Planets are not uniform inside. Normally, they are densest at the center and have decreasing density outward toward the surface. Model a spherically symmetric planet, with the same radius as the earth, as having a density that decreases linearly with distance from the center. Let the density be 1.30×104 kg/m3 at the center and 2100 kg/m3 at the surface. Part A What is the acceleration due to gravity at the surface of this planet?

Answer:

The number of available energy states per unit volume is [tex]4.01\times10^{48}[/tex]

Explanation:

Given that,

Average energy  [tex]E=2\times10^{-4}\ eV[/tex]

Photon = [tex]4\times10^{-5}\ eV[/tex]

We need to calculate the number of available energy states per unit volume

Using formula of energy

[tex]g(\epsilon)d\epsilon=\dfrac{8\pi E^2dE}{(hc)^3}[/tex]

Where, E = energy

h = Planck constant

c = speed of light

Put the value into the formula

[tex]g(\epsilon)d\epsilon=\dfrac{8\times\pi\times2\times10^{-4}\times4\times10^{-5}\times1.6\times10^{-19}}{(6.67\times10^{-34}\times3\times10^{8})^3}[/tex]

[tex]g(\epsilon)d\epsilon=4.01\times10^{48}[/tex]

Hence, The number of available energy states per unit volume is [tex]4.01\times10^{48}[/tex]

To solve this problem it is necessary to apply the concept related to root mean square velocity, which can be expressed as

[tex]v_{rms} = \sqrt{\frac{3RT}{n}}[/tex]

Where,

T = Temperature

R = Gas ideal constant

n = Number of moles in grams.

Our values are given as

[tex]v_e =11.2km/s = 11200m/s[/tex]

The temperature is

[tex]T = 30\°C = 30+273 = 303K[/tex]

Therefore the root mean square velocity would be

[tex]v_{rms} = \sqrt{\frac{3(8.314)(303)}{0.002}}[/tex]

[tex]v_{rms} = 1943.9m/s[/tex]

The fraction of velocity then can be calculated between the escape velocity and the root mean square velocity

[tex]\alpha = \frac{v_{rms}}{v_e}[/tex]

[tex]\alpha = \frac{1943.9}{11200}[/tex]

[tex]\alpha = 0.1736[/tex]

Therefore the fraction of the scape velocity on the earth for molecula hydrogen is 0.1736

Answer:

Explanation:

The expression relating length and time period

T  = 2π [tex]\sqrt{\frac{l}{g} }[/tex]

3.2 = [tex]2\pi \sqrt{\frac{l}{9.8} }[/tex]

l = 2.54 m

On Mars g = 3.7

[tex]3.2 = 2\pi \sqrt{\frac{L}{3.7} }[/tex]

L = .96 m

b )

Expression for elastic constant and time  period is as follows

[tex]T  = 2\pi \sqrt{\frac{m}{k} }[/tex]

[tex]3.2=2\pi \sqrt{\frac{m}{20} }[/tex]

m = 5.19 N/s

Time period of oscillation due to spring is not dependent on g , so same time period will be found on Mars as that on the earth.

Answer:

the effective coefficient of kinetic friction between the wheel and the wet rag is 0.31

Explanation:

given information:

radius, r = 0.47 m

moment of inertia, I = 14.2 kg[tex]m^{2}[/tex]

angular velocity, ω0 = 53 rev/min = 53 x 2π/60 = 5.5 rad/s

time, t = 8.0 s

inward force, N = 68 N

τ = I α

F r = I α, F is friction force, F = μ N

μ N r = I α

μ = I α / N r

We have to find α

ωt = ω0 + αt. ωt = 0 because the wheel stop after 8 s

0 = 5.5 + α 8

α = -5.5/8 = 0.69 [tex]rad/s^{2}[/tex]

Now we can calcultae the coeffcient of kinetik friction

μ = I α / N r

  = (14.2) (0.69) / (68) (0.47)

  = 0.31

Answer:

  d. They both have the same change in magnitude of momentum because momentum is conserved.                

Explanation:

      We know that if there is no any external force on the system the linear     momentum of the system remain conserve.Or in the other other words change in the linear momentum is zero.

    Here the external force is zero ,that is why initial and the final momentum will be conserved.

     change in the momentum  for both car as well as truck will be same.Because momentum should be conserved.

Therefore the answer is -d

The statement that best describes the situation is that they both have the same change in magnitude of momentum because momentum is conserved. Option D is correct

Momentum has to do with the strength an object has when moving with speed.

For the truck and the small car given in the question, there was no external force acting on the system.

Since there was no force acting on the system, we can conclude that the linear momentum of the system is conserved that is there is no change in the linear momentum of the system.

