The acceleration due to gravity on the moon is about 1/6 of the acceleration due to gravity on the earth. A net force F acts horizontally on an object on the Moon, producing an acceleration equal to am. In the absence of friction and drag, the same force acting on the same object on Earth would produce an acceleration i.e. equal to

a. 6am
b. (1/6)am
c. am
d. 0
e. 9.8 m/s2

Explanation:

The dimension of a single rectangular loop is 0.46 m x 0.68 m.

Magnetic field, B = 3 T

The loop is inclined at an angle of 67 degrees with respect to the normal to the plane of the loop.

It is required to find the magnitude of the average emf induced in the loop if the magnetic field decreases to zero in a time of 0.49 s.

Te induced emf in the loop is given by :

[tex]\epsilon=\dfrac{-d\phi}{dt}\\\\\epsilon=\dfrac{-d(BA)}{dt}\\\\\epsilon=A\dfrac{dB}{dt}\cos\theta\\\\\epsilon=0.46\times 0.68\times \dfrac{3}{0.49}\times \cos(67)\\\\\epsilon=0.74\ V[/tex]

So, the magnitude of the average emf induced in the loop is 0.74 V.

Answer:

The strength of the magnetic field is 0.0842 mT

Explanation:

Given:

Velocity of rod [tex]v = 3.07[/tex] [tex]\frac{m}{s}[/tex]

Length of rod [tex]l = 1.11[/tex] m

Induced emf across the rod [tex]\epsilon = 0.287 \times 10^{-3}[/tex] V

According to the faraday's law

We have a special case for moving rod in magnetic field.

Induced emf in moving rod is given by,

   [tex]\epsilon = Blv[/tex]

Where [tex]B =[/tex] strength of magnetic field

  [tex]B = \frac{\epsilon}{lv}[/tex]

  [tex]B = \frac{0.287 \times 10^{-3} }{3.07 \times 1.11}[/tex]

  [tex]B = 0.0842 \times 10^{-3}[/tex] T

  [tex]B = 0.0842[/tex] mT

Therefore, the strength of the magnetic field is 0.0842 mT

Answer:

True.

The day a huge asteroid strikes the earth will likely be a weekday.

Explanation:

Mathematically, there are 5 weekdays in the week and there are only 2 weekend days.

Total number of days in a week = 7

Since, the asteroids can hit on any day,

The probability of the asteroid hitting on a weekend day = (2/7) = 0.2857

The probability that an asteroid hitting on a weekday = (5/7) = 0.7143.

So, by the virtue of the probability of the asteroid hitting on a weekday or on a weekend day, the asteroid is more likely to hit on a weekday as

P(weekday) > P(weekend)

0.7143 > 0.2857.

Hope this Helps!!!

Answer:

0.2cm towards the retina.

Explanation:

the focal length of the frog eye is

(1/f) = (1/10) + (1/0.8)

f = 0.74cm

Since the distance of the object is 15cm Hence

(1/0.74) = (1/15) + (1/V)

V = 0.78cm

Therefore the distance the retina is to move is

0.78cm - 0.8cm = 0.02cm towards the retina.

Answer:

False

Explanation:

Friction is the resisting force of motion that converts kinetic energy into heat energy. Kinetic energy is the energy of movement. Removing kinetic energy makes the object slower.

The ranking from largest to smallest the values of the magnetic field should be like

Rb = 4.95 cm

r= 5.40 cm

Ra =7.75 cm

r> Ra

It is a vector field that explained the magnetic impact on moving electric charges, electric currents, and magnetic materials.

In this, the force should be perpendicular to the velocity and the magnetic field. Also, it should be inversely proportional with respect to the distance with the axis of the cylinder.

So,

The largest magnetic field =Rb =4.95 cm

And,

Smallest magnetic field = r>Ra

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The magnetic field inside a conducting cylinder is maximized at certain points before dropping off outside. The ranked values from largest to smallest  are: r = 5.40 cm, Rb = 4.95 cm, Ra = 7.75 cm, and r > Ra.

To determine the magnetic field  at different distances from the axis of a conducting cylinder, we need to understand how the magnetic field varies inside and outside a cylinder carrying a current.

