]

    The values of the distance between the proton and an electron  [tex]z = 2.63a_o[/tex]

The electric force is mathematically represented as

     [tex]F = \frac{k * n * p }{r^2}[/tex]

Where n and p are charges on a single electron and on a single proton which is mathematically represented as

      [tex]n = p = 1.60 * 10^{-19} \ C[/tex]

    and  k is the coulomb's  constant with a value

           [tex]k =9*10^{9} \ kg\cdot m^3\cdot s^{-4}\cdot A^2.[/tex]

substituting values

       [tex]F = \frac{9*10^{9} * [(1.60*10^{-19} ]^2)}{(2.63 * 0.529 * 10^{-10})^2}[/tex]

         [tex]F = 11.9 *10^{-9} \ N[/tex]

Answer:

N = 13.65 rpm

Explanation:

given data

radius = 11 m

centripetal acceleration =  2.3 times that due to gravity

to find out

how many revolutions per minute

solution

we know here centripetal accel = 2.3 × g

ω²r  = 2.3 × 9.8

ω² × 11  = 2.3 × 9.8  

solve it we get

ω² = 2.0490

ω = 1.43 rad/s

and

ω = [tex]\frac{2\pi N}{60}[/tex]

1.43 = [tex]\frac{2\pi N}{60}[/tex]  

solve it we get

N = 13.65 rpm

Answer:

a) [tex]E = \frac{1}{2} \cdot k \cdot x^{2} + \frac{1}{2} \cdot m \cdot v^{2}[/tex], b) Amplitude of the motion is [tex]A = \sqrt{\frac{2\cdot E}{k} }[/tex], c) The maximum speed attained by the object during its motion is [tex]v_{max} = \sqrt{\frac{2\cdot E}{m} }[/tex].

Explanation:

a) The total energy of the object is equal to the sum of potential and kinetic energies. That is:

[tex]E = K + U[/tex]

Where:

[tex]K[/tex] - Kinetic energy, dimensionless.

[tex]U[/tex] - Potential energy, dimensionless.

After replacing each term, the total energy of the object at any point in its motion is:

[tex]E = \frac{1}{2} \cdot k \cdot x^{2} + \frac{1}{2} \cdot m \cdot v^{2}[/tex]

b) The amplitude of the motion occurs when total energy is equal to potential energy, that is, when objects reaches maximum or minimum position with respect to position of equilibrium. That is:

[tex]E = U[/tex]

[tex]E = \frac{1}{2} \cdot k \cdot A^{2}[/tex]

Amplitude is finally cleared:

[tex]A = \sqrt{\frac{2\cdot E}{k} }[/tex]

Amplitude of the motion is [tex]A = \sqrt{\frac{2\cdot E}{k} }[/tex].

c) The maximum speed of the motion when total energy is equal to kinetic energy. That is to say:

[tex]E = K[/tex]

[tex]E = \frac{1}{2}\cdot m \cdot v_{max}^{2}[/tex]

Maximum speed is now cleared:

[tex]v_{max} = \sqrt{\frac{2\cdot E}{m} }[/tex]

The maximum speed attained by the object during its motion is [tex]v_{max} = \sqrt{\frac{2\cdot E}{m} }[/tex].

Answer:

The magnitude of the displacement of the car = 16.97 miles (North-West of A)

Explanation:

Attached to this answer is a diagram to give you a visual on what is going on i the question

Let the magnitude of the car's displacement be 'd'

The triangle formed is a right angled triangle, using the Pythagoras theorem:

d² = 12² + 12² (Hyp² = Opp² + Adj²)

d² = 144 +144 = 288

d =√ 288 = 16.97 miles

Therefore the magnitude of the displacement of the car = 16.97 miles (North-West of A)

Answer:

xtotal = 90km

displacement = 18km N

Explanation:

To find the total distance traveled by the car, you first calculate the distance traveled by the car when it travels to north. You use the following formula:

[tex]x=vt[/tex]    (1)

x: distance

v: speed of the car = 30 m/s

t: time = one half hour

In order to calculate the distance you convert the time from hours to seconds:

