A 2.0-kg block travels around a 0.40-m radius circle with an angular speed of 16 rad/s. The circle is parallel to the xy plane and is centered on the z axis, 0.60 m from the origin. What is the magnitude of the component in the xy plane of the angular momentum around the origin?

Answer:

Explanation:

a ) The direction of angular velocity vector of second hand will be along the line going into the plane of dial perpendicular to it.

b )  If the angular acceleration of a rigid body is zero, the angular velocity will remain constant.

c )  If another planet the same size as Earth were put into orbit around the Sun along with Earth  the moment of inertia of the system will increase because the mass of the system increases. Moment of inertia depends upon mass and its distribution around the axis.

d ) Increasing the number of blades on a propeller increases the moment of inertia , because both mass and mass distribution around axis of rotation increases.

e ) It is not possible  that  a body has the same moment of inertia for all possible axes because a body can not remain symmetrical about all axes possible. Sphere has same moment of inertia about all axes passing through its centre.

f ) To maximize the moment of inertia of a flywheel while minimizing its weight, the  shape and distribution of mass should be such that maximum mass of the body may be situated at far end of the body from axis of rotation . So flywheel must have thick outer boundaries and this should be

attached with axis with the help of thin rods .

g ) When the body is rotating at the same place , its translational kinetic   energy is zero but its rotational energy can be increased

at the same place.

To develop the problem it is necessary to apply the concepts related to Hooke's Law. For which it is understood that

[tex]F = kx[/tex]

Where,

k = Spring constant

x = Displacement of Spring

By the theorem of work we understand that it is the force realized when there is the path of an object therefore

[tex]dW =Fdx[/tex]

Our value of F is

[tex]dW = (kx)dx[/tex]

Integrating

[tex]W = k\int\limit_0^{x_1} xdx[/tex]

Therefore the expresion is

[tex]W = \frac{kx_1^2}{2}[/tex]

Answer:

Compression in the spring, x = 0.20 m

Explanation:

Given that,

Spring constant of the spring, k = 490 N/m

Mass of the block, m = 5 kg

To find,

Compression in the spring.

Solution,

Since the block is suddenly dropped on the spring gravitational potential energy of block converts into elastic potential energy of spring. Its expression is given by :

[tex]mgx=\dfrac{1}{2}kx^2[/tex]

Where

x is the compression in the spring

[tex]x=\dfrac{2mg}{k}[/tex]

[tex]x=\dfrac{2\times 5\times 9.8}{490}[/tex]

x = 0.20 m

So, the compression in the spring due to block is 0.20 meters.

The vertical spring with spring constant of 490N/m will compress at a distance of 0.2m.

According to this question, the following information were given:

To calculate the compression in the spring, we deduce that the gravitational potential energy of the spring converts into elastic potential energy. Its expression is given by:

mgx = ½kx²

Where;

x = 2mg/k

x = 2 × 5 × 9.8/490

x = 98/490

x = 0.2m

Therefore, the spring will compress at a distance of 0.2m.

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Answer:

C. less than 950 N.

Explanation:

Given that

Force in north direction F₁ = 500 N

Force in the northwest F₂ = 450 N

Lets take resultant force R

The angle between force = θ

θ = 45°

The resultant force R

[tex]R=\sqrt{F_1^2+F_2^2+2F_1F_2cos\theta}[/tex]

[tex]R=\sqrt{500^2+450^2+2\times 450\times 500\times cos\theta}[/tex]

R= 877.89 N

Therefore resultant force is less than 950 N.

C. less than 950 N

Note- When these two force will act in the same direction then the resultant force will be 950 N.

The total force on the stump is less than the sum of the individual forces because the forces are vectors and not aligned in the same direction. The correct answer is (c) less than 950 N.

When you pull on a stump with two ropes at different angles, the total force is not simply the sum of the individual forces because the forces are vectors. To find the total force, you must consider both the magnitude and direction of each force. In this case, you pull with a force of 500 N to the north and your friend pulls with 450 N to the northwest. Since these forces are not in the same direction, you need to use vector addition to find the resultant force. Without calculating the exact value, we can already state that the resultant force will be less than 950 N because part of the forces cancel each other out due to the angle at which they are applied. Therefore, the correct answer is (c) less than 950 N.

