A 415kg satellite orbiting the earth experiences 215N of gravitational force from the Earth. (RE=6.38x106m, ME=5.97x1024kg). What is the potential energy of the satellite relative to the Earth's surface?

Answer:

jogger:  6 km

boat:  5 km

Explanation:

1/2 hr = 0.5 hr

distance = rate x time

jogger:  d = rt = (12 km/hr)(0.50 hr) = 6 km

boat:  d = (10 km/hr)(0.50 hr) = 5 km

The gas temperature is approximately 608.76 K.

To find the gas temperature, we'll use the ideal gas law, which is given by the equation:
PV = nRT
where P is pressure, V is volume, n is the number of moles, R is the gas constant, and T is temperature. We are given the following information:

- Volume (V) = 2.00 L
- Number of moles (n) = 0.5 mol
- Pressure (P) = 12.5 atm
- Gas constant (R) = 0.0821 L×atm/mol×K

We need to solve for the temperature (T). Using the given values, the equation becomes:

12.5 atm × 2.00 L = 0.5 mol × 0.0821 L×atm/mol×K × T

Now, we can solve for T:

25.00 L×atm = 0.04105 L×atm/mol×K × T

To find T, divide both sides by 0.04105 L×atm/mol×K:

T = 25.00 L×atm / 0.04105 L×atm/mol×K ≈ 608.76 K

The temperature of the gas is roughly 608.76 K.

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Answer:Neither red, green, nor blue

Explanation: It is because it is light not paint that absorbs colour.

If you illuminate red paint with pure blue light, then Black color will that paint appear. Hence option D is correct.

Visible light spectrum is nothing but the range of wavelength of radiation from 4000 angstrom to 7000 angstrom(Violet to Red). light is a energy packet. Every Photon having different wavelength travels with same velocity c (velocity of light). When we focus numbers of colors from visible spectrum to a point, that point appears as a white light. hence white light is composed of numbers of Colors in it.

a red paint absorbs blue and green light therefore it is appear to be black.

Hence option D is correct.

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When the length of a simple pendulum is decreased by 600 mm, the period of oscillation is halved. The original length of the pendulum should be 800 mm. The right option is A.

The period of oscillation of a simple pendulum is the time it takes for the pendulum to complete one full cycle of motion.

The period is determined by the length of the pendulum, with longer pendulums having longer periods.

The relationship between the period and the length of a simple pendulum is given by the equation

T = 2π√(L/g),

where T is the period, L is the length of the pendulum, and g is the acceleration due to gravity.

In this problem, we are told that when the length of the pendulum is decreased by 600 mm, the period of oscillation is halved.

Let's assume that the original length of the pendulum is L and the new length is

L - 600.

Using the equation above, we can set up the following relationship between the two lengths and periods:

[tex]2\pi \sqrt(L/g) = (1/2) \times 2\pi \sqrt((L - 600)/g)[/tex]

Simplifying this equation, we get:

[tex]\sqrt L = (1/2) \times \sqrt(L - 600)[/tex]

Squaring both sides of the equation, we get:

L = 4(L - 600)

Solving for L, we get:

L = 800 mm

Therefore, the original length of the pendulum was 800 mm. The right answer is A.

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The efficiency of a heat engine is calculated by the η =  (1₋T₂)/T₁).  The efficiency is 3.3%.

The efficiency of the heat engine was identified with the help of Carnot's engine. The Carnot's engine gives the efficiency of the engine, in which heat energy flows from the hot reservoir to the cold reservoir.

The efficiency is:

η =  (1₋T₂)/T₁)

T₂ (cold temperature) = 4000J

T₁ (hot temperature) = 6000 J

η = (1 - 4000)/ 6000

  = (6000 - 4000) / 6000

  = 2000 /6000 = 0.33

   = 0.33×100

   = 3.3 %

Thus, the efficiency of the heat engine is 3.3%.

