An 800 N box is pushed across a level floor for a distance of 5.0 m with a force of 400 N. How much work was done on this box.

Answer:

check the diagram in the attachment below.

After the switch closes, the voltage across the membrane will be zero. It is so due to the fact that the  capacitor will be short circuited.

Explanation:

question

Potential Difference Across Axon Membrane The axoplasm of an axon has a resistance Rax. The axon's membrane has both a resistance (Rmem) and a capacitance (Cmem). A single segment of an axon can be modeled by a circuit with Rmem and Cmem in parallel with each other and in series with an open switch, a battery, and Rax. Imagine the voltage of the battery is ΔV. Part A We can model the firing of an action potential by the closing of the switch, which completes the circuit. Immediately after the switch closes, what is the potential difference across the membrane of this single segment?

ANSWER;

After the switch closes, the voltage across the membrane will be zero. It is so due to the fact that the  capacitor will be short circuited.

Answer:

the potential difference across the membrane of this single segment is zero.

ΔVmem=0

Explanation:

When the switch is closed, the capacitor ([tex]C_{mem}\\[/tex]) will be short. It means the current will not flow through the resistor([tex]R_{mem[/tex]). Rather current will only flow through the capacitor as there is no resistance. Due to zero resistance, the voltage across the capacitor will also be zero. So, the potential difference across the membrane of this single segment is zero.

ΔVmem=0

Answer:

Explanation:

find the solution below

The work, heat, and internal energy changes are calculated for different stages of the gas expansion and cooling processes in a cylinder with a piston containing oxygen as an ideal gas.

Part A: The work done by the gas during the initial expansion can be calculated using the formula:

Work = Pressure * Change in Volume

Since the expansion is isobaric (constant pressure) and the volume doubles, the change in volume is 2 times the initial volume. Therefore, the work done is 2 times the initial pressure times the initial volume.

Part B: The heat added to the gas during the initial expansion can be calculated using the formula:

Heat = Pressure * Change in Volume, since the expansion is isobaric.

Part C: The internal energy change of the gas during the initial expansion is equal to the heat added minus the work done.

Part D: The work done during the final cooling is zero because the process is isochoric (constant volume) and no work is done.

Part E: The heat added during the final cooling can be calculated using the equation:

Heat = Change in Internal Energy, since no work is done.

Part F: The internal energy change during the final cooling is equal to the negative of the heat added.

Part G: The internal energy change during the isothermal compression is also equal to the negative of the heat added, as no work is done during an isothermal process.

https://brainly.com/question/34205246

#SPJ3

Answer:

Towards the west

Explanation:

Magnetic force is the interaction between a moving charged particle and a magnetic field.

Magnetic force is given as

F = q (V × B)

Where F is the magnetic force

q is the charge

V is the velocity

B is the magnetic field

V×B means the cross product of the velocity and the magnetic field

NOTE:

i×i=j×j×k×k=0

i×j=k.  j×i=-k

j×k=i.  k×j=-i

k×i=j.  i×k=-j

So, if the electron is moving southward, then, it implies that the velocity of it motion is southward, so the electron is in the positive z-direction

Also, the electron is curved upward due to the magnetic field, this implies that the force field is directed up in the positive y direction.

Then,

V = V•k

F = F•j

Then, apply the theorem

F •j = q ( V•k × B•x)

Let x be the unknown

From vector k×i =j.

This shows that x = i

Then, the magnetic field point in the direction of positive x axis, which is towards the west

You can as well use the Fleming right hand rule

The thumb represent force

The index finger represent velocity

The middle finger represent field

Answer:

n1/p + n2/q = (n2-n1)/R

1.45/p + 1.6/1.15 = (1.6 - 1.45)/0.035 (m)

1.45/p + 1.39 = 4.28

p = 0.50 m (50 cm)

Answer:

A) μ = A.m²

B) z = 0.46m

Explanation:

A) Magnetic dipole moment of a coil is given by; μ = NIA

Where;

N is number of turns of coil

I is current in wire

A is area

We are given

N = 300 turns; I = 4A ; d =5cm = 0.05m

Area = πd²/4 = π(0.05)²/4 = 0.001963

So,

μ = 300 x 4 x 0.001963 = 2.36 A.m².

B) The magnetic field at a distance z along the coils perpendicular central axis is parallel to the axis and is given by;

B = (μ_o•μ)/(2π•z³)

Let's make z the subject ;

z = [(μ_o•μ)/(2π•B)] ^(⅓)

Where u_o is vacuum permiability with a value of 4π x 10^(-7) H

Also, B = 5 mT = 5 x 10^(-6) T

Thus,

z = [ (4π x 10^(-7)•2.36)/(2π•5 x 10^(-6))]^(⅓)

Solving this gives; z = 0.46m =

Answer:

The wavelength is 3500 nm.

