Two particles, one with charge − 7.97 μC and one with charge 3.55 μC, are 6.59 cm apart. What is the magnitude of the force that one particle exerts on the other?

Answer:

The angle that the door must rotate is 70.5 graus

Explanation:

When the door rotates through and angel X, the magnetic flux that passes through the door decreases from its maximum value to 0.3 of its maximum value

This way,

X = 0.3 Xmax

X = B A cosX = 0.3 B A  

or

cosX = 0.3

or

X = [tex]cos^{-1}[/tex] (0.3) = 70.5

X = 70.5 graus

Answer:

Ft

Explanation:

We are given that

Initial velocity=u=0

We have to find the magnitude of p of the momentum of the particle at time t.

Let mass of particle=m

Applied force=F

Acceleration, [tex]a=\frac{F}{m}[/tex]

Final velocity , [tex]v=a+ut[/tex]

Substitute the values

[tex]v=0+\frac{F}{m}t=\frac{F}{m}t[/tex]

We know that

Momentum, p=mv

Using the formula

[tex]p=m\times \frac{F}{m}t=Ft[/tex]

The magnitude of the momentum of the particle after time, t is Ft = mv.

The given parameters:

The magnitude of the momentum of the particle after time, t is calculated as follows;

[tex]P =mv[/tex]

The force applied to the particle is calculated as;

[tex]F = ma = \frac{mv}{t} \\\\Ft = mv[/tex]

Thus, the magnitude of the momentum of the particle after time, t is Ft = mv.

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a. The quantity of heat rejected by the Carnot engine is equal to -101.2 kJ/s.

b. The power developed by the Carnot engine is equal to 148.8 kJ/s.

Given the following data:

Conversion:

Temperature of heat-source = 525°C to Kelvin = 525 + 273 = 798K

Temperature of heat rejected = 50°C to Kelvin = 50 + 273 = 323K

To find the power developed and the heat rejected, we would use Carnot's equation:

[tex]-\frac{Q_R}{T_R} = \frac{Q_S}{T_S}[/tex]

Where:

Making [tex]Q_R[/tex] the subject of formula, we have:

[tex]Q_R = -( \frac{Q_S}{T_S})T_R[/tex]

Substituting the given parameters into the formula, we have;

[tex]Q_R = -( \frac{250}{798}) \times 323\\\\Q_R = -( \frac{80750}{798})[/tex]

Quantity of heat rejected = -101.2 kJ/s

Now, we can determine the power developed by the Carnot engine:

[tex]P = -Q_S - Q_R\\\\P = -250 - (-101.2)\\\\P = -250 + 101.2[/tex]

Power, P = 148.8 kJ/s.

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The power developed by the Carnot engine is approximately 148.8 kilowatts. The heat rejected by the Carnot engine is approximately 101.2 kilowatts.

The Carnot efficiency (η) of a heat engine is given by the formula:

η = 1 - (T₁ ÷ T₂)

Heat received (Q(in)) = 250,000 J/s

Temperature of the heat-source reservoir (T(Hot)) = 798.15 K

Temperature of the heat-sink reservoir (T(Cold) = 323.15 K

The Carnot efficiency:

η = 1 - (T₁ ÷ T₂)

η = 1 - (323.15  ÷ 798.15 )

η = 0.5952

Therefore, The Carnot efficiency is 0.5952, which means the engine converts 59.52% of the heat received into useful work.

Power Developed:

P = η × Q(in)

P = 0.5952 × 250,000

P =  148,800 = 148.8 kW

Therefore, The power developed by the Carnot engine is approximately 148.8 kilowatts.

Heat Rejected:

Q(out) = Q(in) - P

Q(out) = 250,000- 148,800 = 101,200 J/s

Q(out) = 101.2 kW

Therefore, The heat rejected by the Carnot engine is approximately 101.2 kilowatts.

