What is the work done by a gravitational force of 30N on a 10kg box being moved 7m horizontally?

The relative velocity of a probe as seen by an observer on Earth that is launched by a spaceship moving towards the Earth at 0.78c with a speed of 0.22c is 0.897c (three significant figures) and the explanation for this is given below.

Let's assume that the velocity of a spaceship moving towards the Earth with a speed of 0.78c and the velocity of a probe away from the Earth with a speed of 0.22c are V1 and V2 respectively, as seen from the Earth.

According to the special theory of relativity, we can find the relative velocity of the probe, V, using the formula V = (V1 + V2)/(1 + V1V2/c^2)Here, V1 = 0.78c and V2 = 0.22cSo, V = (0.78c + 0.22c)/(1 + (0.78c x 0.22c)/(c^2))= 1 c/(1 + 0.1716)≈ 0.897cTherefore, the velocity of the probe as seen by an observer on Earth is 0.897c (three significant figures).Hence, the  answer is 0.897c

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In order to calculate the absolute error (AL) for the given three measurements L1, L2, and L3 which are 9.3 cm, 9.7 cm, and 9.5 cm respectively,

we need to first calculate the average length and then find the difference of each measurement from the average length.

Then, the absolute error (AL) for each measurement is calculated by taking the absolute value of the difference between the measurement and the average length.

Finally, the average of these absolute errors is taken as the absolute error (AL).

Thus, the absolute error (AL) is given as:

AL = (|9.3 - 9.5| + |9.7 - 9.5| + |9.5 - 9.5|)/3

     = (0.2 + 0.2 + 0)/3

     = 0.13 cm

Therefore, the correct option is

5.0.13.

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The light ray takes approximately 2.25 nanoseconds to travel through the plastic. The index of refraction of the plastic is approximately 1.34. We need to use Snell's law and the equation for the speed of light in a medium.

(i) (a) Determining the index of refraction of the plastic:

Snell's law relates the angles of incidence and refraction to the indices of refraction of the two mediums. The equation is given by:

[tex]n_1[/tex] * sin(θ1) =[tex]n_2[/tex]* sin(θ2)

n1 is the index of refraction of the medium of incidence (in this case, air),

θ1 is the angle of incidence,

n2 is the index of refraction of the medium of refraction (in this case, plastic),

θ2 is the angle of refraction

[tex]n_air[/tex] * sin(47.8°) =[tex]n_{plastic[/tex] * sin(75.7°)

[tex]n_{plastic = (n_{air[/tex] * sin(47.8°)) / sin(75.7°)

The index of refraction of air is approximately 1.00 (since air is close to a vacuum).

[tex]n_plastic[/tex] = (1.00 * sin(47.8°)) / sin(75.7°)

≈ 1.34

Therefore, the index of refraction of the plastic is approximately 1.34.

(b) Determining the time taken for the light ray to travel through the plastic:

The speed of light in a medium can be calculated using the equation:

v = c / n

Where:

v is the speed of light in the medium,

c is the speed of light in a vacuum (approximately 3.00 x 10^8 m/s),

n is the index of refraction of the medium.

v = (3.00 x [tex]10^8[/tex]m/s) / 1.34

To find the time taken, we need to divide the distance traveled by the speed:

t = d / v

Given that the distance traveled through the plastic is 50.0 cm, or 0.50 m:

t = (0.50 m) / [(3.00 x [tex]10^8[/tex]m/s) / 1.34]

Evaluating the expression:

t ≈ 2.25 x[tex]10^-9[/tex]s

Therefore, the light ray takes approximately 2.25 nanoseconds to travel through the plastic.

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The magnitude and direction of the resultant force acting on the body in the given figure can be found using vector addition. We can add the two vectors using the parallelogram law of vector addition and then calculate the magnitude and direction of the resultant force.

Here are the steps to find the magnitude and direction of the resultant force:

Step 1: Draw the vectors .The vectors can be drawn to scale on a piece of paper using a ruler and a protractor. The given vectors in the figure are P and Q.

Step 2: Complete the parallelogram .To add the vectors using the parallelogram law, complete the parallelogram by drawing the other two sides. The completed parallelogram should look like a closed figure with two parallel sides.

Step 3: Draw the resultant vector  Draw the resultant vector, which is the diagonal of the parallelogram that starts from the tail of the first vector and ends at the head of the second vector.

Step 4: Measure the magnitude .Measure the magnitude of the resultant vector using a ruler. The magnitude of the resultant vector is the length of the diagonal of the parallelogram.

Step 5: Measure the direction  Measure the direction of the resultant vector using a protractor. The direction of the resultant vector is the angle between the resultant vector and the horizontal axis.The magnitude and direction of the resultant force acting on the body below is shown in the figure below. We can see that the magnitude of the resultant force is approximately 7.07 N, and the direction is 45° above the horizontal axis.