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Final answer:

The moment of inertia for each object can be calculated using specific formulas. The formulas are: For a thin hoop: I = mR², for a solid cylinder: I = (1/2)MR², for a solid sphere: I = (2/5)MR², and for a thin spherical shell: I = (2/3)MR².

Explanation:

The moment of inertia for each object as it rotates about its axis can be calculated using the formulas for moment of inertia for different objects:

1. Hoop: The moment of inertia for a thin hoop rotating about an axis perpendicular to its plane is given by the formula I = mR², where m is the mass and R is the radius of the hoop. In this case, the mass is 4.01 kg and the radius is 0.260 m, so the moment of inertia for the hoop is (4.01 kg)(0.260 m)².

2. Solid Cylinder: The moment of inertia for a solid cylinder rotating about its central axis is given by the formula I = (1/2)MR², where M is the mass and R is the radius of the cylinder. In this case, the mass is 4.01 kg and the radius is 0.260 m, so the moment of inertia for the solid cylinder is (1/2)(4.01 kg)(0.260 m)².

3. Solid Sphere: The moment of inertia for a solid sphere rotating about its central axis is given by the formula I = (2/5)MR², where M is the mass and R is the radius of the sphere. In this case, the mass is 4.01 kg and the radius is 0.260 m, so the moment of inertia for the solid sphere is (2/5)(4.01 kg)(0.260 m)².

4. Thin Spherical Shell: The moment of inertia for a thin spherical shell rotating about its central axis is given by the formula I = (2/3)MR², where M is the mass and R is the radius of the shell. In this case, the mass is 4.01 kg and the radius is 0.260 m, so the moment of inertia for the thin spherical shell is (2/3)(4.01 kg)(0.260 m)².

Answer:

ΔL = 53.14*10⁻⁶ m

Explanation:

Given

E = 20.7*10¹⁰ N/m²

D = 2.5 mm = 2.5*10⁻³ m

L = 12 cm = 0.12 m

P = 450 N

ΔL = ?

We can use the formula

ΔL = P*L / (A*E)

where    A = π*D² / 4 = π*(2.5*10⁻³ m)² / 4

⇒   A = 4.908*10⁻⁶ m²

then

ΔL = (450 N)*(0.12 m) / (4.908*10⁻⁶ m²*20.7*10¹⁰ N/m²) = 53.14*10⁻⁶ m

Answer:

3.2 C

Explanation:

e = Charge of electron = [tex]1.6\times 10^{-19}\ C[/tex]

Number of synapses = [tex]10^{16}[/tex]

Signals transferred by each synapse 1000 calcium ions [tex]Ca^{2+}[/tex]

Each calcium ion carries 2 charges

Number of charges would be [tex]2\times 1000=2000[/tex]

Total charges would be

[tex]N=10^{16}\times 2000=2\times 10^{19}[/tex]

Charge is given by

[tex]Q=Ne\\\Rightarrow Q=2\times 10^{19}\times 1.6\times 10^{-19}\\\Rightarrow Q=3.2\ C[/tex]

The total electric charge transfer in coulombs during that short time interval is 3.2 C

Final answer:

In a fictional scenario where 10¹⁶ synapses simultaneously transmit signals using 1000 calcium ions each, the total electric charge transferred is 3.20 coulombs, which is significant but still less than the 5 coulombs typically involved in a lightning flash.

Explanation:

Children have about 1016 synapses that can transfer signals between neurons in the brain and between neurons and muscle cells. If these synapses simultaneously transmit a signal, sending 1000 calcium ions (Ca²⁺) across the membrane at each synaptic ending, and given that the charge of each Ca²⁺ is twice that of the electron charge (e = 1.60 × 10⁻¹⁹ C), we can calculate the total electric charge transfer in coulombs during that time interval.

The total number of calcium ions transferred is 1016 synapses × 1000 ions/synapse = 10¹⁹ ions. Since each Ca²⁺ carries twice the charge of an electron, the charge per ion is 2 × 1.60 × 10⁻¹⁹ C = 3.20 × 10⁻¹⁹ C. Therefore, the total charge transferred is 1019 ions × 3.20 × 10⁻¹⁹ C/ion = 3.20 coulombs.

Comparing this to a lightning flash, which involves about 5 coulombs of charge transfer, we can see that the total charge transfer in this hypothetical scenario is significant, yet smaller than that of a lightning flash.

Answer:

C = 3.77*10⁻¹⁰ F = 377 pF

Q = 1.13*10⁻⁵ C

Explanation:

Given

D = 8.0 cm = 0.08 m

d = 0.95 cm = 0.95*10⁻² m

k = 80.4  (dielectric constant of the milk)

V = 30000 V

C = ?