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Explanation:

Given data:

Area A = 10 cm×2 cm = 20×10⁻⁴ m²

Distance d between the plates = 1 mm = 1×10⁻³m

Voltage of the battery is emf = 100 V

Resistance = 1025 ohm

Solution:

In RC circuit, the voltage between the plates is related to time t. Initially the voltage is equal to that of battery V₀ = emf = 100V. But After time t the resistance and capacitor changes it and the final voltage is V that is given by

[tex]V = V_{0}(1-e^{\frac{-t}{RC} } )\\\frac{V}{V_{0} } = 1-e(^{\frac{-t}{RC} }) \\e^{\frac{-t}{RC} } = 1- \frac{V}{V_{0} }[/tex]

Taking natural log on both sides,

[tex]e^{\frac{-t}{RC} } = 1- \frac{V}{V_{0} } \\\frac{-t}{RC} = ln(1-\frac{V}{V_{0} } )\\t = -RCln(1 - \frac{V}{V_{0} })[/tex]

[tex]t = -RC ln (1-\frac{V}{V_{0} })[/tex]        (1)

Now we can calculate the capacitance by using the area of the plates.

C = ε₀A/d

  = [tex]\frac{(8.85*10^{-12))} (20*10^{-4}) }{1*10^{-3} }[/tex]

  = 18×10⁻¹²F

Now we can get the time when the voltage drop from 100 to 55 V by putting the values of C, V₀, V and R in the equation (1)

[tex]t = -RC ln (1-\frac{V}{V_{0} })[/tex]

 = -(1025Ω)(18×10⁻¹² F) ln( 1 - 55/100)

 = 15×10⁻⁹s

= 15 ns

Answer:

$175

Explanation:

Insurance premium is expressed as a rate $1000

($3.50 per $1000)

Therefore;

Annual premium= $50000x$3.50/$1000

= $175

Final answer:

The annual premium for a $50,000 policy at the rate of $3.50 per unit of coverage from the Acorn Insurance Company would be $175.00.

Explanation:

The Acorn Insurance Company charges $3.50 for each unit of coverage under a 1-year term life insurance policy. To calculate the annual premium for a $50,000 policy, we'll need to divide the total coverage amount by the unit price and then multiply by the cost per unit. Here's the math:

Total Coverage Needed: $50,000

Cost Per Unit of Coverage: $3.50

Number of Units: $50,000 / $1,000 = 50

Annual Premium: 50 units * $3.50 = $175.00

So, the annual premium amount for a $50,000 policy in this block would be $175.00.

Answer with Explanation:

We are given that

Number of turns=n=169

Radius of coil=r=2.6 cm=[tex]2.6\times 10^{-2} m[/tex]

[tex]1 cm=10^{-2}m[/tex]

Area of circular coil=[tex]\pi r^2[/tex]

Where [tex]\pi=3.14[/tex]

Using the formula

Area of circular coil=[tex]3.14\times (2.6\times 10^{-2})^2=21.2\times 10^{-4}m^2[/tex]

a.Magnetic dipole  moment=[tex]\mu=3.4 Am^2[/tex]

[tex]I=\frac{\mu}{nA}[/tex]

Using the formula

[tex]I=\frac{3.4}{169\times 21.2\times 10^{-4}}[/tex]

[tex]I=9.5 A[/tex]

b.Magnetic field,  B=0.03 T

[tex]\tau_{max}=\mu B[/tex]

Substitute the value

[tex]\tau_{max}=3.4\times \times 0.03=0.102 Nm[/tex]

c.[tex]\theta=44.9^{\circ}[/tex]

[tex]\tau=\tau_{max}sin\theta[/tex]

Substitute the values

[tex]\tau=0.102sin44.9=0.07 Nm[/tex]

Answer:

a. 20m/s

b.50N

c. Turkey has a larger mass than the ball. Neglible final acceleration and therefore remains stationery.

Explanation:

a. Given the force as 50N, times as 0.2seconds and the weight of the ball as 0.5 kg, it's final velocity can be calculated as:

[tex]F\bigtriangleup t=m\bigtriangleup v\\\\50N\times 0.2s=0.5kg\times \bigtriangleup v\\\\\bigtriangleup v=2(50N\times0.2)\\\\=20m/s[/tex]

Hence, the velocity of the ball after the kick is 20m/s

b.The force felt by the turkey:

#Applying Newton's 3rd Law of motion, opposite and equal reaction:

-The turkey felt a force of 50N but in the opposite direction to the same force felt by the ball.

c. Using the law of momentum conservation:

-Due to ther external forces exerted on the turkey, it remains stationery.