Answer: 0.999959 c

Explanation:  

According to the special relativity theory, time is measured differently by two observers moving one relative another, according to the Lorentz Transform Equation, as follows:

t = t’ / t=t^'/√(1-(v)2/c2 )

where t= time for the moving observer (relative to the spacecraft, fixed on Earth) = 110 years.

t’= time for the observer at rest respect from spacecraft = 1 year

v= spacecraft constant speed

c= speed of light

Solving for v, with a six decimals precision as a multiple of c, we get:

v = 0.999959 c

Answer:

Explanation:

Atmospheric pressure = 7 x 10⁴ Pa

force on  a disk-shaped region 2.00 m in radius at the surface of the ocean due to atmosphere  = pressure x area

= 7 x 10⁴ x 3.14 x 2 x 2

= 87.92 x 10⁴ N

b )

weight, on this exoplanet, of a 10.0 m deep cylindrical column of methane with radius 2.00 m

Pressure x area

height x density x acceleration of gravity x π r²

= 10 x 415 x 6.2 x 3.14 x 2 x 2

=323168.8 N

c ) Pressure at a depth of 10 m

atmospheric pressure + pressure due to liquid column

= 7 x 10⁴ + 10 x 415 x 6.2 ( hρg)

= 7 x 10⁴ + 10 x 415 x 6.2

(7 + 2.57 )x 10⁴ Pa

9.57 x 10⁴ Pa

The Force exerted by the atmosphere on a disk-shaped area is 8.8 x 10^5 N. The weight of a 10 m cylindrical column of methane is 1.31 x 10^7 N. The pressure at a depth of 10 m in the methane ocean is 1.22 x 10^5 Pa.

To answer this question, we need to apply concepts of fluid pressure and buoyancy.

(a) The force exerted by the atmosphere on a disk-shaped region is given by the atmospheric pressure multiplied by the area of the disk. This is calculated as Force = Pressure x Area. The Area of the disk is given by πr², where r is the radius. Therefore, the force = (7.00 x 10^4 Pa) x π(2 m)² = 8.8 x 10^5 N.

(b) The weight of the methane column can be found by using the formula for the weight of a liquid column which is Weight = density x gravity x height x Area. Plugging in the values from the question, it comes to (415 kg/m³) x (6.20 m/s²) x (10 m) x π(2 m)² = 1.31 x 10^7 N.

(c) The pressure at a depth in the methane ocean can be calculated using the equation P = Po + pgd, where Po is atmospheric pressure, p is the density of the fluid, g is the acceleration due to gravity and d is the depth. Substituting the given values, P = 7.00 x 10^4 Pa + (415 kg/m³)(6.20 m/s²)(10 m) = 1.22 x 10^5 Pa.

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Using conservation of momentum and the work-energy principle, the initial speed of the bullet can be calculated. The collision is inelastic because kinetic energy is not conserved. The impulse on the block is the change in momentum, calculated from the initial combined momentum to zero when it stops.

Initial Speed of the Bullet

To find the initial speed of the bullet, we use the principle of conservation of momentum for the collision and the work-energy principle for the block's movement after the collision.

For the conservation of momentum:

After the collision, the bullet and block move together, so the total final momentum is the combined mass times their velocity.

The normal force is equal to the weight of the block since the surface is horizontal.

Kinetic energy can then be equated to this work to find the velocity right after the collision.

Type of Collision

The initial momentum right after impact is the combined mass of the block and bullet times the velocity just after collision, which we obtained earlier.

Analyzing the result, we can discuss the magnitude of impulse and how it relates to the force of friction and the distance slid.

To solve this problem it is necessary to apply the concepts related to the kinematic equations of movement description.

From the definition we know that the speed of a body can be described as a function of gravity and height

[tex]V = \sqrt{2gh}[/tex]

[tex]V = \sqrt{2*9.8*0.15}[/tex]

[tex]V = 1.714m/s[/tex]

Then applying the kinematic equation of displacement, the height can be written as

[tex]H = \frac{1}{2}gt^2[/tex]

Re-arrange to find t,

[tex]t = \sqrt{2\frac{h}{g}}[/tex]

[tex]t = \sqrt{2\frac{0.5}{9.8}}[/tex]

[tex]t = 0.3194s[/tex]

Thus the calculation of the displacement would be subject to

[tex]x = vt[/tex]

[tex]x =1.714*0.3194[/tex]

[tex]x = 0.547m[/tex]

Therefore the required distance must be 0.547m

The maximum kinetic energy that can be stored in the flywheel is 27,909.78 J.

To calculate the maximum kinetic energy that can be stored in the flywheel, we need to find the moment of inertia. For a uniform solid disk, the moment of inertia is given by the formula I = 0.5 * m * r^2, where m is the mass of the disk and r is the radius. Plugging in the values, we get I = 0.5 * 67.0 kg * (1.22 m)^2 = 49.518 kg·m².

