A bungee jumper, whose mass is 85 kg, jumps from a tall building. After reaching his lowest point, he continues to oscillate up and down, reaching the low point two more times in 6.8 s. Ignoring air resistance and assuming that the bungee cord is an ideal spring, determine its spring constant.

Explanation:

Given that,

Distance between two long wires, d = 16 cm = 0.16 m

Current in one wire, [tex]I_1=2.9\ A[/tex]

Current in wire 2, [tex]I_2=5.7\ A[/tex]    

The magnetic force per unit length of one wire on the other is given by the following expression as :

[tex]\dfrac{F}{l}=\dfrac{\mu_o I_1I_2}{2\pi d}[/tex]

[tex]\dfrac{F}{l}=\dfrac{4\pi \times 10^{-7}\times 2.9\times 5.7}{2\pi \times 0.16}[/tex]

[tex]\dfrac{F}{l}=2.06\times 10^{-5}\ N/m[/tex]

The current is flowing in opposite direction, the magnetic force acting on it is repulsive. Hence, this is the required solution.

Answer:

0.15694 m

Explanation:

m = Mass of block = [tex]2.16\times 10^{-2}\ kg[/tex]

v = Velocity of block = 11.2 m/s

k = Spring constant = 110 N/m

Here the kinetic energy of the fall and spring are conserved

[tex]\frac{1}{2}mv^2=\frac{1}{2}kA^2\\\Rightarrow mv^2=kA^2\\\Rightarrow A=\sqrt{\frac{mv^2}{k}}\\\Rightarrow A=\sqrt{\frac{2.16\times 10^{-2}\times 11.2^2}{110}}\\\Rightarrow A=0.15694\ m[/tex]

The amplitude of the resulting simple harmonic motion is 0.15694 m

Answer:

Induced EMF,[tex]\epsilon=0.0143\ volts[/tex]

Explanation:

Given that,

Radius of the circular loop, r = 5 cm = 0.05 m

Time, t = 0.0548 s

Initial magnetic field, [tex]B_i=200\ mT=0.2\ T[/tex]

Final magnetic field, [tex]B_f=300\ mT=0.3\ T[/tex]

The expression for the induced emf is given by :

[tex]\epsilon=\dfrac{d\phi}{dt}[/tex]

[tex]\phi[/tex] = magnetic flux

[tex]\epsilon=\dfrac{d(BA)}{dt}[/tex]

[tex]\epsilon=A\dfrac{d(B)}{dt}[/tex]

[tex]\epsilon=A\dfrac{B_f-B_i}{t}[/tex]

[tex]\epsilon=\pi (0.05)^2\times \dfrac{0.3-0.2}{0.0548}[/tex]

[tex]\epsilon=0.0143\ volts[/tex]

So, the induced emf in the loop is 0.0143 volts. Hence, this is the required solution.

Final answer:

The magnitude of the induced emf in the loop is -0.0184 V.

Explanation:

The magnitude of the emf induced in a single-turn circular loop of wire can be calculated using Faraday's law of electromagnetic induction. According to the law, the magnitude of the induced emf is equal to the rate of change of magnetic flux through the loop. The formula for calculating the induced emf is:

emf = -N * ΔB/Δt

Where emf is the induced electromotive force, N is the number of turns in the loop, ΔB is the change in magnetic field strength, and Δt is the change in time. Plugging in the given values, we have:

emf = -1 * (300 - 200) * 10^-3 / 0.0548

emf = -0.0184 V

The angular momentum of the particle with respect to the origin is 50 kgm²/s.

The angular momentum of an object is the product of moment of inertia and angular velocity.

L = mvr

where;

r = 5i + 5tj

v = dr/dt

v = 5 m/s

L = m(v x r)

v x r = 5j x (5i + 5(7)j)

v x r = 5j x (5i + 35j)

v x r = -25k

|v x r| = 25

L = m(v x r)

L = 2 x 25

L = 50 kgm²/s

Thus, the angular momentum of the particle with respect to the origin is 50 kgm²/s.

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Final answer:

The magnitude of the angular momentum of the particle with respect to the origin at time 7 s is 50 kg m²/s.

Explanation:

To find the magnitude of the angular momentum of a particle with a certain position vector as a function of time, we use the formula ℒ = r × p, where r is the position vector and p is the linear momentum vector (p = mv, with m as mass and v as velocity).

Given the position vector r(t) = (5 m)î + (5 m/s)tì for a mass of 2 kg, we first find the velocity vector by differentiating the position vector with respect to time, v(t) = dr/dt = 0î + (5 m/s)ì. The linear momentum at time t is p(t) = (2 kg)(v(t)) = (2 kg)(0î + (5 m/s)ì) = 0î + (10 kg m/s)ì.

To find the angular momentum at 7 s, we evaluate r at t = 7 s: r(7 s) = (5 m)î + (5 m/s)(7 s)ì = (5 m)î + (35 m)ì. Then, the angular momentum ℒ(7 s) = r(7 s) × p(7 s) = ((5 m)î + (35 m)ì) × (0î + (10 kg m/s)ì), which must be computed using the cross product. ℒ(7 s) ends up being ((5 m)(10 kg m/s))ê = (50 kg m²/s)ê. Therefore, the magnitude of the angular momentum is 50 kg m²/s.