-The turkey has a larger mass than the ball. It will therefore have a negligible acceleration if any and thus remains stationery.

-Momentum is not conserved due to these external forces.

The velocity of the ball after the kick is 200 m/s. The turkey feels a force of 50N. The turkey doesn't go flying backward because of its greater mass compared to the ball.

The velocity of the ball after the kick can be calculated using the equation:

velocity = force / mass * time

Substituting the values, we get:

velocity = 50N / 0.5kg * 0.2s = 200 m/s

The force that the turkey feels can be determined using Newton's third law, which states that for every action, there is an equal and opposite reaction. So, the force the turkey feels will be the same as the force of the kick, which is 50N.

The turkey doesn't go flying backward because the turkey has a greater mass than the ball. According to Newton's second law, the acceleration of an object is inversely proportional to its mass. Since the turkey has a greater mass, it experiences less acceleration compared to the ball. Conservation of momentum is upheld in this situation, as the momentum of the turkey and ball together remains the same before and after the kick.

Answer:

(a)

[tex]f=20Hz\\And \\w=125.7s^{-1}[/tex]

(b)

[tex]K=3.490m^{-1}[/tex]

Explanation:

We know that the speed of any periodic wave is given by:

v=f×λ

The wave number k is given by:

K=2π/λ

Given data

Amplitude A=2.50mm

Wavelength λ=1.80m

Speed v=36 m/s

For Part (a)

For the wave frequency we plug our values for v and λ.So we get:

v=f×λ

[tex]36.0m/s=(1.80m)f\\f=\frac{36.0m/s}{1.80m}\\ f=20Hz\\[/tex]

And the angular speed we plug our value for f so we get:

[tex]w=2\pi f\\w=2\pi (20)\\w=125.7s^{-1}[/tex]

For Part (b)

For wave number we plug the value for λ.So we get

K=2π/λ

[tex]K=\frac{2\pi }{1.80m}\\ K=3.490m^{-1}[/tex]

The answers for this question are

a.) frequency of the wave is 20 Hz.

b.) angular frequency of the wave is [tex]125.71428\ s^{-1}[/tex]

c.) wave number of the wave is [tex]k=3.4920\ m^{-1}[/tex].

Given to us:

Amplitude A= 2.50 mm,

Wavelength λ= 1.80 m,

Velocity V= 36.0 m/sec,

a.) To find out frequency and angular frequency of the wave,we know

[tex]frequency=\dfrac{Velocity}{Wavelength}[/tex]

[tex]f=\dfrac{V}{\lambda}[/tex]

Putting the numerical value,

[tex]f=\dfrac{36}{1.80}\\\\f= 20\ Hz[/tex]

Therefore, the frequency of this wave is 20 Hz.

Also, for angular frequency

[tex]f=2\pi \omega[/tex]

Putting the numerical value,

[tex]\omega=2\pi f \\\\\omega=2\times\pi \times 20\\\\\omega= 125.71428\ s^{-1}[/tex]

Therefore, the angular frequency of this wave is [tex]125.71428\ s^{-1}[/tex].

b.) To find out the wave number of the wave (k),

The wave number for an EM field is equal to 2π divided by the wavelength(λ) in meters.

[tex]k=\dfrac{2\pi}{\lambda}[/tex]

Putting the numerical value,

[tex]k=\dfrac{2\pi}{\lambda}\\\\k=\dfrac{2\pi}{1.80}\\\\k=3.4920\ m^{-1}[/tex]

Therefore, the wave number of the wave is [tex]k=3.4920\ m^{-1}[/tex].

Hence, for this wave

a.) frequency of the wave is 20 Hz.

b.) angular frequency of the wave is [tex]125.71428\ s^{-1}[/tex]

c.) wave number of the wave is [tex]k=3.4920\ m^{-1}[/tex].

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Final answer:

The velocity of the defensive tackle before the collision is -6 m/s (toward the left).

Explanation:

According to the law of conservation of momentum, the total momentum before the collision is equal to the total momentum after the collision. Since the two players stick together after the collision, their velocities will be equal but opposite in direction.