Q = ?

We can get the capacitance of the system applying the formula

C = k*ε₀*A / d

where

ε₀ = 8.854*10⁻¹² F/m

and   A = π*D²/4 = π*(0.08 m)²/4

⇒  A = 0.00502655 m²

then

C = (80.4)*(8.854*10⁻¹² F/m)*(0.00502655 m²) / (0.95*10⁻² m)

⇒  C = 3.77*10⁻¹⁰ F = 377 pF

Now, we use the following equation in order to obtain the charge on each plate when they are fully charged

Q = C*V

⇒  Q = (3.77*10⁻¹⁰ F)*(30000 V)

⇒  Q = 1.13*10⁻⁵ C

The capacitance of the system is calculated by applying the physics of parallel-plate capacitors, using characteristics of the plates and the milk as the dielectric constant. The charge on each plate when fully charged is then deduced from the calculated capacitance and the applied voltage.

The concept this question revolves around is the electrical mechanism in a parallel-plate capacitor. This system uses the property of the dielectric constant (the same as water for milk, in this case) of the substance between the plates.

The capacitance of such a system may be calculated as C = ε * (A/d), where ε denotes the permittivity of the substance (milk), A is the area of one of the plates, and d is the distance separating the plates. For a circular plate, the area can be computed as A = π * (D/2)^2 where D is the diameter of the plate.

Here, ε = 8.854*10^-12 F/m (for water), D = 8 cm = 0.08 m (converted into meters for unit consistency), and d = 0.95 cm = 0.0095 m. Substituting these values, we compute the capacitance C which should then be used to calculate the charge on each plate when fully charged using the formula, Q = C * V, where V is the voltage applied.

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Answer:

a. gender intensification

Explanation:

This theory states that in the adolescence both girls and boys are pressured to follow gender roles established culturally.

Answer:

0.7274 m

Explanation:

X denotes the distance from the reference point

M denotes the mass of the point

The center of mass of a system is given by

[tex]X_{CM}=\sum_{n=1}^n\frac{X_n\times M_n}{M_n}[/tex]

Taking the position of Juliet as the reference point

[tex]X_{CM}=\frac{59\times 0+85\times 2.7+75\times 1.35}{59+85+75}\\\Rightarrow X_{CM}=1.51027\ m[/tex]

After the boat has moved the distance between the center of mass of the boat and the shore remains the same. The change is observed relative to the rear of the boat

[tex]X_{CM}=\frac{75\times 1.35+(85+59)\times 2.7}{59+85+75}\\\Rightarrow X_{CM}=2.23767\ m[/tex]

The displacement of the boat towards the shore is

[tex]2.23767-1.51027=0.7274\ m[/tex]

By applying the conservation of momentum for a system with no external forces, the distance the boat moves when Juliet goes to the rear to kiss Romeo is 2.124 meters toward the shore.

The question involves the concept of conservation of momentum, particularly in systems with no external forces. Here, we consider a scenario where Juliet transitions from the front to the rear of the boat, causing the boat to move toward shore. To solve for the movement of the boat toward the shore, we need to realize that the total momentum of the system (Juliet, Romeo, and the boat) before and after Juliet's movement must remain constant, as there is no external force in the horizontal direction.

Initially, both Juliet and the boat are at rest, so the total initial momentum is zero. When Juliet, having mass 59.0 kg, moves a distance of 2.70 m towards Romeo, the boat will move in the opposite direction to conserve momentum.

To find the distance the boat moves, we use the conservation of momentum equation: (mass of Juliet) x (distance Juliet moves) = (mass of boat) x (distance boat moves). Rearranging gives us the distance the boat moves: distance boat moves = (mass of Juliet x distance Juliet moves) / mass of boat.

By substituting the given values, we get:

distance boat moves = (59.0 kg x 2.70 m) / 75.0 kg
distance boat moves = 2.124 m

Therefore, the boat moves 2.124 meters toward the shore when Juliet moves to the rear to kiss Romeo.

Answer:

[tex]T=172.37\ K[/tex]

[tex]P_s=11.1095\ Pa[/tex]

Explanation:

Triple point is that temperature and pressure for a substance at which the chemical substance coexists in liquid, solid and gaseous state with mutual equilibrium.

Given expressions of vapor pressure:

[tex]ln (P_s)=24.320 -\frac{3777  K}{T}[/tex] ........................................(1)

[tex]ln (P_l)=17.892 -\frac{2669 K}{T}[/tex] ..........................................(2)

Equating the vapor pressure of two phases of chlorine:

[tex]24.320 -\frac{3777  K}{T}=17.892 -\frac{2669 K}{T}[/tex]

[tex]T=172.37\ K[/tex]

The vapor pressure at this temperature:

[tex]ln (P_s)=24.320 -\frac{3777 }{172.37}[/tex]

[tex]P_s=11.1095\ Pa[/tex]

To find the triple point of chlorine, we set the vapor pressure equations of solid and liquid chlorine equal and solve for temperature, then use either equation to find the vapor pressure. However, numerical values for the vapor pressure equations are required to compute the specific temperature and pressure. The Clausius-Clapeyron equation can also be relevant in such calculations.