[tex]t=0.5\ h*\frac{3600s}{1\ h}=1800s[/tex]

Then, you replace the values of t and v in the equation (1):

[tex]x=(30m/s)(1800s)=54000m[/tex]     (2)

Next, you calculate the distance traveled by the car when it travels to south:

[tex]x'=v't'\\\\v'=40\frac{m}{s}\\\\t'=15\ min[/tex]

You convert the time from minutes to seconds:

[tex]t'=15\ min*\frac{60s}{1min}=900s[/tex]

[tex]x'=(40m/s)(900s)=36000m[/tex]

Finally, you sum both distances x and x':

[tex]x_{total}=x+x'=54000m+36000m=90000m=90km[/tex]

The total distance traveled by the car is 90km

The total displacement is the final distance of the car respect to the starting point of the motion. This is calculated by subtracting x' to x:

[tex]d=x-x'=54000m-36000m=18000m=18km[/tex]

The total displacement of the car is 18km to the north from its starting point of motion.

Answer:

Force

Explanation:

Force is simply known as pull or push of an object

Answer:

It is the force that opposes motion between two surfaces touching each other. ( OR ) The force between two surfaces that are sliding or trying to slide across each other.

Explanation:

Answer:

a constant force that acts on objects that rub together

Explanation:

a constant force that acts on objects that rub together

The question is incomplete, however, the correct question is attached

in the image format:

Answer:

B. 171 N

Explanation:

The equation of the forces along the

Horizontal direction:

[tex]T_{2} cos62^{0} = T_{1} cos20^{0}[/tex]...... 1

Verticalb direction:

[tex]T_{1} sin20^{0} = T_{2} sin62^{0}[/tex] = W . . . 2

Where W = 180 N is the weight of the box.

From equation (1),

[tex]= T_{1} =T_{2} \frac{cos62^{0}}{ cos20^{0}}[/tex]

Substituting into equation (2),

[tex](T_{2} \frac{cos62^{0}}{ cos20^{0}})[/tex][tex]sin20^{0} = T_{2} sin62^{0}[/tex]

= [tex]T = \frac{W}{cos62x^{0} tan20x^{0}+sin62x^{0} }[/tex]

=117 N

Thus, the correct answer is option B. 117 N

Answer:

The answer is electromagnetic

Answer:

electromagnetic

Explanation:

edge 2021

Answer:

the speed of the fluid in the wider section of the pipe is 1m/s.

Explanation:

By equation of continuity we can write (for ideal (non-viscous, in-compressible).

[tex]A_1v_1 =A_2v_2[/tex]

A_1,A_2 are areas of the pipe at inlet and outlet of the pipe.

[tex]\Rightarrow \pi d_1^2v_1=\pi d_2^2v_2[/tex]_1

Here, d_1 , d_2 are diameters of inlet and outlet, also v_1, v_2 are velocities at inlet and outlet.

putting values we get

[tex]\Rightarrow \p 0.7^2\times9=\pi 2.1^2\timesv_2[/tex]

solving we get

[tex]v_2= 1m/s[/tex]

Answer:

4.1 seconds

Explanation:

The height of the football is given by the equation:

[tex]H = -16t^2 + V*t + S[/tex]

Using the inicial position S = 4 and the inicial velocity V = 64, we can find the time when the football hits the ground (H = 0):

[tex]0 = -16t^2 + 64*t + 4[/tex]

[tex]4t^2 - 16t - 1 = 0[/tex]

Using Bhaskara's formula, we have:

[tex]\Delta = b^2 - 4ac = (-16)^2 - 4*4*(-1) = 272[/tex]

[tex]t_1 = (-b + \sqrt{\Delta})/2a[/tex]

[tex]t_1 = (16 + 16.49)/8 = 4.06\ seconds[/tex]

[tex]t_2 = (-b - \sqrt{\Delta})/2a[/tex]

[tex]t_2 = (16 - 16.49)/8 = -0.06\ seconds[/tex]

A negative time is not a valid result for this problem, so the amount of time the football is in the air before hitting the ground is 4.1 seconds.