Let's assume that the velocity of the defensive tackle before the collision is v. The total momentum before the collision is given by:

m1 * v1 + m2 * v2 = (m1 + m2) * v

Where:

m1 = mass of the running back = 86 kg

v1 = velocity of the running back = 9 m/s (toward the right)

m2 = mass of the defensive tackle = 129 kg

v2 = velocity of the defensive tackle (to be determined)

Using the above equation, we can solve for v:

(86 kg * 9 m/s) + (129 kg * v2) = (86 kg + 129 kg) * 0

774 kg*m/s + 129 kg * v2 = 0 kg*m/s

v2 = -6 m/s

Therefore, the velocity of the defensive tackle before the collision is -6 m/s (toward the left).

Answer:

W = 37.2J

Explanation:

See attachment below.

Answer:

a) The magnitude of the magnetic field = 7.1 mT

b) The direction of the magnetic field is the +z direction.

Explanation:

The force, F on a current carrying wire of current I, and length, L, that passes through a magnetic field B at an angle θ to the flow of current is given by

F = (B)(I)(L) sin θ

F/L = (B)(I) sin θ

For this question,

(F/L) = 0.113 N/m

B = ?

I = 16.0 A

θ = 90°

0.113 = B × 16 × sin 90°

B = 0.113/16 = 0.0071 T = 7.1 mT

b) The direction of the magnetic field will be found using the right hand rule.

The right hand rule uses the first three fingers on the right hand (the thumb, the pointing finger and the middle finger) and it predicts correctly that for current carrying wires, the thumb is in the direction the wire is pushed (direction of the force; -y direction), the pointing finger is in the direction the current is flowing (+x direction), and the middle finger is in the direction of the magnetic field (hence, +z direction).

Answer:

The ratio of electric field is 16:9.

Explanation:

Given that,

Radius [tex]R_{2}=\dfrac{3}{4}R_{1}[/tex]

Charge = Q

We know that,

The electric field is directly proportional to the charge and inversely proportional to the square of the distance.

In mathematically term,

[tex]E=\dfrac{kQ}{R^2}[/tex]

Here, [tex]E\propto\dfrac{1}{R^2}[/tex]

We need to calculate the ratio of electric field

Using formula of electric field

[tex]\dfrac{E_{2}}{E_{1}}=\dfrac{R_{1}^2}{R_{2}^2}[/tex]

Put the value into the formula

[tex]\dfrac{E_{2}}{E_{1}}=\dfrac{(4R_{1})^2}{(3R_{1})^2}[/tex]

[tex]\dfrac{E_{2}}{E_{1}}=\dfrac{16}{9}[/tex]

Hence, The ratio of electric field is 16:9.

Final answer:

The ratio of the electric fields E2/E1 at the surface of two conducting spheres with radii R2 = 3/4R1 carrying the same charge is 16/9.

Explanation:

The question is asking for the ratio of the electric fields near the surface of two conducting spheres carrying the same charge Q but having different radii, R1 and R2 where R2 is three-fourths of R1. To find the electric field E near the surface of a conducting sphere, we use the formula:

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

where k is Coulomb's constant, Q is the charge, and R is the radius of the sphere. Since the charge Q is the same on both spheres, we can calculate the ratio of the electric fields by plugging in the radii:

E2/E1 = (kQ/[tex]r2^{2}[/tex]) / (kQ/[tex]r1^{2}[/tex])

Simplifying further, since k is a constant it cancels out, along with Q, which is the same for both spheres, we get:

E2/E1 = ([tex]r1^{2}[/tex]) / ([tex]r2^{2}[/tex])

Substituting R2 = 3/4R1:

E2/E1 = [tex]r1^{2}[/tex] / (3/4 R1)[tex]{2}[/tex]

E2/E1 = 1 / (3/4)^2

E2/E1 = 1 / (9/16) = 16/9

Therefore, the ratio E2/E1 is 16/9.

Answer:

3.93 m/s

Explanation:

Let the kinetic energy of hammer be 'K' and speed of hitting the target be 'v'.

Given:

Mass of the hammer (M) = 7.76 kg

Mass of the metal piece (m) = 0.372 kg

Kinetic energy of the hammer used by the metal piece = 29.7% of 'K' = 0.297K

Vertical height traveled by the metal piece (h) = 4.87 m

From conservation of energy, the kinetic energy used by the metal piece is transformed to the gravitational potential energy when it reaches the height of the bell.