The triple point of chlorine is determined by finding the temperature and pressure at which the vapor pressures of solid and liquid chlorine are equal. Given the vapor pressure equations for solid and liquid chlorine, both can be set equal to each other and solved for temperature (T), as both will have the same pressure at the triple point.

Unfortunately, without the numerical expressions for ln(Ps) and ln(Pl), it is impossible to provide a numerical answer. Typically, this would involve algebraic manipulation to find T, and then either expression can be used to solve for the vapor pressure at the triple point.

For example, the Clausius-Clapeyron equation is used to relate the temperatures and pressures for phase changes, such as moving from solid to gas (sublimation) at the triple point. However, more information is necessary to calculate the temperature and pressure explicitly.

Answer:20.03 m/s

Explanation:

Given

[tex]L_r=1:7[/tex]

velocity of Prototype [tex]v_p=53 m/s[/tex]

Taking Froude number same for both flow as it is a dimensionless number for different flow regimes in open Flow

[tex](\frac{v_m}{\sqrt{L_mg}})=(\frac{v_p}{\sqrt{L_pg}})[/tex]

[tex]v_m=v_p\times \sqrt{\frac{L_m}{L_p}}[/tex]

[tex]v_m=53\times \frac{1}{\sqrt{7}}[/tex]

[tex]v_m=20.03 m/s[/tex]

Answer:

Explanation:

The inductance of a long solenoid can be approximated by:

[tex]L=\mu \frac{N^2A}{L}[/tex]

Where:

[tex]N=Number\hspace{3}of\hspace{3}turns\\A=Cross-sectional\hspace{3}area\\L=Length\hspace{3}of\hspace{3}the\hspace{3}coil\\\mu=Magnetic\hspace{3}permeability[/tex]

Therefore, according to this, we can conclude that  the inductance of a solenoid depends on the number of turns per unit length and the area of each turn.

Answer:[tex]k=10.091\times 10^{-3} N/m[/tex]

Explanation:

Given

mass of spider [tex]m=2.3 gm[/tex]

Largest amplitude can be obtained by Tapping after every 3 second

i.e. Time period of oscillation is [tex]T= 3 s[/tex]

considering spider to execute Simple harmonic motion

time of oscillation is given by

[tex]T=2\pi\sqrt{\frac{m}{k}}[/tex]

substituting values

[tex]3=2\pi \sqrt{\frac{2.3\times 10^{-3}}{k}}[/tex]

[tex]\frac{3}{2\pi }=\sqrt{\frac{2.3\times 10^{-3}}{k}}[/tex]

[tex]0.477=\sqrt{\frac{2.3\times 10^{-3}}{k}}[/tex]

[tex](0.477)^2=\frac{2.3\times 10^{-3}}{k}[/tex]

[tex]\frac{2.3\times 10^{-3}}{k}=0.228[/tex]

[tex]k=10.091\times 10^{-3} N/m[/tex]

Answer:

Positive.

Explanation:

As a consequence of the photoelectric effect, electrons that will get hit by sufficiently energetic photons will abandon the metal surfaces exposed to bright sunlight. This decreases the negative charge of the surface, thus causing it to develop a positive net charge.

Answer:

The net torque about the pivot is and the answer is 'c'

c. [tex]T_{net}=8.58[/tex]

Explanation:

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

The torque is the force apply in a distance so it is the moment so depends on the way to be put it the signs so:

[tex]T_1=F_1*d_1[/tex]

[tex]T_1=7.8N*1.6m=12.48N*m[/tex]

[tex]T_2=F_2*d_2[/tex]

[tex]T_2=2.60N**cos(30)*3.0m[/tex]

[tex]T_2= - 3.9 N*m[/tex]

Now to find the net Torque is the summation of both torques

[tex]T_{net}=T_1+T_2[/tex]

[tex]T_{net}=12.48N-3.9N=8.58N[/tex]

The net torque about the pivot is calculated by finding the individual torques caused by each force and then subtracting the clockwise torque from the counterclockwise torque, resulting in a positive net torque of 8.58 N·m. So the correct option is c.