Explanation:

d= [tex]\frac{1}{700 lines per mm} = 0.007mm = 7000 nm[/tex]

n= 1

θ= 30°

λ= unknown

Solution:

d sinθ = nλ

λ = [tex]\frac{7000 nm sin 30}{1}[/tex]

λ = 3500 nm

Answer:

The magnitude of the acceleration of earth due to the gravitational pull of earth is a = Gm/r^2

Where r = the center to center distance between the earth and the moon,

m = mass of the moon, and,

G is the gravity constant.

Explanation:

Detailed explanation and calculation is shown in the image below

Answer:

[tex]a_e = \frac{Gm}{r^2}[/tex]

Explanation:

We assume that:

M to represent the mass of the earth

m to equally represent the  mass of the moon

r should be the distance between the center of the earth to the center of the moon.

Then;

the expression for the gravitational force can be written as:

[tex]F = \frac{GMm}{r^2}[/tex]

Where [tex]a_e[/tex] is the acceleration produced by the earth; then:

[tex]F =M *a_e[/tex]

Then:

[tex]M*a_e = \frac{GMm}{r^2}[/tex]

[tex]a_e = \frac{GMm}{Mr^2}[/tex]

[tex]a_e = \frac{Gm}{r^2}[/tex]

Therefore, the  magnitude of the acceleration of the earth due to  the gravitational pull of the moon  [tex]a_e = \frac{Gm}{r^2}[/tex]

Answer:

B) Lengths will appear shorter and time will appear to pass faster.

Explanation:

This is in line with the laws of relativity.

Answer:

A. Lengths will appear shorter and time will appear to pass slower.  

Explanation:

From theory of relativity, we know that:

L₀ = length of object, measured in stationary frame of reference

L = length of object measured from a frame moving with respect to object, called ‘relativistic length’

v = relativistic speed between observer and the object

c = speed of light

then,

L = L₀ √(1-v²/c² )

Hence, the length of the object decreases with the increase in its relativistic speed "v"

t₀ = time measured by clock at rest with respect to event.

t = time measured by clock in motion relative to the event

v = relativistic speed between observer and the object

c = speed of light

then,

t =  t₀/√(1-v²/c² )

Hence, the time increases with the increase in in relativistic speed and as a result it appears to pass slower.

Hence, the correct option is:

A. Lengths will appear shorter and time will appear to pass slower.  

Answer:

R₁ = 50.77 Ω

Explanation:

Since, we know that:

Electric Power = P = VI

but from Ohm's Law:

V = IR

(or) I = V/R

Therefore,

P = V²/R

(OR) R = V²/P

where,

V = Battery Voltage

R = Resistance of combination

FOR SERIES COMBINATION:

R = Rs = (57 V)²/48 W

Rs = 67.69 Ω

but, we know that:

Rs = R₁ + R₂

R₁ + R₂ = 67.69 Ω

R₁ = 67.69 Ω - R₂  __________ eqn (1)

FOR PARALLEL COMBINATION:

R = Rp = (57 V)²/256 W

Rp = 12.69 Ω

but, we know that:

Rp = (R₁R₂)/(R₁ + R₂) = 12.69 Ω

using eqn (1) and value of R₁ + R₂, we get

Rp = 12.69  = R₂(67.69 - R₂)/67.69

859.08 = 67.69 R₂ - R₂²

R₂² - 67.69 R₂ + 859.08 = 0

Solving this quadratic equation we get the answers:

Either, R₂ = 50.76 Ω

Either, R₂ = 16.92 Ω

Since, it is stated in the question that R₁ > R₂. Therefore, we choose the second value. So,

R₂ = 16.92 Ω

using this value in eqn (1), we get:

R₁ = 67.69 Ω - 16.92 Ω

R₁ = 50.77 Ω

Final answer:

To calculate R1, first, find the total resistance for series (R1 + R2) and parallel (1/R1 + 1/R2) connections using the power formula P = V^2 / R, with provided power values for each case. Then solve the simultaneous equations.

Explanation:

The problem can be solved by using the formulas for resistances in series and parallel, as well as the formula for the power supplied by the battery.

In series, the resistances add up: Rtotal = R1 + R2. The power provided by the battery to the series circuit is given by P = V2 / Rtotal, where P is 48.0 W and V is 57.0 V. Rearranging to solve for Rtotal, we get Rtotal = V2 / P.

For parallel resistances, we have 1/Rtotal = 1/R1 + 1/R2. The power in the parallel case is P = V2 / Rtotal. With V and P given as 57.0 V and 256 W, respectively, we can solve for Rtotal.