The maximum kinetic energy is equal to 0.5 * I * ω^2, where ω is the angular velocity. Since the radial acceleration of a point on the rim is given as 3510 m/s², we can calculate ω using the formula a = r * ω^2. Rearranging the formula, we get ω = √(a / r) = √(3510 m/s² / 1.22 m) = 33.24 rad/s.

Plugging in the values, the maximum kinetic energy is 0.5 * 49.518 kg·m² * (33.24 rad/s)^2 = 27,909.78 J.

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The maximum kinetic energy that can be stored in the flywheel is approximately 71,791 Joules.

To determine the maximum kinetic energy that can be stored in the flywheel, we need to use the concepts of rotational motion. The relevant formulas are:

Kinetic Energy of a rotating object: KE = 1/2 I  ω², where I is the moment of inertia and ω is the angular velocity.

Moment of Inertia for a solid disk: I = 1/2 m R², where m is the mass and R is the radius.

Relation between radial acceleration and angular velocity: a = ω² R.

We are given:

Radius (R): 1.22 m

Mass (m): 67.0 kg

Maximum radial acceleration (a): 3510 m/s²

First, solve for angular velocity (ω) using the radial acceleration formula:

ω² = a / R

⇒ ω² = 3510 m/s² / 1.22 m

⇒ ω² ≈ 2877.05 s⁻²

⇒ ω ≈ 53.61 rad/s

Next, calculate the moment of inertia (I) for the flywheel:

I = 1/2 m R² => I = 0.5 × 67.0 kg × (1.22 m)²

⇒ I ≈ 49.917 kgm²

Finally, calculate the maximum kinetic energy:

KE = 1/2 I ω² => KE = 1/2 × 49.917 kgm² × (53.61 rad/s)²

⇒ KE ≈ 71,791 Joules

Thus, the maximum kinetic energy that can be stored in the flywheel is approximately 71,791 Joules.

Final answer:

To find the height Sheila will ascend before stopping, we use energy conservation, calculating her initial kinetic energy and the work done against friction to solve for the final potential energy, which includes the height she reaches on the incline.

Explanation:

To determine the height Sheila will travel up the embankment before coming to rest, we need to apply the principles of energy conservation and include the work done against friction. Sheila's initial kinetic energy (KE) at the bottom of the hill is converted into gravitational potential energy (PE) and the work done against friction as she moves up the incline.

We can calculate the initial kinetic energy using the formula KE = 1/2 * m * v2, where m is her mass and v is her velocity. Then, we find the work done against friction, which is equal to the force of friction times the distance traveled (Wfriction = Ffriction * d). The force of friction is calculated as the coefficient of friction multiplied by the normal force, which, on an incline, is the component of the gravitational force perpendicular to the slope.

Using these concepts, we can set up the equation: KEinitial = PEfinal + Wfriction. Solving for the final potential energy gives us PEfinal = m * g * h, where h is the height she will reach. The height can be determined by rearranging this equation after calculating the work done against friction and knowing the initial kinetic energy.

It is important to note that since no values are given for distances or the length of the incline and we are assuming a constant coefficient of friction, we find the height as a function of distance she travels up the slope until she comes to rest.

Answer:

The maximum mass that can fall on the mattress without exceeding the maximum compression distance is 16.6 kg

Explanation:

Hi there!

Due to conservation of energy, the potential energy (PE) of the mass at a height of 3.32 m will be transformed into elastic potential energy (EPE) when it falls on the mattress:

PE = EPE

m · g · h = 1/2 k · x²

Where:

m = mass.

g = acceleration due to gravity.

h = height.

k = spring constant.

x = compression distance

The maximum compression distance is 0.1289 m, then, the maximum elastic potential energy will be the following:

EPE =1/2 k · x²

EPE = 1/2 · 65144 N/m · (0.1289 m)² = 541.2 J

Then, using the equation of gravitational potential energy:

PE = m · g · h =  541.2 J

m =  541.2 J/ g · h

m = 541.2 kg · m²/s² / (9.8 m/s² · 3.32 m)

m = 16.6 kg

The maximum mass that can fall on the mattress without exceeding the maximum compression distance is 16.6 kg.

This answer clarifies various aspects related to a transverse harmonic wave, such as amplitude, frequency, and tension in the rope. The wave is traveling in the -x direction. And, the period of oscillation will increase if the wavelength increases.

To answer such questions, we need to understand the equation of the wave given by y(x,t) = A sin (kx + ωt). Here, 'A' represents the amplitude of the wave, 'k' is the wave number, and 'ω' is the angular frequency. We get these values by comparing the given equation with the standard wave equation.

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Answer:

The speed of the rod's center of mass after the collision is 6 m/s.

