which argument does this evidence best support? a larger magnets can attract more objects. b a magnet can attract magnetic objects through various materials. c magnetic fields exist between objects that are not in contact with each other. d only objects that are made of metal have a magnetic field.

A comet's tail points after its closest approach to the Sun:

When a comet approaches the Sun, the heat causes some of its frozen gases and ices to vaporize, creating a cloud of gas and dust around the nucleus of the comet.

The solar wind, which is a stream of charged particles constantly flowing out from the Sun, interacts with the gas and dust in the comet's atmosphere and pushes it away from the Sun.

The direction of the solar wind is generally outward from the Sun, so the gas and dust in the comet's tail is pushed in the opposite direction, away from the Sun.

The direction of the tail, therefore, is always away from the Sun, regardless of the position or motion of the comet.

Therefore, the correct answer is not among the options provided, but if we assume that the question is asking about the direction of the tail relative to the comet's direction of motion, the answer would be B) behind its direction of motion.

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The upper limb is the side of the chicken's body did this wing belong to.

Humerus, shoulder, and joint are related to the anatomy of the upper limb. The humerus is the long bone in the upper arm, the shoulder is the joint that connects the arm to the body, and the joint refers to the articulation between bones.

In a chicken, the shoulder joint is located at the junction of the humerus (upper arm bone) and the scapula (shoulder blade). It is a ball-and-socket joint that allows for a wide range of motion in the chicken's wing. The shoulder joint is important for a chicken's ability to fly, flap its wings, and perform other movements that require mobility and stability in the upper limb.

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The width of the central diffraction peak is 0.045 meters or 4.5 centimeters.

The width of the central diffraction peak on a screen 2.50 m behind a 0.0328-mm-wide slit illuminated by 588-nm light can be calculated using the formula:

w = (λL) ÷ a

where w denotes the width of the central diffraction peak, λ denotes the light's wavelength, L denotes the separation between the slit and the screen, and a denotes the slit's width.

When we enter the specified values into the formula, we obtain:

w = (588 nm x 2.50 m) ÷ 0.0328 mm

Converting the units to meters:

w = (588 x 10⁻⁹ m x 2.50 m) ÷ (0.0328 x 10⁻³ m)

Simplifying:

w = 0.045 m

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When an electrical current passes through a resistor, energy is dissipated, and the rate at which this energy is dissipated is the power, which is given by. [tex]P = i^{2} 2R[/tex] The amount of electricity passing through the resistor is determined by the current.

In the scenario described, when the switch is closed, the current prefers to travel through the short circuit wire rather than through bulb B, which causes no current to flow through bulb B. Since there is no current passing through bulb B, it does not receive any electrical energy and goes out.

On the other hand, all the current flows through bulb A, and thus, it receives more electrical energy, resulting in it getting brighter. This happens because the power dissipated by the resistor is proportional to the square of the current, and since all the current flows through bulb A, it receives more power and gets brighter.

In summary, the current passing through the resistor determines the amount of electricity passing through it, and the distribution of this current through different paths can result in some bulbs getting brighter, some getting dimmer, or even going out.

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Zach's weight before the elevator starts braking is 833 Newton.

Identifying Zach's weight is necessary to prevent the braking of the lift in which he is now riding. Zach is 85 kg in weight and the lift is dropping at 11 m/s.

The first floor is reached after 2.5 seconds of braking by the elevator. We employ the weight formula—which is the sum of mass and gravity—to solve the issue.

Zach's weight can be determined by dividing his mass of 85 kg by the gravitational acceleration, which equals about 9.8 m/s2. This results in an 833 Newton weight before the lift begins to brake.

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Escape velocity is the minimum speed required for an object to escape the gravitational pull of a celestial body. It depends on the mass and radius of the celestial body, as well as the temperature and mass of the gas molecules in the atmosphere.