With both Rtotal values calculated, we can set up two equations with two unknowns (R1 and R2), knowing that R1 > R2. Solving these simultaneous equations gives us the value of R1.

Final answer:

The air resistance force on three nested coffee filters falling is 3*F1.

Explanation:

The air resistance force on three nested coffee filters falling is 3*F1.

When the coffee filters fall, they quickly reach a terminal speed of approximately 1.7 m/s. Terminal velocity occurs when the air resistance force equals the weight of the object. Since the filters are nested, the air resistance force on a single falling filter is F1. Therefore, assuming the air resistance force is the same for each filter, the air resistance force on the three falling filters is 3*F1.

Answer: 3.78 m

Explanation:

Volume = 1.9 * 1.9 * 1.9

Volume = 6.859 m³

Density of iron assumed to be 7870 kg/m³

Recall,

Density = mass / volume, so

Mass = density * volume

Mass = (7870 * 6.859)

Mass = 53980.33 kg

This mass we calculated, is the mass of water the new cube would have to displace, absolute minimum, so that it can float.

Now density of fresh water is assumed to be (1000 kg/m³).

Thus, the volume of water that will be displaced has to be

Volume = mass / density

Volume = (53980.33 / 1,000)

Volume = 53.98 m³.

Cube root of 53.88 = 3.78 m

Therefore, the minimum side length is 3.78 m

Answer:

3.781488032m or greater

Explanation:

General Rule of thumb is that any thing that is less dense than water will float in it.

So

density of water is 997Kg/m^3 and density of iron on the other hand is  7860kg/m^3.

so to make iron less dense it has to be in larger volume.

mass of the given cube is 53911.74Kg and we have contain it in volume such that density is less than water, mathematically this translates to .

[tex]\frac{53911.74Kg}{V}\leq \frac{997Kg}{m^3}[/tex] left side is density of iron and right side is density of water, solving v in this inequality gives us.

[tex]v \geq 54.0739m^3[/tex] which means each side is [tex]s \geq 3.7814880m[/tex]. so the minum is just greater than that.

Answer: [tex]160 \Omega[/tex]

Explanation:

According to Ohm's law:  

[tex]V=R.I[/tex]  

Where:  

[tex]V=120 V[/tex] is the voltage difference across the light bulb

[tex]R[/tex] is the resistance of the light bulb   (the value we want to find)

[tex]I=0.75 A[/tex] is the electric current

Isolating [tex]R[/tex]:  

[tex]R=\frac{V}{I}[/tex]

[tex]R=\frac{120 V}{0.75 A}[/tex]

Finally:

[tex]R=160 \Omega[/tex]  This is the resistance of the light bulb

Final answer:

To calculate the resistance of a lightbulb with a current of 0.75 amperes and a voltage difference of 120 volts, use Ohm's law. The formula is R = V / I, which yields a resistance of 160 ohms for the lightbulb.

Explanation:

Calculating the Resistance of a Lightbulb

The student has asked how to calculate the resistance of a lightbulb when a current of 0.75 amperes flows through it and the voltage difference across it is 120 volts. To find the resistance, we can use Ohm's law, which states that the resistance (R) of a circuit is equal to the voltage (V) across it divided by the current (I) flowing through it, which can be written as:

R = V / I

Plugging in the given values, we get:

R = 120 V / 0.75 A

R = 160 ohms

Therefore, the resistance of the lightbulb is 160 ohms.

The correct result of the given operation expressed in scientific notation and with the appropriate number of significant figures should be 3.4 x 10^3. However, there are no matching options provided. A possible mistake might exist in the question.

To solve the problem, you should first add the two numbers in the brackets together. This gives us 0.82 + 0.042 = 0.862. Next, we need to multiply this result by the number outside the brackets, which is 4.4 x 103. Thus, our equation becomes 0.862 x 4.4 x 103 = 3.3928 x 103.

The result needs to be expressed in scientific notation and with the correct number of significant figures. The least precise number in our calculation is 4.4 (which has two significant figures), so our final answer should also have two significant figures. Therefore, we round 3.3928 x 103 to 3.4 x 103.

However, none of the options provided matches this result. Please double-check the question as there might be a typo.

https://brainly.com/question/2005529

#SPJ2

First, add 0.82 + 0.042 = 0.862. Second, multiply the sum 0.862 x 4.4 = 3.7928. Finally, round the result to two significant figures in scientific notation giving the answer as 3.8 x 10 or just 3.8.

To solve this problem, first, we need to add the numbers in the parentheses, then multiply the sum by 4.4 x 10⁰, which is just 4.4 since any number raised to the power of zero equals one.