Therefore, the answer is:

Magnitude = 7.07 N

Direction = 45°

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Atoms and molecules in it are significantly attracted to neighboring atoms and molecules. - a. solids ,Can carry a sound wave - c. liquids ,Takes on the shape of the container - f. liquids and gases ,Retains its own shape and size - a. solids, Takes on the size of the container - g. solids, liquids, and gases,The property of being a fluid is included as "fluids" - f. liquids and gases

Matching the descriptions with the appropriate states of matter:

Atoms and molecules in it are significantly attracted to neighboring atoms and molecules: a. solids

Can carry a sound wave: c. liquids

Takes on the shape of the container: f. liquids and gases

Retains its own shape and size: a. solids

Takes on the size of the container: g. solids, liquids, and gases

The property of being a fluid is included as "fluids": f. liquids and gases

The descriptions of properties of substances are matched with the most appropriate states of matter as follows:

Solids are characterized by significant attraction between atoms and molecules, retaining their own shape and size.

Liquids can carry a sound wave, take on the shape of the container, and are included in the category of fluids.

Gases take on the size of the container and are also included in the category of fluids.

Solids are characterized by significant attractions between atoms and molecules, and they retain their own shape and size. Liquids can carry sound waves, take on the size of the container, and are included in the category of fluids. Gases take on the shape of the container. Both solids and liquids can take on the size of the container.

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The minimum acceleration needed for the plane to take flight is 1.45 m/s² (to 2 decimal places).

Given:To take off, an airplane needs to reach a speed of 215 km/h.

The runway available is 1738 m. To find:

Solution:Let's first convert the speed of 215 km/h to m/s.

1 km = 1000 m

∴ 215 km/h = (215 x 1000) / 3600 m/s

= 59.72 m/s

The equation of motion that relates speed, acceleration, and distance is:v² - u² = 2as

Here,

v = final velocity

u = initial velocity = 0

s = distance = 1738 m

Rearranging the equation, we get

a = (v² - u²) / 2s

Substituting the values,

a = (59.72² - 0²) / 2 x 1738

a = 1.45 m/s²

Therefore, the minimum acceleration needed for the plane to take flight is 1.45 m/s² (to 2 decimal places).

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Since the spacecraft is moving with a constant velocity, the observer on the spacecraft would measure the Earth-based clock's ticking rate to be slower than their own clock. Therefore, the correct answer is (d) It runs at one-third the rate of his own.

An observer on the spacecraft measures that an undamaged clock on the spacecraft is ticking at one-third the rate of an identical clock on the Earth. This means that time appears to be passing more slowly on the spacecraft compared to the Earth.

From the perspective of an observer on the spacecraft, the Earth-based clock would appear to be running slower than their own clock. This is because time dilation occurs when an object is moving at a high velocity relative to another object. The faster an object moves, the slower time appears to pass for that object.

Since the spacecraft is moving with a constant velocity, the observer on the spacecraft would measure the Earth-based clock's ticking rate to be slower than their own clock. Therefore, the correct answer is (d) It runs at one-third the rate of his own.

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The magnitude of the image height will be between 3 and 6 mm.

Thus, the correct option is Between 3 and 6 mm.

Radius of curvature of concave mirror = -20 cmObject distance, u = -5 cmObject height, h = 4 mmFor concave mirror, f = -10 cm, as f = R/2Where R is the radius of curvatureThe focal length of a concave mirror is negative, which means the mirror is concave and reflects the incoming light rays inward toward a focal point.Use the formula,1/f = 1/v + 1/uHere, v = ?1/-10 = 1/v + 1/-5⇒ -1/10 = 1/v - 1/5⇒ 1/v = -1/20⇒ v = -20 cm.

The image distance is -20 cm.Now, using the magnification formula,m = -v/u = -(-20)/(-5) = -4m = -v/uThe negative sign indicates that the image is inverted. The magnitude of the image height will be between 3 and 6 mm.Thus, the correct option is Between 3 and 6 mm.

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The impedance of the circuit is approximately 13.68 kΩ.

To calculate the frequency of the source in radians per second, we can use the formula:

ω = 2πf

where ω is the angular frequency in radians per second and f is the frequency in hertz.

Given that the frequency is 3000 Hz, we can calculate the angular frequency as follows:

ω = 2π * 3000 Hz

  = 6000π rad/s

Therefore, the frequency of the source in radians per second is 6000π rad/s.

To calculate the resonant frequency of the circuit, we can use the formula:

f_res = 1 / (2π√(LC))

where f_res is the resonant frequency, L is the inductance, and C is the capacitance.

Given that the capacitance is 2000 pF (picoFarad) and the inductance is 3 mH (milliHenry), we need to convert the units to Farads and Henrys respectively:

C = 2000 pF = 2000 * 10^(-12) F

L = 3 mH = 3 * 10^(-3) H

Now we can calculate the resonant frequency:

f_res = 1 / (2π√(3 * 10^(-3) * 2000 * 10^(-12)))

      ≈ 212.20 kHz

Therefore, the resonant frequency of the circuit is approximately 212.20 kHz.