Explanation:

Given that,

Mass of rod = 4 kg

Length l = 1.8 m

Moment of inertia [tex]I=\dfrac{ML^2}{12}[/tex]

Mass of puck = 0.4 kg

Initial speed= 20 m/s

Distance = 0.3 m

Final speed = 10 m/s

(a). We need to calculate the speed v of the rod's center of mass after the collision

As there is no external force acting on the system so, linear and angular momentum of the system will be conserved.

Using conservation of momentum

[tex]m_{i}v_{i}=m_{f}v_{f}+Mv[/tex]

Put the value into the formula

[tex]0.4\times20=-0.4\times10+2v[/tex]

[tex]v=\dfrac{8+4}{2}[/tex]

[tex]v=6\ m/s[/tex]

Hence, The speed of the rod's center of mass after the collision is 6 m/s.

To determine if the ball will clear the fence, calculate the range and maximum height of the ball's trajectory using given initial velocity and angle. Compare the calculated range with the distance to the fence.

To determine whether the ball will clear the fence, we need to calculate the range and maximum height of the ball's trajectory. Using the given initial velocity of the ball (which is equal to the linear velocity of the bat), we can decompose it into horizontal and vertical components. The horizontal component remains constant throughout the flight, while the vertical component is affected by gravity. We can use the equations of motion to find the range and maximum height.

First, let's calculate the horizontal distance (range) the ball will travel. We can use the formula: range = (initial horizontal velocity) * (time of flight). Since the initial velocity and angle are given, we can calculate the initial horizontal velocity using trigonometry:

Next, we need to find the time of flight. Since the vertical displacement is zero at the peak of the trajectory, we can use the equation: time of flight = 2 * (initial vertical velocity) / (acceleration due to gravity). From the given height and angle, we can calculate the initial vertical velocity using trigonometry:

Now, we can substitute the calculated values into the formula for range and solve for the time of flight:

Finally, we can compare the calculated range with the distance to the fence. If the range is greater than the distance to the fence, the ball will clear the fence.

Answer:

a) L₂ = 0.676 m

b) σ₁ = 2.28*10⁸ N/m²

σ₂ = 9.62*10⁸ N/m²

c) ε₁ = 0.00253678

ε₂ = 0.00457875

Explanation:

Given info

L₁ = 1.22 m

A₁ = 2.19 cm² = 2.19*10⁻⁴ m²

L₂ = ?

A₂ = 0.52 cm² = 0.52*10⁻⁴ m²

P = 5.00*10⁴ N

E₁ = 9*10¹⁰ N/m²

E₂ = 2.1*10¹¹ N/m²

In order to get the length L of the nickel rod if the elongations of the two rods are equal, we can say that

ΔL₁ = ΔL₂   ⇒  P*L₁/(A₁*E₁) = P*L₂/(A₂*E₂)

⇒  L₂ = A₂*E₂*L₁ / (A₁*E₁)

⇒  L₂ = (0.52*10⁻⁴ m²)*(2.1*10¹¹ N/m²)*(1.22 m) / (2.19*10⁻⁴ m²*9*10¹⁰ N/m²)

⇒  L₂ = 0.676 m

The stress in the brass rod is obtained as follows

σ₁ = P/A₁ ⇒ σ = 5.00*10⁴ N / 2.19*10⁻⁴ m² = 2.28*10⁸ N/m²

The stress in the niquel rod is obtained as follows

σ₂ = P/A₂ ⇒ σ = 5.00*10⁴ N / 0.52*10⁻⁴ m² = 9.62*10⁸ N/m²

The strain in the brass rod is obtained as follows

σ₁ = E₁*ε₁    ⇒   ε₁ = σ₁ / E₁

⇒   ε₁ = 2.28*10⁸ N/m² / 9*10¹⁰ N/m² = 0.00253678

The strain in the niquel rod is obtained as follows

σ₂ = E₂*ε₂    ⇒   ε₂ = σ₂ / E₂

⇒   ε₂ = 9.62*10⁸ N/m² / 2.1*10¹¹ N/m² = 0.00457875

Answer:

S= 1.40x10⁻⁵mol/L

Explanation:

The Henry's Law is given by the next expression:

[tex] S = k_{H} \cdot p [/tex] (1)

where S: is the solubility or concentration of Ar in water, [tex]k_{H}[/tex]: is Henry's law constant and p: is the pressure of the Ar

Since the argon is 0.93%, we need to multiply the equation (1) by this percent:

[tex] S = 1.5 \cdot 10^{-3} \frac{mol}{L\cdot atm} \cdot 1.0atm \cdot \frac{0.93}{100} = 1.40 \cdot 10^{-5} \frac{mol}{L} [/tex]

Therefore, the argon solubility in water is 1.40x10⁻⁵mol/L.