Answer:

(a) Kav Ne = Kav Kr = 7.29x10⁻²¹J

(b) v(rms) Ne= 659.6m/s and v(rms) Kr= 323.7m/s

Explanation:

(a) According to the kinetic theory of gases the average kinetic energy of the gases can be calculated by:

[tex] K_{av} = \frac{3}{2}kT [/tex] (1)        

where [tex] K_{av} [/tex]: is the kinetic energy, k: Boltzmann constant = 1.38x10⁻²³J/K, and T: is the temperature

From equation (1), we can calculate the average kinetic energies for the krypton and the neon:

[tex] K_{av} = \frac{3}{2} (1.38\cdot 10^{-23} \frac{J}{K})(352.2K) = 7.29\cdot 10^{-21}J [/tex]  

(b) The rms speeds of the gases can be calculated by:

[tex] K_{av} = \frac{1}{2}mv_{rms}^{2} \rightarrow v_{rms} = \sqrt \frac{2K_{av}}{m} [/tex]  

where m: is the mass of the gases and [tex]v_{rms}[/tex]: is the root mean square speed of the gases

For the neon:

[tex] v_{rms} = \sqrt \frac{2(7.29 \cdot 10^{-21}J)}{20.1797 \frac{g}{mol} \cdot \frac {1mol}{6.022\cdot 10^{23}molecules} \cdot \frac{1kg}{1000g}} = 659.6 \frac{m}{s} [/tex]          

For the krypton:

[tex] v_{rms} = \sqrt \frac{2(7.29 \cdot 10^{-21}J)}{83.798 \frac{g}{mol} \cdot \frac {1mol}{6.022\cdot 10^{23}molecules} \cdot \frac{1kg}{1000g}} = 323.7 \frac{m}{s} [/tex]  

Have a nice day!

The average kinetic energy and root mean square speed of both neon and krypton gases can be calculated using constants such as the Boltzmann constant, the molecular mass of the gases, and the temperature of the system in Kelvins.

The average kinetic energy (Kav) of a gas molecule, irrespective of the type of gas, is given by the equation Kav = 3/2 kT, where k is Boltzmann's constant and T is the absolute temperature. The root mean square speed (vrms) of the molecules in a gas is given by vrms = sqrt(3kT/m), where m is the molecular mass of the gas.

The temperature should be converted to Kelvins by adding 273.15 to the Celsius temperature, hence T = 79.2°C + 273.15 = 352.35K.

For neon, the molecular mass, m = 20.1797 u. Plugging in these values, we can calculate the average kinetic energy and rms speed for neon molecules in the vessel. Similar calculations are done for krypton with m = 83.798 u.

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To develop this problem it is necessary to apply the concepts related to the Aerodynamic Drag Force.

By definition the Drag Force is defined as

[tex]F_D = \frac{1}{2} \rho A C_D v^2[/tex]

Where,

A = Area

[tex]\rho[/tex]= Density

[tex]C_d[/tex] = Drag coefficient

v = Velocity

According to our values we have,

[tex]A = 1.8*1.8=3.24m^2[/tex]

[tex]C_D = 1.4[/tex]

[tex]V = 5m/s[/tex]

Replacing we have

[tex]F_D = \frac{1}{2} 1.23*3.24*1.4*5^2[/tex]

[tex]F_D = 69.74[/tex]

By definition we know that the thermal energy is given by the force applied in a given displacement then

[tex]W = F*d[/tex]

[tex]W = 69.74*200[/tex]

[tex]W = 13948J[/tex]

Therefore the thermal energy is added to the air by the drag force is 13.9kJ

The thermal energy added to the air by the drag force from a runner's parachute can be calculated by determining the work done against this force during a run. This involves first calculating the drag force with known parameters, then using the force to calculate the work done over the run's distance. This quantity represents the thermal energy imparted to the air.

The calculation for thermal energy added to the air by the drag force requires understanding the basic principles of work and energy. The work done by the drag force is given by the formula W = Fd, where W is work, F is force, and d is distance. In this case, the force is the drag force internalized by the parachute. The drag force is calculated using the equation F = 0.5 * p * v² * C * A, where:

By substituting these values into the formula, we can compute the drag force. Thereafter, we can use this force in our initial work equation to calculate the work done over a 200 m run. It's important to note that the work done against the drag force is transformed into heat (thermal energy). Thus, the work done equals the thermal energy added to the air by the drag force.

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Answer:

The cheerleader does a total work of 8,532 J (8,541 J without any intermediate rounding)

Explanation:

Hi there!

The equation of work is the following:

W = F · d

Where:

W = work.

F = applied force.

d = distance.

The cheerleader´s partner is on the ground due to the force of gravity acting on her, also known as weight. To lift the partner at a constant velocity, the cheerleader has to suppress this force applying on the partner a force that is equal to the partner´s weight but in opposite direction.

The weight of the partner is calculated as follows:

Weight = m · g

Where m is the mass of the partner and g is the acceleration due to gravity.

Let´s calculate the weight of the partner:

Weight = 43.8 kg · 9.8 m/s²

Weight = 429 N

]Then, the work done in one lift by the cheerleader is the following:

W = F · d

W = 429 N · 0.737 = 316 J

If the cheerleader does 27 lifts, the work done will be (316 J · 27) 8,532 J

The work done by the cheerleader to lift his partner 27 times is calculated as the product of force (which itself is the product of the partner's mass and gravity) and distance, hence resulting in a total work done of 8570.61 Joules.

In Physics, energy exerted to move an object is often calculated as work done. Work is defined as the product of the force applied to an object and the distance over which it is applied, and its unit of measurement is Joules (J). Regarding the given problem, the work done by the cheerleader to lift his partner is calculated using the formula: Work = force x distance, where force is derived from the product of the partner's mass and gravity (Force = mass x gravity). So, the work done for one lift would be calculated as follows:

Work(std.) = Force * distance = mass * gravity * distance = 43.8 kg * 9.8 m/s ² * 0.737 m = 317.43 J.

To find out the total work done after 27 lifts, simply multiply this result by 27: Total Work = 27 * Work(std.) = 27 * 317.43 J = 8570.61 J. Thus, the cheerleader does 8570.61 Joules of work by lifting his partner 27 times.

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Answer:

Final velocity at the bottom of hill is 15.56 m/s.