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Between points II and III  E is zero and must be closer to the smaller charge to make up for the weaker field. The correct option is (C).

The electric field due to the charges is a vector sum of the fields due to each charge. The electric field vectors due to the charges are directed away from each other, so there must be at least one point on the line where the field is zero. The electric field is proportional to the inverse square of the distance from the charges, so the field becomes weaker as the distance increases

To determine the range where the electric field strength is zero, we need to consider the electric field vectors due to the two charges at different points on the line. The electric field due to a point charge varies as 1/r^2, where r is the distance from the charge. At a point on the line to the left of charge, I, the electric field vectors due to both charges point in the same direction, so the resultant electric field is non-zero. So, option A is not true.

At a point on the line between charges I and II, the electric field vectors point in opposite directions, which means that there is a point where the electric field due to the two charges cancels out and is zero. So, option B could be a possible answer, but relevant to the Question.

At a point on the line between charges II and III, the electric field vectors still point in opposite directions, but the electric field due to the smaller charge (2q) is weaker than the electric field due to the larger charge (3q). Therefore, the point where the electric field is zero must be closer to the smaller charge to make up for the weaker field. So, option C is the correct answer.

At a point on the line to the right of charge III, the electric field vectors due to both charges point in the same direction, so the resultant electric field is non-zero. So, option D is not true.

Finally, it is not true that the electric field is zero only at infinity, as there are many points along the line where the electric field is zero. So, option E is not true.

Therefore, option C is the correct answer.

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The specific heat capacity and thermal conductivity of the material added to it.

Yes, the time it takes for the water to come to an equilibrium temperature can depend on the material added to it. This is because the specific heat capacity of the material added can differ from that of water. Specific heat capacity is the amount of heat energy required to raise the temperature of 1 gram of a substance by 1 degree Celsius.

For example, if a material with a low specific heat capacity, such as a metal spoon, is added to the water, it will heat up quickly and transfer heat energy to the water faster than a material with a higher specific heat capacity, such as a plastic spoon. This means that the water will reach its equilibrium temperature faster when a metal spoon is used compared to a plastic spoon.

Additionally, if the material added to the water is an insulator, such as a styrofoam cup, it will slow down the rate of heat transfer from the water to the environment. This can result in the water taking longer to reach its equilibrium temperature.

Therefore, the time it takes for the water to come to an equilibrium temperature can depend on the specific heat capacity and thermal conductivity of the material added to it.

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In an upstream direction, the push/pull boundaries will be encountered in the reverse order as they appear in the supply chain, moving from the final customer back towards the initial supplier.

To answer your question regarding the correct relative order of push/pull boundary locations moving in an upstream direction:
1. Start at the downstream end of the supply chain.
2. Identify the push/pull boundary closest to the downstream end.
3. Move upstream to the next push/pull boundary in the supply chain.
4. Continue moving upstream, identifying push/pull boundaries in order.
The push/pull boundaries will be encountered travelling from the end client back towards the first supplier in an upward orientation, in the supply chain's reverse sequence.

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In a double-slit interference experiment with electrons, increasing the energy of the electrons can have an effect on the resulting interference pattern.

If the energy of the electrons is increased:

These changes occur because the de Broglie wavelength of the electrons decreases as their energy increases. This means that the electrons behave more like particles and less like waves, which reduces the amount of interference that occurs between them. As a result, the interference pattern becomes less spread out and more intense.

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A car with an initial speed of 113 km/h can coast up a hill of approximately 51.32 meters if the work done by friction is negligible.

If the work done by friction is negligible and a car's initial speed is 113 km/h, the height a car can coast up a hill can be determined using the conservation of mechanical energy principle. The kinetic energy at the bottom of the hill will be converted into gravitational potential energy at the top.

Initial kinetic energy (KE) = 0.5 * m * v^2, where m is the mass of the car and v is the initial speed in meters per second.

To convert 113 km/h to m/s, multiply by (1000 m/km) / (3600 s/h) = 31.389 m/s.