Gravitational potential energy of the piece is given as:

[tex]U=mgh\\\\U=0.372\times 9.8\times 4.87=17.754\ J[/tex]

Now, as per question:

[tex]0.297K=17.754\ J\\\\K=\frac{17.754}{0.297}\\\\K=59.78\ J[/tex]

Therefore, the kinetic energy of the hammer is 59.78 J.

We know that,

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

So, [tex]K=\frac{1}{2}mv^2[/tex]

Expressing in terms of 'v', we get:

[tex]mv^2=2K\\\\v^2=\frac{2K}{m}\\\\v=\sqrt{\frac{2K}{m}}[/tex]

Plug in the given values and solve for 'v'. This gives,

[tex]v=\sqrt{\frac{2\times 59.78}{7.76}}\\\\v=3.93\ m/s[/tex]

Therefore, the hammer must move with a speed of 3.93 m/s when it strikes the target so that the bell just barely rings.

Mass of the block is 0.557 kg

Solution:

The quantity of heat (q)  liberated during any process is equal to the product of the mass of the block (m), specific heat (C) and the change in temperature (ΔT). Specific heat of lead is 130 J/kg °C.

We have to rearrange the equation to find the mass of the block of lead as,

[tex]\begin{array}{l}\boldsymbol{q}=\boldsymbol{m} \times \boldsymbol{C} \times \boldsymbol{\Delta} \mathbf{T}\\ \\\boldsymbol{m}=\frac{\mathbf{q}}{\boldsymbol{c} \times \mathbf{\Delta} \mathbf{T}}\\ \\\mathbf{m}=\frac{427 \mathbf{J}}{13 \mathbf{0}_{\mathbf{4} *}^{\prime} \mathbf{r} \times \mathbf{s} \mathbf{9} \mathbf{0}^{*} \mathbf{c}}=\mathbf{0} . \mathbf{5} \mathbf{5} \mathbf{7} \mathbf{k} \mathbf{g}\end{array}[/tex]

Thus the mass (m) = 0.577 kg

Answer:

the correct answer is 0.57

Explanation:

Answer:

the kinetic energy decreases and the potential energy Increases.

Explanation:

as the comet travels away from the star it gains an energy which it posses because of its position or state.once the comet moves away form the star the kinetic decreases until its lost all together to where the potential energy starts increasing.

Answer:

The potential energy increase and the kinetic energy decrease.

Answer:

1.732

Explanation:

Let

Tension in wire B=T

Tension in wire A=3 T

We have to find the ratio of the frequencies of the first harmonic in these two wires.

When two wires are identical then the length of both wires are same.

Suppose, the length of each wire=l

Frequency=[tex]\frac{1}{2l}\sqrt{\frac{T}{\mu}}[/tex]

Where [tex]\mu=[/tex]Mass per unit length

Mass per unit length of both wires are same because the two wires are identical.

[tex]\mu_A=\mu_B[/tex]

[tex]\frac{f_A}{f_B}=\frac{\frac{1}{2l}\sqrt{\frac{T_A}{\mu_A}}}{\frac{1}{2l}\sqrt{\frac{T_B}{\mu_B}}}[/tex]

[tex]\frac{f_A}{f_B}=\frac{\frac{1}{2l}\sqrt{\frac{T_A}{\mu_A}}}{\frac{1}{2l}\sqrt{\frac{T_B}{\mu_A}}}=\sqrt{\frac{T_A}{T_B}}=\sqrt{\frac{3T}{T}}[/tex]

[tex]\frac{f_A}{f_B}=\sqrt 3=1.732[/tex]

The ratio of the frequencies of the first harmonic in these two wires is [tex]\sqrt{3}[/tex].