Explanation:

The given problem can be divided into four parts:

1. Use conservation of momentum to determine the speed of the combined mass (Gayle and sled)

From the law of conservation of momentum (perfectly inelastic collision), the combined velocity is given as:  

[tex]p_i = p_f[/tex]  

[tex]m_1u_1 + m_2v_2 = (m_1 + m_2)v[/tex]

[tex]v = \frac{(m_1u_1 + m_2v_2)}{(m_1 + m_2)} [/tex]

[tex]v=\frac{[50.0\ kg)(3.85\ m/s) + 0]}{(50.0\ kg + 5.00\ kg)}= 3.5\ m/s[/tex]  

2. Use conservation of energy to determine the speed after traveling a vertical height of 5 m.

The velocity of Gayle and sled at the instant her brother jumps on is found from the law of conservation of energy:  

[tex]E(i) = E(f)[/tex]  

[tex]KE(i) + PE(i) = KE(f) + PE(f)[/tex]  

[tex]0.5mv^2(i) + mgh(i) = 0.5mv^2(f) + mgh(f)[/tex]  

[tex]v(f) = \sqrt{[v^2(i) + 2g(h(i) - h(f))]}[/tex]

Here, initial velocity is the final velocity from the first stage. Therefore:  

[tex]v(f) = \sqrt{[(3.5)^2+2(9.8)(5.00-0)]}= 10.5\ m/s[/tex]

3. Use conservation of momentum to find the combined speed of Gayle and her brother.  

Given:

Initial velocity of Gayle and sled is, [tex]u_1(i)=10.5[/tex] m/s

Initial velocity of her brother is, [tex]u_2(i)=0[/tex] m/s

Mass of Gayle and sled is, [tex]m_1=55.0[/tex] kg

Mass of her brother is, [tex]m_2=30.0[/tex] kg

Final combined velocity is given as:

[tex]v(f) = \frac{[m_1u_1(i) + m_2u_2(i)]}{(m_1 + m_2)}[/tex]  

[tex]v(f)=\frac{[(55.0)(10.5) + 0]}{(55.0+30.0)}= 6.79 [/tex] m/s  

4. Finally, use conservation of energy to determine the final speed at the bottom of the hill.

Using conservation of energy, the final velocity at the bottom of the hill is:  

[tex]E(i) = E(f)[/tex]  

[tex]KE(i) + PE(i) = KE(f) + PE(f)[/tex]  

[tex]0.5mv^2(i) + mgh(i) = 0.5mv^2(f) + mgh(f)[/tex]  

[tex]v(f) = \sqrt{[v^2(i) + 2g(h(i) - h(f))]} \\v(f)=\sqrt{[(6.79)^2 + 2(9.8)(15 - 5.00)]}\\v(f)= 15.56\ m/s[/tex]

Using principles of kinetic and potential energy, and assuming ideal conditions devoid of friction and air resistance, Gayle and her brother's final speed would be equal to the square root of twice the product of acceleration due to gravity and the total height of the hill.

This question relates to the principles of kinetic energy and potential energy, as well as conservation of energy. When Gayle initially sleds down the hill, she converts potential energy (mgh) into kinetic energy (1/2 mv^2). Taking 'g' as acceleration due to gravity (9.8 m/s^2) and 'h' as the vertical height she descends (5.0 m), the speed she attains at the time her brother joins (v') can be calculated using √(2gh).

The potential energy at that point is their combined mass times gravity and their height, which is transformed to kinetic energy at the bottom. If 'H' is the total height of the hill (15.0 m), their final combined speed is given by √(2gH). Ignoring resistive forces, they maintain this speed for the entire ride down the hill.

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Answer:

2993 °C

Explanation:

A reaction is spontaneous if the free Gibbs energy (ΔG) is negative. ΔG is related to the enthalpy of the reaction (ΔH) and the entropy of the reaction (ΔS) through the following expression.

ΔG = ΔH - T . ΔS

For 1 mol, if ΔG < 0, then

ΔH - T . ΔS < 0

ΔH < T . ΔS

-320.1 × 10³ J < T . (-98.00 J/K)

T < 3266 K

To convert Kelvin to Celsius we use the following expression.

K = °C + 273.15

°C = K - 273.15 = 3266 - 273.15 = 2993 °C

The force per unit length between the two wires is [tex]6.0\cdot 10^{-5} N/m[/tex]

Explanation:

The magnitude of the force per unit length exerted between two current-carrying wires is given by

[tex]\frac{F}{L}=\frac{\mu_0 I_1 I_2}{2\pi r}[/tex]

where

[tex]\mu_0 = 4\pi \cdot 10^{-7} Tm/A[/tex] is the vacuum permeability

[tex]I_1, I_2[/tex] are the currents in the two wires

r is the separation between the two wires

For the wires in this problem, we have

[tex]I_1 = 1.75 A[/tex]

[tex]I_2 = 3.45 A[/tex]

r = 2.00 cm = 0.02 m

Substituting into the equation, we find

[tex]\frac{F}{L}=\frac{(4\pi \cdot 10^{-7})(1.75)(3.45)}{2\pi (0.02)}=6.0\cdot 10^{-5} N/m[/tex]

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Answer:

C. The bullet will hit the monkey because both the monkey and the bullet are falling downward at the same rate due to gravity.

Explanation:

As we know that acceleration due to gravity is equal g m/s².The acceleration due to gravity is in downward direction always and the numerical value is equal to g =10 m/s².

Both the bullet and money moving downward with constant acceleration that is why bullet will hit the money.

Therefore the answer is C.

Answer:

31.66 m/s

Explanation:

mass of player, M = 75 kg

mass of ball, m = 0.45 kg

initial velocity of player, U = + 4 m/s

initial velocity of ball, u = - 24 m/s

Let the final speed of player is V and the ball is v.

use conservation of momentum

Momentum before collision = momentum after collision

75 x 4 - 0.45 x 24 = 75 x V + 0.45 x v

289.2 = 75 V + 0.45 v    .... (1)

As the collision is perfectly elastic, coefficient of restitution,e = 1

So, [tex]e=\frac{v_{1}-v_{2}}{u_{2}-u_{1}}[/tex]

V - v = u - U

V - v = -24 - 4 = - 28

V = v - 28, put this value in equation (1), we get

289.2 = 75 (v - 28) + 045 v

289.2 = 75 v - 2100 + 0.45 v

2389.2 = 75.45 v

v = 31.66 m/s

Thus, the velocity of ball after collision is 31.66 m/.

In order to solve this problem, it is necessary to apply the concepts related to the Pressure according to the Force and the Area as well as to the pressure depending on the density, gravity and height.