The inductive reactance (XL) of the circuit is given by the formula:

XL = ωL

where XL is the inductive reactance, ω is the angular frequency, and L is the inductance.

Given that the inductance is 3 mH and the angular frequency is 6000π rad/s, we can calculate the inductive reactance:

XL = (6000π rad/s) * (3 * 10^(-3) H)

    ≈ 56.55 Ω

Therefore, the inductive reactance of the circuit is approximately 56.55 Ω.

The capacitive reactance (XC) of the circuit is given by the formula:

XC = 1 / (ωC)

where XC is the capacitive reactance, ω is the angular frequency, and C is the capacitance.

Given that the capacitance is 2000 pF and the angular frequency is 6000π rad/s, we can calculate the capacitive reactance:

XC = 1 / ((6000π rad/s) * (2000 * 10^(-12) F))

    ≈ 26.53 kΩ

Therefore, the capacitive reactance of the circuit is approximately 26.53 kΩ.

The impedance (Z) of the circuit is given by the formula:

Z = √(R^2 + (XL - XC)^2)

where Z is the impedance, R is the resistance, XL is the inductive reactance, and XC is the capacitive reactance.

Given that the resistance is 170 Ω, the inductive reactance is 56.55 Ω, and the capacitive reactance is 26.53 kΩ, we can calculate the impedance:

Z = √((170 Ω)^2 + (56.55 Ω - 26.53 kΩ)^2)

    ≈ 13.68 kΩ

Therefore, the impedance of the circuit is approximately 13.68 kΩ.

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The speed of sound in water is 1.53 x 103 m s-1. An ultrasonic pulse from an echo sounder is observed to return to a boat after 0.200 s.

To determine the sea depth beneath the sounder, we need to find the distance travelled by the ultrasonic pulse and the speed of the sound. Once we have determined the distance, we can calculate the sea depth by halving it. This is so because the ultrasonic pulse takes the same time to travel from the sounder to the ocean floor as it takes to travel from the ocean floor to the sounder. We are provided with speed of sound in water which is 1.53 x 10³ m/s.We know that speed = distance / time.

Rearranging the formula for distance:distance = speed × time. Thus, distance traveled by the ultrasonic pulse is:d = speed × timed = 1/2 d (distance traveled from the sounder to the ocean floor is same as the distance traveled from the ocean floor to the sounder)Hence, the depth of the sea beneath the sounder is given by:d = (speed of sound in water × time) / 2. Substituting the given values:speed of sound in water = 1.53 x 103 m s-1, time taken = 0.200 s. Therefore,d = (1.53 × 10³ m/s × 0.200 s) / 2d = 153 m. Therefore, the sea depth beneath the sounder is 153 m.Option (c) is correct.

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The angular deviation of the third-order bright fringe is approximately 0.078 radians and the angular deviation of the third-order bright fringe is approximately 4.47 degrees.

To calculate the angular deviation of the third-order bright fringe,

we can use the formula for the angular position of the bright fringes in a double-slit interference pattern:

(a) In radians:

θ = λ / d

where θ is the angular deviation,

λ is the wavelength of the light,

and d is the distance between the slits.

Given:

λ = 574 nm = 574 × 10^(-9) m

d = 7.35 μm = 7.35 × 10^(-6) m

Substituting these values into the formula, we get:

θ = (574 × 10^(-9) m) / (7.35 × 10^(-6) m)

  ≈ 0.078 radians

Therefore, the angular deviation of the third-order bright fringe is approximately 0.078 radians.

(b) To convert this value to degrees, we can use the fact that 1 radian is equal to 180/π degrees:

θ_degrees = θ × (180/π)

          ≈ 0.078 × (180/π)

          ≈ 4.47 degrees

Therefore, the angular deviation of the third-order bright fringe is approximately 4.47 degrees.

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The time taken by the hammer to fall from the edge of the roof to the ground is 2.03 seconds. and the horizontal distance travelled by the hammer from the edge of the roof until it hits the ground is 23.9 m.

Given, Length of the roof, L = 60.5 m

Angle of the roof, α = 15.0°

Acceleration of the hammer, a = 2.54 m/s²

Height fallen by the hammer, h = 40.0 m

(a) Time taken by the hammer to fall from the edge of the roof to the ground can be calculated as follows:

The velocity of the hammer at the edge of the roof can be calculated by using the formula:

v² - u² = 2 as Where v is the final velocity of the hammer, u is the initial velocity of the hammer,

a is the acceleration of the hammer, and

s is the distance covered by the hammer.

The initial velocity of the hammer, u is zero since it is released from rest.

Also, the distance covered by the hammer s = L sin α.