Based on a plot of escape velocity versus atmospheric temperature, we can see that lighter gases such as hydrogen and helium require lower escape velocities, while heavier gases such as nitrogen and oxygen require higher escape velocities. The plot also shows that the escape velocity decreases as the temperature of the gas increases.

Mars has a relatively low escape velocity compared to Earth, which means that lighter gases such as hydrogen and helium are more likely to escape into space. This suggests that Mars' atmosphere should retain heavier gases such as nitrogen and oxygen, which have higher escape velocities and are less likely to escape into space due to their mass. Therefore, it is likely that Mars' atmosphere is rich in heavier gases, which is consistent with current observations.

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The spring constant of the spring is 3.00N/m. Therefore option 3 is correct.

To find the spring constant, we can use Hooke's Law, which states that the force exerted by a spring is directly proportional to the displacement of the spring from its equilibrium position.

The formula for Hooke's Law is F = kx, where F is the force, k is the spring constant, and x is the displacement.

In this case, we are given that compressing the spring by 0.500m causes a force of 1.50N. Using the formula F = kx, we can substitute the values:

1.50N = k * 0.500m

To find the value of k, we can rearrange the equation:

k = F / x

k = 1.50N / 0.500m

k = 3.00N/m

Therefore, the spring constant of the spring is 3.00N/m, which corresponds to option 3.

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The resistance of R1 and R2 in parallel is lower than their resistance in series.

When two resistors, R1 and R2, are in parallel, the equivalent resistance is calculated as

R = (R1 * R2) / (R1 + R2).

The resulting resistance is always lower than either of the individual resistors. In contrast, when R1 and R2 are in series, the equivalent resistance is calculated as R = R1 + R2. The resulting resistance is always higher than either of the individual resistors.

1. Resistance in Series: In a series circuit, the total resistance R(total) is the sum of the individual resistances (R1 and R2). Mathematically, it is given by:
R (total)= R1 + R2
2. Resistance in Parallel: In a parallel circuit, the total resistance R(total) is found using the reciprocal formula. Mathematically, it is given by:
1/R(total) = 1/R1 + 1/R2
Now, let's compare the two cases:
In a series circuit, the total resistance is simply the sum of the individual resistances, whereas in a parallel circuit, the total resistance is determined by the reciprocal formula. Generally, the total resistance in a parallel circuit is lower than that in a series circuit, due to the reciprocal relationship. This means that when R1 and R2 are connected in parallel, their combined resistance will be less than when they are connected in series.

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The maximum torque on the wire is 0.1306 Nm.

Hi, I'd be happy to help you with your question. To find the maximum torque on a wire formed into a circle with a diameter of 10.9 cm, placed in a uniform magnetic field of 2.80 mT, and carrying a current of 5.00 A, follow these steps:

1. Calculate the radius of the circle:
Radius = Diameter / 2 = 10.9 cm / 2 = 5.45 cm = 0.0545 m (converted to meters)

2. Calculate the area of the circle:
Area = π * Radius^2 = π * (0.0545 m)^2 = 0.00933 m^2

3. Convert the magnetic field from millitesla (mT) to tesla (T):
Magnetic Field = 2.80 mT = 0.00280 T

4. Calculate the maximum torque on the wire:
Torque = (Current * Area * Magnetic Field) * sin(θ)
Since we need to find the maximum torque, we will use sin(θ) = 1:
Torque = (5.00 A * 0.00933 m^2 * 0.00280 T) * 1 = 0.1306 Nm

The maximum torque on the wire is 0.1306 Nm.

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As the ball is pulled inward, the radius of the circle decreases, which means that the tangential speed of the ball must increase in order to maintain uniform centripetal motion. Option (A)

This increase in tangential speed means that the angular velocity of the ball also increases, as angular velocity is directly proportional to tangential speed divided by the radius of the circle.

Since angular momentum is given by the product of rotational inertia and angular velocity, any change in angular velocity will result in a change in angular momentum.