Have a nice day!          

To solve this problem we must rely on the concepts related to wavelength in terms of the speed of light and frequency.

Mathematically one of the ways to express the wavelength is,

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

Where,

c = Speed of light [tex](3*10^8m/s)[/tex]

f = Frequency

The value of the frequency given is

f = 45Hz

Therefore replacing we can find it,

[tex]\lambda = \frac{3*10^8}{45Hz}[/tex]

[tex]\lambda = 6.6667*10^6m[/tex]

Hence the wavelength of the very low frequency electromagnetic wave is [tex]6.6667*10^6m[/tex]

Final answer:

The wavelength of this very-low-frequency electromagnetic wave is approximately 6.67 x 10^6 meters.

Explanation:

The wavelength (λ) of an electromagnetic wave can be calculated using the formula:

λ = c/f

Where c is the speed of light, approximately 3 x 10^8 m/s, and f is the frequency of the wave. In this case, the frequency is 45 Hz. Substituting the values into the formula, we get:

λ = 3 x 10^8 m/s / 45 Hz = 6.67 x 10^6 m

Therefore, the wavelength of this very-low-frequency electromagnetic wave is approximately 6.67 x 10^6 meters.

Answer:

[tex]v_1=-2.616\ m/s[/tex]

Explanation:

Given that,

Mass of ball 1, [tex]m_1=0.25\ kg[/tex]

Initial speed of ball 1, [tex]u_1=5\ m/s[/tex]

Mass of ball 2, [tex]m_2=0.8\ kg[/tex]

Initial speed of ball 2, [tex]u_2=0[/tex] (at rest)

After the collision,

Final speed of ball 2, [tex]v_2=2.38\ m/s[/tex]

Let [tex]v_2[/tex] is the final speed of ball 1.

Initial momentum of the system is :

[tex]p_i=m_1u_1+m_2u_2[/tex]

[tex]p_i=0.25\times 5+0[/tex]

[tex]p_i=1.25\ m/s[/tex]

Final momentum of the system is :

[tex]p_f=m_1v_1+m_2v_2[/tex]

[tex]p_f=0.25\times v_1+0.8\times 2.38[/tex]

[tex]p_f=0.25 v_1+1.904[/tex]

According the law of conservation of linear momentum :

initial momentum = final momentum

[tex]1.25=0.25 v_1+1.904[/tex]

[tex]v_1=-2.616\ m/s[/tex]

So, the final velocity of ball 1 is (-2.616)m/s.

Answer:

mass of ball 1= 0.25 kg

initial speed of ball 1= 5. m/s

mass ball 2= 0.8 kg

initial speed ball 2= 0 ( it was at rest)

final speed of ball 2= 2.38m/s

the formula is:

m1 . v 1 + m2 . v2 = m1 . v1f+ m2 . v2f

0.25 . 5 + 0.8 . 0 = o.25 . x + 0.8 . 2.38

-2.6288 m/s

Explanation:

i got it right on the flvs

Answer:

vf₁  =  15.29 cm/s : to the right

vf₂ =  25.29 cm/s : to the right

Explanation:

Theory of collisions  

Linear momentum is a vector magnitude (same direction of the velocity) and its magnitude is calculated like this:  

p=m*v  

where  

p:Linear momentum  

m: mass  

v:velocity  

There are 3 cases of collisions : elastic, inelastic and plastic.  

For the three cases the total linear momentum quantity is conserved:  

P₀ = Pf Formula (1)  

P₀ :Initial linear momentum quantity  

Pf : Final linear momentum quantity  

Data

m₁= 11 g : mass of  object₁

m₂= 24 g  : mass of  object₂

v₀₁ = 29 cm/s , to the right : initial velocity of m₁

v₀₂=  19 cm/s, to the right  i :initial velocity of m₂

Problem development

We appy the formula (1):

P₀ = Pf  

m₁*v₀₁ + m₂*v₀₂ = m₁*vf₁ + m₂*vf₂  

We assume that the two objects move to the right at the end of the collision, so, the sign of the final speeds is positive:

( 11)*( 29) + (24 )*(19) = ( 11)*vf₁ +(24)*vf₂

775 = ( 11)*vf₁ +(24)*vf₂ Equation (1)

Because the shock is elastic, the coefficient of elastic restitution (e) is equal to 1.