Final gravitational potential energy (PE) = m * g * h, where g is the acceleration due to gravity (approximately 9.81 m/s^2) and h is the height of the hill.

Since KE_initial = PE_final, we have:
0.5 * m * (31.389)^2 = m * 9.81 * h

The mass of the car (m) cancels out, leaving:
0.5 * (31.389)^2 = 9.81 * h

Solving for h, we get:
h ≈ 51.32 meters

So, a car with an initial speed of 113 km/h can coast up a hill of approximately 51.32 meters if the work done by friction is negligible.

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In order to calculate the speed of a uniform solid sphere at the bottom of a 3 m slope, one needs to know the sphere's mass, radius, and acceleration due to gravity.

This is accomplished by applying the principle of conservation of energy, which connects the sphere's potential energy at the top of the incline to its kinetic energy at the bottom of the slope. The requisite parameters may be calculated by equating the two energies and calculating for the velocity of the sphere at the bottom of the slope.

Furthermore, the sphere is supposed to roll without sliding, which means that the velocity of the centre of mass equals the product.

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The source that produces long-lived hazardous wastes is nuclear fission.

The source that produces long-lived hazardous wastes is nuclear fission. During the process of nuclear fission, the nucleus of an atom is split into smaller fragments, releasing a large amount of energy.

This energy is used to generate electricity in nuclear power plants. However, the byproducts of nuclear fission are highly radioactive and can remain dangerous for thousands of years.

These hazardous wastes need to be carefully stored and managed to prevent exposure to humans and the environment.

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The approximate surface temperature of the star is 5796 Kelvin (K). Wien's law states that the wavelength of the peak radiation emitted by an object is inversely proportional to its temperature. This means that as the temperature of an object increases, the peak wavelength of its emitted radiation decreases. Therefore, if a star emits the most radiation at a wavelength of 500 nm, we can use Wien's law to estimate its surface temperature.

We can start by rearranging Wien's law equation to solve for temperature:

T = b / λmax

where T is the temperature, λmax is the wavelength of peak radiation (500 nm in this case), and b is Wien's displacement constant (2.898 x 10^-3 m*K).

First, we need to convert the peak wavelength from nanometers to meters:

λmax = 500 nm = 5 x 10^-7 m

Now, we can plug in the values and solve for the temperature:

T = (2.898 x 10^-3 m*K) / (5 x 10^-7 m)
T = 5796 K

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To find the % composition of the compound, we need to first determine the empirical formula by finding the smallest whole number ratio of atoms present in the compound.

Step 1: Convert the given masses of Mg and N to moles using their respective atomic masses.

Moles of Mg = 9.03 g / 24.31 g/mol = 0.371 mol
Moles of N = 3.48 g / 14.01 g/mol = 0.248 mol

Step 2: Divide both the number of moles by the smallest number of moles obtained to get the simplest whole number ratio.

0.371 mol / 0.248 mol = 1.49 (approx. 1.5)
0.248 mol / 0.248 mol = 1

Therefore, the empirical formula of the compound is Mg3N2.

Step 3: Calculate the total molar mass of the compound.

Mg3N2 = (3 x 24.31 g/mol) + (2 x 14.01 g/mol) = 100.95 g/mol

Step 4: Calculate the % composition of each element in the compound.

% composition of Mg = (3 x 24.31 g/mol) / 100.95 g/mol x 100% = 72.12%
% composition of N = (2 x 14.01 g/mol) / 100.95 g/mol x 100% = 27.88%

Therefore, the % composition of the compound Mg3N2 is 72.12% Mg and 27.88% N.

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A 0.200kg ball is shot out of a toy gun from a height of 3.00m. The gun works by compressing a spring k=175N/m a distance of 0.400m. then the force applied to the ball is 70 N.