The amount of time the football spent in air before it hits the ground is 4.1 s.

The given parameters;

To find:

Using the vertical model equation given as;

[tex]H = -16t^2 + Vt + S\\\\[/tex]

the final height when the ball hits the ground, H = 0

[tex]0 = -16t^2 + 64t + 4\\\\16t^2 - 64t - 4 = 0\\\\divide \ through \ by\ 4\\\\4t^2 - 16t - 1= 0\\\\solve \ the \ quadratic \ equation \ using \ the \ formula \ method;\\\\\\a = 4, \ b = -16, \ c = - 1\\\\t = \frac{-b \ \ + /- \ \ \ \sqrt{b^2 - 4ac} }{2a} \\\\[/tex]

[tex]t = \frac{-(-16) \ \ + /- \ \ \ \sqrt{(-16^2 )- 4(4\times -1)} }{2\times 4}\\\\t = \frac{16 \ \ + /- \ \ \sqrt{272} }{8} \\\\t = \frac{16 \ \ +/- \ \ 16.49}{8} \\\\t = \frac{16 - 16.49}{8} \ \ \ \ or \ \ \ \frac{16 + 16.49}{8} \\\\t = -0.61 \ s \ \ or \ \ \ 4.06 \ s\\\\t\approx 4.1 \ s[/tex]

Thus, the amount of time the football spent in air before it hits the ground is 4.1 s.

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Answer:

Cost per year = $131.4

Explanation:

We are given;

Power rating of computer with monitor;P = 300 W = 0.3 KW

Cost of power per KWh = 15 cents = $0.15

Time used per day by the computer with monitor = 8 hours

Thus; amount of power consumed per 8 hours each day = 0.3 × 8 = 2.4 KWh per day

Thus, for 365 days in a year, total amount amount of power = 2.4 × 365 = 876 KWh

Now, since cost of power per KWh is $0.15, then cost for 365 days would be;

876 × 0.15 = $131.4

Answer:

s = 15.84m

Explanation:

In order to calculate the distance traveled by the bucket, you first use the formula for the torque exerted on the pulley by the weight of the bucket:

[tex]\tau=I\alpha[/tex]        (1)

I: moment of inertia of the pulley

α: angular acceleration of the pulley

You can calculate the angular acceleration by taking into account that the torque is also:

[tex]\tau=Wr[/tex]     (2)

W: weight of the bucket = Mg = (1.9kg)(9,8m/s^2) = 18.62N

r: radius of the pulley = 0.561m

[tex]\tau=(18.62N)(0.561m)=10.44Nm[/tex]

The moment of inertia is given by:

[tex]I=\frac{1}{2}M_pr^2[/tex]     (3)

Mp: mass of the pulley = 8kg

[tex]I=\frac{1}{2}(8kg)(0.561m)^2=1.25kg.m^2[/tex]

You solve the equation (1) for α and replace the values of the moment of inertia and the torque to obtain the angular acceleration:

[tex]\alpha=\frac{\tau}{I}=\frac{10.44Nm}{1.25kgm^2}=8.35\frac{rad}{s^2}[/tex]

Next, you use the following formula to find the angular displacement:

[tex]\theta=\frac{1}{2}\alpha t^2[/tex]

[tex]\theta=\frac{1}{2}(8.35rad/s^2)(2.6s)^2=28.24rad[/tex]

Finally, you calculate the arc length traveled by the pulley, this arc length is equal to the vertical distance traveled by the bucket:

[tex]s=r\theta =(0.561m)(28.24rad)=15.84m[/tex]

The distance traveled by the bucket is 15.84m

Answer:

Yes we can induce current in the coil by moving the magnet in and out of the coil steadily.

Explanation:

A current can be induced there using the magnetic field and the coil of wire. Moving the bar magnet around the coil can induce a current and this is called electromagnetic induction.

The generation of an electromotive force  across an electrical conductor in a fluctuating magnetic field is known as electromagnetic or magnetic induction.

