Three particles are placed in the xy plane. A 50-g particle is located at (3, 4) m, and a 40-g particle is positioned at ( 2, 6) m. Where must a 20-g particle be placed so that the center of mass of this three-particle system is located at (3, -6)?

A simple random sample is a sample drawn in such a way that each member of the population has equal chance for being included in the sample.

The mass percent of hydrogen in CH₄O is 12.5%.

Mass percent is the mass of the element divided by the mass of the compound or solute.

Step 1: Calculate the mass of the compound.

mCH₄O = 1 mC + 4 mH + 1 mO = 1 (12.01 amu) + 4 (1.00 amu) + 1 (16.00 amu) = 32.01 amu

Step 2: Calculate the mass of hydrogen in the compound.

mH in mCH₄O = 4 mH = 4 (1.00 amu) = 4.00 amu

Step 3: Calculate the mass percent of hydrogen in the compound.

%H = (mH in mCH₄O / mCH₄O) × 100%

%H = 4.00 amu / 32.01 amu × 100% = 12.5%

The mass percent of hydrogen in CH₄O is 12.5%.

CO2 = 1.580 grams H2O = 0.592 grams Lookup the molar mass of each element in the compound Carbon = 12.0107 Hydrogen = 1.00794 Oxygen = 15.999 Calculate the molar mass of CH4O by adding the total masses of each element used. 12.0107 + 4 * 1.00794 + 15.999 = 32.04146 Now calculate how many moles of CH4O you have by dividing by the molar mass. m = 1.15 g / 32.04146 g/mole = 0.035891 mole Now figure out how many moles of carbon and hydrogen you have. Carbon = 0.035891 moles Hydrogen = 0.035891 moles *

Therefore, The mass percent of hydrogen in CH₄O is 12.5%.

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Answer:

Explanation:

Frictional force acting on incline = μ mg cosθ

μ is coefficient of friction , m is mass of object , θ is incline

= .09 x m x 9.8 x cos 28

= .78 m

work done by friction

= frictional force x displacement

= - .78m x 100

= -  78m

Potential energy of sli at height

= mgh

= m x 9.8 x 100 sin 28

= 460.08 m

net energy at the base

= 460.08m - 78 m

= 382.08 m

 This will be in the form of kinetic energy .

1/2 m v² = 382.08 m

.5 x v² = 382.08

v = 27.64 m/s

After that it travels on plane surface .

Let the distance travelled be d

work done by frictional force

= μ mg x d

= .09 x m x 9.8 x d

This will be equal to kinetic energy at the base

.09 x m x 9.8 x d  = 382.08 m

d = 433.2 meter .

Complete Question

The complete question is  shown on the first uploaded image (reference for Photobucket )

Answer:

The  electric field is  [tex]E = -1.3 *10^{-4} \ N/C[/tex]

Explanation:

 From the question we are told that

    The linear charge density on the inner conductor is  [tex]\lambda _i = -26.8 nC/m = -26.8 *10^{-9} C/m[/tex]

    The linear charge density on the outer conductor is

  [tex]\lambda_o = -60.0 nC/m = -60.0 *10^{-9} \ C/m[/tex]

     The position of interest is r =  37.3 mm =0.0373 m

Now this position we are considering is within the outer conductor so the electric field  at this point is due to the inner conductor (This is because the charges on the conductor a taken to be on the surface of the conductor according to Gauss Law )

Generally according to Gauss Law

         [tex]E (2 \pi r l) = \frac{ \lambda_i }{\epsilon_o}[/tex]

=>    [tex]E = \frac{\lambda _i }{2 \pi * \epsilon_o * r}[/tex]

substituting values  

       [tex]E = \frac{ -26 *10^{-9} }{2 * 3.142 * 8.85 *10^{-12} * 0.0373}[/tex]

       [tex]E = -1.3 *10^{-4} \ N/C[/tex]

The  negative  sign tell us that the direction of the electric field is radially inwards

    =>   [tex]|E| = 1.3 *10^{-4} \ N/C[/tex]

Answer:

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Explanation:

Answer:

The  total number of maxima produced is   [tex]m_T = 7[/tex] maxima

Explanation:

From the question we are told that

    The number of lines per cm is  [tex]n = 5000 \ lines/cm[/tex]