Simple harmonic motion is a specific kind of periodic motion of a body that arises from a dynamic equilibrium between an inertial force that is proportional to the body's acceleration away from the static equilibrium position and a restoring force on the moving object that is directly proportional to the magnitude of the object's displacement and acts towards the object's equilibrium position. Oscillating spring perform SHM.

Force applied on the spring is spring constant times distance.

F = kx

Given,

mass m = 0.2 kg

height h = 3 m

k = 175 N/m

x = 0.4 m

The force applied to the ball is,

F = kx

F = 175×0.4

F = 70 N

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Each sphere has a final charge of -4.0 μC after separation.

When two identical conducting spheres touch and then are separated again, they distribute the total charge evenly between them. The final charge on each sphere depends on the initial charges and the ratio of their radii.

Let the initial radius of each sphere be denoted by "r", and the charges on the spheres be denoted by Q1 and Q2, where Q1 is the charge on the 4.0 μC sphere and Q2 is the charge on the -12 μC sphere. The total charge of the system is:

Q = Q1 + Q2 = 4.0 μC - 12 μC = -8.0 μC

When the spheres touch, charge flows between them until they reach the same potential. At this point, the potential of each sphere is:

V = kQ1/r = kQ2/r

After separation, the charge on each sphere can be calculated as follows:

Q1 = (V1/V)Q and Q2 = (V2/V)Q

where V1 and V2 are the potentials of the spheres after separation.

Using the equation for the potential, we have:

V1 = kQ1/r = kQ/r and V2 = kQ2/r = kQ/r

Therefore, the potential of each sphere is the same after separation.

Substituting into the equations for Q1 and Q2, we get:

Q1 = (V1/V)Q = (1/2)Q = -4.0 μC

Q2 = (V2/V)Q = (1/2)Q = -4.0 μC

Therefore, each sphere has a final charge of -4.0 μC after separation.

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Based on the information given, we can use the equation for the motion of a mass on a spring:

x(t) = A*cos(ωt + φ)

where x is the displacement of the mass from its equilibrium position, A is the amplitude (maximum displacement), ω is the angular frequency, and φ is the phase angle.

The angular frequency can be found using:

ω = sqrt(k/m)

where k is the spring constant and m is the mass.

Given that the spring is initially stretched by 0.100 m and the object is released from rest there, we can find the amplitude:

A = 0.100 m

The mass is 1.00 kg, and the spring constant is not given, so we cannot find ω directly. However, we are given that the next time the speed of the object is zero is 0.200 s later. This means that the object goes through one complete oscillation in that time. Therefore, we can use the period of oscillation:

T = 2π/ω

to find ω:

ω = 2π/T = 2π/0.200 s = 31.4 rad/s

Now we can find the maximum speed of the object. At the maximum displacement, the velocity is zero, so we need to find the maximum displacement:

x_max = A = 0.100 m

Then we can use the equation for velocity:

v(t) = -A*ω*sin(ωt + φ)

The maximum speed occurs at t = π/2ω, when the sine function is at its maximum value of 1:

v_max = -A*ω*sin(π/2 + φ) = -A*ω*sinφ

We do not know the phase angle φ, but we can use the fact that the object is released from rest at x = A to set φ = 0:

v_max = -A*ω*sin(0) = 0

Therefore, the maximum speed of the object is 0 m/s.

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The given statement "A braking force is always negative and leads to a decrease in velocity" is true.

The force that slows the car when the driver depresses the brake pedal is known as the braking force.

The given statement is True.

A braking force is a force that opposes the direction of motion and acts to slow down or stop an object. It is always negative in the direction of velocity, which means it acts opposite to the direction of motion. This negative force results in a decrease in velocity, as the force slows down the object or brings it to a stop. Therefore, a braking force always leads to a decrease in velocity.

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An angle of 1 arcsecond is less than the thickness of a human hair held at arm's length.

Arcsecond is a unit of angular measurement, where one degree is divided into 60 minutes, and one minute is further divided into 60 seconds. This means that an angle of 1 arcsecond is a very small angle. It is often used in astronomy to measure the apparent size of celestial objects, as well as their separation.