Given the distances Ra = 7.75 cm, Rb = 4.95 cm, r = 5.40 cm, and r > Ra, we will rank the magnetic field intensities:

1.) r = 5.40 cm:

Since r is within the cylinder where current is distributed uniformly, the magnetic field at this point can be calculated using Ampère's Law.

2.) Rb = 4.95 cm:

Still within the cylinder but closer to the center, thus the field here will not yet be maximized.

3.) Ra = 7.75 cm:

Outside the cylinder where the current configuration influences how the field drops off with increasing distance.

4.) r > Ra:

This point is furthest from the axis, hence the magnetic field will be the smallest.

The magnetic field reaches a maximum inside the conducting cylinder before decreasing outside of it.

Answer:

The same in both the regions of constructive interference and the regions of destructive interference.

Explanation:

Interference is a phenomenon which occurs when two waves meet while moving along the same medium . The amplitude formed as a result of the interference could be greater, lower, or the same amplitude.

Constructive and destructive interference result from the interaction of waves that are correlated or coherent with each other. This is because arose from the same source or they have the same or nearly the same frequency.

The waves being coherent, arising from the same source and having the same frequency explains why it’s the same in both the regions of constructive interference and the regions of destructive interference.

Answer:

Explanation:

Constructive interference occurs when the maxima of two waves add together (the two waves are in phase), so that the amplitude of the resulting wave is equal to the sum of the individual amplitudes. Whereas in destructive interference opposite is true.

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Answer:

0.2923 V

Explanation:

Given that

Angle between the rails, θ = 19°

Speed of the rod, v = 0.6 m/s

Magnetic field present, B = 0.63 T

Time used, t = 7.5 s

E = -ΔΦ/Δt

where, Φ = BA, so

E = -BΔA / Δt

To get the area, if we assume the rails are joined in a triangular fashion(see attachment)

E = -B(1/2 * AC * BC) / Δt

E = -B(vΔt * vΔt tanθ) / 2Δt

E = -(B * v² * Δt² * tanθ) / 2Δt

E = -Bv²Δt.tanθ/2

E = -(0.63 * 0.6² * 7.5 * tan 19) / 2

E = -0.5857 / 2

E = -0.2923

Thus, the magnitude of average emf induced if 0.2923 V

Answer:

The frequency of the sona-pulse reflected back is  [tex]f_b = 48109.22Hz[/tex]

Explanation:

From the question we are told that

     The speed of the bat is  [tex]v = 5.1 m/s[/tex]

      The speed of the insect is [tex]v_i = 1.1 m/s[/tex]

       The frequency emitted by the bat is [tex]f = 47000 \ Hz[/tex]

        The speed of sound is  [tex]v_s = 343 m/s[/tex]

Let look at this question in this manner

At the first instant the that the bat  emits the sonar pulse

     Let the bat be the source of sound

      Let the insect be the observer

This implies that the frequency of sound the the insect would receive is mathematically represented as

                    [tex]f_a = [\frac{v_s - v_i}{v_s - v}] f[/tex]

Substituting values

                 [tex]f_a = [\frac{343 - 1.1}{345 -5.1} ] * 47000[/tex]

                     [tex]f_a = 47556.4 Hz[/tex]

Now at the instant the sonar pules reaches the insect

            Let the bat be the observer

            Let the insect be the source of the sound

Here the sound wave is reflected back to the bat

This implies that the frequency of sound the the bat  would receive is mathematically represented as

                   [tex]f_b =[ \frac{x}{y} ] * f_a[/tex]

                   [tex]f_b =[ \frac{v_s + v}{v_s + v_i} ] * f_a[/tex]

                  [tex]f_b =[ \frac{343 + 5.1}{343 + 1.1} ] * 47556.4[/tex]

                  [tex]f_b = 48109.22Hz[/tex]

Final answer:

To calculate the frequency a bat hears from a sonar pulse reflected back by an insect, the Doppler effect formula is used. By substituting the given values into the formula, the result is approximately 47,544 Hz, which is the frequency at which the bat detects the echo from the insect.