      The wavelength of the light is  [tex]\lambda = 633 nm = 633 *10^{-9} \ m[/tex]

Now the distance between the lines is mathematically evaluated as

           [tex]d = \frac{1}{n}[/tex]

substituting values  

          [tex]d = \frac{1}{5000}[/tex]

          [tex]d = \frac{1 *10^{-2}}{5000}[/tex]     N/B - this  statement convert it from  cm to m

         [tex]d = 2 *10^{ -6} \ m[/tex]

Generally the condition for diffraction i mathematically represented as  

          [tex]dsin(\theta ) = m \lambda[/tex]

at maximum  [tex]\theta = 90 ^o[/tex]

             [tex]d sin (90) = \lambda m[/tex]

here m is the  number of  maxima  

      Thus  making  m the subject we have

          [tex]m = \frac{d sin (90)}{ \lambda }[/tex]

So     [tex]m = \frac{2*10^{-6} sin (90)}{ 633 *10^{-9}}[/tex]

          [tex]m = 3.2[/tex]

=>          m  =3  

  Now the total number of maxima would include the bright fringe(3) and  dark fringe (3) plus the central maxima (1)

Thus  

      [tex]m_T = 3 + 3 +1[/tex]

       [tex]m_T = 7[/tex] maxima

Note: question B is incomplete.

Complete Question

A solid ball of radius rb has a uniform charge density ρ.

a.  What is the magnitude of the electric field E(r) at a distance r>rb from the center of the ball?  Express your answer in terms of ρ, rb, r, and ϵ0.

b.   What is the magnitude of the electric field E(r) at a distance r<rb from the center of the ball?  Express your answer in terms of ρ, r, rb, and ϵ0.

c.   Let E(r) represent the electric field due to the charged ball throughout all of space. Which of the following statements about the electric field are true?

1. E(0) = 0.

2. E(rb) = 0

3. lim E(r) = 0.

4. The maximum electric field occurs when r = 0.

5. The maximum electric field occurs when r = rb.

6. The maximum electric field occurs as r to infinity.

Answer:

a) the magnitude of E(r)= ρr³/3 ε₀r²

b) the magnitude at distance r from the centre E(r)= ρr/3 ε ₀ ( if r<rb)

c) statements 1(E(0) = 0), 3(E(0) = 0) and 5(The maximum electric field occurs when r = rb.) are true

Explanation:

given

charge density = ρ ,  ε

Volume of sphere , V = (⁴/₃)πr³

a) charge density = charge/volume

ρ = q ÷ V

make charge the subject of the formula

∴q = ρ × V=  ρ× (⁴/₃)πr³

where r³ = rb³(at distance rb³)

recall

E= q/4πε₀r²

E=  ρ × (⁴/₃)πrb³/4πε₀r²

∴E(r)= ρrb³/3 ε ₀r²

(b)  The Gaussian surface is inside the ball, therefore, surface only encloses a portion of ball's charge .

The net charge enclosed by the Gaussian surface is different to the of net charge enclosed in (a)

Recall

E= q/4πε₀r²

V= (⁴/₃)πr³

E=  ρ × (⁴/₃)πr³/4πε₀r²

∴E(r)= ρr/3 ε₀

(c)  E(0)= 0

limr-----∝

E(r)= 0

The maximum electric field occurs when r=rb.

Answer:

Convection is heat transfer through the movement of liquids and gases.

The induced current in the loop at the given dimension is 10.25 A.

The given parameters:

The area are of the solenoid is calculated as;

[tex]A = \frac{\pi d^2}{4} \\\\A = \frac{\pi \times 0.02^2}{4} = 0.000314 \ m^2[/tex]

The emf induced in the solenoid is calculated as;

[tex]emf = N\frac{d\phi}{dt} \\\\emf = N (\frac{BA}{t} )\\\\emf = N(\frac{\mu_0 NI \times A} {L\times t} )\\\\emf = \frac{N^2 \mu_0 I A}{Lt} \\\\emf = \frac{(1200)^2 \times (4\pi \times 10^{-7}) \times (1.3) \times (0.000314)}{0.075 \times 30\times 10^{-3}} \\\\emf = 0.328 \ V[/tex]

The induced current in the loop is calculated as follows;

[tex]I = \frac{emf}{R} \\\\I = \frac{0.328}{0.032} \\\\I = 10.25 \ A[/tex]

Thus, the induced current in the loop is 10.25 A.