As a result, the proper prediction for the angular momentum and rotational inertia of the ball about the axis of revolution as the ball is drawn inward is: A) The angular momentum of the ball rises. The rotational inertia of the ball about the axis of revolution remains constant.

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The net force pulling up on the bottom pulley is equal to one-sixth of the weight of the mass.

In this scenario, we can use the concept of tension in the rope to determine the net force pulling up on the bottom pulley.

The tension in the rope is the same throughout, so the tension in the strand being pulled by the man is equal to the tension in the six strands running between the two pulleys.

The force of tension pulling up on the bottom pulley is equal to six times the tension in the rope, since there are six strands of rope running between the pulleys.

The force of gravity pulling down on the mass is equal to its weight, which is given by:

F_gravity = m *

where m is the mass of the object and g is the acceleration due to gravity.

Since the mass is suspended at a constant speed, the net force on the mass must be zero, which means that the force of tension pulling up on the bottom pulley must be equal to the force of gravity pulling down on the mass:

6 * T = m *

where T is the tension in the rope.

Solving for the net force pulling up on the bottom pulley, we get:

6 * T = m * g

T = m * g / 6

Therefore, the net force pulling up on the bottom pulley is equal to one-sixth of the weight of the mass.

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The light wave is traveling in the +y direction, as its direction of propagation is perpendicular to both the electric and magnetic fields, which are oscillating in the -x and -z directions, respectively.

Based on the direction of the electric and magnetic fields, the wave is traveling in the +y direction (out of the page on a standard xy coordinate system).

This is because light waves are transverse waves, meaning that the direction of their oscillation (in this case, the electric and magnetic fields) is perpendicular to the direction of their propagation. In this case, the electric field is oscillating in the -x direction and the magnetic field is oscillating in the -z direction, which means that the wave is propagating in a direction perpendicular to both of these directions, which is the +y direction.

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The temperature increases at a rate of 0.152 K/s

To determine the rate of temperature increase in the electronic circuit, we can use the formula:

Rate of temperature increase = Power absorbed / (mass × specific heat)

Here, the power absorbed is given as 8 mW, which is equal to 8 × [tex]10^{-3}[/tex] W or 8 × [tex]10^{-3}[/tex] J/s.

The mass of the silicon is 73 mg, which is equal to 73 × [tex]10^{-6}[/tex] kg.

The specific heat of silicon is 705 J/kg K.

Now, Substitute these values into the formula:

Rate of temperature increase = (8 × [tex]10^{-3}[/tex] J/s) / ((73 × [tex]10^{-6}[/tex] kg) × (705 J/kg K))

Rate of temperature increase = 0.152 K/s

So, the temperature of the electronic circuit increases at a rate of approximately 0.152 K/s when no heat can move out of it.

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The speed of the proton relative to the accelerator is approximately 0.82 times the speed of light.

In the special theory of relativity, the total energy of a particle can be expressed as the sum of its rest energy and its kinetic energy. If a proton in a certain particle accelerator has a kinetic energy that is equal to its rest energy, then its total energy is twice its rest energy, i.e.,

[tex]E_total^2 = (pc)^2 + (mc^2)^2[/tex]

where m is the rest mass of the proton and c is the speed of light.

According to the relativistic energy-momentum relation, the total energy of a particle is related to its momentum and rest mass by the equation:

[tex]E_total^2 = (pc)^2 + (mc^2)^2[/tex]

where p is the momentum of the particle.

Substituting the expression for the total energy of the proton in terms of its rest mass and the speed of light, we get:

[tex](2mc^2)^2 = (pc)^2 + (mc^2)^2[/tex]

Simplifying, we get:

[tex]4m^2c^4 = p^2c^2 + m^2c^4[/tex]

Rearranging and simplifying further, we get:

p = mc * sqrt(3)

Therefore, the momentum of the proton is mc times the square root of 3. Since the speed of the proton is related to its momentum by the equation:

[tex]p = mv / sqrt(1 - v^2/c^2)[/tex]

where v is the speed of the proton relative to the accelerator, we can solve for v to get:

[tex]v = c * sqrt(1 - 1/3) = c * sqrt(2/3)[/tex]

Therefore, the speed of the proton relative to the accelerator is approximately 0.82 times the speed of light.