In the first instance we know that the pressure can be defined as

[tex]P = \frac{F}{A}[/tex]

Where

F= Force

A =  Mass

In the second instance the pressure can also be defined as

[tex]P = \rho gh[/tex]

Where,

[tex]\rho=[/tex]Density of Fluid at this case Water

g = Gravitational Acceleration

h = Height

If we develop the problem to find the pressure then,

[tex]P = \frac{F}{A}[/tex]

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

[tex]P = \frac{2*10^6}{\pi (0.1)^2}[/tex]

[tex]P = 6.37*10^{7} Pa[/tex]

Through the second equation we can find the depth to which it can be submerged,

[tex]P = \rho gh[/tex]

Re-arrange to find h

[tex]h = \frac{P}{\rho g}[/tex]

[tex]h = \frac{6.37*10^{7}}{1000*9.8}[/tex]

[tex]h = 6499.4m[/tex]

Answer:

Speed of ball A after collision is 3.7 m/s

Speed of ball B after collision is 2 m/s

Direction of ball A after collision is towards positive x axis

Total momentum after collision is m×4·21 kgm/s

Total kinetic energy after collision is m×8·85 J

Explanation:

Let the mass of each ball be m kg

v[tex]_{1}[/tex] be the velocity of ball A along positive x axis

v[tex]_{2}[/tex] be the velocity of ball A along positive y axis

u be the velocity of ball B along positive y axis

Conservation of momentum along x axis

m×3·7 = m× v[tex]_{1}[/tex]

∴  v[tex]_{1}[/tex] = 3.7 m/s along positive x axis

Conservation of momentum along y axis

m×2 = m×u + m× v[tex]_{2}[/tex]

2 = u +  v[tex]_{2}[/tex] → equation 1

∴ relative velocity of approach = relative velocity of separation

-2 =  v[tex]_{2}[/tex] - u → equation 2

By adding both equations 1 and 2 we get

v[tex]_{2}[/tex] = 0

∴ u = 2 m/s along positive y axis

Kinetic energy before collision and after collision remains constant because it is an elastic collision

Kinetic energy = (m×2² + m×3·7²)÷2

                         = 8·85×m J

Total momentum = m×√(2² + 3·7²)

                             = m× 4·21 kgm/s

To solve this problem it is necessary to apply the concepts related to the drag force.

By definition we know that drag force can be expressed as

[tex]F_D = \frac{1}{2} \rho C_D AV^2[/tex]

Where,

\rho = Density

[tex]C_D =[/tex]Drag Coefficient

A = Area

V = Velocity

Our values are given as

[tex]A = 2.5ft^2[/tex]

[tex]V = 88ft/s[/tex]

[tex]C_D = 0.9[/tex]

[tex]\rho = 0.0765lb/ft^3 \rightarrow[/tex] Air at normal temperature

Replacing at the equation we have,

[tex]F_D = \frac{1}{2} \rho C_D AV^2[/tex]

[tex]F_D = \frac{1}{2} (0.0765lb/ft^3) (0.9) (2.5ft^2) (88ft/s)^2[/tex]

[tex]F_D = 666.468lbf[/tex]

The aerodynamic drag force is 666.468Lbf

To solve this problem it is necessary to apply the concepts related to the Pressure which describes the amount of Force made on an area unit.

Its mathematical expression can be defined as

[tex]P = \frac{F}{A}[/tex]

Where,

F= Force

A = Area

Our values are given as

[tex]d = 0.987*10^{-2}m[/tex]

With the diameter we can find the Area of the circular heel, that is

[tex]A = \pi (\frac{0.987*10^{-2}}{2})^2[/tex]

[tex]A = 7.6511*10^{-5}m^2[/tex]

To find the force by weight we need to apply the Newton's second Law

[tex]F = mg[/tex]

[tex]F = 53*9.8[/tex]

[tex]F = 519.4N[/tex]

Finally the pressure would be

[tex]P = \frac{F}{A}[/tex]

[tex]P = \frac{519.4}{7.6511*10^{-5}}[/tex]

[tex]P = 6788566.35Pa[/tex]

[tex]P = 6.788MPa[/tex]

Therefore the pressure that she exerts on the carpet sample is 6.788Mpa

Answer:

  W = 661.6 N

Explanation:

The weight of a body is the force of attraction of the plant on the body, so we must use the law of gravitational attraction

       F = G m M / r²

Where G is the gravitational attraction constant that values ​​6.67 10-11 N m² / kg², M is the mass of the planet and r is the distance from the center of the planet.

Let's look for the mass of the planet, for this we write Newton's second law for the landing craft

     F = m a

Acceleration is centripetal a = v² / r

     G m M / r² = m (v² / r)

The ship rotates rapidly (constant velocity module), let's use uniform kinematic relationships

    v = d / t

The distance of a circle is

    d = 2π r

    v = 2π r / t

We replace

     G m M / r² = m (4π² r² / t² r)

    G M = 4 π² r³ / t²

    M = 4π² r³ / G t²

The measured distance r from the center of the plant is

     r = R orbit + R planet

     r = 5.90 10⁵ + ½ 9.80 10⁶

     r = 5.49 10⁶ m

    M = 4 π² (5.49 10⁶)³ / (6.67 10⁻¹¹ (5.900 10³)²)

    M = 6,532 10²¹ / 2,321 10⁺³

    M = 2.814 10²⁴ kg

With this data we calculate the astronaut's weight

     W = (G M / R²) m

     W = (6.67 10⁻¹¹ 2,816 10²⁴ /(4.90 10⁶)2)   84.6

     W = 7.82  84.6

     W = 661.57 N

To calculate the weight of the astronaut on the surface of the planet, we first need to find out the gravitational acceleration at the planet's surface using the parameters of the landing craft's orbit. After we have the value of gravitational acceleration, we multiply it by the mass of the astronaut.