"Your question is not complete, it seems to be missing the following information;"

A solenoid passes through the center of a wire loop, as shown in (Figure 1). The solenoid has 1200 turns, a diameter of 2.0 cm, and is 7.5 cm long. The resistance of the loop is 0.032 Ω.If the current in the solenoid is increased by 1.3 A in 30 ms, what is the induced current in the loop?

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Answer:

From the edge of the  dock this distance is 0.221 m

Explanation:

Length of the plank = 4 m

mass of the plank = 8 kg

mass of the child = 57.2 kg

We will assume that:

This means that the moment of the mass of the plank acts at (3.58 - 2 = 1.58 m) from the balance point.

For the maximum point the boy can walk while still maintaining stability, we balance the moment due to the mass of the plank against the moment that will be generated due to the mass of the boy, at the maximum distance at which stability is possible.

moment of the mass of the plank about the 3.58 m mark is

==> 8 x 1.58 = 12.64 kg-m

moment of the boy about  the 3.58 m mark is

==> 57.2 x d = 57.2d

where d is the maximum point at which stability is still possible

equating the two moments,

12.64 = 57.2d

d = 12.64/57.2 = 0.221 m away from the 3.58 m mark

the maximum distance at which stability is still possible is the maximum distance that the boy can walks before he falls into the water.

From the edge of the  dock this distance is 0.221 m

Answer:

The horizontal force the sprinter exerts on the starting blocks is 705 N

Explanation:

Given;

mass of the sprinter, m = 47 kg

magnitude of the his horizontal acceleration, aₓ = 15 m/s²

The horizontal force the sprinter exerts on the starting blocks to produce this acceleration, is calculated by applying Newton's second law of motion.

∑Fₓ = maₓ

∑Fₓ = 47 x 15

∑Fₓ = 705 N

Therefore, the horizontal force the sprinter exerts on the starting blocks is 705 N

Answer:

I = 27kg.mi/h

Explanation:

In order to calculate the impulse of the ball, you use the following formula:

[tex]I=m\Delta v[/tex]  [tex]=m(v-v_o)[/tex]      (1)

m: mass of the ball = 0.3kg

v: speed of the ball after the bat hit it = 60mi/h

vo: speed of the ball before the bat hit it = 30mi/h

You replace the values of all parameters in the equation (1):

[tex]I=(0.3kg)(60mi/h-(-30mi/h))=27kg\frac{mi}{h}[/tex]

where the minus sign of the initial velocity means that the motion of the ball is opposite to the final direction of such a motion.

The imulpse of the ball is 27 kg.miles/hour

In final state, every metal sphere carries 1 unit of negative charge.

Hence, In final state, every metal sphere carries 1 unit of negative charge.

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Answer:

I = 81.5 W/m^2

Explanation:

In order to calculate the intensity of the sound at the speaker, you use the following formula:

[tex]I=\frac{P}{A}[/tex]          (1)

P: power of the speaker's sound = 1.63W

A: surface area of the stereo set = 0.07m^2

You assume that the intensity of the sound at the speaker depends only of the surface area of the stereo set. Furthermore, you consider that the wave front of the sound is approximately plane.

You replace the values of the parameters in the equation (1):

[tex]I=\frac{1.63W}{0.02m^2}=81.5\frac{W}{m^2}[/tex]

The intensity of the speaker's sound at the speaker is 81.5 W/m^2

Answer:

Zero

Explanation:

See attached file pls

Answer:

wavelength is = 0.05m

frequency is = 639.65 Hz

Explanation:

F= 3V/4L

(3 x 342)/(4 x 0.401) = 639.65Hz

Wavelenght =4L/3

wavelength =(4x0.401)/3 = 0.05m

The characteristics of standing waves in tubes allows to find the results for the third harmonic of the clarinet are:

Standing waves are formed when a wave collides with an obstacle and is reflected, the sum of the incident wave and the reflected wave forms a standing wave that does not move in time. There are several types of obstacles:

They indicate that the clarinet is approximated to a tube with one end open and the other closed, therefore at the closed end we have a node and at the open end a antinode, in the adjoint we see a diagram of the resonance, the expression for the resonance should be:

      L = [tex]\frac{\lambda}{4}[/tex]                1st harmonic

       L = [tex]3 \frac{\lambda}{4}[/tex]             3th harmonic

      L = [tex](2n-1) \frac{\lambda}{4}[/tex]    General term

where L is the length of the tube, λ the wavelength and n an integer.