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The speed of the proton relative to the accelerator is 2.19 x 10⁸ m/s. in a certain particle accelerator, a proton has a kinetic energy that is equal to its rest energy.

Based on the given information, we can use the formula for kinetic energy:
KE = (1/2)mv²
where KE is the kinetic energy, m is the mass of the proton, and v is its velocity.
Since the proton's kinetic energy is equal to its rest energy (mc²), we can set the two equations equal to each other:
mc² = (1/2)mv²
Simplifying this equation, we can cancel out the mass on both sides:
c² = (1/2)v²
Solving for v, we can take the square root of both sides:
v = √(2c²)
Plugging in the value for the speed of light (c = 3.00 x 10⁸ m/s), we get:
v = √(2 x (3.00 x 10⁸)²)
v = 2.19 x 10⁸ m/s

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A mechanical wave is a wave that requires a medium to travel through, such as sound waves or water waves. In everyday life, we experience mechanical waves when we hear sounds or see water waves in a pond.

Transverse Wave: A transverse wave is a wave that vibrates perpendicular to the direction of wave propagation, such as light waves or radio waves.

We use transverse waves every day when we use our phones to receive radio waves.

Longitudinal Wave: A longitudinal wave is a wave that vibrates parallel to the direction of wave propagation, such as sound waves or seismic waves.

We hear sound through longitudinal waves, and we feel earthquakes through seismic waves.

Wave Speed: Wave speed is the speed with which a wave propagates via a particular medium.

When we watch a wave on the beach, we can estimate the wave speed by observing how fast it moves across the sand.

Wavelength: Wavelength is the distance between two corresponding points on a wave, such as the distance between two crests.

We can measure the wavelength of light using a spectroscope.

Frequency: Frequency is the number of waves that pass a given point in a given amount of time, such as the number of waves passing a fixed point in one second.

We use frequency to measure the pitch of sound or the radio frequency of a station.

Amplitude: Amplitude is the maximum displacement of a wave from its resting position, such as the height of a wave from its crest to its trough.

The amplitude of a sound wave determines how loud the sound is.

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The time required for the object attached to a spring to move from the equilibrium position to half the amplitude depends on the specifics of the motion and cannot be determined solely from the period of oscillation.

During its motion, the object attached to a spring oscillates with a sinusoidal motion, which means its speed is not constant. At the maximum displacement, the speed is zero, while it is maximum when the object passes through the equilibrium position. Therefore, the time required for the object to move from the equilibrium position to half the amplitude is not half the period, but rather a smaller fraction of the period.

To determine the time required, one would need to use the equation of motion for a simple harmonic oscillator:

x(t) = A cos(ωt + φ)

where x(t) is the position of the object at time t, A is the amplitude, ω is the angular frequency, and φ is the phase constant. From this equation, we can find the position of the object when it is halfway to the amplitude by setting x(t) equal to A/2 and solving for t:

A/2 = A cos(ωt + φ)

cos(ωt + φ) = 1/2

ωt + φ = ±π/3

t = (±π/3 - φ) / ω

Therefore, the time required for the object to move from the equilibrium position to half the amplitude depends on the phase constant φ and the angular frequency ω. It is important to note that this is a general solution for a simple harmonic oscillator, and specific values for these variables would need to be provided to obtain a numerical answer.

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Baffles are flat plates or bars that are placed inside a shell-and-tube heat exchanger to promote turbulence and enhance heat transfer. The baffles create a series of parallel flow paths, forcing the fluid to change direction several times as it flows through the heat exchanger.