The student is asking to calculate the net torque about the pivot on a rod being acted upon by two forces causing opposing torques. To find the net torque, we need to calculate each torque and then subtract the clockwise (cw) torque from the counterclockwise (ccw) torque. Torque (τ) can be calculated using the formula τ = rFsin(θ), where r is the distance from the pivot, F is the force applied, and θ is the angle at which the force is applied relative to the rod.

Step-by-step calculation:

Since the counterclockwise (ccw) torque is the positive direction, the net torque of 8.58 N·m is positive, giving us option c) 8.58 N·m as the correct answer.

Answer:

a) x (t) = 0.3187 cos (7.416 t + 1.008) ,  b)  v = -2,363 sin (7,416 t + 1,008)

c)  a = - 17.52 cos (7.416t + 1.008)

Explanation:

The spring mass system creates a harmonic oscillator that is described by the equation

    x = Acos (wt + φ)

Where is the amplitude, w the angular velocity and fi the phase

a) Let's reduce the SI system

    x = 17.0 cm (1 m / 100 cm) = 0.170 m

The angular velocity is given by

      w = √ (k / m)

      w = √ 11 / 0.200

      w = 7.416 rad / s

Let's look for the terms of the equation with the data for time zero (t = 0 s)

      0.170 = A cos  φ

Body speed can be obtained by derivatives

      v = dx / dt

      v = -A w sin (wt + φ)

     2.0 = -A 7.416 sin φ

Let's write the two equations

     0.170 = A cos φ

     2.0 / 7.416 = -A sin φ

Let's divide those equations

    tan φ= 2.0 / (7.416 0.170)

     φ= tan⁻¹ (1,586)

     φ= 1.008 rad

We calculate A

   A = 0.170 / cos φ

   A = 0.170 / cos 1.008

   A = 0.3187 m

With these values ​​we write the equation of motion

    x (t) = 0.3187 cos (7.416 t + 1.008)

b) the speed can be found by derivatives

      v = dx / dt

      v = - 0.3187 7.416 sin (7.416 t +1.008)

      v = -2,363 sin (7,416 t + 1,008)

c) the acceleration we look for conserved

    a = dv / dt

    a = -2,363 7,416 cos (7,416 t + 1,008)

    a = - 17.52 cos (7.416t + 1.008)

To solve the problem it is necessary to apply the concepts related to Helmholtz free energy. By definition in a thermodynamic system the Helmholtz energy is defined as

[tex]\Delta F = \Delta U - T\Delta S[/tex]

Where,

[tex]\Delta U[/tex] is the internal energy equivalent to

[tex]\Delta U = C \Delta T[/tex]

And [tex]\Delta S[/tex] means the change in entropy represented as

[tex]\Delta S = C ln \frac{T_2}{T_1}[/tex]

Note: C means heat capacity.

Replacing in the general equation we have to

[tex]\Delta F = C \Delta T - T C ln \frac{T_2}{T_1}[/tex]

The work done of a thermodynamic system is related by Helmholtz free energy as,

[tex]W = - \Delta F[/tex]

[tex]W = -(C \Delta T - T C ln \frac{T_2}{T_1})[/tex]

[tex]W = T C ln \frac{\T_2}{T_1}-C \Delta T[/tex]

Replacing with our values we have,

[tex]W = (293.15)(1.2)ln(\frac{293.15}{273.15})-(1.2)(20)[/tex]

[tex]W = 0.858 J[/tex]

Therefore the maximum work that can be accomplished is 0.858J

The maximum work that can be accomplished by the stone is 24 J.

To find the maximum work that can be accomplished by the stone as the cold side of a reversible engine, we can use the formula for the maximum work of a Carnot engine:

Wmax = Qh - Qc

where Qh is the heat transferred from the hot reservoir and Qc is the heat transferred to the cold reservoir.

Since the stone is the cold side, Qc is the negative of the heat capacity times the temperature difference:

Qc = -C(Tin - Tcold)

Substituting the given values, we have:

Qc = -(1.2 J/K)(293.15 K - 273.15 K) = -24 J

Since Qh is the negative of Qc, we have:

Qh = -Qc = -(-24 J) = 24 J

Therefore, the maximum work that can be accomplished by the stone is:

Wmax = 24 J

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A speedometer often known as aspeed meter do act as a boundary or gauge that helps us to take note, measures and displays the speed of a moving automobile.

An increase in the radius of the tires does not increase the speed measured by a speedometer.

An increase in the size of the tires will cause the car to move faster than it would with smaller tires. This will leaf tothe speed of the car will be much more than what the speedometer is reading.

Conclusively we can say that option b is the best option that explains what the statement means

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The torque exerted about the center of the disk is 1.76 Nm.

To determine the torque exerted about the center of the disk, we need to calculate the perpendicular component of the force applied by the string. Since the force is applied tangentially, it can be resolved into two components: the perpendicular component and the parallel component. The perpendicular component creates the torque.