Ask for the wavelength of the third harmonic m = 3

     λ = [tex]\frac{4L}{3}[/tex]

     λ  = [tex]\frac{4 \ 0.401}{3}[/tex]  

     λ  = 0.5365 m

The speed of the wave is related to the product of the wavelength and the frequency.

     v = λ f

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

Let's calculate.

     f = [tex]\frac{342}{0.5365}[/tex]  

     f = 639.7 Hz

In conclusion, using the characteristics of standing waves in tubes we can find the results for the third harmonic of the clarinet are:

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Answer:

a. 15.4 seconds

b. 0.455 m/s

Explanation:

a. The carousel rotates at 0.13 rev/s.

This means that it takes the carousel 1 sec to make 0.13 of an entire revolution.

This means that time it will take to make a complete revolution is:

1 / 0.13 = 7.7 seconds

Therefore, the time it will take to make 2 revolutions is:

2 * 7.7 = 15.4 seconds

b. Let us calculate the linear velocity. Angular velocity is given as:

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

where v = linear velocity and r = radius

The radius of the circle is 3.5 m and the angular velocity is 0.13 rev/s, therefore:

0.13 = v / 3.5

v = 3.5 * 0.13 = 0.455 m/s

Linear velocity is 0.455 m/s

Answer:

The correct answer is - 1.

Explanation:

The one cubic centimeter is equal to the one mililitter of a liquid. It is same de to the fact that volume of water that fits in a one cubic centimeter is equal to the liquid present in one mililiter of a liquid.

1 cm² = 1 ml

1 cm³ = 1 ml

Thus, the use of the both unit is interchangebly.

So , correct answer is - 1.

Answer:

Lightning

Explanation:

Air is a non-conductor of electricity because it does not have free electrons to carry the current. But when there is a high voltage, as in the case of lightning, the molecules of air get ionized and electrons are available to flow to make the current and conduct electricity through the air.

Answer:

corona discharge

Explanation:

A corona discharge is an electrical discharge caused by the ionization of a fluid such as air, surrounding a conductor that is electrically charged.

Answer:

h = 1.94 m

Explanation:

When the bull dog and skate board reach the bottom of the well, all of its potential energy is converted to the kinetic energy:

Kinetic Energy Gained by Bull Dog and Skate Board = Potential Energy Lost by Bull Dog and Skate Board

K.E = P.E

K.E = mgh

h = K.E/mg

where,

h = depth of well = ?

K.E = Kinetic Energy at bottom = 380 J

m = mass of bull dog and skate board = 20 kg

g = 9.8 m/s²

Therefore,

h = 380 J/(20 kg)(9.8 m/s²)

h = 1.94 m

Answer:

(a) α = -0.16 rad/s²

(b) t = 33.2 s

Explanation:

(a)

Applying 3rd equation of motion on the circular motion of the tire:

2αθ = ωf² - ωi²

where,

α = angular acceleration = ?

ωf = final angular velocity = 0 rad/s (tire finally stops)

ωi = initial angular velocity = 5.45 rad/s

θ = Angular Displacement = (14.4 rev)(2π rad/1 rev) = 28.8π rad

Therefore,

2(α)(28.8π rad) = (0 rad/s)² - (5.45 rad/s)²

α = -(29.7 rad²/s²)/(57.6π rad)

α = -0.16 rad/s²

Negative sign shows deceleration

(b)

Now, we apply 1st equation of motion:

ωf = ωi + αt

0 rad/s = 5.45 rad/s + (-0.16 rad/s²)t

t = (5.45 rad/s)/(0.16 rad/s²)

t = 33.2 s

Answer:

The index of refraction of this material is 1.7241

Explanation:

Recall that the index of refraction (n) of a medium is defined as the quotient between the speed of light in vacuum divided the speed of light in the medium whose index of refraction is being calculated. In mathematical terms:

[tex]n=\frac{c}{v}[/tex]

Therefore, in our case, since we know the speed of light in the medium ([tex]v=1.74\,\,10^8\,\,m/s[/tex]) and the speed of light in vacuum ([tex]c=3\,\,10^8\,\,m/s[/tex]), we can estimate the index of refraction of the medium:

[tex]n=\frac{c}{v} \\n=\frac{3\,\,10^8}{1.74\,\,10^8} \\n=1.7241[/tex]

Answer:

1.0 cm from the lens

Explanation:

Answer:

1.0cm from the lens

Explanation:

I had this in a lesson and got it right with this answer.