Induction was first observed in 1831 by Michael Faraday, and James Clerk Maxwell mathematically named it Faraday's law of induction. The induced field's direction is described by Lenz's law.

Electrical equipment like electric motors and generators as well as parts like inductors and transformers have all found uses for electromagnetic induction.

Here, moving the bar magnet around the coil generates the electronic movement followed by a generation of electric current.

Find more on electromagnetic induction :

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Answer:

a) v₁ = 3.92 m / s , b)     ΔP =  = 9.0 10⁴ Pa, c)  t = 0.0297 s  

Explanation:

This is a fluid mechanics exercise

a) let's use the continuity equation

let's use index 1 for the hose and index 2 for the nozzle

        A₁ v₁ = A₂v₂

in area of ​​a circle is

       A = π r² = π d² / 4

we substitute in the continuity equation

        π d₁² / 4 v₁ = π d₂² / 4 v₂

        d₁² v₁ = d₂² v₂

the speed of the water in the hose is v1

       v₁ = v₂ d₂² / d₁²

       v₁ = 14 (1.8 / 3.4)²

        v₁ = 3.92 m / s

b) they ask us for the pressure difference, for this we use Bernoulli's equation

       P₁ + ½ ρ v₁² + m g y₁ = P₂ + ½ ρ v₂² + mg y2

as the hose is horizontal y₁ = y₂

       P₁ - P₂ = ½ ρ (v₂² - v₁²)

      ΔP = ½ 1000 (14² - 3.92²)

       ΔP = 90316.8 Pa = 9.0 10⁴ Pa

c) how long does a tub take to flat

the continuity equation is equal to the system flow

        Q = A₁v₁

        Q = V t

where V is the volume, let's equalize the equations

         V t = A₁ v₁

         t = A₁ v₁ / V

A₁ = π d₁² / 4

let's reduce it to SI units

         V = 120 l (1 m³ / 1000 l) = 0.120 m³

          d1 = 3.4 cm (1 m / 100cm) = 3.4 10⁻² m

let's substitute and calculate

         t = π d₁²/4   v1 / V

         t = π (3.4 10⁻²)²/4 3.92 / 0.120

         t = 0.0297 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).

Reception devices pick up the variation in the electric field vector of the electromagnetic wave sent out by the satellite. Given the satellite specifications listed in the problem introduction, what is the amplitude E0 of the electric field vector of the satellite broadcast as measured at the surface of the earth? Use ϵ0=8.85×10^−12C/(V⋅m) for the permittivity of space and c=3.00×10^8m/s for the speed of light.

Answer:

The electric field vector of the satellite broadcast as measured at the surface of the earth is  [tex]E_o = 6.995 *10^{-6} \ V/m[/tex]

Explanation:

From the question we are told that

     The height of the satellite is  [tex]r = 35000 \ km = 3.5*10^{7} \ m[/tex]

      The power output of the satellite is [tex]P = 1 \ KW = 1000 \ W[/tex]

Generally the intensity of the electromagnetic radiation of the satellite at the surface of the earth is  mathematically represented as  

     [tex]I = \frac{P}{4 \pi r^2}[/tex]

substituting values

      [tex]I = \frac{1000}{4 * 3.142 (3.5*10^{7})^2}[/tex]

      [tex]I = 6.495*10^{-14} \ W/m^2[/tex]

This intensity of the electromagnetic radiation of the satellite at the surface of the earth can also be   mathematically represented as  

          [tex]I = c * \epsilon_o * E_o^2[/tex]

Where [tex]E_o[/tex] is the amplitude of the electric field vector of the satellite broadcast so

         [tex]E_o = \sqrt{\frac{2 * I}{c * \epsilon _o} }[/tex]

substituting values

          [tex]E_o = \sqrt{\frac{2 * 6.495 *10^{-14}}{3.0 *10^{8} * 8.85*10^{-12}} }[/tex]

           [tex]E_o = 6.995 *10^{-6} \ V/m[/tex]

Answer:

The induced EMF, and hence the induced current produced will increase or decrease with the number of loops on the coil.