Explanation:

To calculate the frequency at which a bat hears the sonar pulse reflected back from an insect, we can use the Doppler effect formula for sound in the same direction as the source of the sound is moving:

[tex]f' =\frac{f (v + v_d)}{(v + v_s)}[/tex]

Where:

f' is the frequency heard by the bat.

f is the emitted frequency of the bat's sonar pulse (47,000 Hz).

v is the speed of sound (343 m/s).

[tex]v_d[/tex] is the speed of the detector (bat), which is 5.1 m/s.

[tex]v_s[/tex] is the speed of the source (insect), which is 1.1 m/s.

Substituting the values into the equation:

[tex]f' = \frac{47000 Hz \times (343 m/s + 5.1 m/s)}{(343 m/s + 1.1 m/s)}[/tex]

[tex]f' = \frac{47000 Hz * 348.1 m/s}{344.1 m/s}[/tex]

[tex]f' = 47000 Hz \times 1.0116[/tex]

f' = 47544.2 Hz

Therefore, the bat hears the pulse reflected back from the insect at approximately 47,544 Hz.

Answer:

a) 22.06m/s

b)45°

Explanation:

Let 'm' be  mass of 1st and 2nd pieces

mass of 3rd piece=3m

[tex]v_{1}[/tex]=velocity of 1st piece = -47iˆ  m/s

[tex]v_{2}[/tex]=velocity of 2nd piece = -47jˆ  m/s

[tex]v_{3}[/tex]=velocity of 3rd piece=?

By considering conservation of linear momentum, we have

m[tex]v_{1}[/tex] + m[tex]v_{2}[/tex] + 3m[tex]v_{3}[/tex]=0

[tex]v_{1}[/tex] + [tex]v_{2}[/tex] + 3[tex]v_{3}[/tex]=0

3[tex]v_{3}[/tex]= - ([tex]v_{1}[/tex] + [tex]v_{2}[/tex] )

[tex]v_{3}[/tex] = -[tex]\frac{1}{3}[/tex] ([tex]v_{1}[/tex] + [tex]v_{2}[/tex] )

Substituting the values of [tex]v_{1}[/tex] and [tex]v_{2}[/tex] in above equation

[tex]v_{3}[/tex] = -[tex]\frac{1}{3}[/tex] (-47iˆ -47jˆ ) => 15.6iˆ + 15.6jˆ

(a)Magnitude of the velocity of  the third piece is given by

|[tex]v_{3}[/tex]| =√15.6²+15.6² => 22.06m/s

(b) its direction (as an angle relative to the +x axis)  'θ'

θ= [tex]tan^{-1} (\frac{15.6}{15.6} )[/tex] => [tex]tan^{-1} (1 )[/tex] =>45°

Answer:

The answer is C.

Explanation:

Current can be represented in the symbol of I.

The symbol for voltage is V.

The symbol for power is W.

The symbol for resistance is R.

Answer:

The cart would speed up.

Explanation:

According to Newton's 1st law, object subjected to no force, or net force 0, would have a constant speed. In our case the cart is initially at constant speed, meaning the man exerts a force that is equal to friction force. If he increases the force on the cart, the net force would no longer be 0. The cart would gain an acceleration and increases its speed.

Answer:

A. The cart accelerates

Explanation:

Answer:

0.25

Explanation:

Since there is a vertical displacement of 0.5cm from the crest to the trough, there is half of that displacement to the midline, which is also known as the amplitude. Therefore, the amplitude is 0.5/2=0.25cm. Hope this helps!

Answer:

A

Explanation:

Peaks are in opposite direction because change in magnetic field at one end of the coil is opposite to the change in magnetic field at other end of the coil. Faraday's law predict that the direction of induced voltage is dependent on the nature of change in magnetic field

Answer:

About eq (1)

[tex]mv^2/r = eVB[/tex]

when a charged particle (electron) enters into the magnetic field which is perpendicular to direction of motion than there will be magnetic force on particle and particle will travel in circular path in with constant speed.