Answer:

1) Option D is correct.

The electric field inside a conductor is always zero.

2) Option A is correct.

The charge density inside the conductor is 0.

3) Charge density on the surface of the conductor at that point = η = -E ε₀

Explanation:

1) The electric field is zero inside a conductor. Any excess charge resides entirely on the surface or surfaces of a conductor.

Assuming the net electric field wasn't zero, current would flow inside the conductor and this would build up charges on the exterior of the conductor. These charges would oppose the field, ultimately (in a few nanoseconds for a metal) canceling the field to zero.

2) Since there are no charges inside a conductor (they all reside on the surface), it is logical that the charge density inside the conductor is also 0.

3) Surface Charge density = η = (q/A)

But electric field is given as

E = (-q/2πε₀r²)

q = -E (2πε₀r²)

η = (q/A) = -E (2πε₀r²)/A

For an elemental point on the surface,

A = 2πrl = 2πr²

So,

η = -E ε₀

Hope this Helps!!!

Answer:

The effectiveness of that same country's worldwide weights, as well as Measures Bureau, has always been chosen to give elsewhere here.

Explanation:

Answer:

w'=(1/2)w

Explanation:

In order to calculate the angular velocity of the second wheel, you use the following formula:

[tex]\omega=\frac{v}{r}[/tex]      (1)

v: speed of the wheel 1 = speed of the wheel 2

r: radius of the wheel 1

For the second wheel you have:

r'=2r

You replace this value of r' in the following equation:

[tex]\omega'=\frac{v}{r'}=\frac{v}{2r}=\frac{1}{2}\frac{v}{r}=\frac{1}{2}\omega\\\\\omega'=\frac{1}{2}\omega[/tex]

The angular velocity of the second wheel is one half of the angular velocity of the first wheel

Answer:

The  average coefficient of friction is 0.104

Explanation:

Given;

velocity of the skier, v = 9.4 m/s

angle of inclination, θ = 16°

height of the slope, h = 12 m

Calculate the kinetic energy of the skier at the given velocity;

KE =¹/₂mv²

KE = ¹/₂m(9.4)²

KE = 44.18m

Calculate the potential energy of the skier up the slope;

PE = mghsinθ

PE = m x 9.8 x 12 x sin16

PE = 32.411 m

Calculate the friction force on the inclined plane;

Fk = μk x mgCosθ

Fk =  μk x m x 9.8 x Cos16

Fk =  μk x m x 9.421

Calculate the work done by friction;

Work done = Fk x d

Work done = μk x m x 9.421 x d

Work done = μk x m x 9.421 x 12

Work done = 113.052mμk

Apply the principle of conservation of energy;

KE = PE + work done by friction

44.18m = 32.411 m + 113.052mμk (factor out m and divide through by it)

44.18 = 32.411  + 113.052μk

44.18 - 32.411  = 113.052μk

11.769 = 113.052μk

μk = 11.769 / 113.052

μk = 0.104

Therefore, the  average coefficient of friction is 0.104

Answer:

Horizontal component: [tex]F_x = 58\ N[/tex]

Vertical component: [tex]F_y = 33.5\ N[/tex]

Explanation:

To find the horizontal and vertical components of the force, we just need to multiply the magnitude of the force by the cosine and sine of the angle with the horizontal, respectively.

Therefore, for the horizontal component, we have:

[tex]F_x = F * cos(angle)[/tex]

[tex]F_x = 67 * cos(30)[/tex]

[tex]F_x = 58\ N[/tex]

For the vertical component, we have:

[tex]F_y = F * sin(angle)[/tex]

[tex]F_y = 67 * sin(30)[/tex]

[tex]F_y = 33.5\ N[/tex]

So the horizontal component of the tension force is 58 N and the vertical component is 33.5 N.

Answer:

The heat rate produced from the motor is 84.216 watts.