This results in an increase in the heat transfer coefficient by promoting better mixing and reducing the thickness of the thermal boundary layer.

The presence of baffles increases the pressure drop across the heat exchanger, which in turn increases the pumping power requirements. However, the increase in heat transfer coefficient outweighs the increase in pressure drop, resulting in an overall improvement in the heat transfer efficiency of the heat exchanger. The baffles also serve to support the tubes and prevent damage from tube vibration, which can occur in the absence of baffles.

The selection and design of baffles are critical to the performance of a shell-and-tube heat exchanger. The spacing, angle, and number of baffles must be carefully considered to optimize the heat transfer rate and minimize the pumping power requirements.

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This is due to the fact that the gravitational pull of the sun is proportionate to the mass of each body, with the larger body being subjected to a stronger gravitational pull than the smaller body.

Depending on how far away from the Sun a planet is, it orbits the Sun at a different speed. When a planet is closer to the Sun, it moves more quickly due to the Sun's stronger gravitational pull.

A planet's angular momentum does not change as it gets further from the Sun, thus it moves more slowly at that distance. The angular momentum of a planet in a circular orbit is determined by its mass (m), its distance from the Sun (d), and its velocity (v).

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The minimum uncertainty in the ball's position is 3.5 x 10^-32 meters.

To calculate the uncertainty, multiply the speed (30.0 m/s) by the accuracy (0.001). This results in an uncertainty in speed of 0.03 m/s.

Now, apply Heisenberg's Uncertainty Principle to find the minimum uncertainty in position. The formula is:

Δx * Δp ≥ ħ/2

where Δx is the uncertainty in position, Δp is the uncertainty in momentum, and ħ is the reduced Planck constant (approximately 1.05 x 10^-34 Js).

First, find Δp by multiplying the mass of the ball (50.0 g or 0.05 kg) by the uncertainty in speed (0.03 m/s). This gives a Δp of 0.0015 kg m/s.

Now, solve for Δx:

Δx ≥ ħ / (2 * Δp)

Δx ≥ (1.05 x 10^-34 Js) / (2 * 0.0015 kg m/s)

Δx ≥ 3.5 x 10^-32 m

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The velocity of the object when it hits the Earth's surface depends only on the height from which it was dropped and the acceleration due to gravity.

The velocity of an object when it hits the Earth's surface can be calculated using the principle of conservation of energy. When the object is released from rest at a distance r0 from the Earth's center, it has an initial gravitational potential energy of mgh0, where g is the acceleration due to gravity and h0 is the height of the object above the Earth's surface.

As the object falls towards the Earth's surface, its potential energy is converted into kinetic energy. When it hits the Earth's surface, all of its potential energy has been converted into kinetic energy. Therefore, we can write:

[tex]mgh0 = (1/2)mv^2[/tex]

where v is the velocity of the object when it hits the Earth's surface.

Solving for v, we get:

v = sqrt(2gh0)

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The forces are both, electrical and magnetic forces.

Hi! Danielle's device, which consists of an iron nail wrapped with a thin copper wire connected to a battery, can produce both electrical and magnetic forces. When the battery is connected, an electrical current flows through the copper wire, creating an electrical force. This current also generates a magnetic field around the wire, turning the iron nail into an electromagnet and producing a magnetic force. Therefore, the correct answer is both electrical and magnetic forces.

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If total internal reflection occurs, it means that the angle of incidence of the light is greater than the critical angle, and the light cannot pass through the interface between two media.

The critical angle is defined as the angle of incidence at which the angle of refraction becomes 90 degrees, and the refracted light travels along the interface.

The critical angle depends on the refractive indices of the two media, and can be calculated using Snell's law. For the case of light traveling from a medium with a higher refractive index (such as a solid or a liquid) to a medium with a lower refractive index (such as air), the critical angle can be calculated as:

sin(critical angle) = n2 / n1

where n1 is the refractive index of the medium with the higher refractive index, and n2 is the refractive index of the medium with the lower refractive index.