The given parameters;

The frequency of first harmonic of each wire is calculated as follows;

[tex]F_ A = \frac{1}{2l} \sqrt{\frac{3T}{\mu} } \\\\F_B = \frac{1}{2l} \sqrt{\frac{T}{\mu} }[/tex]

where;

The ratio of the two frequencies is calculated as follows;

[tex]\frac{F_A}{F_B} = \frac{\frac{1}{2l} \sqrt{\frac{3T}{\mu} } }{\frac{1}{2l} \sqrt{\frac{T}{\mu} } } \\\\\frac{F_A}{F_B} = \sqrt{\frac{3T}{T} } \\\\\frac{F_A}{F_B} = \sqrt{3}[/tex]

Thus, the ratio of the frequencies of the first harmonic in these two wires is [tex]\sqrt{3}[/tex].

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Answer:

3.6μF

Explanation:

The charge on the capacitor is defined by the formula

q = CV

because the charge will be conserved

q₁ = C₁V₂

q₂ = C₂V₂ where C₂ V₂ represent the charge on the newly connected capacitor  and the voltage drop across the two capacitor will be the same

q = q₁ + q₂ = C₁V₂ + C₂V₂

CV = CV₂ + C₂V₂

CV - CV₂ = C₂V₂

C ( V - V₂) = C₂V₂

C ( V/ V₂ - V₂ /V₂) = C₂

C₂ = 0.9 ( 10 /2) - 1) = 0.9( 5 - 1) = 3.6μF

Answer:

Explanation:

The ball from which electrons are transferred will acquire Q charge and the ball receiving electrons will acquire - Q charge . force of attraction between them

= k Q² / d²

9 x 10⁹ x Q² / .12² = 17 X 10⁻³

Q² = .0272 X 10⁻¹²

Q = .1650 X 10⁻⁶ C

No of electrons = .1650 x 10⁻⁶ / 1.6 x 10⁻¹⁹

= .103125 x 10¹³

1.03125 x 10¹²

Answer:

The work done on the 45.0nC charge is 2.24×10^-3J. The detailed solution can be found in the attachment below.

Explanation:

The Problem solution makes use of the potential energy relationship between the charges. This solution assumes the distance as shown in the diagram. For a different distance arrangement adjustments should be made appropriately.

The question in Physics pertains to the work needed by an external agent to move a charge within an electric field, and it involves applying the concept of electric potential energy. The work done is equal to the change in electric potential energy, which requires knowledge of the charges' positions and potentials.

The question asks: How much work does it take for an external agent to move a 45.0-nC charge from a point on the +x-axis, 3.40 cm from the origin to a point halfway between the 41.0-nC and 52.0-nC charges? To answer this question, we would use the concept of electric potential energy in the electric field created by point charges. Work is required to move a charge within an electric field against electric forces. The work done by an external force to move a charge from one point to another is equal to the change in electric potential energy, which can be calculated from the initial and final electric potentials at the points in question.

To find the required work, we need to know the initial and final positions relative to other charges, and then we apply the electric potential energy formula. However, a complete solution would require additional specifics about the configuration and distances between the charges. Without these details, we cannot provide an exact numerical answer.

Answer:x=2 and x=3

Explanation:

Given

Potential Energy for a certain mass is

[tex]U(x)=2x^3-15x^2+36x-23[/tex]

and we know force is given by

[tex]F=-\frac{\mathrm{d} U}{\mathrm{d} x}[/tex]

[tex]F=-(2\times 3x^2-15\times 2x+36)[/tex]

For Force to be zero F=0

[tex]\Rightarrow 6x^2-30x+36=0[/tex]

[tex]\Rightarrow x^2-5x+6=0[/tex]

[tex]\Rightarrow x^2-2x-3x+6=0[/tex]

[tex]\Rightarrow (x-2)(x-3)=0[/tex]

Therefore at x=2 and x=3 Force on particle is zero.

Answer:

Explanation:

total mass, M = 15.8 kg

initial velocity, u = 0 m/s

m1 = 4.5 kg

m2 = 5.4 kg

v1 = 27.5 m/s at an angle 18°

v2 = 21.4 m/s at an angle 23°

As there is no external force acts on the system, so the moemntum of the system is conserved.

Momentum before collision = momentum after collision

as the momentum before collision is zero, so the momentum after collision is also zero.

Explanation:

The given data  is as follows.