Step 1: Add 0.82 + 0.042 = 0.862

Step 2: Multiply 0.862 x 4.4 = 3.7928

Lastly, we need to express the answer in scientific notation with the correct number of significant figures. As the question gives the numbers 0.82 and 0.042 with two and three significant figures respectively, we should express our final answer to two significant figures, as you always round to the fewest number of significant figures.

So, round 3.7928 to two significant figures, gives you 3.8 x 10⁰, which can alternatively be written as just 3.8, making the correct answer (a) 3.8 x 10.

https://brainly.com/question/2005529

#SPJ2

Answer:

[tex]B = 187\ \mu T[/tex]

Explanation:

Given,

Number of turns, N = 325

Diameter of coil, d = 9.4 cm

time,t = 2.48 m s

average voltage,ε = 0.17 V

Earth magnetic field, B = ?

We know that

[tex]\epsilon = \dfrac{NBA}{t}[/tex]

[tex]0.17= \dfrac{325\times B \times \pi (0.047)^2}{2.48\times 10^{-3}}[/tex]

[tex]B = 187 \times 10^{-6}\ T[/tex]

[tex]B = 187\ \mu T[/tex]

Magnetic field of the earth is equal to [tex]B = 187\ \mu T[/tex]

Answer:

e) indicated that the speed of light is the same in all inertial reference frames.

Explanation:

In 18th century, many scientists believed that the light just like air and water needs a medium to travel. They called this medium aether. They believed that even the space is not empty and filled with aether.

Michelson and Morley tried to prove the presence and speed of this aether through an interference experiment in 1887. They made an interferometer in which light was emitted at various angles with respect to the supposed aether. Both along the flow and against the flow to see the difference in the speed of light. But they did not find no major difference and thus it became the first proof to disprove the theory of aether.

It thus proved that the speed of light remains same in all inertial frames.

Also, it became a base for the special theory of relativity by Einstein.

Find the given attachment

To calculate the work required to pump water out of the swimming pool, physics principles such as the formula for work, volume of a cylinder, and weight of water are used to derive the necessary values for the complete calculation.

The question requires the use of physics concepts to calculate work done in pumping water out of a swimming pool. Since we are dealing with the force of gravity, density of water, height to which water is raised, and volume of water, we must use the formula for work done (work = force x distance) alongside formulas for the volume of a cylinder (Volume = πr^2h) and the weight of the water (weight = mass x gravity).

To solve the problem, first calculate the volume of water in the pool using the volume formula for a cylinder, taking into account the water's depth. Then, calculate the mass by multiplying the volume by the density of water. The weight of the water is found by multiplying the mass by the acceleration due to gravity. Finally, calculate the work done by multiplying the weight of the water by the height to which it needs to be lifted, considering both scenarios: pumping over the side and pumping through an outlet 2 meters over the side.

Final answer:

Calculation of work required to pump water out of a circular swimming pool at different heights.

Explanation:

The work required to pump all the water over the side of the pool is:
Work = mgh = density x volume x gravity x height = 1000 kg/m³ x (pi x (9m)² x 1.5m) x 9.8 m/s² x 3m = 1222540 J

For pumping all water out of the outlet 2m over the side:
Work = mgh = density x volume x gravity x height = 1000 kg/m³ x (pi x (9m)²x 1.5m) x 9.8 m/s² x 5m = 2037567 J

Answer:

V = 1.1658 × [tex]10^{-5}[/tex] V

Explanation:

given data

strip of copper thick = 130 µm

strip of copper wide = 4.40 mm

uniform magnetic field of magnitude B = 0.79 T

current i = 26 A

number of charge carriers per unit volume = 8.47 × [tex]10^{28}[/tex] electrons/m³

solution

we know that number density is express as

n = \frac{Bi}{Vle}      ...............1

B  is uniform magnetic field and i is current  and V is hall potential difference and l is thickness and e is electron charge 1.6 × [tex]10^{-19}[/tex]  C

so V will be as

V = \frac{iB}{nle}      .....................2

so put here value and we get V

V = [tex]\frac{26 \times 0.79}{8.47\times 10^{28}\times 130\times10^{-6}\times1.6 \times10^{-19}}[/tex]

V = 1.1658 × [tex]10^{-5}[/tex] V

Answer: 0.512 kgm²

Explanation:

Given

Force, F = 2*10^3 N

Angular acceleration, α = 121 rad/s²

Lever arm, r(⊥) = 3.1 cm = 3.1*10^-2 m

τ = r(⊥) * F

Also,

τ = Iα

Using the first equation, we have

τ = r(⊥) * F

τ = 0.031 * 2*10^3

τ = 62 Nm

Now we calculate for the inertia using the second equation

τ = Iα, making I subject of formula, we have

I = τ / α, on substituting, we have

I = 62 / 121

I = 0.512 kgm²

Thus, the moment of inertia of the boxers forearm is 0.512 kgm²

This question involves applying the principles of Conservation of Energy and Angular Momentum to calculate the minimum speed of a bullet impacting a physical pendulum. The solution requires us to consider different scenarios: when the bullet passes through and when it embeds itself into the board.