So using force balance on charged particle:

[tex]F_{net} = Fc - Fm[/tex]

Since particle is traveling at constant speed, So acceleration is zero, and

[tex]F_{net} = 0[/tex]

[tex]Fc - Fm=0[/tex]

[tex]Fc = Fm[/tex]

Fc = centripetal force on particle [tex]= m*v^2/r[/tex]

Fm = magnetic force on electron = [tex]q*VxB = q*V*B*sin \theta[/tex]

q = charge on electron = e

since magnetic field is perpendicular to the velocity of particle, So theta = 90 deg

sin 90 deg = 1

So,

[tex]m*v^2/r = e*v*B[/tex]

About equation 2:

When this charged particle is released from rest in a potential difference V, and then it enters into above magnetic field, then using energy conservation on charge particle

[tex]KEi + PEi = KEf + PEf[/tex]

KEi = 0, since charged particle started from rest

[tex]PEi - PEf = q*dV[/tex]

[tex]PEi - PEf = eV[/tex]

KEf = final kinetic energy of particle when it leaves [tex]= (1/2)*m*v^2[/tex]

So,

[tex]0 + eV = (1/2)*m*v^2[/tex]

[tex]eV = (1/2)*m*v^2[/tex]

From above equation (1) and (2)

[tex]m*v^2/r = evB[/tex]

[tex]e/m = v/(r*B)[/tex]

Now

[tex]eV = (1/2)*m*v^2[/tex]

[tex]v = \sqrt{(2*e*V/m)}[/tex]

[tex]e/m = \sqrt{ (2*e*V/m)/(r*B)}[/tex]

[tex]\frac{e^2}{m^2} = \frac{2*e*V}{(m*r^2*B^2)}[/tex]

[tex]e/m = 2*V/(r^2*B^2)[/tex]

[tex]e/m = 2V/(Br)^2[/tex]

Answer:

a.)r=4RE/4

b.)r=2RE

c.)ZERO

Explanation:

a.) given v= 0.462 which is V= 0.466Ve

Since the projectile is shot directly away from earth surface the speed it escape with;

v=√2GM/RE......................eqn(1)

M is the Earth's Mass

RE is the Radius

From the Law of conservation of Energy

K+U=0...............................eqn(2)

K₁+U₁=K₂+U₂....................eqn(3)

where K₁ and U₁ is initial kinetic and potential energy

K₂ and U₂ are final kinetic and potential energy

Kinetic Energy (K.E) decrease with time as the projectile moves up and there is decrease in Potential Energy (P.E) , it will let to a point where K.E will turn to zero i.e K₂=0

U₂=K₁U₂ ..........................eqn(3)

From Gravitational Law

U₁= -GMm/RE ..................(5)

U₂= -GMm/r .....................(6)

Where "r" is the distance

v= 0.462√2GM/RE

v= √GM/2RE

GM/4RE - GM/RE = -GM/r

r= 4RE/3

b.) "r" is calculated by this equation;

K₁=0.466

K₁= 1/4MVe².............................eqn(9)

substitute eqn(1) into eqn (9) then

1/4m2GM/RE=0.466GM/2Re

GM/2RE - GM/RE =-GM/r

r=2RE

c.)The potential energy and kinetic energy is the same in terms of their size both in different directions, while the potential energy face outward, the kinetic energy face inward therefore the least initial mechanical energy

required at launch if the projectle is to escape is ZERO

To calculate the electric-field magnitude at points inside and outside a uniformly charged insulating sphere, we apply Gauss's Law, considering the proportion of enclosed charge within a Gaussian surface for points inside, and treating the sphere as a point charge for points outside.

We apply Gauss's Law to understand the electric-field magnitude around a uniformly charged insulating sphere, which states that the electric flux through a closed surface is proportional to the enclosed charge. We'll calculate the electric field (E) at two distances from the centre of the sphere: 4.00 cm, which is inside the sphere, and 6.00 cm, which is outside the sphere.

For the inside point (r = 4.00 cm), we only consider the charge enclosed by a Gaussian surface of radius 4.00 cm. Using the fact that charge is distributed uniformly throughout the volume of the sphere, we calculate the enclosed charge (q_enclosed) by using the ratio of volumes: q_enclosed = (Q * (4/3 * π * r^3)) / (4/3 * π * R^3), where Q is the total charge of the sphere. R is the radius of the sphere.

The electric field inside the sphere at 4.00 cm is then E = (1 / (4 * π * ε_0)) * (q_enclosed / r^2). We substitute the values using the given radius and charge and solve for E.