Here, α is the angle of the roof with respect to the horizontal.

v² = 2as = 2 × 2.54 m/s² × 60.5 m × sin 15.0°= 46.5 m²/s²v = √46.5 m²/s²= 6.81 m/s

The hammer falls a distance of h = 40.0 m.

We can use the formula for displacement of a body under free fall to calculate the time taken by the hammer to hit the ground.

h = 1/2 gt²gt² = 2hh = gt²t² = 2h/gt = √(2h/g)t = √(2 × 40.0 m/9.81 m/s²)= 2.03 s

Therefore, the time taken by the hammer to fall from the edge of the roof to the ground is 2.03 seconds.

(b) The horizontal distance travelled by the hammer can be calculated by using the formula:

s = ut + 1/2 at² Where

s is the horizontal distance travelled by the hammer,

u is the horizontal velocity of the hammer,

t is the time taken by the hammer to fall from the edge of the roof to the ground and a is the acceleration of the hammer.

s = ut + 1/2 at²

The horizontal velocity of the hammer,

u = v cos α= 6.81 m/s × cos 15.0°= 6.50 m/st = 2.03 s∴s = ut + 1/2 at²= 6.50 m/s × 2.03 s + 1/2 × 2.54 m/s² × (2.03 s)²= 13.2 m + 10.7 m= 23.9 m

Therefore, the horizontal distance travelled by the hammer from the edge of the roof until it hits the ground is 23.9 m.

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To show that the Fourier transform of a function f(x-x0) differs from F[f(x)] only by a linear phase factor, we can use the shift theorem of Fourier transforms.

The shift theorem states that if F[f(x)] is the Fourier transform of a function f(x), then the Fourier transform of f(x - xo) is given by:

F[f(x - xo)] = e^(-i2πxoω) * F[f(x)]

where e^(-i2πxoω) is the linear phase factor introduced by the shift.

Let's denote F[f(x)] as Ff(x) for simplicity. Now we can substitute this expression into the shift theorem:

F[f(x - xo)] = e^(-i2πxoω) * Ff(x)

This shows that the Fourier transform of f(x - xo) differs from Ff(x) only by the linear phase factor e^(-i2πxoω). Therefore, the two Fourier transforms are related by this linear phase factor.

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Tread patterns on tires, the frictional force on the rear tire is in the backward direction, providing the necessary traction for the bicycle to move forward. And directional tires, designed with specific tread patterns to channel water away from the center of the tire, perform better than non-directional tires in wet weather.

Statement (A) is true. When a bicycle is accelerating along a straight line, the frictional force acting on the front tire is in the forward direction, opposite to the direction of motion.

Statement (B) is true. Tires with tread patterns provide better traction on the road in dry weather compared to tires without tread. The tread patterns help to increase the surface area of contact between the tire and the road, improving grip and reducing the likelihood of slipping.

Statement (C) is also true. The directional tread patterns enhance water dispersion, reducing the risk of hydroplaning and improving traction on wet surfaces.

Therefore, the correct answer is (D) Both (A) and (C) are true.

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the velocity of the object 4.8 m away from its initial position, under the influence of a 3.2 N force, is approximately 1.989 m/s.

To find the velocity of an object moving under the influence of a constant force, we can use Newton's second law of motion, which states that the force acting on an object is equal to the mass of the object multiplied by its acceleration.

Force (F) = 3.2 N

Mass (m) = 9.8 kg

Distance (d) = 4.8 m

F = m * a

a = F / m

a = 3.2 N / 9.8 kg

a ≈ 0.3265 m/s²

v² = u² + 2 * a * d

v² = 2 * a * d

v² = 2 * 0.3265 m/s² * 4.8 m

v² ≈ 3.96 m²/s²

v ≈ √3.96 m/s

v ≈ 1.989 m/s

Therefore, the velocity of the object 4.8 m away from its initial position, under the influence of a 3.2 N force, is approximately 1.989 m/s.

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The power delivered to the headlights varies by approximately 32.25% as the voltage changes from 12 V to 13.8 V, assuming the headlight resistance remains constant.

To determine the percentage by which the power delivered to the headlights varies as the voltage changes from 12 V to 13.8 V, we can use the formula for power:

Power = (Voltage²) / Resistance

Given that the headlight resistance remains constant, we can compare the powers at the two different voltages.

At 12 V:

Power_12V = (12^2) / Resistance = 144 / Resistance

At 13.8 V:

Power_13.8V = (13.8^2) / Resistance = 190.44 / Resistance

To calculate the percentage change, we can use the following formula:

Percentage Change = (New Value - Old Value) / Old Value × 100

Percentage Change = (Power_13.8V - Power_12V) / Power_12V × 100

Substituting the values:

Percentage Change = (190.44 / Resistance - 144 / Resistance) / (144 / Resistance) × 100

Simplifying:

Percentage Change = (190.44 - 144) / 144 * 100

Percentage Change = 46.44 / 144 * 100

Percentage Change ≈ 32.25%

Therefore, the power delivered to the headlights varies by approximately 32.25% as the voltage changes from 12 V to 13.8 V, assuming the headlight resistance remains constant.