This problem involves the concepts of Conservation of Energy and Conservation of Angular Momentum.

(a) If the bullet passes through the board, we consider that the board moves by gaining kinetic energy (KE) from the bullet’s impact. The bullet's final speed is (1/3)*v, so the KE lost by the bullet will be (4/9)*mv². This energy is used for the board to perform a complete circle, which means it acquires a potential energy of (2*M*g*H), where H is the height when the board makes a complete circle (H=L/2). Equating these energies (4/9)*mv²-2*M*g*H = 0, we solve for v.

(b) If the bullet embeds itself, the system's final angular momentum equals its initial, which gives (1/2*M*L)v = (M+m)Lω. Then we equate the initial kinetic energy and potential energy during the complete circle, getting (1/2)(M+m)L²ω² = (M+m)gL. Solving for v will give us the minimum speed.

https://brainly.com/question/29716949

#SPJ12

Answer:

He sees the light as 1c

Explanation:

According to relativity, the speed of light is the same in all inertial frame of reference.

If we were to add the velocities as applicable to a normal moving bodies, the relative speed of the light beam will exceed c which will break relativistic law since nothing can go past the speed of light.

The receiver of the satellite dish, which is shaped like a paraboloid, should be positioned 9 feet from the base along the axis of symmetry for optimal signal reception.

This question is related to the properties of a parabolic dish (or paraboloid). The satellite dish is a 3D shape formed by rotating a parabola along its axis of symmetry. For a parabola, the focus is located a certain distance from the vertex, and this distance is defined by the depth of the dish.

The formula for the focus (F) in a parabolic mirror/dish is given by: F = D^2/16d where D is the diameter of the dish (48ft in this case) and d is the depth of the dish (4ft in this case). By substitifying these values, we obtain F = 48^2/(16*4) = 144/16 = 9 feet.

Therefore, to ensure the strongest reception of signals, the receiver of the satellite dish should be positioned 9 feet from the base along the axis of symmetry.

https://brainly.com/question/32342363

#SPJ12

Answer:

Explanation:

width of central diffraction maxima = 2 λD / d₁

λ  is wave length of light , D is screen distance and   d₁ is slit width

width of each interference fringe =  λD / d₂  , d₂ is slit separation.

No of interference fringe  in central diffraction fringe

= width of central diffraction maxima / width of each interference fringe

= 2 λD / d₁  x  λDd₂ / λD

No = 2 d₂ / d₁

No = 5

5 = 2 d₂ / d₁

Since this number does not depend upon wavelength so it will remain the same

No of required fringe will be 5 .

right option

e ) 5.

When 900-nm light is incident on the same slit system the number is 5.

The given parameters:

The number of interference fringe in central diffraction fringe is calculated as follows;

[tex]n = \frac{width \ of \ central \ diffraction\ maxima}{ width \ of \ each \ interference\ fringe}\\\\n = \frac{2\pi \lambda D/d_1}{2\pi \lambda D/d_2} \\\\n = \frac{2d_2}{d_1}[/tex]

The number of  number of interference fringe is independent of the wavelength.

Thus, when 900-nm light is incident on the same slit system the number is 5.

Learn more about number of interference fringe here: https://brainly.com/question/4449144

Answer:

The average angular acceleration is  [tex]\alpha =125.487 rad /s^2[/tex]

Explanation:

From the question we are told that

  From the question we are told that

        The length of the bat is [tex]l = 0.85m[/tex]  \

         The initial linear velocity is  [tex]u = 0 m/s[/tex]

         The time is  [tex]t = 0.15s[/tex]

         The velocity at t is  [tex]v = 16 m/s[/tex]

  Generally average  angular acceleration is mathematically represented as

                [tex]\alpha = \frac{w_f - w_o}{t}[/tex]

        Where [tex]w_f[/tex] is the finial angular velocity which is mathematically evaluated as  

            [tex]w_f = \frac{v}{l}[/tex]

                  [tex]w_f = \frac{16}{0.85}[/tex]

                        [tex]= 18.823 rad/s[/tex]

 and [tex]w_o[/tex] is the initial angular velocity which is zero since initial linear velocity is zero

               So

                         [tex]\alpha = \frac{18.823 - 0}{0.15}[/tex]

                               [tex]\alpha =125.487 rad /s^2[/tex]

Find the attachments for complete solution

The function giving the height of the ball at time t is s(t) = 96t - 16t^2 + 256. The ball takes 6 seconds to reach the ground and achieves a maximum height of 400 feet.