For the outside point (r = 6.00 cm), we use the formula for the electric field outside a spherically symmetric charge distribution, which is E = (1 / (4 * π * ε_0)) * (Q / r^2), and solve for E using the sphere's total charge and the distance of 6.00 cm.

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Final answer:

To find the voltage across the secondary winding of a step-up transformer with a primary voltage of 141 V and a turns ratio of 1110 to 5, the secondary voltage is calculated to be 31302 V.

Explanation:

Calculating the Voltage Across the Secondary in a Step-Up Transformer

To calculate the voltage across the secondary winding of a step-up transformer, we use the transformer equation that relates the primary and secondary voltages with the number of turns on the primary (Np) and secondary (Ns) windings:

Vs / Vp = Ns / Np

Given that the primary voltage (Vp) is 141 V, and the ratio of the number of turns is 1110 to 5 (Ns / Np), we can rearrange the equation to solve for the secondary voltage (Vs) as follows:

Vs = Vp × (Ns / Np)

Vs = 141 V × (1110 / 5)

Vs = 141 V × 222

Vs = 31302 V

Thus, the voltage across the secondary winding is 31302 V.

Answer:

 The  high-leg voltage is [tex]V_h= 497.76V[/tex]

Explanation:

A diagram showing the arrangement of this three phase transformer is shown on the first uploaded image

The high - leg terminal is in the diagram is from [tex]Z_1 - n[/tex]

Generally the high-leg terminal is 1.732 times of the the voltage from line to center tap which is given as 277 V

    The high -voltage can be computed as follows  

          [tex]V_h = 1.732 *277[/tex]

               [tex]V_h= 497.76V[/tex]

Answer:

The distance of the star is [tex]3.40x10^{16}[/tex] meters

Explanation:

It is known that the speed of light has a value of [tex]3x10^{8}m/s[/tex] in vacuum. That is, it travels [tex]3x10^{8]m[/tex] in one second, according with the following equation:    

[tex]v = \frac{x}{t}[/tex]

Where v is the speed, x is the distance and t is the time.

[tex]x = v\cdot t[/tex] (1)

Equation 1 can be used to determine the distance that the light travels in 1 year:  

It is necessary to find how many seconds are in 1 year (365.25 days).

[tex]365.25 days \cdot \frac{86400s}{1 day}[/tex]  ⇒  [tex]31557600s[/tex]

[tex]x = (3x10^{8}m/s)(31557600s)[/tex]    

[tex]x = 9.46x10^{15}m[/tex]      

Therefore, in 1 year, light travels [tex]9.46x10^{15}[/tex] meters.

If the distance to a star is 3.6 light-years, what is this distance in meters?  

A simple conversion between units can be used to get the distance in meters

[tex]x_{star} = 3.6ly \cdot \frac{9.46x10^{15}m}{1ly}[/tex] ⇒ [tex]3.40x10^{16}m[/tex]

Hence, the distance of the star is [tex]3.40x10^{16}[/tex] meters.              

A light-year, a distance unit used in astronomy, is approximately 9.46 x [tex]10^{15[/tex] meters. Hence, a distance of 3.6 light years would convert to approximately 3.4 x [tex]10^{16[/tex] meters.

A light-year is a unit of distance used in astronomy, which represents the distance light travels in one year. Light travels at a speed of 186,000 miles per second. Over the course of a year, this distance adds up significantly.

To calculate a light-year in meters, we would carry out the following calculation - light travels at 299,792 kilometers per second. This converts to exactly 299,792,000 meters per second. If we multiply this by the number of seconds in a year (60 seconds/minute, 60 minutes/hour, 24 hours/day, 365.25 days/year) we find that one light-year is approximately 9.46 x [tex]10^{15[/tex]  meters.

Therefore, if the distance to a star is 3.6 light-years, then this would convert to about 3.4 x  [tex]10^{16[/tex]  meters.