Mass of oxygen present = 100 mg = [tex]100 \times 10^{-3}[/tex] g

So, moles of oxygen present are calculated as follows.

      n = [tex]\frac{100 \times 10^{-3}}{32}[/tex]

         = [tex]3.125 \times 10^{-3}[/tex] moles

Diameter of cylinder = 6 cm = [tex]6 \times 10^{-2}[/tex] m

                              = 0.06 m

Now, we will calculate the cross sectional area (A) as follows.

    A = [tex]\pi \times \frac{(0.06)^{2}}{4}[/tex]

        = [tex]2.82 \times 10^{-3} m^{2}[/tex]

Length of tube = 11 cm = 0.11 m

Hence, volume (V) = [tex]2.82 \times 10^{-3} \times 0.11[/tex]

                              = [tex]3.11 \times 10^{-4} m^{3}[/tex]

Now, we assume that the inside pressure is P .

And,   [tex]P_{atm}[/tex] = 100 kPa = 100000 Pa,

Pressure difference = 100000 - P

Hence, force required to open is as follows.

      Force = Pressure difference × A

                = [tex](100000 - P) \times 2.82 \times 10^{-3}[/tex]

We are given that force is 173 N.

Thus,

         [tex](100000 - P) \times 2.82 \times 10^{-3}[/tex] = 173

Solving we get,

          P = [tex]3.8650 \times 10^{4} Pa[/tex]

            = 38.65 kPa

According to the ideal gas equation, PV = nRT

So, we will put the values into the above formula as follows.

                PV = nRT

    [tex]38.65 \times 3.11 \times 10^{-4} = 3.125 \times 10^{-3} \times 8.314 \times T[/tex]

                    T = 462.66 K

Thus, we can conclude that temperature of the gas is 462.66 K.

Answer:

0.938 m/s.

Explanation:

Given:

ω = 1 rev in 0.67 s

In rad/s,

1 rev = 2pi rad

ω = 2pi ÷ 0.67

= 9.38 rad/s

Rp = 10 cm

= 0.1 m

V = ω × r

= 9.38 × 0.1

= 0.938 m/s.

Explanation:

The formula to calculate total time taken is as follows.

      Total time = time to fall + time for sound

So,   time for sound = [tex]\frac{distance}{velocity}[/tex]

                                 = [tex]\frac{7.03}{343}[/tex]

                                 = 0.0204  sec

Hence, time to fall is as follows.

          (0.81 - 0.0204) sec

         = 0.7896 sec

Now, we will calculate the time to fall as follows.  

            y = [tex]y_{o} + v_{o}yt + \frac{1}{2}at^{2}[/tex]

            0 = [tex]h + v \times t - \frac{1}{2}gt^{2}[/tex]

            0 = [tex]7.03 + v \times (0.81 - 0.0204) - 0.5 \times 9.81 \times(0.81 - 0.0204)^{2}[/tex]

               = [tex]7.8196 - 0.5 \times 9.81 \times 0.623[/tex]

              = 7.8196 - 3.058

              = 4.7616 m/s  

Therefore, she threw the coin at 4.76 m/s in the upward direction.

Answer:

Series circuit approximation = R1 >> R2 then R2 ≈ 0

Parallel circuit approximation = R1 << R2 then R2 ≈ 0

Explanation:

in a series circuit, if there is a large difference between two resistors then we can omit the resistor which has low resistance because the higher value resistor dominates.

R1 >> R2 then R2 ≈ 0

in a parallel circuit, if there is a large difference between two resistors then we can omit the resistor which has high resistance because the lower value resistor dominates.

R1 << R2 then R2 ≈ 0

Answer:

159.1 ton

Explanation:

The solution is shown in the attached file

Answer:

The safe load is 159 ton

Explanation:

The safe load is equal to:

[tex]L=\frac{WHBV^{2/3} }{K}[/tex]

Where:

W = weight of hammer = 2.5 ton

H = drop height = 22 ft

B = number of blows used to drive the last batch = 36/4 = 9 ft³

K = dimensionless constant = 28

V = uncompacted volume = 27 ft³

Replacing values:

[tex]L=\frac{2.5*22*9*(27^{2/3}) }{28} =159ton[/tex]

Answer: a) VW = 1.28m/s

b) Vb = 3.86m/s

c) p = 5.82kgm/s

d) E = 11.84J

Explanation: To solve this question, we make use of explosion formula in linear momentum concept.