The physics problem you've posed can be approached by first understanding that the height of the ball (s(t)) at time t can be found by integrating the velocity function, due to v(t) being the derivative of s(t). So, integrating v(t)=96-32t with respect to t gives s(t) = 96t - 16t^2 + 256, where 256 is the constant of integration corresponding to the initial height from the ground.

To find out how long will the ball take to reach the ground, we solve the function s(t)=0, yielding t = 6 seconds as the answer, as that's when the ball hits the ground. Now, for the maximum height reached by the ball, it's where the ball has a velocity of zero before it begins its descent, i.e. v(t)=0. Solving this gives t=3 seconds, substituting this back into the s(t) equation gives the maximum reached height as 400 feet.

https://brainly.com/question/29545516

#SPJ11

Complete Question

The complete is shown on the first uploaded image

Answer:

[tex]\alpha = 5.89 rad/s^2[/tex]

[tex]w__{0.4}}= 2.36 \ rad/s[/tex]

[tex]v= 0.212m/s[/tex]

[tex]a_t= 0.5301 m/s[/tex]

[tex]a_r = 0.499 m/s[/tex]

[tex]a = 0.7279 m/s[/tex]

[tex]F_{net}=5.823*10^{-4}N[/tex]

Explanation:

From the question we are told that

       mass of the ant is [tex]m_a = 0.8g = \frac{0.8}{1000} = 0.00018kg[/tex]

         The distance from the center is [tex]d = 9cm = \frac{9}{100} = 0.09m[/tex]

         The angular speed is [tex]w = 45rpm = 45 * \frac{2 \pi }{60} = 1.5 \pi[/tex]

          The time taken to attain  angular acceleration of 45rpm [tex]t_1 = 0.8s[/tex]

           The time taken is [tex]t_2 = 0.4 s[/tex]

The  angular acceleration is mathematically represented as

                       [tex]\alpha = \frac{w}{t}[/tex]  

                          [tex]= \frac{1.5}{0.8}[/tex]

                           [tex]\alpha = 5.89 rad/s^2[/tex]

   The angular velocity at time t= 0.4s is mathematically represented as

                         [tex]w__{0.4s}} = \alpha * t_2[/tex]          Recall angular acceleration is constant

                                 [tex]= 5.89 * 0.4[/tex]

                                 [tex]w__{0.4}}= 2.36 \ rad/s[/tex]

The linear velocity is mathematically represented as

                 [tex]v = w__{t_2}} * r[/tex]

                    [tex]= 2.36 * 0.09[/tex]

                    [tex]v= 0.212m/s[/tex]

The tangential acceleration is mathematically represented as

                [tex]a_{t} = \alpha * r[/tex]

                      [tex]= 5.89 * 0.09[/tex]

                      [tex]a_t= 0.5301 m/s[/tex]

The radial acceleration is mathematically represented as

                  [tex]a_r = \frac{v^2}{r}[/tex]

                       [tex]= \frac{0.212^2}{0.09}[/tex]

                  [tex]a_r = 0.499 m/s[/tex]

The resultant velocity is mathematically represented as

                 [tex]a = \sqrt{a_t^2 + a_r^2}[/tex]

                     [tex]= \sqrt{0.53^2 + 0.499^2}[/tex]

                  [tex]a = 0.7279 m/s[/tex]

The net force is mathematically represented as

        [tex]F_{net} = 0.0008 * 0.7279[/tex]

                 [tex]F_{net}=5.823*10^{-4}N[/tex]

Answer:

He becomes a croco-dile food

Explanation:

From the question we are told that

    The height is h = 2.0 m

      The angle is  [tex]\theta = 20^o[/tex]

     The distance is  [tex]w = 10m[/tex]

       The speed is  [tex]u = 11 m/s[/tex]

       The coefficient of static friction is  [tex]\mu = 0.02[/tex]

At equilibrium the forces acting on the motorcycle are mathematically represented as

        [tex]ma = mgsin \theta + F_f[/tex]

where  [tex]F_f[/tex] is the frictional force mathematically represented as

            [tex]F_f =\mu F_x =\mu mgcos \theta[/tex]

where [tex]F_x[/tex] is the horizontal component of the force

substituting into the equation

            [tex]ma = mgsin \theta + \mu mg cos \theta[/tex]

            [tex]ma =mg (sin \theta + \mu cos \theta )[/tex]

               making  a the subject of the formula

      [tex]a = g(sin \theta = \mu cos \theta )[/tex]

          substituting values

      [tex]a = 9.8 (sin(20) + (0.02 ) cos (20 ))[/tex]