To answer your question, we first need to calculate the gravitational acceleration at the surface of the planet, denoted by g. We can use the orbital parameters of the landing craft to find g using the following formula where G represents the universal gravitation constant, M is the mass of the planet, and r is the radius of the planet:

g = GM/r^2

After we solve this, we can then calculate the weight of the astronaut on the surface using W = mg, where m is the mass of the astronaut.

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To create a gauge pressure of 62.5 cm H₂O on an area of 51 cm², you must exert a force of approximately 31.27 newtons on the balloon. This is obtained by converting the pressure to pascals, the area to square meters and using the formula Pressure = Force/Area.

To find the force you must exert on the balloon to create a gauge pressure of 62.5 cm H₂O when squeezing an area of 51 cm², you can use the relationship between pressure, force, and area given by the formula Pressure (P) = Force (F) / Area (A). First, convert the gauge pressure from cm H₂O to pascals (Pa) since 1 cm H₂O is approximately 98.0665 Pa. Then multiply the converted pressure by the area in m² to find the force in newtons (N).

Step 1: Convert cm H₂O to pascals (Pa):
62.5 cm H₂O * 98.0665 Pa/cm H₂O = 6131.65 Pa

Step 2: Convert the area from cm²to m² (since there are 10,000 cm2 in 1 m²):
51 cm² / 10,000 = 0.0051 m²

Step 3: Calculate the force:
Force (F) = Pressure (P) * Area (A)
F = 6131.65 Pa * 0.0051 m² = 31.27 N

Therefore, you must exert a force of approximately 31.27 newtons on the balloon.

Answer:

a. 0 kgm/s

b. 0 kgm/s

c. 66 kgm/s

d. -66 kgm/s

e. 0 kgm/s

f. -27.05 m/s

g. 173.68 N

h. 12.58 m/s

i. 0.772 m

j. 14487 J

Explanation:

150 g = 0.15 kg

a. Before the bullet is fired, both rifle and the bullet has no motion. Therefore, their velocity are 0, and so are their momentum.

b. The combination is also 0 here since the bullet and the rifle have no velocity before firing.

c. After the bullet is fired, the momentum is:

0.15*440 = 66 kgm/s

d. As there's no external force, momentum should be conserved. That means the total momentum of both the bullet and the rifle is 0 after firing. That means the momentum of the rifle is equal and opposite of the bullet, which is -66kgm/s

e. 0 according to law of momentum conservation.

f. Velocity of the rifle is its momentum divided by mass

v = -66 / 2.44 = -27.05 m/s

g. The average force would be the momentum divided by the time

f = -66 / 0.38 = 173.68 N

h. According the momentum conservation the bullet-block system would have the same momentum as before, which is 66kgm/s. As the total mass of the bullet-block is 5.1 + 0.15 = 5.25. The velocity of the combination right after the impact is

66 / 5.25 = 12.58 m/s

i. The normal force and also friction force due to sliding is

[tex]F_f = N\mu = Mg\mu = 5.25*9.81*0.83 = 42.75N[/tex]

According to law of energy conservation, the initial kinetic energy will soon be transformed to work done by this friction force along a distance d:

[tex]W = K_e[/tex]

[tex]dF_f = 0.5Mv_0^2 [/tex]

[tex]d = \frac{Mv_0^2}{2F_f} = \frac{5.25*12.58^2}{2*42.75} = 0.772 m[/tex]

j.Kinetic energy of the bullet before the impact:

[tex]K_b = 0.5*m_bv_b^2 = 0.5*0.15*440^2 = 14520 J[/tex]

Kinetic energy of the block-bullet system after the impact:

[tex]K_e = 0.5Mv_0^2 = 0.5 * 5.25*12.58^2 = 33 J[/tex]

So 14520 - 33 = 14487 J was lost during the lodging process.

Answer:

Explanation:

Let us first calculate for Virgo

[tex]A= d_{virgo} = 17;M_{pc}, V_{virgo} = 1200 km/s, [/tex]

Using Hubble's law

[tex]v = H_{0}D[/tex] For Virgo

[tex]V_{virgo} = H_{0}D_{virgo}[/tex]

[tex]O = D_{virgo} = \frac{v_{virgo}}{H_{0}} = \frac{1200 km/s}{70 km/s/Mpc}= 17.143 Mpc [/tex]

Percentage difference for the Virgo

[tex]\% = \frac{|A-O|}{A}\times 100 = \frac{|17 Mpc-17.143 Mpc|}{17 Mpc}\times 100 = 0.84 \% [/tex]

Now for calculate for Corona Borealis

[tex]A= d_{Corona Borealis}  = 310 Mpc, v_{Corona Borealis}  = 22000 km/s, [/tex]

Using Hubble's law

[tex]v = H_{0}D[/tex] For Corona Borealis

[tex]v_{Corona Borealis } = H_{0}D_{Corona Borealis } \\O = D_{Corona Borealis } = \frac{v_{Corona Borealis }}{H_{0}} = \frac{22000 km/s}{70 km/s/Mpc}= 314.286 Mpc [/tex]

Percentage difference for the Virgo

[tex]\% = \frac{|A-O|}{A}\times 100 = \frac{|310 Mpc-314.286 Mpc|}{310 Mpc}\times 100 = 1.3825 \% [/tex]

So clearly  Hubble's law is more accurate for the closer objects

To solve this problem it is necessary to apply the concepts related to the Gravitational Force, for this purpose it is understood that the gravitational force is described as

[tex]F_g = \frac{Gm_1m_2}{r^2}[/tex]

Where,

G = Gravitational Universal Force

[tex]m_i =[/tex] Mass of each object

To solve this problem it is necessary to divide the gravitational force (x, y) into the required components and then use the tangent to find the angle generated between both components.