The perpendicular component of the force is equal to the tension in the string multiplied by the sine of the angle between the force and the radius. In this case, the angle is 90 degrees, so sin(90) = 1. Therefore, the torque is equal to the tension in the string multiplied by the radius of the disk.

Given that the force applied by the string is 16 N and the radius of the disk is 11 cm (0.11 m), the torque exerted about the center of the disk is 16 N * 0.11 m = 1.76 Nm.

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The torque exerted on the disk is calculated using the formula Torque = Force x Distance, where the distance is the radius of the disk. The torque in this situation is 1.76 N.m.

In your question, we're being asked to find the torque exerted on a disk with radius R that's being pulled along a frictionless surface by a force F. The torque exerted on an object can be calculated using the formula Torque = Force x Distance, where distance refers to the perpendicular distance from the axis of rotation to the line of action of the force. In this case, the force is being applied at the edge of the disk, and the radius of the disk serves as the lever arm distance. Therefore, the torque exerted about the center of the disk is Torque = F * R = 16 N * 0.11 m = 1.76 N.m. Please note that the radius was converted from cm to m in order to keep the units consistent.

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Answer:

2d

Explanation:

For any instance equivalent force acting on the body is

[tex]mg-kd= m\frac{d}{dt}\frac{dx}{dt}[/tex]

Where

m is the mass of the object

k is the force constant of the spring

d is the extension in the spring

and

d/dt(dx/dt)=  is the acceleration of the object

solving the above equation we get

[tex]x= Asin\omega t +d[/tex]

where

[tex]\omega= \sqrt{\frac{k}{m} } = \frac{2\pi}{T}[/tex]

A is the amplitude of oscillation from the mean position.

k= spring constant , T= time period

Here  we are assuming  that at t=T/4

x= 0   since, no extension in the spring

then

A=- d

Hence

x=- d sin wt + d

now, x is maximum when sin wt=- 1

Therefore,

x(maximum)=2d

Final answer:

When an object falls onto a spring, it will stretch the spring further than if it were slowly lowered due to kinetic energy turning into additional elastic potential energy. The maximum stretch can be calculated using energy conservation, resulting in a stretch that is √(2mgd/k) where d is the equilibrium stretch, m is the mass, g is gravity, and k is the spring constant.

Explanation:

Maximum Stretch of a Spring with a Falling Object

When an object of mass m is attached to a vertical spring and slowly lowered to its equilibrium position, the spring stretches by a distance d, producing potential energy in the spring equal to k·d²/2. Meanwhile, the work done by gravity equals mg·d. If instead the object is allowed to fall and attaches to the spring, the spring will stretch further due to the kinetic energy acquired during the fall, turning into additional elastic potential energy at maximum stretch.

If we assume no energy losses due to non-conservative forces, the energy conservation equation just before the object attaches to the spring would be:

Kinetic energy + gravitational potential energy = elastic potential energy at maximum extension.

Since the object starts from rest at a height d above the equilibrium position:

1/2·mv² + mgd = 1/2·k·x² (with x being the total distance the spring stretches).

At the point of maximum stretch, all kinetic energy has been converted into elastic potential energy, and the object is momentarily at rest, so:

mgd = 1/2·k·x²

In the special case where there are no other forms of energy conversion (like heat due to air resistance), the spring will stretch maximum distance x satisfying:

x = √(2·mg·d / k)

Using the initial condition that the spring stretches by d when the object is slowly lowered, we can deduce that the object in free fall will stretch the spring more than d due to extra energy from its fall. The exact factor would depend on the stiffness of the spring (expressed by k) and the mass of the object (m).

Answer:

b. v = 0, a = 9.8 m/s² down.

Explanation:

Hi there!

The acceleration of gravity is always directed to the ground (down) and, near the surface of the earth, has a constant value of 9.8 m/s². Since the answer "b" is the only option with an acceleration of 9.8 m/s² directed downwards, that would solve the exercise. But why is the velocity zero at the highest point?

Let´s take a look at the height function:

h(t) = h0 + v0 · t + 1/2 g · t²

Where

h0 = initial height

v0 = initial velocity

t = time

g = acceleration due to gravity

Notice that the function is a negative parabola if we consider downward as negative (in that case "g" would be negative). Then, the function has a maximum (the highest point) at the vertex of the parabola. At the maximum point, the slope of the tangent line to the function is zero, because the tangent line is horizontal at a maximum point. The slope of the tangent line to the function is the rate of change of height with respect to time, i.e, the velocity. Then, the velocity is zero at the maximum height.