Explanation:

According to Faraday' law of electromagnetic induction, the induced EMF increases with the speed with which we turn the coil, the surface area of the coil, the number of loops, and the strength of the magnetic field. From this, we can see that increasing the number of loops also increases the surface area involved. This means that if we move the magnet in this experiment through the coils with different number of loops, the induced EMF, and hence the induced current, will increase or decrease with an increase or decrease  in the number of loops respectively.

Answer:

t = 0.731s

Explanation:

In order to calculate the time that the capacitor takes to have a voltage of 70V, you use the following formula:

[tex]V=V_oe^{-\frac{t}{RC}}[/tex]           (1)

V: final voltage across the capacitor = 70V

Vo: initial voltage across the capacitor = 100V

R: resistance of the resistor in the circuit = 1kΩ = 1*10^3Ω

C: capacitance of the capacitor = 2mF = 2*10^-3F

t: time

You use properties of logarithms to solve the equation (1) for t:

[tex]\frac{V}{V_o}=e^{-\frac{t}{RC}}\\\\ln(\frac{V}{V_o})=ln(e^{-\frac{t}{RC}})\\\\ln(\frac{V}{V_o})=-\frac{t}{RC}\\\\t=-RCln(\frac{V}{V_o})[/tex]

Next, you replace the values of the parameters:

[tex]t=-(1*10^3\Omega)(2*10^{-3})ln(\frac{70V}{100V})\\\\t=0.713s[/tex]

The capacitor takes 0.731s to reache a voltage of 70V

Answer:

a) v = 11.24 m / s ,    θ = 17.76º   b) Kf / K₀ = 0.4380

Explanation:

a) This is an exercise in collisions, therefore the conservation of the moment must be used

Let's define the system as formed by the two cars, therefore the forces during the crash are internal and the moment is conserved

Recall that moment is a vector quantity so it must be kept on each axis

X axis

initial moment. Before the crash

     p₀ₓ = m₁ v₁

where v₁ = -25.00 me / s

the negative sign is because it is moving west and m₁ = 900 kg

final moment. After the crash

      [tex]p_{x f}[/tex]= (m₁ + m₂) vx

       p₀ₓ =  p_{x f}

       m₁ v₁ = (m₁ + m₂) vₓ

     vₓ = m1 / (m₁ + m₂) v₁

let's calculate

       vₓ = - 900 / (900 + 1200) 25

       vₓ = - 10.7 m / s

Axis y

initial moment

      [tex]p_{oy}[/tex]= m₂ v₂

where v₂ = - 6.00 m / s

the sign indicates that it is moving to the South

final moment

     p_{fy}= (m₁ + m₂) [tex]v_{y}[/tex]

     p_{oy} = p_{fy}

     m₂ v₂ = (m₁ + m₂) v_{y}

     v_{y} = m₂ / (m₁ + m₂) v₂

we calculate

    [tex]v_{y}[/tex] = 1200 / (900+ 1200) 6

    [tex]v_{y}[/tex]  = - 3,428 m / s

for the velocity module we use the Pythagorean theorem

      v = √ (vₓ² + v_{y}²)

      v = RA (10.7²2 + 3,428²2)

      v = 11.24 m / s

now let's use trigonometry to encode the angle measured in the west clockwise (negative of the x axis)

      tan θ = [tex]v_{y}[/tex] / Vₓ

      θ = tan-1 v_{y} / vₓ)

      θ = tan -1 (3,428 / 10.7)

       θ = 17.76º

This angle is from the west to the south, that is, in the third quadrant.

b) To search for loss of the kinetic flow, calculate the kinetic enegy and then look for its relationship

      Kf = 1/2 (m1 + m2) v2

      K₀ = ½ m₁ v₁² + ½ m₂ v₂²

      Kf = ½ (900 + 1200) 11.24 2

      Kf = 1.3265 105 J

      K₀ = ½ 900 25²  + ½ 1200 6²

      K₀ = 2,8125 10⁵ + 2,16 10₅4

        K₀ = 3.0285 105J

the wasted energy is

        Kf / K₀ = 1.3265 105 / 3.0285 105

        Kf / K₀ = 0.4380

this is the fraction of kinetic energy that is conserved, transforming heat and transforming potential energy

Answer:

When the magnet is leaving the loop

Explanation:

According to Lenz's law the direction of an induced current in a conductor will oppose the effect which produces it. As the current is induced in the wire loop and force is exerted on the magnet, the force between the magnet and the loop will be attractive when the magnet is leaving the loop because it's is the one that produces the effect which create the current.