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The emf induced in a coil by the change in magnetic flux within a uniform magnetic field is given by the formula, emf = −N(dΦ/dt), where N is the number of turns in the coil, and dΦ/dt is the rate of change of the magnetic flux that threads through each turn of the coil.

The negative sign indicates the direction of the induced emf, which follows Lenz’s Law. In this case, we have a coil wrapped with 139 turns of wire around the perimeter of a circular frame (radius = 2 cm), and a uniform magnetic field perpendicular to the plane of the coil that changes at a constant rate of 20 to 80 mT in a time of 7 ms.

The area of each turn of wire is equal to the area of the circular frame, and the magnitude of the magnetic field at the instant of interest is 50 mT. Therefore, we can calculate the induced emf using the formula above as follows: emf = −N(dΦ/dt)Given: N = 139 turns, r = 2 cm = 0.02 m, A = πr² = π(0.02 m)² = 0.00126 m², dB/dt = (80 − 20)/(7 × 10⁻³ s) = 8571.43 T/s, and B = 50 mT = 0.05 T.∴ Φ = BA = (0.05 T)(0.00126 m²) = 6.3 × 10⁻⁴ Wb

Therefore, the induced emf in the coil at the instant the magnetic field has a magnitude of 50 mT is given by emf = −N(dΦ/dt)= −(139)(8571.43 T/s) = -1.19 × 10⁶ V.

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For an object positioned 30 cm from the lens and a lens with a focal length of 10 cm, the image is inverted, real, and located 15 cm away from the lens on the opposite side of the object.

The given details are:An object is placed at a distance of 30 cm from a converging lens that has a focal length of 10 cm. Let us try to solve the problem by using ray tracing. The process of ray tracing is a geometrical method for identifying the image position formed by a lens. It's also used to check the size and nature of the image.The following is the step-by-step ray tracing method:

1: Use a ruler and a pencil to draw a straight line on the optical axis. This represents the primary axis of the lens.

2: Draw the two focal points F1 and F2 on the axis with a ruler. For a converging lens, the focal point F1 is situated to the left of the lens. F2 is located on the right side of the lens. For a diverging lens, the opposite is true.

3: Draw an object, AB, located on the left of the lens and perpendicular to the optical axis. Draw an arrowhead to show the direction of light's travel.

4: Draw a straight line from the top of the object to the lens. This line, which starts at the top of the object, is the incident ray.

5: From the object's base, draw another straight line to the lens. This line, which originates at the object's base, is the principal axis.

6: Draw a line from the top of the object parallel to the principal axis, which intersects the incident ray as it passes through the lens. This line is the refracted ray.

7: Draw a line from the intersection point of the refracted ray and the principal axis to F2. This line represents the extended refracted ray.Step 8: Draw a dotted line from the top of the object through the lens and then to the other side of the lens, forming an image. The image will be inverted as per the laws of reflection and the properties of the lens.

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Without vision correction, the student can see clearly up to 3.04 meters as her farthest distance. The farthest distance (far point) that a person with contact lenses can see clearly without vision correction is the focal point of the lens.

To determine the farthest distance (far point) that the student can see clearly without vision correction, we need to use the concept of focal length and the formula:

Far point distance = 1 / (focal length)

The focal length can be calculated using the formula:

Focal length = 1 / (diopters)

Given that the prescription for the contact lenses is -3.04 diopters, we can calculate the focal length as follows:

Focal length = 1 / (-3.04) ≈ -0.3289 meters (Note: Diopters have units of reciprocal meters)

To find the farthest distance, we can substitute the focal length into the formula:

Far point distance = 1 / (-0.3289) = -3.04 meters

However, distance cannot be negative, so we take the absolute value of the result:

Far point distance 3.04 meters

Therefore, without vision correction, the student can see clearly up to 3.04 meters as her farthest distance.

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d ≈ 3.88427 × 10^(-6) m. To determine the distance d between the two slits in a double-slit experiment, we can use the formula for fringe spacing in interference patterns.

Given that there are 11 bright and dark fringes per centimeter on a screen located 8.60 m away, and the incident light has a wavelength of 550 nm, we can calculate the distance d between the slits.

The fringe spacing in an interference pattern is given by the formula:

Δy = λL / d

where Δy is the fringe spacing (distance between adjacent bright or dark fringes), λ is the wavelength of the incident light, L is the distance from the double-slit to the screen, and d is the distance between the slits.

We need to convert the fringe spacing from centimeters to meters, so we divide the given value of 11 fringes per centimeter by 100 to obtain the value in meters:

Δy = (11 fringes/cm) / (100 cm/m) = 0.11 m.