        [tex]= 3.54 m/s^2[/tex]

Applying " SOHCAHTOA" rule we mathematically evaluate that length of the ramp as  

             [tex]sin \theta = \frac{h}{l}[/tex]

making [tex]l[/tex] the subject

          [tex]l = \frac{h}{sin \theta }[/tex]

substituting values

        [tex]l = \frac{2}{sin (20)}[/tex]

           [tex]l = 5.85m[/tex]

Apply Newton equation of motion we can mathematically evaluate the  final velocity at the end of the ramp  as

      [tex]v^2 =u^2 + 2 (-a)l[/tex]

  The negative a means it is moving against gravity

      substituting values

      [tex]v^2 = (11)^2 - 2(3.54) (5.85)[/tex]

           [tex]v= \sqrt{79.582}[/tex]

              [tex]= 8.92m/s[/tex]

The initial velocity at the beginning of the pool (end of ramp) is composed of two component which is

    Initial velocity along the x-axis which is mathematically evaluated as

          [tex]v_x = vcos 20^o[/tex]

       substituting values

         [tex]v_x = 8.92 * cos (20)[/tex]

              [tex]= 8.38 m/s[/tex]

Initial velocity along the y-axis which is mathematically evaluated as

             [tex]v_y = vsin\theta[/tex]

      substituting values

             [tex]v_y = 8.90 sin (20)[/tex]

                  [tex]= 3.05 m/s[/tex]

Now the motion through the pool in the vertical direction can mathematically modeled as

        [tex]y = y_o + u_yt + \frac{1}{2} a_y t^2[/tex]

where [tex]y_o[/tex] is the initial height,

         [tex]u_y[/tex] is the initial velocity in the y-axis

    [tex]a_y[/tex]  is the  initial  acceleration in the y axis  with a constant value of ([tex]g = 9.8 m/s^2[/tex])

at the y= 0 which is when the height above ground is zero

      Substituting values

              [tex]0 = 2 + (3.05)t - 0.5 (9.8)t^2[/tex]

The negative sign is because the acceleration is moving against the motion

                 [tex]-(4.9)t^2 + (2.79)t + 2m = 0[/tex]

   Solving using quadratic formula

              [tex]\frac{-b \pm \sqrt{b^2 -4ac} }{2a}[/tex]

substituting values

             [tex]\frac{-3.05 \pm \sqrt{(3.05)^2 - 4(-4.9) * 2} }{2 *( -4.9)}[/tex]

                [tex]t = \frac{-3.05 + 6.9}{-9.8} \ or t = \frac{-3.05 - 6.9}{-9.8}[/tex]

                [tex]t = -0.39s \ or \ t = 1.02s[/tex]

since in this case time cannot be negative

             [tex]t = 1.02s[/tex]

At this time the position the  motorcycle along the x-axis is mathematically evaluated as

              [tex]x = u_x t[/tex]

               x  [tex]=8.38 *1.02[/tex]

                   [tex]x =8.54m[/tex]

So from this value we can see that the motorcycle would not cross the pool as the position is less that the length of  the pool

If the horizontal distance x covered by the motorcyclist is greater than or equal to 10 meters, he survives; otherwise, he does not, From the given calculations, x = 8.21 m, so he becomes crocodile food.

According to question, the height of motorcycle daredevil is h = 2.0 m, the angle of the ramp is θ = 20°, the distance of the wide pool is w = 10 m, the speed of the motorcycle daredevil is u = 11 m/s, and the coefficient of static friction between the ramp and the tyres of the motorcycle daredevil is μ = 0.02.

At equilibrium, the forces acting on the motorcycle are equated as:

ma = mgsinθ + f

here,  m = mass of the motorcycle, a is the acceleration of the motorcycle, g is the acceelration due to gravity (g = 9.8 m/s²), and f is the frictional force between the ramp and the tyres of the motorcycle daredevil mathematically represented using normal reaction N as

f =μ N = μ mgcosθ

substituting into the equation

ma = mg sinθ + μ mg cosθ

ma  =mg (sinθ + μ cosθ)

⇒ a = g(sinθ + μ cosθ)

⇒ a = 9.8 (sin(20°) + (0.02) cos (20°))

⇒ a = 3.54 m/s²

Now, for the ramp, we can say that:

[tex]sin \theta = \frac{h}{l}[/tex]

[tex]\therefore l = \frac{h}{sin \theta}[/tex]

substituting the above values, we get:

[tex]l = \frac{2}{sin20^{\circ}}[/tex]

or, l = 5.85m

Using Newton equation of motion, the final velocity of the motorcycle at the end of the ramp, can be given as:

[tex]v^2 =u^2 + 2 (-a)l[/tex]

As the motorcycle is moving against gravity, the acceleration (a) is taken negative. From the above values, we get:

[tex]v^2 = (11)^2 - 2(3.54) (5.85)[/tex]

⇒ [tex]v= \sqrt{79.582} \hspace{0.8 mm} m/s[/tex]

or, v = 8.92m/s

The motion of the motorcycle is a projectile motion. The initial velocity at the beginning of the pool (end of ramp) is composed of two component which are the x, and the y components respectively.