[tex]e = \frac{v_{f2} -v_{f1}}{v_{o1} -v_{o2}}[/tex]

1*(v₀₁ - v₀₂ )  = (vf₂ -vf₁)

(29 -  19 )  = (vf₂ -vf₁)

10 =  (vf₂ -vf₁)

vf₂ = 10 + vf₁  Equation (2)

We replace Equation (2) in the Equation (1)

775 = ( 11)*vf₁ +(24)*(10 + vf₁ )

775 = ( 11)*vf₁ +240+(24) vf₁

775 - 240= ( 35)*vf₁

535 = ( 35)*vf₁

vf₁  = 535 / 35

vf₁  =  15.29 cm/s : to the right : Final velocity of object₁  

We replace vf₁  =  15.29  cm/s in the Equation (2)

vf₂ = 10 + vf₁

vf₂ =10 +  15.29

vf₂ =  25.29 cm/s, to the right: Final velocity of object₂

To solve this problem it is necessary to apply the kinematic equations of Energy for which the rotation of a circular body is described as

[tex]KE = \frac{1}{2}mv^2+\frac{1}{2}I\omega^2[/tex]

Where,

m = Mass of the Vall

v = Velocity

I = Moment of inertia abouts its centre of mass

[tex]\omega =[/tex] Angular speed

Basically the two sums of energies is the consideration of translational and rotational kinetic energy.

a. so that it was also rotating?

The ball is rotating means that it has some angular speed:

[tex]KE = \frac{1}{2}mv^2+\frac{1}{2}I\omega^2[/tex]

[tex]1000J = \frac{1}{2}mv^2+\frac{1}{2}I\omega^2[/tex]

When there is a little angular energy (and not linear energy to travel faster), translational energy will be greater than the 1000J applied.

[tex]1000J > \frac{1}{2}mv^2[/tex]

The ball will not go faster.

c. so that it wasn't rotating?

For the case where the angular velocity does not rotate it is zero therefore

[tex]KE = \frac{1}{2}mv^2+\frac{1}{2}I\omega^2[/tex]

[tex]1000J = \frac{1}{2}mv^2+\frac{1}{2}I(0)^2[/tex]

[tex]1000J = \frac{1}{2}mv^2[/tex]

All energy is transoformed into translational energy so it is possible to go faster. This option is CORRECT.

b. It makes no difference.

Although the order presented is different, I left this last option because as we can see with the previous two parts if there is an affectation regarding angular movement, therefore it is not correct.

The rotational movement of the ball doesn't contribute to its linear speed. If the same amount of energy is used, a ball, whether rotating or not, should travel at the same speed, ignoring air resistance.

The rotational movement of the ball in this case would not alter the speed of the ball's travel when projected. One reason is that only the kinetic energy associated with linear motion (or translational motion) would affect the speed. Rotational energy doesn't contribute to the ball's translational or linear speed. So, regardless of whether the ball is rotating or not if the same amount of energy (1000 J in this case) is used, the ball would travel at the same speed. Therefore, the correct option would be "It makes no difference."

However, it's worth noting that in the real world, where we cannot ignore air resistance, a spinning ball might travel a different path due to the Magnus effect.

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Answer:

(a) Energy will be 675 J

(B) charge will be 450 C

(C) Total number of particles will be [tex]281.25\times 10^6[/tex]

Explanation:

We have given that a flashlight uses 0.75 watts of power

So power P = 0.75 watt

Voltage is given as V = 1.5 volt

Time is given as t = 15 minutes

We know that 1 minute = 60 sec

So 15 minutes = [tex]15\times 60=900sec[/tex]

(A) We know that energy is given by [tex]E=P\times T=0.75\times 900=675j[/tex]

(b) We know that energy is also given by [tex]E=QV[/tex]

So [tex]675=Q\times 1.5[/tex]

[tex]Q=450C[/tex]

Now we have given charge on each particle [tex]=1.6\times 10^{-6}C[/tex]

So number of charge particle [tex]n=\frac{450}{1.6\times 10^{-6}}=281.25\times 10^6[/tex]

Answer:

C. The object will slow down, momentarily stopping, then pick up speed moving to the left.

Explanation:

Given that

Speed of the object = 10 m/s ( right direction)

Acceleration ,a=  - 2 m/s

A negative sign shows that acceleration is in the opposite direction to the speed.

We know that if speed and acceleration is in the opposite direction then the final speed of the objects becomes zero. for a moment and it will increase in the opposite direction.

Therefore the answer is C

The correct statement is c. The object will slow down, momentarily stop, then pick up speed moving to the left. This is due to the object's negative acceleration, which means it is slowing down.