Substituting the values into the formula, we have:

0.11 m = (550 nm) * (8.60 m) / d

To solve for d, we rearrange the equation:

d = (550 nm) * (8.60 m) / 0.11 m

d ≈ 3.88427 × 10^(-6) m

Performing the calculation yields the value for d ≈ 3.88427 × 10^(-6) m.

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(a) The magnitude of the current required to remove the tension in the supporting leads is approximately 2.92 A.

(b) The direction of the current should be from right to left.

(a) We can use the equation that relates the magnetic force experienced by a current-carrying wire in a magnetic field to the length of the wire, the magnetic field strength, and the current flowing through the wire. The formula is given as F = BIL, where F is the force, B is the magnetic field strength, I is the current, and L is the length of the wire. In this case, we are looking for the current, so we can rearrange the formula as I = F / (BL). The tension in the supporting leads must be equal to the weight of the wire, which is given by the formula weight = mass × gravity. Plugging in the values and solving for the current, we find that the magnitude of the current required is approximately 2.92 A.

(b) The direction of the current can be determined using the right-hand rule. By convention, the direction of the magnetic field is into the page, and the force experienced by a current-carrying wire is perpendicular to both the magnetic field and the current. Applying the right-hand rule, with the thumb pointing in the direction of the magnetic field (into the page) and the fingers pointing in the direction of the current, we find that the current should flow from right to left in order to remove the tension in the supporting leads.

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a. The density of lead at 90 degrees Celsius in SI units is [tex]36 kg / (V0 + (36 kg / (11.3 x 10^3 kg/m³) * (29 x 10^-6 K^-1) * 363.15 K)[/tex]

b.  Mass of the lead sample at 90 degrees Celsius is ρ * (V0 + ΔV)

To solve this problem, we can use the formula for volumetric expansion to find the new density and mass of the lead sample at 90 degrees Celsius.

(a) Density of lead at 90 degrees Celsius:

The formula for volumetric expansion is:

[tex]ΔV = V0 * β * ΔT[/tex]

where ΔV is the change in volume, V0 is the initial volume, β is the coefficient of linear expansion, and ΔT is the change in temperature.

We can rearrange the formula to solve for the change in volume:

[tex]ΔV = V0 * β * ΔT[/tex]

[tex]ΔV = (m / ρ0) * β * ΔT[/tex]

where m is the mass of the sample and ρ0 is the initial density.

The new volume V is given by:

[tex]V = V0 + ΔV[/tex]

The new density ρ can be calculated as:

ρ = m / V

Substituting the expression for ΔV:

[tex]ρ = m / (V0 + (m / ρ0) * β * ΔT)[/tex]

m = 36 kg

[tex]ρ0 = 11.3 x 10^3 kg/m³[/tex]

[tex]β = 29 x 10^-6 K^-1[/tex]

[tex]ΔT = (90 - 0) = 90 degrees Celsius[/tex]

Converting ΔT to Kelvin:

[tex]ΔT = 90 + 273.15 = 363.15 K[/tex]

Substituting the values:

[tex]ρ = 36 kg / (V0 + (36 kg / (11.3 x 10^3 kg/m³) * (29 x 10^-6 K^-1) * 363.15 K)[/tex]

Calculating this expression will give us the density of lead at 90 degrees Celsius in SI units.

(b) Mass of the lead sample at 90 degrees Celsius:

To find the mass at 90 degrees Celsius, we can use the equation:

[tex]m = ρ * V[/tex]

Substituting the values:

[tex]m = ρ * (V0 + ΔV)[/tex]

We already calculated ρ and ΔV in part (a).

Calculating this expression will give us the mass of the lead sample at 90 degrees Celsius in SI units.

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Given:

Charge q = +5 µC = 5 × 10⁻⁶ C

Velocity of charge, v = 200 m/s

Magnetic field strength, B = 7 × 10⁻⁵ T

Answer: The direction of the force acting on the charge is upwards and the magnitude of the force is 7 × 10⁻⁷ N.

To determine:

The direction and magnitude of the force acting on the charge.

Sketch the scenario using right-hand rule. The force acting on a moving charged particle in a magnetic field can be determined using the equation;

F = qvBsinθ

Where, q is the charge of the

is the velocity of the particle

B is the magnetic field strength

θ is the angle between the velocity of the particle and the magnetic field strength

In this problem, the magnetic field is pointing out of the board. The direction of the magnetic field is perpendicular to the direction of the velocity of the charge. Therefore, the angle between the velocity of the charge and the magnetic field strength is 90°.

sin90° = 1

Putting the values of q, v, B, and sinθ in the above equation,

F= 5 × 10⁻⁶ × 200 × 7 × 10⁻⁵ × 1

= 7 × 10⁻⁷ N

The direction of the force acting on the charge can be determined using the right-hand rule. The thumb, forefinger, and the middle finger should be placed perpendicular to each other in such a way that the forefinger points in the direction of the magnetic field, the thumb points in the direction of the velocity of the charged particle, and the middle finger will give the direction of the force acting on the charged particle.