Initial velocity along the x-axis which is [tex]v_x[/tex] = v cos 20°

substituting values, we get:

[tex]v_x[/tex] = 8.92 cos (20°)

or, v = 8.38 m/s

Initial velocity along the y-axis which [tex]v_y[/tex] = v sin 20°

substituting values, we get:

[tex]v_y[/tex] = 8.90 sin (20)

[tex]v_y[/tex] = 3.05 m/s

Now the motion through the pool in the vertical direction can mathematically modeled as

[tex]y = y_o + u_yt + \frac{1}{2}a_y t^2[/tex]

where y₀ is the initial height, [tex]u_y[/tex] is the initial velocity in the y-axis, and [tex]a_y[/tex] is the initial acceleration in the y-axis with a constant value of (g = 9.8 m/s^2)

At y = 0  

0 = 2 + (3.05) t - 0.5 (9.8) t²

The negative sign is because the acceleration is moving against the motion:

- (4.9) t² + (2.79) t + 2m = 0

To solve for t, we can use the quadratic formula:

[tex]t = \frac{- b \hspace{0.5} \pm \sqrt{(b^2 - 4ac)}}{2a}[/tex]

In this case, a = 4.9, b = -2.79, and c = -2.

Plugging in these values, we get:

[tex]t = \frac{(2.79 \pm \sqrt{(-2.79)^2 - 4(4.9)(-2)}}{2(4.9)}[/tex]

Solving for both possible values of t, we get:

t ≈ [tex]\frac{(2.79 + 6.858)}{9.8}[/tex] ≈ 0.98 seconds

t ≈ [tex]\frac{(2.79 - 6.858)}{9.8}[/tex] ≈ -0.41 seconds

Since time cannot be negative,

∴ t ≈ 0.98 seconds

Hence displacement along the x-coordinate will be:              

x = [tex]u_x[/tex] t

⇒ x  =8.38 × 0.98 m

x = 8.21 m

So from this value we can see that the motorcycle would not cross the pool as the position is less that the length of the pool.

Answer with Explanation:

Let mass of one vehicle =m

Mass of other vehicle=m'

[tex]\frac{m}{m'}=\frac{1}{4}[/tex]

[tex]m'=4m[/tex]

Velocity of one vehicle=[tex]v=13 im/s[/tex]

Velocity of other vehicle=[tex]v'=13jm/s[/tex]

In x- direction

By law of conservation of momentum

[tex]mv+0=(m+m')V_x[/tex]

[tex]13m=(m+4m)V_x[/tex]

[tex]13m=5mV_x[/tex]

[tex]V_x=\frac{13}{5}[/tex]

In y- direction

By law of conservation of momentum

[tex]0+m'v'=(m+m')V_y[/tex]

[tex]4m(13)=5mV_y[/tex]

[tex]V_y=\frac{52m}{5m}=\frac{52}{5}[/tex]

Magnitude of velocity of the wreck,V=[tex]\sqrt{V^2_x+V^2_y}=\sqrt{(\frac{13}{5})^2+(\frac{52}{5})^2}=10.72 m/s[/tex]

Direction:[tex]\theta=tan^{-1}(\frac{V_y}{V_x})[/tex]

[tex]\theta=tan^{-1}(\frac{\frac{52}{5}}{\frac{13}{5}})=75.96^{\circ}[/tex]

Answer:

the speed of the apple half way between the release and the maximum height is not half the initial speed due to the acceleration due to gravity numerically equal to 9.81 m/s2. An acceleration in the direction of motion of a body will cause its velocity to increase, thus, this acceleration due to gravity increases the velocity of the apple so that it will be at its maximum speed before hitting the ground.

The value of this acceleration implies that there is an increase of 9.8 m/s in its speed for every one seconds of fall. This means that at 1 sec when it starts to fall, the speed will be 9.8 m/s. By two seconds it becomes 19.62 m/s. It is clear to see that the velocity halfway will be more than its initial velocity.

Answer:

The voltage will increase.

Explanation:

Increason the number of coil in the secondary will increase the voltage in a transformer.