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Given that,

Magnetic field strength is

B = 1.8T

The wedding ring has a diameter of

d = 2.23 cm = 0.023m

Time take t = 0.32 secs

A. Current induced

From ohms law

V= iR, given that R = 0.01Ω

So, we need to get the induced emf

Using

ε = -NdΦ / dt

Where Φ = BA

ε = -A ∆B / ∆t

ε = -¼πd²(B2-B1) / (t2-t1)

ε = -¼ × π × 0.023² × -1.8 / 0.32

ε = 0.0023371 V

Then

I = ε / R

I = 0.002337 / 0.01

I =0.2337 A

B. Power discippated?

Power is given as

P = iV

P = 0.2337 × 0.002337

P = 0.0005462 W

P = 0.56 mW

C. The magnetic field at the centre of the ring.

The electric field at the centre of the ring is zero because each part of the ring will cause a symmetrical opposite magnitude at every point,

Then, B = 0 T

Answer:

0.685

Explanation:

the background-corrected light measurement at 29mm: 20.7mv- 5.1mv⇒15.6mv

at 32.5mm: 15.8mv- 5.1mv⇒ 10.7mv

So, Normalize the data to the maximum value probably means to set the peak value to unity and scale the remaining data by the same factors.

Therefore, the normalized corrected value at 32.5mm is ⇒ 10.7mv/15.6mv ⇒0.685

Answer:

The number of revolutions of the rotor required to turn the probe is 118 revolutions

Explanation:

Given;

rotational inertia of the electric motor,  Im = 4.36 x 10⁻³ kg·m²

rotational inertia of the probe, Ip = 6.07 kg·m²

the angular position of the probe, θ = 30.6°

From the principle of conservation of angular momentum;

[tex]I_m \omega _m = I_p \omega _p \\\\Also;\\\\I_m \theta _m = I_p \theta _p[/tex]

where;

[tex]\omega _m[/tex] is the angular velocity of the electric motor

[tex]\omega _p[/tex] is the angular velocity of the probe

[tex]\theta _m[/tex] is the angular position of the electric motor

[tex]\theta _p[/tex] is the angular position of the probe

[tex]\theta _m = \frac{I_p \theta_p}{I_m} \\\\\theta _m = \frac{6.07* 30.6^o}{4.36*10^{-3}} = 42601.4^o[/tex]

360° = One revolution

42601.4° = ?

Divide 42601.4°  by 360°

= 118 revolutions

Therefore, the number of revolutions of the rotor required to turn the probe is 118 revolutions

Final answer:

The calculated density ratio is 0.5.

The ratio of the densities of two blocks, A and B, is found by comparing the apparent weight reductions when they are submerged in a fluid. According to Archimedes' principle, this reduction is due to the buoyant force, which is equal to the weight of the fluid displaced.

Explanation:

The question revolves around calculating the ratio of the densities of two blocks, A and B, using the concept of buoyant force according to Archimedes' principle. The apparent weight of each block when submerged in a fluid gives us the buoyant force acting upon it, which is equal to the weight of the fluid displaced. Since both blocks are submerged in the same fluid, the difference in weights in air versus submerged gives us a measure of the volume of fluid displaced due to the respective densities of the blocks.

To determine the ratio of densities (A/B), we use the formula:

Ratio of densities = (Weight of A in air - Apparent weight of A) / (Weight of B in air - Apparent weight of B)

Substituting the given weights:

Ratio of densities = (12 N - 8 N) / (20 N - 12 N) = 4 N / 8 N = 0.5

Thus, the ratio of the densities of block A to block B is 0.5.

The correct answer for the gravitational field of a point mass is [tex]g = -\dfrac{GM_1M_1}{r^2} * \dfrac{r}{m}[/tex]

The gravitational force between two masses is given by Newton's law of gravitation:

[tex]F = \dfrac{GM_1M_2}{r^2}[/tex]

[tex]F[/tex] is the gravitational force between [tex]M_1[/tex] and [tex]M_2[/tex]

[tex]G[/tex] is the gravitational constant,

[tex]r^2[/tex] is the square of the distance between two masses.

The gravitational force is a vector quantity, and it is directed along the line connecting the two masses.

[tex]g= \dfrac{F}{m}[/tex]

[tex]g[/tex] is the gravitational field.

[tex]F[/tex] is the gravitational force.

Let [tex]m[/tex] be the mass test object.