As per the right-hand rule, the direction of the force is upwards. Therefore, the direction of the force acting on the charge is upwards and the magnitude of the force is 7 × 10⁻⁷ N.

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The work required to move the charges closer together is -1.39 × 10^-18 J (negative because work is done against the electric force).

Given that, Two identical point charges of q = +2.25 x 10-8 C are separated by a distance of 0.85 m.

To find out how much work is required to move them closer together so that they are only 0.40 m apart. So,initial separation between charges = r1 = 0.85 m final separation between charges = r2 = 0.40 mq = +2.25 x 10^-8 C

The potential energy of a system of two point charges can be expressed using the formula as,

U = k * (q1 * q2) / r

where,U is the potential energy

k is Coulomb's constantq1 and q2 are point charges

r is the separation between the two charges

To find the work done, we need to subtract the initial potential energy from the final potential energy, i.e,W = U2 - U1where,W is the work doneU1 is the initial potential energyU2 is the final potential energy

Charge on each point q = +2.25 x 10^-8 C

Coulomb's constant k = 9 * 10^9 N.m^2/C^2

The initial separation between the charges r1 = 0.85 m

The final separation between the charges r2 = 0.40 m

The work done to move the charges closer together is,W = U2 - U1

Initial potential energy U1U1 = k * (q1 * q2) / r1U1 = 9 * 10^9 * (2.25 x 10^-8)^2 / 0.85U1 = 4.2 * 10^-18 J

Final potential energy U2U2 = k * (q1 * q2) / r2U2 = 9 * 10^9 * (2.25 x 10^-8)^2 / 0.4U2 = 2.81 * 10^-18 J

Work done W = U2 - U1W = 2.81 * 10^-18 - 4.2 * 10^-18W = -1.39 * 10^-18 J

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The velocity of the object after 10 seconds is -70 m/s. The angle of reflection depends on the angle of incidence and the refractive indices of the media involved (in this case, water and air). Without the necessary information, we cannot determine the exact angle of the reflected beam.

To calculate the velocity of the object after 10 seconds, we need to find the derivative of the position function with respect to time.

Given: y = -4t² + 10t + 50

Taking the derivative of y with respect to t:

dy/dt = -8t + 10

Now we can substitute t = 10 into the derivative to find the velocity at t = 10 seconds:

dy/dt = -8(10) + 10

= -80 + 10

= -70 m/s

Therefore, the velocity of the object after 10 seconds is -70 m/s.

For the second part of your question about the angle of the reflected light beam, more information is needed. The angle of reflection depends on the angle of incidence and the refractive indices of the media involved (in this case, water and air). Without the necessary information, we cannot determine the exact angle of the reflected beam.

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The total resistance is  Req = 2R1 = 2 * 26184 = 52368 Ω

The total energy cost of cooking Sunday lunches in the month is R1.05.

the diameter of the cylindrical wire is approximately 2.12 mm.

(a) When resistors are connected in parallel, the equivalent resistance (Req) is given by the inverse of the sum of the inverses of the individual resistances (R1 and R2). Mathematically, it can be expressed as:

1/Req = 1/R1 + 1/R2 = 1/13092

Since R1 and R2 are identical resistors, we can simplify the equation to:

2/R1 = 1/13092

From this, we can solve for the individual resistance R1:

R1 = 2 * 13092 = 26184 Ω

When identical resistors are connected in series, the total resistance (Req) is equal to the sum of the individual resistances. In this case, since we have two identical resistors, the total resistance is:

Req = 2R1 = 2 * 26184 = 52368 Ω

(b). The power consumed by the stove is given by the product of current (I) and voltage (V). Therefore, the power (P) can be calculated as:

P = IV = 12 * 250 = 3000 W

Assuming the time taken to cook Sunday lunch is 3.5 hours, the energy consumed (E) in one Sunday is:

E = Pt = 3000 * 3.5 = 10500 Wh or 10.5 kWh

If 6000 kWh of energy is bought for R150, the energy cost per kWh is:

Cost per kWh = 150/6000 = 0.025

Hence, the energy cost of cooking on Sunday is:

Energy cost = E * Cost per kWh = 10.5 * 0.025 = 0.2625

The total energy cost of cooking on Sundays in the month (assuming 4 Sundays) is:

Total energy cost = 4 * 0.2625 = 1.05

Therefore, the total energy cost of cooking Sunday lunches in the month is R1.05.