To put it into perspective, imagine holding a strand of hair at arm's length. The thickness of the hair is likely to be greater than an angle of 1 arcsecond. This small angle is also why telescopes with high angular resolution are necessary to observe fine details of celestial objects.

In summary, an angle of 1 arcsecond is an incredibly small angle, less than the thickness of a human hair held at arm's length. Understanding this unit of measurement is crucial for astronomers to accurately observe and study celestial objects.

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The greatest amount of heat is released by the process called condensation. Hence, option A is correct.

Condensation is the process in which the gaseous state is converted into liquid state. When the air molecules come in contact with the cooler surface, they form liquid and this process is called a condensation reaction.

In a gaseous state, the molecules are said to be free. When they come closer to form a bond with the nearby molecules to form a liquid, the kinetic energy of gaseous molecules decreases. When kinetic energy decreases, they give their energy as heat. The release of heat energy is called the exothermic process.

Condensation releases the most energy compared to others. Thus, option A is correct.

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The athlete has x joules of mechanical energy at the top of the hill, she will also have x joules of mechanical energy at the bottom of the hill, neglecting any losses due to friction or other factors.

Assuming that there is no significant loss of mechanical energy due to friction or other factors, the athlete on the skateboard will have the same amount of mechanical energy at the bottom of the hill as she did at the top. This is due to the law of conservation of mechanical energy, which states that the total amount of mechanical energy in a closed system remains constant.

Mechanical energy is the sum of kinetic energy and potential energy. At the top of the hill, the athlete has only potential energy due to her height above the ground. As she moves downhill, some of this potential energy is converted into kinetic energy as she gains speed. At the bottom of the hill, all of the potential energy has been converted into kinetic energy, but the total amount of mechanical energy is the same as it was at the top.

Therefore, if the athlete has x joules of mechanical energy at the top of the hill, she will also have x joules of mechanical energy at the bottom of the hill, neglecting any losses due to friction or other factors.

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When a beam of electrons is directed at a narrow pair of slits, an interference pattern is observed at a screen behind the double slit. This is due to the wave-like nature of electrons, where they can interfere with each other as they pass through the slits.

The interference pattern consists of alternating bright and dark fringes, with the bright fringes corresponding to constructive interference and the dark fringes corresponding to destructive interference.  This phenomenon is known as the double-slit experiment and demonstrates the wave-particle duality of electrons.

The spacing between the fringes depends on the distance between the slits and the screen, as well as the wavelength of the electrons. This phenomenon is known as electron diffraction and is a fundamental aspect of quantum mechanics.

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Answer: 5 n

Explanation:

If the initial and final positions are different, then the angular displacement would be the difference between the two positions, which could be more or less than 115°.

The angular displacement of an object that has rotated through an angular measure of 115° is also 115°, provided that the initial and final positions of the object are fixed. Angular measure and angular displacement are related but not the same concept.

Angular measure refers to the angle swept by an object as it rotates, measured in degrees, radians, or other units. For example, if an object completes one full rotation, its angular measure is 360° or 2π radians.

Angular displacement, on the other hand, refers to the change in angular position of an object, measured in degrees, radians, or other units. It is calculated as the difference between the final and initial angular positions of the object, and it can be positive, negative, or zero depending on the direction of rotation and the initial and final positions.

In the case of an object that has rotated through an angular measure of 115°, if we assume that its initial and final positions are the same, then its angular displacement is also 115°. However, if the initial and final positions are different, then the angular displacement would be the difference between the two positions, which could be more or less than 115°.

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The performance of their circuits and ensure that they meet the required specifications

Resistors in series share the same current, while resistors in parallel share the same voltage.

In a circuit with resistors connected in series, the same current flows through each resistor because they are connected end-to-end and form a single path for the current to flow. The total resistance of the series circuit is the sum of the individual resistances, and the voltage across each resistor is proportional to its resistance.