Another way to see it (without calculus):

When the ball is going up, the velocity vector points up and the velocity is positive. After reaching the maximum height, the velocity vector points down and is negative (the ball starts to fall). At the maximum height, the velocity vector changed its direction from positive to negative, then at that point, the velocity vector has to be zero.

Answer:

[tex]E_{rms} = 2.27 V/m[/tex]

Explanation:

Power of microwave radiation = 13 kW = 13 x 10³ W

Diameter = 1000 m

Radius = R = 1000/2 = 500 m

distance, r = 500 Km

               r = 500 x 10³ m

Electric strength of beam of light is given as

   [tex]S = \dfrac{P}{A} = c\epsilon_0 E_{rms}^2[/tex]

    Now,

   [tex]E_{rms} =\sqrt{\dfrac{P}{Ac\epsilon_0}}[/tex]

 c is speed of light

 ε₀ is permittivity of free space  

 A is the area of circle  = π r² = π x (500 x 10³)² = 7.853 x 10¹¹ m²

    [tex]E_{rms} =\sqrt{\dfrac{13\times 10^3}{7.853 \times 10^{11}\times 3 \times 10^8 \times 8.85\times 10^{-12}}}[/tex]

    [tex]E_{rms} =\sqrt{\dfrac{13\times 10^3}{7.853 \times 10^{11}\times 3 \times 10^8 \times 8.85\times 10^{-12}}}[/tex]

    [tex]E_{rms} = 2.27 V/m[/tex]

Answer

given,

mass of the baseball = 0.145 Kg

Assuming the horizontal velocity of ball = V x = 50 m/s

ball left at an angle of = 30°

At the speed of 65 m/s

time of contact  = 1.75 ms

velocity of time along horizontal direction

v_{horizontal} = -65 cos 30° - 50

                        = -106.29 m/s

Impulse = force x time

impulse is equal to change in momentum

now,

force x time = m v

[tex]F = \dfrac{mv}{t}[/tex]

[tex]F = \dfrac{0.145 \times (-106.29)}{1.75 \times 10^{-3}}[/tex]

F_{horizontal} = - 8.806 kN

now velocity in vertical component

v_{vertical} = 65 sin 30°

                  = 32.5 m/s

[tex]F = \dfrac{mv}{t}[/tex]

[tex]F = \dfrac{0.145 \times (32.5)}{1.75 \times 10^{-3}}[/tex]

F_{vertical} = 2.692 kN

(a) The horizontal component of the average force on the ball is 7,633.63 N.

(b) The vertical component of the average force on the ball is 2,929 N.

The given parameters;

The horizontal component of the ball's acceleration is calculated as follows;

[tex]-v_f_x = v_0_x - a_xt\\\\a_xt = v_0_x + v_f_x\\\\a_x = \frac{v_0_x + v_f_x}{t} \\\\a_x = \frac{50 \ + \ 55cos(40)}{0.00175} \\\\a_x = 52,645.7 \ m/s^2[/tex]

The horizontal component of the average force on the ball is calculated as follows;

[tex]F_x = ma_x\\\\F_x = 0.145 \times 52,645.7 \\\\F_x = 7,633.63 \ N[/tex]

The vertical component of the ball's acceleration is calculated as follows;

[tex]v_f_y = v_0y + a_yt\\\\v_f_y = 0+ a_yt\\\\a_y = \frac{v_f_y}{t} \\\\a_y = \frac{55 \times sin(40)}{0.00175} \\\\a_y = 20,200 \ m/s^2[/tex]

The vertical component of the average force on the ball is calculated as follows;

[tex]F_y = ma_y\\\\F_y = 0.145 \times 20,200\\\\F_y = 2,929 \ N[/tex]

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

A bat strikes a 0.145-kg baseball. Just before impact, the ball is traveling horizontally to the right at 50.0 m/s , and it leaves the bat traveling to the left at an angle of 40 ∘ above horizontal with a speed of 55.0 m/s . The ball and bat are in contact for 1.75 ms .

find the horizontal and vertical components of the average force on the ball.

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To solve this problem it is necessary to apply the concepts related to gravitational potential energy.