(c) The current density (J) is given by the ratio of current (I) and cross-sectional area (A). Mathematically, it can be expressed as:

J = I/A

The area (A) of a wire is given by the formula A = πr^2, where r is the radius of the wire. Thus, the current density can be written as:

J = I/(πr^2)

To find the current density in Amperes per square meter (A/m^2), we need to convert from Amperes per square centimeter (A/cm^2). Given that the current density rises to 440 A/cm^2, we have:

J = 440 A/cm^2 = 440 * 10^4 A/m^2

The area of a wire of unit length (1 m) is given by πr^2. Therefore, we can rewrite the equation as:

440 * 10^4 A/m^2 = I/(πr^2)

Simplifying, we have:

πr^2 = I/(440 * 10^4 A/m^2) = 0.5/440

Solving for the radius (r), we find:

r = √(0.0011364/π) ≈ 1.06 × 10^-3 m or 1.06 mm

Therefore, the diameter of the cylindrical wire is approximately 2.12 mm.

(d) The force (F) experienced by a proton in a magnetic field is given by the formula F = qvB, where q is the charge of the proton, v is its velocity, and B is the magnetic field

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To calculate the resistance of the computer, we can use Ohm's law:

V = IR

where V is the voltage, I is the current, and R is the resistance.

In this case, the voltage is 110V and the current is 3.5A. Substituting these values into the equation gives:

110V = 3.5A * R

Solving for R, we get:

R = 110V / 3.5A

R ≈ 31.43 Ω

Therefore, the resistance of the computer is approximately 31.43 ohms (Ω).

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The need to consider the conservation of mechanical energy. Initially, all the energy is stored in the spring as potential energy, and when the box leaves the spring, it converts into kinetic energy.

The box will travel approximately 2.97 meters up the ramp. a) To find the velocity of the box as it leaves the spring, we can use the conservation of mechanical energy.

The initial potential energy stored in the spring is equal to the final kinetic energy of the box.

Initial potential energy (Uspring) = Final kinetic energy (Kfinal)

Uspring = Kfinal

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

Uspring = (1/2)kx^2

where k is the spring constant and x is the compression of the spring

Uspring = (1/2)kx^2

Uspring = (1/2)(200 N/m)(0.659 m)^2

Uspring = 43.837 J

v = sqrt((2 * Uspring) / m)

v = sqrt((2 * 43.837 J) / 3 kg)

v ≈ 7.82 m/s

Therefore, the box is traveling at approximately 7.82 m/s the moment it leaves the spring.

b) To determine how high up the ramp the box will travel, we need to consider the work done against friction. The work done against friction is equal to the energy dissipated:

Work against friction = Energy dissipated

The force of friction can be calculated using the equation:

Force of friction = μ * m * g

The initial kinetic energy is given by:

Kinitial = (1/2)mv^2

The final potential energy is given by:

Ufinal = m * g * h

h = (Kinitial + Work against friction) / (m * g)

h = ((1/2) * 3 kg * (7.82 m/s)^2 + 12.25 J) / (3 kg * 9.8 m/s^2)

h ≈ 2.97 m

Therefore, the box will travel approximately 2.97 meters up the ramp.

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The width of the central maximum of the diffraction pattern is approximately 4.82 cm.

The width of the central maximum of a diffraction pattern can be determined using the formula:

w = (λ * D) / d

where:

w is the width of the central maximum,

λ is the wavelength of light,

D is the distance between the slit and the screen, and

d is the width of the slit.

In this case, the width of the slit is given as 75.1 μm (or 75.1 × 10^(-6) m) and the wavelength of light is 727 nm (or 727 × 10^(-9) m). The distance between the slit and the screen is 2.23 m.

Substituting these values into the formula:

w = (727 × 10^(-9) m * 2.23 m) / (75.1 × 10^(-6) m)

Simplifying the expression:

w = (1.62 × 10^(-6) m * 2.23 m) / (75.1 × 10^(-6) m)

≈ 0.0482 m

Converting the width to centimeters:

w ≈ 0.0482 m * 100 cm/m

≈ 4.82 cm

Therefore, the width of the central maximum of the diffraction pattern is approximately 4.82 centimeters.

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When a string is tightened on a guitar or violin, it increases the tension, linear mass density, wave speed and frequency of the vibration in the string. Therefore, option DO is the correct answer.

Vibration is an oscillating motion about an equilibrium point. A simple harmonic motion, like vibration, takes place when the motion is periodic and the restoring force is proportional to the displacement of the object from its equilibrium position. Frequency is defined as the number of cycles per unit time. It is typically measured in hertz (Hz), which is one cycle per second. The higher the frequency of a wave, the more compressed its waves are and the higher its pitch is. linear mass Density is the measure of mass per unit length. When the linear mass density is increased, the wave speed in the string increases, and its frequency also increases as frequency is directly proportional to the wave speed and inversely proportional to the wavelength. So, tightening a string on a guitar or violin causes an increase in tension, linear mass density, wave speed, and frequency of the vibration in the string.

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