Answer:

P.E = 0.068 J = 68 mJ

Explanation:

First we need to find the height attained by the ball toy. For this purpose, we will be using 3rd equation of motion:

2gh = Vf² - Vi²

where,

g = -9.8 m/s²  (negative sign due to upward motion)

h = height attained by the ball toy = ?

Vf = Final Velocity = 0 m/s (since it momentarily stops at the highest point)

Vi = Initial Velocity = 3 m/s

Therefore,

2(-9.8 m/s²)h = (0 m/s)² - (3 m/s)²

h = (9 m²/s²)/(19.6 m/s²)

h = 0.46 m

Now, the gravitational potential energy of ball at its peak is given by the following formula:

P.E = mgh

P.E = (0.015 kg)(9.8 m/s²)(0.46 m)

P.E = 0.068 J = 68 mJ

Answer:

(a)    μ = 0.015kg/m

(b)    v = 90.64m/s

Explanation:

(a) The linear density of the string is given by the following relation:

[tex]\mu=\frac{m}{L}[/tex]           (1)

m: mass of the string = 25.3g = 25.3*10-3 kg

L: length of the string = 1.62m

[tex]\mu=\frac{25.3*10^{-3}kg}{1.62m}=0.015\frac{kg}{m}[/tex]

The linear density of the string is 0.015kg/m

(b) The velocity of the string for the fundamental frequency is:

[tex]f_1=\frac{v}{2l}[/tex]         (2)

f1: fundamental frequency = 41.2 Hz

vs: speed of the wave

l: distance between the fixed extremes of the string = 1.10m

You solve for v in the equation (2) and replace the values of the other parameters:

[tex]v=2lf_1=2(1.10m)(41.2Hz)=90.64\frac{m}{s}[/tex]        

The speed of the wave for the fundamental frequency is 90.64m/s

Answer:

The difference is [tex]\Delta B = 1.39 \ T[/tex]

Explanation:

From the question we are told that  

    The inner radius  is  [tex]r_i = 0.700 \ m[/tex]

        The outer radius  is  [tex]r_o = 1.20 \ m[/tex]

        The number of turns is  [tex]N = 900 \ turns[/tex]

        The current on each wire is [tex]I = 13.0 kA = 13*10^{3} \ A[/tex]

Generally magnetic field of a toroid along the outer radius is mathematically evaluated as

        [tex]B_o = \frac{\mu_o * N * I}{2 \pi r_o}[/tex]

Where  [tex]\mu_o[/tex] is the permeability of free space with value [tex]\mu_o= 4\pi * 10^{-7} N/A^2[/tex]

substituting values

            [tex]B_o = \frac{ 4\pi * 10^{-7} * 13*10^{3} * 900}{ 2 * 3.142 * 1.20}[/tex]

           [tex]B_o = 1.95 \ T[/tex]

Generally magnetic field of a toroid along the inner radius is mathematically evaluated as

           [tex]B_i = \frac{\mu_o * N * I}{2 \pi r_i}[/tex]

substituting values

           [tex]B_i = \frac{ 4\pi * 10^{-7} * 900 * 13*10^{3}}{2 *3.142 *0.700}[/tex]

         [tex]B_i = 3.34 \ T[/tex]

The difference in  magnitudes of the magnetic fields of the toroid along the inner and outer radii is mathematically evaluated as

      [tex]\Delta B = B_i - B_o[/tex]

      [tex]\Delta B = 3.34 -1.95[/tex]

      [tex]\Delta B = 1.39 \ T[/tex]