Our values are given as,

[tex]m_1 =4.6 kg\\m_2 = 7.2 kg\\m_3 = 2.6 kg\\r_1 = 5.7 m\\r_2 = 4.2 m[/tex]

Applying the previous equation at X-Axis,

[tex]F_x = \frac{Gm_1m_3}{R_{1}^2}\\F_x = \frac{6.67*10^{-11}*4.6*2.6}{5.7^2}\\F_x = 2.46*10^{-11}N[/tex]

Applying the previous equation at Y-Axis,

[tex]F_y = \frac{Gm_2m_3}{R_2^2}\\F_y = \frac{6.67*10^{-11}*7.2*2.6}{4.2^2}\\F_y = 7.08*10^{-11} N[/tex]

Therefore the angle can be calculated as,

[tex]tan\theta = \frac{F_y}{F_x}\\\theta = tan^{-1} \frac{F_y}{F_x}\\\theta = tan^{-1} \frac{7.08*10^{-11}}{2.46*10^{-11}}\\\theta = 71\°[/tex]

Then in the measure contrary to the hands of the clock the Force in the particle 3 is in between the positive direction of the X and the negative direction of the Y at 71 ° from the positive x-axis.

To solve this problem it is necessary to apply the concepts related to energy as a function of voltage, load and force, and the definition of Force given by Newton in his second law.

By definition we know that force is equal to

F= ma

Where,

m = mass (at this case of an electron)

a = Acceleration

But we also know that the Energy of an electric object is given by two similar definitions.

[tex]1) E= \frac{F}{q}[/tex]

Where,

F= Force

q = Charge of proton/electron

[tex]2) E = \frac{V}{d}[/tex]

V = Voltage

d = Distance

Equating and rearrange for F,

[tex]\frac{F}{q} = \frac{V}{d}[/tex]

[tex]F = \frac{Vq}{d}[/tex]

The two concepts of force can be related to each other, then

[tex]ma = \frac{Vq}{d}[/tex]

Acceleration would be,

[tex]a = \frac{Vd}{dm}[/tex]

Replacing with our values we have that the acceleration is

[tex]a = \frac{Vq}{dm}[/tex]

[tex]a = \frac{(170)(1.6*10^{-19})}{(2*10^{-2})(9.1*10^{-31})}[/tex]

[tex]a = 1.49*10^{15}m/s^2[/tex]

Now through the cinematic equations of motion we know that,

[tex]V_f^2-V_i^2 = 2ax[/tex]

Where,

[tex]V_f =[/tex] Final velocity

[tex]V_i =[/tex] Initial velocity

a = Acceleration

x = Displacement

Re-arrange to find v_f,

[tex]v_f = \sqrt{v_i^2+2ax}[/tex]

[tex]v_f = \sqrt{2.5*10^5+2*(1.49*10^{15})(0.1*10^{-2})}[/tex]

[tex]v_f = 1.726*10^6 m/s[/tex]

Therefore the electron's speed when it is 0.1 cm from the negative plate is [tex]1.726*10^6 m/s[/tex]

Speed of the electron enters in the gape of two large aluminum plates,  when it is 0.1 cm from the negative plate is,

[tex]v_f=1.726\times10^6\rm m/s[/tex]

The electric field is the field, which is surrounded by the electric charged. The electric field is the electric force per unit charge.

The electric force due to the electric field can be given as,

[tex]F=\dfrac{Vq}{d}[/tex]

Here, (V) is the potential difference, (q) is the charge on the body and (d) is the distance.

The charge on a electron is [tex]1.6\times10^{-19}[/tex] C. As the distance between the two plates is 2 meters and the value of potential difference is 170 V. Thus, put the values in the above formula as,

[tex]F=\dfrac{170\times(1.6\times10^{-19})}{0.02}[/tex]

As the force on a body is the product of mass times acceleration and the mass of the electron is [tex]9.1\times10^{-31}[/tex] kg. Thus, the above equation can be rewrite as,

[tex](9.1\times10^{-31})a=\dfrac{170\times(1.6\times10^{-19})}{0.02}[/tex]

[tex]a=1.49\times10^{15}\rm m/s^2[/tex]

The initial speed of the electron is [tex]2.5\times10^5[/tex] m/s and the acceleration is [tex]1.49\times10^{15}\rm m/s^2[/tex]. Thus from the third equation of motion, the final velocity can be given as,

[tex]v_f=\sqrt{2.5\times10^5+2(1.49\times10^{15})(0.1\times10^{-2})}\\v_f=1.726\times10^6\rm m/s[/tex]

Thus, the speed of the electron,  when it is 0.1 cm from the negative plate is,

[tex]v_f=1.726\times10^6\rm m/s[/tex]

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This answer provides the equations and steps to calculate the buoyant force, the mass of the barge, the mass of the coal, and how far the barge would be submerged.

a) The equation for the buoyant force on the empty barge can be written as:

FB = ρgV

where FB is the buoyant force, ρ is the density of water, g is the acceleration due to gravity, and V is the volume of the barge submerged in water.

b) To determine the mass of the barge, we can use the equation:

FB = mg

where FB is the buoyant force, m is the mass of the barge, and g is the acceleration due to gravity.

c) The mass of the coal can be found by subtracting the mass of the empty barge from the mass of the fully loaded barge.

d) To find the mass of the coal in kilograms, you can use the equation:

mc = ρcVc

where mc is the mass of the coal, ρc is the density of the coal, and Vc is the volume of the coal.

e) To calculate how far the barge would be submerged with 250,000 kg of coal, you can use the equation:

FB = mg

and solve for H, where H is the height the barge is submerged.

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Answer:

Explanation:

Given that,

Radius of the wheel, r = 20 cm = 0.2 m

Initial speed of the wheel, [tex]\omega_i=120\ rpm=753.98\ rad/s[/tex]

Displacement, [tex]\theta=90\ rev=565.48\ rad[/tex]

To find,

The angular acceleration and the distance covered by the car.

Solution,

Let [tex]\alpha[/tex] is the angular acceleration of the car. Using equation of rotational kinematics as :

[tex]\theta=\omega_i t+\dfrac{1}{2}\alpha t^2[/tex]

[tex]565.48=753.98\times 60+\dfrac{1}{2}\alpha (60)^2[/tex]

[tex]\alpha =-24.81\ rad/s^2[/tex]

Let t is the time taken by the car before coming to rest.