In this physics problem, an object is moving to the right with an initial velocity of 10 m/s and an acceleration of -2.0 m/s2. Negative acceleration, also known as deceleration, doesn't mean the object is moving in a negative direction, rather it is slowing down. The correct statement is c. The object will slow down, momentarily stopping, then pick up speed moving to the left. This is because as time progresses, the negative acceleration reduces the speed of the object until it comes to a stop, after which it starts moving in the opposite direction, towards the left.

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Answer:

(A) 18667 turns

(B) 1.7 A

Solution:

As per the question:

Voltage at which the electricity is distributed, [tex]V_{p} = 1.6\times 10^{4}\ Hz[/tex]

Frequency of the oscillating voltage, f = 60 Hz

Step down voltage, [tex]V_{s} = 120\ V[/tex]

No. of turns in the secondary coil, [tex]N_{s} = 140\ turns[/tex]

Current in the secondary coil, [tex]I_{s} = 230\ A[/tex]

Now,

(A) To calculate the primary no. of turns, we use the relation:

[tex]\frac{V_{s}}{V_{p}} = \frac{N_{s}}{N_{p}}[/tex]

[tex]N_{p} = \frac{V_{p}}{V_{s}}\times N_{s}[/tex]

[tex]N_{p} = \frac{1.6\times 10^{4}}{120}\times 140 = 18,667\ turns[/tex]

(B) To calculate the current in the primary coil, [tex]I_{p}[/tex], we use the relation:

[tex]\frac{V_{p}}{V_{s}} = \frac{I_{s}}{I_{p}}[/tex]

[tex]I_{p} = \frac{V_{s}}{V_{p}} \times {I_{s}}[/tex]

[tex]I_{p} = \frac{120}{1.6\times 10^{4}} \times 230 = 1.7\ A[/tex]

Answer

given,

mass of an object = 5 Kg

mass of the other object = 5.98 x 10²⁴ Kg

radius of earth = 6371 Km = 6.371 x 10⁶ m

comparison between gravitational force between two object and weight of the object.

gravitational force between two objects

   [tex]F = \dfrac{Gm_1m_2}{r^2}[/tex]

   [tex]F = \dfrac{6.67 \times 10^{-11}\times 5 \times 5.98 \times 10^{24}}{(6.371 \times 10^6)^2}[/tex]

      F = 49.134 N

weight of the object on the earth surface

  F = m g

  F = 5 x 9.81

  F = 49.05 N

From the above two calculation we can conclude that gravitational force is approximately equal to weight of the body.

The location of the mass at t = 5.47s can be determined by the equation for the position associated with SHM. To ascertain the direction of motion at the same time, the velocity function (the derivative of the position function) can be used. If the velocity value is positive, the mass moves in the positive x direction; if negative, it moves in the negative x direction.

The problem describes the motion of a mass attached to a spring - specifically, it's simple harmonic motion (SHM). This can be understood in terms of the mass moving back and forth around a central, or equilibrium, position.

a) To determine the location of the mass at a specific time, t = 5.47s, we need to use the equation for the position x(t) associated with SHM: x(t) = A * cos(2 * π * t / T), where A is the amplitude (0.0360m in this case), π is the mathematical constant Pi, t is the time, and T is the period (2.25s in this case). Substituting the given values into this equation will give the position of the mass at t = 5.47s.

b) To determine the direction of motion at that time, we use the derivative of the position function, which gives us the velocity function: v(t) = dx(t) / dt = -A * (2 * π / T) * sin(2 * π * t / T). If this value is positive, then the mass is moving in the positive x direction; if negative, then it's moving in the negative x direction.

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Answer:

m = 3.91 kg

Explanation:

Given that,

Mass of the object, m = 3.74 kg

Stretching in the spring, x = 0.0161 m

The frequency of vibration, f = 3.84 Hz

When the object is suspended, the gravitational force is balanced by the spring force as :

[tex]mg=kx[/tex]

[tex]k=\dfrac{mg}{x}[/tex]

[tex]k=\dfrac{3.74\times 9.8}{0.0161}[/tex]

k = 2276.52 N/m

The frequency of vibration is given by :

[tex]f=\dfrac{1}{2\pi}\sqrt{\dfrac{k}{m}}[/tex]

[tex]m=\dfrac{k}{4\pi^2f^2}[/tex]

[tex]m=\dfrac{2276.52}{4\pi^2\times (3.84)^2}[/tex]

m = 3.91 kg

So, the mass of the object is 3.91 kg. Hence, this is the required solution.