The change in gravitational potential energy is given by,

[tex]\Delta PE = PE_f - PE_i[/tex]

Where,

[tex]PE = \frac{GMm}{R}[/tex]

Here,

G = Gravitational Universal Constant

M = Mass of Earth

m = Mass of Object

R = Radius

Replacing we have that

[tex]\Delta PE = \frac{GMm}{R+h} -\frac{GMm}{R}[/tex]

Note that h is the height for this object. Then replacing with our values we have,

[tex]\Delta PE = \frac{GMm}{R+h} -\frac{GMm}{R}[/tex]

[tex]\Delta PE = GMm(\frac{1}{R} -\frac{1}{R+h})[/tex]

[tex]\Delta PE = (6.65*10^{-11})(7.36*10^{22})(1170)(\frac{1}{1740*10^3} -\frac{1}{211*10^3+1740*10^3})[/tex]

[tex]\Delta PE = 57264.48*10^{11}(5.1255*10^{-7}-5.747*10^{-7})[/tex]

[tex]\Delta PE = 3.56*10^8J[/tex]

Therefore the gravitational potential  is [tex]3.56*10^8J[/tex]

The angular acceleration of the two flywheels will be different due to their differing moments of inertia, which depend on both the mass and its distribution relative to the rotational axis. The removed hexagonal sections on flywheel A alters its moment of inertia.

The answer to your question is: The angular acceleration of the two flywheels is different but it is impossible to tell which is greater.

The reason for this is tied to the concept known as moment of inertia, an object's resistance to changes in its state of rotation. The moment of inertia depends not only on the mass of an object, but also on its distribution of mass relative to the axis around which it rotates. The hexagonal sections removed from flywheel A affect its distribution of mass, potentially lowering its moment of inertia.

Angular acceleration is the rate of change of angular velocity over time, and is given by the equation: torque = moment of inertia x angular acceleration. The torque on both flywheels is the same, since the same force is exerted on both through the identical masses falling from height h. Therefore, if the moments of inertia of the two flywheels are different, then their angular accelerations must also be different as they both satisfy the above equation.

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The angular acceleration of the two flywheels is different but it is impossible to tell which is greater.

The angular acceleration of the two flywheels is different but it is impossible to tell which is greater. The angular acceleration of a flywheel depends on both its mass and its moment of inertia, which takes into account the distribution of mass relative to the axis of rotation.

In this case, the larger mass of flywheel A would tend to result in a smaller angular acceleration, but the removal of material in hexagonal sections could change the moment of inertia and potentially increase the angular acceleration. Without specific information about the moment of inertia for each flywheel, it is impossible to determine which one would have a greater angular acceleration.

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Answer:[tex]\frac{F}{2}[/tex]

Explanation:

Given

weight of Object is W

Buoyant Force [tex]F_b=F[/tex]

let the density of First Liquid is  [tex]\rho [/tex]

volume of object [tex]=\frac{W}{\rho _0g}[/tex]

where [tex]\rho _0[/tex]=object density

thus buoyant Force in first Liquid is

[tex]F=\rho \times \frac{W}{\rho _0g}\times g=\frac{W\rho }{\rho _0}[/tex]

For Second Liquid

[tex]F'=\frac{\rho }{2}\times \frac{W}{\rho _0g}\times g=\frac{W\rho }{2\rho _0}[/tex]

[tex]F'=\frac{F}{2}[/tex]

The speed of the center of mass just before it hits the horizontal surface can be found using the principle of conservation of energy.

To find the speed of the center of mass just before it hits the horizontal surface, we can use the principle of conservation of energy. When the rod falls freely, it gains gravitational potential energy which is converted into kinetic energy. At the lowest point, where the center of mass hits the horizontal surface, all the gravitational potential energy is converted into kinetic energy. Therefore, we can equate the gravitational potential energy at the top to the kinetic energy at the bottom:

mgh = (1/2)mv^2

Where m is the mass of the rod, g is the acceleration due to gravity, h is the height of the rod, and v is the speed of the center of mass. Solving for v:

v^2 = 2gh

v = sqrt(2gh)

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Answer:

a)Uo= 2 m/s

b)[tex]u_{avg}=1 \ m/s[/tex]

c)Q=7.54  x 10⁻⁴ m³/s

Explanation:

Given that

[tex]u(r)=2\left(1-\dfrac{r^2}{R^2}\right)[/tex]

Diameter ,D= 3.1 cm

Radius ,R= 1.55 cm

We know that in the pipe flow the general equation for laminar fully developed flow given as

[tex]u(r)=U_o\left(1-\dfrac{r^2}{R^2}\right)[/tex]

Uo=Maximum velocity

Therefore maximum velocity

Uo= 2 m/s

The average velocity

[tex]u_{avg}=\dfrac{U_o}{2}[/tex]

[tex]u_{avg}=\dfrac{2}{2}\ m/s[/tex]

[tex]u_{avg}=1 \ m/s[/tex]

The volume flow rate

[tex]Q=u_{avg}. A[/tex]

[tex]Q=\pi R^2\times u_{avg}\ m^3/s[/tex]

[tex]Q=\pi \times (1.55\times 10^{-2})^2\times 1\ m^3/s[/tex]

Q=0.000754 m³/s

Q=7.54  x 10⁻⁴ m³/s