[tex]t=\dfrac{\omega_f-\omega_i}{\alpha }[/tex]

[tex]t=\dfrac{0-753.98}{-24.81}[/tex]

t = 30.39 seconds

Let v is the linear velocity of the car. So,

[tex]v=r\times \omega_i[/tex]

[tex]v=0.2\times 753.98[/tex]

v = 150.79 m/s

Let d is the distance covered by the car. It can be calculated as :

[tex]d=v\times t[/tex]

[tex]d=150.79\ m/s\times 30.39\ s[/tex]

d = 4582.5 meters

or

d = 4.58 km

To develop this problem it is necessary to use the equations of description of the simple harmonic movement in which the acceleration and angular velocity are expressed as a function of the Amplitude.

Our values are given as

[tex]f = 4.11 *10^{12} Hz[/tex]

[tex]A = 1.23 * 10^{-11}m[/tex]

The angular velocity of a body can be described as a function of frequency as

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

[tex]\omega = 2\pi 4.11 *10^{12}[/tex]

[tex]\omega=2.582*10^{13} rad/s[/tex]

PART A) The expression for the maximum angular velocity is given by the amplitude so that

[tex]V = A\omega[/tex]

[tex]V =( 1.23 * 10^{-11})(2.582*10^{13})[/tex]

[tex]V =  = 317.586m/s[/tex]

PART B) The maximum acceleration on your part would be given by the expression

[tex]a = A \omega^2[/tex]

[tex]a =( 1.23 * 10^{-11})(2.582*10^{13})^2[/tex]

[tex]a= 8.2*10^{15}m/s^2[/tex]

The number of electrons emitted from the metal per second increases if the intensity of the incident light is increased.

Answer: Option B

Explanation:

As a result of photoelectric effect, electrons are emitted by the light incident on a metal surface. The emitted electrons count and its kinetic energy can measure as the function of light intensity and frequency. Like physicists, at the 20th century beginning, it should be expected that the light wave's energy (its intensity) will be transformed into the kinetic energy of emitted electrons.

In addition, the electrons count emitting from metal must vary with light wave frequency. This frequency relationship was expected because the electric field oscillates due to the light wave and the metal electrons react to different frequencies. In other words, the number of electrons emitted was expected to be frequency dependent and their kinetic energy should be dependent on the intensity (constant wavelength) of light.

Thus, the maximum in kinetic energy of electrons emitted increases with increase in light's frequency and is experimentally independent of light intensity. So, the number of emitted electrons is proportionate to the intensity of the incident light.

Final answer:

If the intensity of the incident light on a metal surface in a photoelectric effect experiment is increased, while keeping frequency constant, the number of electrons emitted per second increases. This happens because a higher intensity means more photons are available to eject electrons. Neither the work function of the metal, the maximum speed of the emitted electrons, nor the stopping potential are affected by changes in light intensity.

Explanation:

The question relates to the effect of increasing the intensity of light in a photoelectric effect experiment while keeping the frequency of the incident light and the temperature of the metal constant. In this setup:

It is important to note that:

Answer:

a) 1.875 V b) 5.86 W c) 18.75 V 586 W d) 187.5 V 5.86 kW.

Explanation:

a) As the load is purely resistive, we can get the Irms, applying directly the definition of electrical power, as follows:

I = P / V = 250,000 W / 80,000 V = 3.125 A

Applying Ohm’s Law to the resistance of the conductors in the transmission line, we have:

∆V = I. R = 3.125 A . 0.6 Ω = 1.875 V

b) The rate at which energy is dissipated in the line as thermal energy, can be obtained applying Joule’s law, using the RMS value of the current that we have already got:

Pd = I2. R = (3.125)2 A . 0.6Ω = 5.86 W

c) If Vt were 8,000 V instead of 80,000 V, we would have a different value for I, as follows:

I= 250,000 W / 8,000 V = 31.25 A

So, we would have a different ∆V:

∆V = 31.25 A . 0.6 Ω = 18.75 V

As the RMS current is different, we will have a different value por the dissipated power in the line:

P = (31.25)2 . 0.6 Ω = 586 W

d) As above, we will have a new value for I, as follows:

I = 250,000 W / 800 V = 312. 5 A

The new voltage loss in the transmission line will be much larger:

∆V = 312.5 A . 0.6 Ω = 187.5 V

Consequently, we will have a higher dissipated power:

P = (312.5)2 . 0.6 Ω = 58.6 kW

To find the voltage drop across the transmission line and the power dissipated, we use Ohm's Law and the power equation. The voltage drop across the line is ∆V = I * R, and the power dissipated is Ploss = I² * R. Substituting the values, we can calculate the voltage drop and power dissipated for different values of Vt.

To find the voltage drop across the transmission line, we can use Ohm's Law. The total resistance of the transmission line is 0.3 Ω per cable, so the resistance for the entire line is 0.6 Ω. The voltage drop is given by: ∆V = I * R, where I is the current flowing through the transmission line. Since power P = V * I, we can rewrite the equation as: Vt * I = Pt, which gives us I = Pt / Vt. Substituting the values, we get I = 250,000 watts / 80,000 volts = 3.125 A.

(a) The voltage drop ∆V across the transmission line is therefore: ∆V = I * R = 3.125 A * 0.6 Ω = 1.875 V.

(b) The rate at which energy is dissipated in the line as thermal energy is equal to the power loss due to resistance, given by: Ploss = I² * R = (3.125 A)² * 0.6 Ω = 5.859375 W.

(c) If Vt is 8000 V (rms), the current flowing through the transmission line is: I = Pt / Vt = 250,000 watts / 8000 volts = 31.25 A. The voltage drop across the line is then ∆V = I * R = 31.25 A * 0.6 Ω = 18.75 V. The power dissipated in the line is: Ploss = I² * R = (31.25 A)² * 0.6 Ω = 585.9375 W.

(d) If Vt is 800 V (rms), the current flowing through the transmission line is: I = Pt / Vt = 250,000 watts / 800 volts = 312.5 A. The voltage drop across the line is ∆V = I * R = 312.5 A * 0.6 Ω = 187.5 V. The power dissipated in the line is: Ploss = I² * R = (312.5 A)² * 0.6 Ω = 58593.75 W.