In contrast, resistors connected in parallel have the same voltage across each resistor because they are connected across the same two points of the circuit. The total resistance of the parallel circuit is calculated using the reciprocal of the sum of the reciprocals of the individual resistances. The current through each resistor is proportional to its resistance.

These fundamental principles are used in the analysis and design of electronic circuits to determine the current, voltage, power, and other characteristics of the circuit components. By understanding how resistors behave in series and parallel configurations, circuit designers can optimize the performance of their circuits and ensure that they meet the required specifications.

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The watch will be off by the proper amount of time due to travel of sound.

If you set your watch by the sound of the noon whistle from a factory 3 km away, your watch will be behind the correct time. This is because sound travels at a speed of approximately 343 meters per second in air, and it takes time for the sound of the whistle to reach your ears.

Therefore, the sound of the whistle will take approximately 8.74 seconds to reach you (since 3 km = 3000 meters, and 3000/343 = 8.74). By the time you hear the whistle, it will be 8.74 seconds after noon, and if you set your watch at that moment, it will be 8.74 seconds behind the correct time.

To avoid this error, you would need to be closer to the factory, or use a more accurate time signal, such as a radio signal or an atomic clock.

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The COP (Coefficient of Performance) of a refrigerator is defined as the ratio of heat transferred from the cold reservoir to the work input. In this case, the actual refrigerator requires 1 kW of power to transfer 2 kW of heat energy from a low-temperature space to a hot-temperature space therefore, the COP of the refrigerator operating on the reversed Carnot cycle will be 0.934.

To calculate the COP of the refrigerator operating on the reversed Carnot cycle, we need to consider the efficiency of the Carnot cycle.

The Carnot cycle is a theoretical thermodynamic cycle that operates between two heat reservoirs and provides the maximum possible efficiency for a heat engine or refrigerator.

The efficiency of the Carnot cycle is given by the formula:

Efficiency = 1 - (Tc/Th)

where Tc is the temperature of the cold reservoir and Th is the temperature of the hot reservoir.

Since we know that the refrigerator transfers 2 kW of heat energy from the low-temperature space to the high-temperature space, we can assume that the cold reservoir temperature is 10°C and the hot reservoir temperature is 30°C.

Therefore, the efficiency of the Carnot cycle is:

Efficiency = 1 - (283/303) = 0.934

The COP of the refrigerator operating on the reversed Carnot cycle is equal to the efficiency of the Carnot cycle divided by the actual power input:

COP = Efficiency / Power Input = 0.934 / 1 kW = 0.934

Therefore, the COP of the refrigerator operating on the reversed Carnot cycle is 0.934.

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The hydrostatic pressure at a given depth in a large tank of liquid is a function of depth and liquid density. Therefore, choices a and c are both valid.

The hydrostatic pressure at a given depth in a liquid is determined by the weight of the liquid above that depth.

As the depth increases, the weight of the liquid above it increases, resulting in an increase in pressure.

The pressure at a given depth can be calculated using the following formula:

P = ρgh

where P is the pressure, ρ is the density of the liquid, g is the acceleration due to gravity, and h is the depth.

As we can see from the formula, the pressure is directly proportional to the depth and the density of the liquid. The surface area of the tank does not affect the hydrostatic pressure at a given depth.

Therefore, choices a and c are both valid as the hydrostatic pressure at a given depth is a function of depth and liquid density.
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The equation you need to know about the double slit experiment is:
sin(θ) = (mλ) / d

The equation you need to know about the double slit experiment is the interference pattern formula, which helps determine the location of bright and dark fringes on a screen. The equation is:

sin(θ) = (mλ) / d

Where:
- θ is the angle between the central maximum and the m-th order fringe
- m is the order of the fringe (an integer; 0 for the central maximum, 1 for the first-order fringe, etc.)
- λ is the wavelength of the light
- d is the distance between the two slits

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