Substitute the value of gravitational force from Newton's law of gravity:

[tex]g = \dfrac{GM_1M_1}{r^2} * \dfrac{r}{m}[/tex]

[tex]r[/tex]is the unit vector pointing from the mass M to the test mass, which represents the direction of the gravitational field.

[tex]g = -\dfrac{GM_1M_1}{r^2} * \dfrac{r}{m}[/tex]

The negative sign indicates the direction of the gravitational force is attractive.

The gravitational field is [tex]g = -\dfrac{GM_1M_1}{r^2} * \dfrac{r}{m}[/tex]

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The gravitational field of a point mass is given by -GM/(r^2)*r^, where the negative sign indicates the attractive nature (opposite direction to r^) of gravity.

The gravitational field g of a point mass using the same reasoning as for the electric field would be analogous but with some slight modifications to account for the attractive nature of gravity, unlike the repulsive nature of electric charges of the same sign. The formula is given by -GM/(r^2)*r^, where G is the gravitational constant, M is the mass of the object, and r is the distance to the object. The negative sign indicates that the force is attractive and acts in the direction opposite to r (the vector pointing directly away from the mass).

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Answer:

The work done on the jet by the catapult is 1.53 x  10⁷ J

Explanation:

Given;

force of thrust engines, F =  2.3 x 10⁵ N

distance moved by the thrust engines, d =  90 m

kinetic energy of the plane, K.E = 3.60 x 10⁷ J

Based on work-energy theorem;

the net work done on the plane by catapult and the thrust engine is given as;

[tex]W_n = K.E_f = 3.6 *10^7 \ J[/tex]

work done by the thrust engine on the jet;

[tex]W_T_._e_n = fd\\\\W_T_._e_n = 2.3*10^5 * 90\\\\W_T_._e_n = 2.07*10^7 \ J[/tex]

Work done on the jet by the catapult;

[tex]W_c_p= W_n - W_T_._e_g\\\\W_c_p= (3.6*10^7 - 2.07*10^7) J\\\\W_c_p= 1.53*10^7 \ J[/tex]

Therefore, the work done on the jet by the catapult is 1.53 x  10⁷ J

if two objects each have a mass of 10 kg, then the force of gravity between them C) is greater when they are closer together.

We have two objects, each with a mass of 10 kg. We can calculate the force of gravity (F) between them using Newton's law of universal gravitation.

[tex]F = G \frac{m_1m_2}{r^{2} }[/tex]

where,

As we can see from this expression. the gravitational force between the objects depends on their masses and the distance between them. The closer they are, the stronger the gravity force.

if two objects each have a mass of 10 kg, then the force of gravity between them...

A) is constant. No. It varies with the distance.

B) is 100 kg. No. kg is not a unit of force.

C) is greater when they are closer together. Yes.

D) depends only on their masses. No. It also depends on the distance between them.

if two objects each have a mass of 10 kg, then the force of gravity between them C) is greater when they are closer together.

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Answer:

15.4 kg.

Explanation:

From the law of conservation of momentum,

Total momentum before collision = Total momentum after collision

mu+m'u' = V(m+m').................... Equation 1

Where m = mass of the first sphere, m' = mass of the second sphere, u = initial velocity of the first sphere, u' = initial velocity of the second sphere, V = common velocity of both sphere.

Given: m = 7.7 kg, u' = 0 m/s (at rest)

Let: u = x m/s, and V = 1/3x m/s

Substitute into equation 1

7.7(x)+m'(0) = 1/3x(7.7+m')

7.7x = 1/3x(7.7+m')

7.7 = 1/3(7.7+m')

23.1 = 7.7+m'

m' = 23.1-7.7

m' = 15.4 kg.