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To solve the exercise it is necessary to apply the concepts related to Newton's Second Law, as well as the definition of Weight and Friction Force.

According to the problem there is a movement in the body and it is necessary to make a sum of forces on it, so that

[tex]\sum F = ma[/tex]

There are two forces acting on the body, the Force that is pushing and the opposing force that is that of friction, that is

[tex]F - F_f = ma[/tex]

To find the required force then,

[tex]F=F_f+ma[/tex]

By definition we know that the friction force is equal to the multiplication between the friction coefficient and the weight, that is to say

[tex]F = \mu mg +ma[/tex]

[tex]F = 0.35*50*0.8+50*1.2[/tex]

[tex]F=(171.5N)+(50Kg)(1.2m/s^2)[/tex]

[tex]F=231.5N[/tex]

[tex]F\approx 230N[/tex]

Therefore the horizontal force applied on the block is B) 230N

To find the horizontal force necessary to accelerate the box at 1.2 m/s^2, we consider the frictional forces. The maximum static friction can be calculated using the coefficient of static friction and the weight of the box. The horizontal force required is equal to the maximum static friction.

To find the horizontal force required to accelerate the 50-kg box at 1.2 m/s^2, we need to consider the frictional forces acting on the box. First, we calculate the maximum static friction using the formula:

Maximum static friction = coefficient of static friction × normal force

Normal force = mass × gravity

Maximum static friction = 0.65 × (50 kg × 9.8 m/s^2)

Horizontal force = maximum static friction = 0.65 × (50 kg × 9.8 m/s^2)

So, the horizontal force needed is approximately 318.5 N.

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Answer:

e. the air mattress exerts the same impulse, but a smaller net avg force, on the high-jumper than hard-ground.

Explanation:

This is according to the Newton's second law and energy conservation that the force exerted by the hard-ground is more than the force exerted by the mattress.

The hard ground stops the moving mass by its sudden reaction in the opposite direction of impact force whereas the mattress takes a longer time to stop the motion of same mass in a longer time leading to lesser average reaction force.

Mathematical expression for the Newton's second law of motion is given as:

[tex]F=\frac{dp}{dt}[/tex] ............................................(1)

where:

dp = change in momentum

dt = time taken to change the momentum

We know, momentum:

[tex]p=m.v[/tex]

Now, equation (1) becomes:

[tex]F=\frac{d(m.v)}{dt}[/tex]

∵mass is constant at speeds v << c (speed of light)

[tex]\therefore F=m.\frac{dv}{dt}[/tex]

and, [tex]\frac{dv}{dt} =a[/tex]

where: a = acceleration

[tex]\Rightarrow F=m.a[/tex]

also

[tex]F\propto \frac{1}{dt}[/tex]

so, more the time, lesser the force.

& Impulse:

[tex]I=F.dt[/tex]

[tex]I=m.a.dt[/tex]

[tex]I=m.\frac{dv}{dt}.dt[/tex]

[tex]I=m.dv=dp[/tex]

∵Initial velocity and final velocity(=0), of a certain mass is same irrespective of the stopping method.

So, the impulse in both the cases will be same.

Final answer:

According to the impulse-momentum theorem, the air mattress exerts the same impulse as the hard ground on the high-jumper, but with a smaller net average force because the stopping time is extended on the air mattress.

Explanation:

The key to understanding this scenario lies in the impulse-momentum theorem, which states that the change in momentum (impulse) of an object is equal to the average net external force applied to it, times the duration of time this force acts upon the object.

In both cases, landing on the hard ground and landing on an air mattress, the change in momentum of the high-jumper is the same, since she comes to rest from the same initial velocity in both scenarios. Thus, the overall impulse received by the high-jumper must be the same in both situations. However, the difference lies in the time over which the stopping force is applied.

When landing on the air mattress, the stopping time is longer than on the hard ground. According to the impulse-momentum theorem (Ap = Fnet At), since the impulse (Ap) is the same but the time (t) is greater when landing on the air mattress, the average net force (Fnet) must be smaller in comparison with landing on the hard ground. Therefore, the correct statement is that the air mattress exerts the same impulse but a smaller net average force than the hard ground.

Answer:

  α  = 17 rad / s² ,   t = 0.4299 s

Explanation:

Let's use Newton's second angular law or torque to find angular acceleration

     τ = I α

     W r = I α

The weight is applied in the middle of the pencil,

    sin 10 = r / (L/2)

    r = L/2  sin 10

The pencil can be approximated by a bar that rotates on one end, in this case its moment of inertia is

     I = 1/3 M L²

Let's calculate

    mg L / 2 sin 10 = (1/3 m L²) α  

    α f = 3/2 g / L sin 10

    α  = 3/2 9.8 / 0.150 sin 10

    α  = 17 rad / s²

If the pencil has a constant acceleration we can use the angular kinematics relationships, as part of the rest wo = 0

     θ = w₀ t + ½ α  t²

     t = RA (2θ / α )

The angle from the vertical to the ground is

    θ = π / 2

    t = √ (2 π / (2 α ))

    t = √ (π / α )

    t = √ (π / 17)

     t = 0.4299 s

The time for the pencil to hit the ground if it falls from standing perfectly vertical and maintains the angular acceleration is 0.4299s.

Newton's second angular law will be used to find the angular acceleration. This will be:

τ = I α

Wr = I α

Here, the weight is applied in the middle of the pencil, therefore,

sin 10 = r / (L/2)

Make r the subject of the formula

r = L/2 sin 10

Then, the moment of inertia will be:

I = 1/3 M L²

mg L / 2 sin 10 = (1/3 m L²) α  

αf = 3/2 g / L sin 10

α  = [3/2 × 9.8] / [0.150 sin10]

α  = 17 rad/s²

The angle from the vertical to the ground will be denoted as:

θ = π / 2

t = √ (2 π / (2 α ))

t = √(π / α )

t = √(π / 17)

t = √3.142 / 17

t = [tex]\sqrt{0.1848}[/tex]

t = 0.4299s

Therefore, the time for the pencil to hit the ground is 0.4299s.

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