If total internal reflection occurs, it means that the angle of incidence is greater than the critical angle, which implies that the refractive index of the liquid must be greater than the refractive index of the medium with the lower refractive index (e.g., air). Therefore, we can say that the minimum possible index of refraction of the liquid is equal to the refractive index of the medium with the lower refractive index.

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The angular velocity of the track star is approximately 0.105 radians/second.

The time taken to run the race is 60 seconds, and the distance covered by the track star is one lap, which is the circumference of the circle. Therefore, the average speed of the track star is:

Average speed = distance / time

Average speed = 2πr / 60 seconds

Average speed = (2π x 63.66 meters) / 60 seconds

Average speed = 6.67 meters/second (rounded to two decimal places)

The angular velocity (ω) of the track star can be calculated using the formula: ω = v / r

where v is the linear velocity of the track star, and r is the radius of the circular track. Since the track star is running at a constant speed, the linear velocity is equal to the average speed calculated above. Therefore, the angular velocity of the track star is:

ω = v / r

ω = 6.67 meters/second / 63.66 meters

ω = 0.105 radians/second (rounded to three decimal places)

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James' gun emits the most energetic light as ultraviolet light has a higher frequency and shorter wavelength than infrared, red, and blue light.

The energy of light is determined by its frequency and wavelength. James' gun produces the most energetic light because ultraviolet light has a higher frequency and shorter wavelength than infrared, red, and blue light. This means that each photon of ultraviolet light carries more energy than a photon of blue, red, or infrared light.

Therefore, James' gun emits light with the highest energy. It is important to note that high-energy light, such as ultraviolet light, can be harmful to live organisms and precautions should be taken to limit exposure.

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The tower of Pisa can lean up to an additional 3.5 m off center before becoming unstable.

To determine how much farther the tower can lean before it becomes unstable, we need to calculate the current location of the center of mass and the maximum distance it can move before leaving the base.

Assuming the tower is a uniform cylinder, we can calculate the location of its center of mass using the formula:

x_cm = L/2 + h/4

where L is the length of the cylinder (equal to the diameter, or 7.0 m), and h is the height of the cylinder (equal to 55 m).

Substituting the given values, we get:

x_cm = 7.0/2 + 55/4

x_cm = 5.25 + 13.75

x_cm = 19.0 m

This means that the center of mass of the tower is currently located 19.0 m from the center of the base.

To determine how much farther the tower can lean before becoming unstable, we need to calculate the maximum distance the center of mass can move before leaving the base. This distance is equal to half the diameter of the base, or:

d_max = 7.0/2

d_max = 3.5 m

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The velocity of the astronaut as he moves backward is -0.33 m/s.

Velocity is the rate of change of dispalcement.

To calculate the velocity the astronaut moves backward, we use the formula below

Formula:

Where:

From  the question,

Given:

Substitute these values into equation 1 and solve for v

Hence, the velocity is -0.33 m/s.

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When retrograde motion occurs and how it is related to Mars's orbit around the Sun:

Retrograde motion occurs when a planet appears to move backward in the sky from Earth's perspective. In the case of Mars, this happens when Earth overtakes Mars in their respective orbits around the Sun.

To understand when Mars will be in retrograde motion, consider these steps:

1. Picture both Mars and Earth orbiting the Sun, with Mars having a larger, slower orbit due to its greater distance from the Sun.
2. As Earth moves faster in its orbit, it eventually catches up to and passes Mars.
3. During this time, the relative positions of Earth, Mars, and the Sun create the illusion of Mars moving backward in the sky, as seen from Earth.

So, when trying to identify the spot where Mars will be in retrograde motion, look for the point in its orbit where Earth is passing Mars, creating the optical illusion of Mars moving backward in the sky.

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