Answer:

0.25 kg m^2

Explanation:

mass of each , m = 500 g = 0.5 kg

distance, r = 50 cm = 0.5 m

Moment of inertia about the axis passing through one corner and perpendicular to the plane of triangle

I = mr^2 + mr^2

I = 2 mr^2

I = 2 x 0.5 x 0.5 x 0.5

I = 0.25 kgm^2

Answer:

P = 1.99 10⁸ Pa

Explanation:

The definition of the bulk module is

      B = - P / (ΔV / V)

The negative sign is included for which balk module is positive, P is the pressure and V that volume

They tell us that the variation in volume is 9.05%, that is

    ΔV / V = ​​9.0Δ5 / 100 = 0.0905

    P = - B DV / V

    P = 2.2 10⁹ (0.0905)

    P = 1.99 10⁸ Pa

Final answer:

The force per unit area water exerts on a container when it freezes is calculated using the bulk modulus of water, resulting in a pressure of 1.99 × 10⁴ N/cm². This explains why freezing water can cause significant damage to rigid structures.

Explanation:

When water freezes, its volume increases by 9.05% (ΔV/V = 9.05 × 10⁻²). The force per unit area that water can exert on a container when it freezes can be calculated using the bulk modulus of water, which is given as B = 2.2 × 10⁹ N/m². The change in volume fraction (ΔV/V) is directly related to the change in pressure (ΔP) and the bulk modulus (B) by the formula ΔP = -B(ΔV/V), where the negative sign indicates a reduction in volume leads to an increase in pressure, but in this case, we're dealing with an expansion, so ΔV/V is positive.

To find the pressure in N/cm², we first calculate the pressure in Pascals (Pa) using the given values:

ΔP = B(ΔV/V)

= (2.2 × 10⁹ N/m²)(9.05 × 10⁻²)

= 1.99 × 10⁸ Pa.

Since 1 Pa equals 1 N/m² and 1 N/m² equals 0.0001 N/cm²,

the pressure in N/cm² is 1.99 × 10⁴ N/cm².

Answer:

The power in this flow is [tex]9.56\times10^{8}\ W[/tex]

Explanation:

Given that,

Distance = 221 m

Power output = 680 MW

Height =150 m

Average flow rate = 650 m³/s

Suppose we need to calculate the power in this flow in watt

We need to calculate the pressure

Using formula of pressure

[tex]Pressure=\rho g h[/tex]

Where, [tex]\rho[/tex]= density

h = height

g = acceleration due to gravity

Put the value into the formula

[tex]Pressure=1000\times9.8\times150[/tex]

[tex]Pressure=1470000\ Nm^2[/tex]

We need to calculate the power

Using formula of power

[tex]P=Pressure\times flow\ rate[/tex]

Put the value into the formula

[tex]P=1470000\times650[/tex]

[tex]P=9.56\times10^{8}\ W[/tex]

Hence, The power in this flow is [tex]9.56\times10^{8}\ W[/tex]

To solve this problem it is necessary to apply the concepts related to the condition of path difference for destructive interference between the two reflected waves from the top and bottom of a surface.

Mathematically this expression can be described under the equation

[tex]\delta = 2nt[/tex]

Where

n = Refractive index

t = Thickness

In terms of the wavelength the path difference of the reflected waves can be described as

[tex]\delta = \frac{\lambda}{4}[/tex]

Where

\lambda = Wavelenght

Equation the two equations we have that

[tex]2nt = \frac{\lambda}{4}[/tex]

[tex]t = \frac{\lambda}{8n}[/tex]

Our values are given as

[tex]\lambda = 380nm \rightarrow[/tex] Wavelength of light

[tex]n = 1.4[/tex]

[tex]t = \frac{380nm}{8*1.4}[/tex]

[tex]t = 33.93nm[/tex]

Therefore the minimum thickness of the oil for destructive interference to occur is approximately 34.0 nm

The maximum thickness of the oil film that will appear dark at all visible wavelengths is approximately 33.9 nm, ensuring destructive interference for all visible light.

The oil film appears dark when its thickness is such that the path length difference is less than one-fourth the wavelength of the light. This is due to the destructive interference of light waves. Given that the thickest the oil can be and still appear dark when the path length difference is one-fourth the shortest visible wavelength in oil, we need to find this thickness value.

The shortest visible wavelength of light in air is typically about 380 nm, which is violet. However, the speed and consequently the wavelength of light will decrease in oil due to its refractive index being higher. Therefore, the wavelength of light in oil is shorter than in air and can be found by dividing the wavelength in the air by the index of refraction, which gives about 271 nm for violet light in oil.

Since the path length difference is twice the film thickness, the maximum thickness of the oil should be one-eighth the shortest visible wavelength in oil to appear dark, which is approximately 33.9 nm. This calculation ensures destructive interference for all visible wavelengths and hence, the film will appear black or dark at all visible wavelengths.

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