Explanation:

The electric motor receives power from electric current and releases power in the form of mechanical energy (torque) and waste heat and can be considered an stable-state system. The model based on the First Law of Thermodynamics for the electric motor is:

[tex]\dot W_{e} - \dot W_{T} -\dot Q = 0[/tex]

Where:

[tex]\dot Q[/tex] - Heat transfer from the electric motor, measured in watts.

[tex]\dot W_{e}[/tex] - Electric power, measured in watts.

[tex]\dot W_{T}[/tex] - Mechanical power, measured in watts.

The heat transfer rate can be calculated in terms of electric and mechanic powers, that is:

[tex]\dot Q = \dot W_{e} - \dot W_{T}[/tex]

The electric and mechanic powers are represented by the following expressions:

[tex]\dot W_{e} = i \cdot V[/tex]

[tex]\dot W_{T} = T \cdot \omega[/tex]

Where:

[tex]i[/tex] - Current, measured in amperes.

[tex]V[/tex] - Steady-state voltage, measured in volts.

[tex]T[/tex] - Torque, measured in newton-meters.

[tex]\omega[/tex] - Angular speed, measured in radians per second.

Now, the previous expression for heat transfer rate is expanded:

[tex]\dot Q = i \cdot V - T \cdot \omega[/tex]

The angular speed, measured in radians per second, can be obtained by using the following expression:

[tex]\omega = \frac{\pi}{30}\cdot \dot n[/tex]

Where:

[tex]\dot n[/tex] - Rotational rate of change, measured in revolutions per minute.

If [tex]\dot n = 1000\,rpm[/tex], then:

[tex]\omega = \left(\frac{\pi}{30} \right)\cdot (1000\,rpm)[/tex]

[tex]\omega \approx 104.720\,\frac{rad}{s}[/tex]

Given that [tex]i = 10\,A[/tex], [tex]V = 110\,V[/tex], [tex]T = 9.7\,N\cdot m[/tex] and [tex]\omega \approx 104.720\,\frac{rad}{s}[/tex], the heat transfer rate from the electric motor is:

[tex]\dot Q = (10\,A)\cdot (110\,V) -(9.7\,N\cdot m)\cdot \left(104.720\,\frac{rad}{s} \right)[/tex]

[tex]\dot Q = 84.216\,W[/tex]

The heat rate produced from the motor is 84.216 watts.

Answer:

1.11×10⁸  Electrons.

Explanation:

Applying,

Q = CV..................... Equation 1

Where Q = Total charge on the capacitor, C = Capacitance of the capacitor, V = Voltage of the battery.

Given: C = 1.97 pF = 1.97×10⁻¹² F, V = 9.0 V

Substitute this value into equation 1

Q = 1.97×9×10⁻¹²

Q = 1.773×10⁻¹¹ C.

If the charge on one electron = 1.602×10⁻¹⁹ C.

Therefore number of electron = 1.773×10⁻¹¹ /1.602×10⁻¹⁹

Number of electron = 1.11×10⁸

Answer:

The battery transferred 1.107 x 10⁸ electrons from one capacitor plate to the other.

Explanation:

Given;

capacitance of the capacitor, C = 1.97 pF = 1.97 x 10⁻¹² F

the battery potential, V = 9 V

The charge on each capacitor is calculated as;

Q = CV

Q = 1.97 x 10⁻¹² x 9

Q = 1.773 x 10⁻¹¹ C

1 electron has 1.602 x 10⁻¹⁹ Coulomb's charge

⇒1.602 x 10⁻¹⁹ C = 1 electron

⇒1.773 x 10⁻¹¹ C = ?

= (1.773 x 10⁻¹¹ C x electron) / (1.602 x 10⁻¹⁹ C)

= 1.107 x 10⁸ electrons

Therefore, the battery transferred 1.107 x 10⁸ electrons from one capacitor plate to the other.

Answer:

17.69 m

Explanation:

The time it takes the brick to strike the ground is 1.90 seconds.

We can apply one of Newton's equation of linear motion to find the height of the building:

[tex]s = ut + 0.5gt^2[/tex]

where s = distance (in this case height)

u = initial velocity = 0 m/s

t = time = 1.90 s

g = acceleration due to gravity = 9.8 m/s^2

Therefore:

s = (0 * 1.9) + (0.5 * 9.8 * 1.9 * 1.9)

s = 0 + 17.68

s = 17.69 m

The height of the building is 17.69 m.