Hence the mass of the second sphere = 15.4 kg

Answer:

The mass of the second sphere is 15.4 kg

Explanation:

Given;

mass of the first sphere, m₁ = 7.7 kg

initial velocity of the second sphere, u₂ = 0

let mass of the second sphere =  m₂

let the initial velocity of the first sphere = u₁

final velocity of the composite system, v = ¹/₃ x u₁ = [tex]\frac{u_1}{3}[/tex]

From the principle of conservation of linear momentum;

Total momentum before collision = Total momentum after collision

m₁u₁ + m₂u₂ = v(m₁ + m₂)

Substitute the given values;

[tex]7.7u_1 + 0=\frac{u_1}{3} (7.7+m_2)[/tex]

Divide through by u₁

7.7 = ¹/₃(7.7 + m₂)

multiply both sides by 3

23.1 = 7.7 + m₂

m₂ = 23.1 - 7.7

m₂ = 15.4 kg

Therefore, the mass of the second sphere is 15.4 kg

Answer:

0.372 kg

Explanation:

The collision between the bullet and the block is inelastic, so only the total momentum of the system is conserved. So we can write:

[tex]mu=(M+m)v[/tex] (1)

where

[tex]m=11.9 g = 11.9\cdot 10^{-3}kg[/tex] is the mass of the bullet

[tex]u=261 m/s[/tex] is the initial velocity of the bullet

[tex]M[/tex] is the mass of the block

[tex]v[/tex] is the velocity at which the bullet and the block travels after the collision

We also know that the block is attached to a spring, and that the surface over which the block slides after the collision is frictionless. This means that the energy is conserved: so, the total kinetic energy of the block+bullet system just after the collision will entirely convert into elastic potential energy of the spring when the system comes to rest. So we can write

[tex]\frac{1}{2}(M+m)v^2 = \frac{1}{2}kx^2[/tex] (2)

where

k = 205 N/m is the spring constant

x = 35.0 cm = 0.35 m is the compression of the spring

From eq(1) we get

[tex]v=\frac{mu}{M+m}[/tex]

And substituting into eq(2), we can solve to find the mass of the block:

[tex](M+m) \frac{(mu)^2}{(M+m)^2}=kx^2\\\frac{(mu)^2}{M+m}=kx^2\\M+m=\frac{(mu)^2}{kx^2}\\M=\frac{(mu)^2}{kx^2}-m=\frac{(11.9\cdot 10^{-3}\cdot 261)^2}{(205)(0.35)^2}-11.9\cdot 10^{-3}=0.372 kg[/tex]

The mass of the wooden block is approximately 0.404 kg.

The initial kinetic energy of the bullet is given by:

KE_initial = 0.5 * mb * vb^2

where:

`m_b` is the mass of the bullet (11.9 g = 0.0119 kg)

`v_b` is the velocity of the bullet (261 m/s)

The potential energy stored in the compressed spring is given by:

PE_spring = 0.5 * k * x^2

where:

`k` is the spring constant (205 N/m)

`x` is the compression of the spring (0.35 m)

Since the system comes to a stop, the initial kinetic energy is converted to potential energy stored in the spring:

KE_initial = PE_spring

Solving for the mass of the wooden block, we get:

m_w = (2 * KE_initial) / (v_b^2 - (k * x) / m_b)

Plugging in the values, we get,

m_w = (2 * 0.5 * 0.0119 kg * (261 m/s)^2) / ((261 m/s)^2 - (205 N/m * 0.35 m) / 0.0119 kg)

m_w ≈ 0.404 kg

Therefore, the mass of the wooden block is approximately 0.404 kg.

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The work done by the gas when the volume increases from 12.0 m³ to 16.2 m³ at atmospheric pressure is 425.565 kJ. The change in internal energy of the gas when 254 kcal of heat is added is 636.931 kJ.

To calculate the work done by the gas during a quasi-static expansion, we can use the formula W = P ΔV, where W is work, P is pressure, and ΔV is the change in volume. Given the atmospheric pressure is 1 atm or 101,325 Pa, and the volume change is from 12.0 m³ to 16.2 m³, the work done by the gas can be calculated as:

W = P ΔV = 101,325 Pa × (16.2 m³ - 12.0 m³)

W = 101,325 Pa × 4.2 m³

W = 425,565 J or 425.565 kJ

To calculate the change in internal energy (ΔU) of the gas, we can use the first law of thermodynamics, which states that ΔU = Q - W, where Q is the heat added to the system. The heat is given as 254 kcal, which needs to be converted to joules (1 kcal = 4.184 kJ).

ΔU = Q - W = (254 kcal × 4.184 kJ/kcal) - 425.565 kJ

ΔU = 1062.496 kJ - 425.565 kJ

ΔU = 636.931 kJ

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