Please find the attached file for the solution

The motion involves energy conversion between kinetic and potential energy, with ball B reaching maximum potential energy at θmax and θmin, and maximum kinetic energy at θ = 0. Cart A's velocity will be adjusted according to the change in motion of ball B, based on the conservation of momentum.

The question relates to the physics concept known as conservation of momentum and energy in the context of pendular motion and collisions within an isolated system. When cart A is given an initial velocity and ball B is at rest, the force that accelerates ball B will be the component of the tension in the string that acts horizontally, as there's no friction resistance on the track. During the motion, the total energy of ball B will be conserved, converting between potential energy when at its highest at θmax and θmin, and kinetic energy when passing through the lowest point at θ = 0. As the system consists of pendular motion, for a given displacement, the velocity of the pendulum and cart at various angles can be determined by using energy conservation.

Given that cart A and ball B have the same mass, the velocities can be tracked by considering the movement as a combination of the cart rolling and the pendulum swinging, respecting the conservation of angular momentum around the axis from which the ball B is suspended.

Answer:

a) W = 180.87 J , b)  ΔU = -180.87 J , c)  ΔU = -180.87 J

Explanation:

a) Work is defined as

         W = F .ds

Where bold indicates vectors, we can write the scalar product

         W = F s cos θ

Where the angle is between force and displacement.

The force of gravity is the weight of the body, which is directed downwards and the displacement thickens the tip of the cliff at the bottom, so that it is directed downwards, therefore the angle is zero degrees

        W = [tex]F_{g}[/tex] y

        W = m g y

For this problem we must fix a reference system, from the statement it is established that the system is placed at the base of the cliff, so that final height is zero and the initial height (y₀ = 7.69m)

    W = 2.40 9.8 (7.69-0)

    W = 180.87 J

b) The potential energy is

            U = mg y

The change in potential energy,

        ΔU = [tex]U_{f}[/tex]- U₀

       ΔU = mg ([tex]y_{f}[/tex]- y₀)

      ΔU = 2.4 9.8 (0 -7.69)

      ΔU = -180.87 J

c) in this case we change the reference system to the height of the cliffs, for this configuration

          y₀ = 0

          [tex]y_{f}[/tex] = -7.69 m

          ΔU = 2.4 9.8 (-7.69 -0)

          ΔU = -180.87 J

Complete Question

The two isolated parallel plate capacitors be-  low, one with plate separation d and the other  with D > d, have the same plate area A and

are given the same charge Q.

What is the energy in the spark produced by discharging the second capacitor?

 1. The same as the discharge spark of the first capacitor

2. More energetic than the discharge spark of the first capacitor

3. Less energetic than the discharge spark of the first capacitor

Answer:

The correct option is 2

Explanation:

The formula for the energy stored in the capacitor is

             [tex]U = \frac{Q^2}{2C}[/tex]

And generally the formula for finding the capacitance of a capacitor is

               [tex]C = \frac{\epsilon_oA}{d}[/tex]

We can denote the capacitance of the first capacitor as [tex]C_1 = \frac{\epsilon_oA}{d}[/tex]

          and   denote the capacitance of the second  capacitor as [tex]C_2 = \frac{\epsilon_oA}{D}[/tex]

Looking at this formula we can see that C varies inversely with d            

as D > d it means that [tex]C_1 > C_2[/tex]

                Since the charge is constant

                         [tex]U\ \alpha\ \frac{1}{C}[/tex] i.e U varies inversely with C

           So [tex]C_1 > C_2[/tex]   => [tex]U_2 >U_1[/tex]

This means that the energy of spark would be more for capacitor two compared to capacitor one

The correct option is 2

The energy in the spark produced by discharging a capacitor can vary between different capacitors based on their capacitance and potential difference.

When discharging a capacitor, the energy stored in the capacitor is released as a spark, which can be compared between different capacitors.

In this case, if the second capacitor discharges, the spark produced may have varying energy levels compared to the spark produced by the first capacitor, depending on the capacitance and potential difference.

The energy in the spark produced by discharging the second capacitor can be calculated using relevant formulas relating to capacitance, potential difference, and energy stored.