Calculate the total C pool (above- and belowground C) for the Control group.
a. 10,125 g C/m2
b. 2,500 g C/m2
c. 11, 522 C/m2
d. 10,00 C/m2

The average acceleration of the runner at the initial instant t0 (when the runner started from rest) is 3.5 m/sec^2.

To answer your question, we first need to calculate the acceleration of the runner. We can use the formula:
acceleration = (final velocity - initial velocity) / time
In this case, the final velocity is 7 m/sec, the initial velocity is 0 m/sec (since the runner started from rest), and the time is 2 seconds. So we can plug these values into the formula:
acceleration = (7 m/sec - 0 m/sec) / 2 sec
acceleration = 3.5 m/sec^2

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To fully describe the velocity of the bicyclist, we would need to know both the units (likely km/hour) and the direction (e.g. north, south, east, west). Without this information, we can only make assumptions and calculations based on what we do know.

To answer your question, the missing piece in the bicyclist's velocity is the units. It's important to note that velocity is a vector quantity, meaning it has both magnitude and direction. In this case, the direction is not given, but we know the distance traveled (50 km) and the average velocity (35).
Average velocity is calculated by dividing the total distance traveled by the total time taken. So if we assume the bicyclist took 2 hours to complete the 50-km race, the average velocity would be 25 km/hour. However, since the bicyclist claims their average velocity was 35, we can assume that either the units are missing or they made a mistake in their calculation.

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Polarity is an important factor to consider when studying molecular interactions, as it influences properties such as solubility, melting and boiling points, and chemical reactivity. Nonpolar molecules have an even distribution of electrons and no distinct charge separation.

Polarity is a condition in which opposite ends of a molecule have slightly different charges but overall is neutral. This phenomenon occurs when a molecule has polar covalent bonds, which means that the electrons are shared unequally between atoms. The three main factors that determine the polarity of a molecule are electronegativity, molecular geometry, and the presence of polar bonds. Electronegativity is the ability of an atom to attract electrons towards itself in a chemical bond. When two atoms with different electronegativities bond, the electrons are pulled towards the more electronegative atom, creating a partial positive charge on the less electronegative atom and a partial negative charge on the more electronegative atom. In addition, the molecular geometry can also contribute to the overall polarity of the molecule.

In a polar molecule, the distribution of electrons between atoms is uneven, leading to a partial positive charge on one end and a partial negative charge on the other. This is often due to the presence of atoms with differing electronegativities within the molecule. An example of a polar molecule is water (H2O), where the oxygen atom has a higher electronegativity than the hydrogen atoms, resulting in a polar structure.

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The newly discovered element with atomic number 108 and atomic mass 277 has a neutral atom with 108 protons, 169 neutrons, and 108 electrons.

The atomic number of an element represents the number of protons in its nucleus, which determines its identity. In this case, the element has an atomic number of 108, indicating that it has 108 protons. Since the atom is neutral, it means that the number of electrons is equal to the number of protons. Therefore, there are also 108 electrons orbiting the nucleus.

To find the number of neutrons, we subtract the atomic number from the atomic mass. The atomic mass represents the sum of protons and neutrons in the nucleus. In this case, the atomic mass is 277, and the atomic number is 108. Subtracting 108 from 277 gives us 169 neutrons.

In summary, a neutral atom of this newly discovered element with an atomic number of 108 and atomic mass of 277 consists of 108 protons, 169 neutrons, and 108 electrons.

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The ranking from largest to smallest initial frequency is: Evita, Buffy, Aiko, Freja, Chandra.

To rank each member of the guitar septet based on the initial frequency of their low E string.

We can list the members in descending order

Evita = 5 Hz (highest initial frequency)

Buffy = 4 Hz

Aiko = 3 Hz

Freja = 3 Hz

Chandra = 1 Hz (lowest initial frequency)

Therefore, the ranking from largest to smallest initial frequency is: Evita, Buffy, Aiko, Freja, Chandra.

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Answer:

F= 129.6 N ≈ 130 N

Explanation:

According to Hook's Law:

F = kx

F = Force necessary to stretch the spring

k = spring constant

x = displacement of the spring (stretch in the spring), in meters

Given x = 48 cm = 0.48 m

k = 270 N/m

F = kx

F = (270 N/m)(0.48 m) = 129.6 N

F = 129.6 N ≈ 130 N

A piece of room temperature metal feels cooler to the touch than paper, wood, or cloth because metal is a better conductor of heat than these other materials. When you touch the metal, heat from your hand is rapidly transferred to the metal, which absorbs the heat and becomes warmer. The nerves in your skin sense this temperature change and send a signal to your brain, which interprets the sensation as feeling cool.

In contrast, materials like paper, wood, or cloth are poor conductors of heat and have lower thermal conductivity than metal. When you touch them, heat from your hand is not transferred as quickly to these materials, and they don't absorb the heat as readily as metal does. As a result, the nerves in your skin don't sense as much of a temperature change, and your brain interprets the sensation as feeling warmer than when you touch metal.

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The object is located 10.4 cm away from the concave mirror.

1/f = 1/v + 1/u

Substituting the given values into the formula, we get:

1/-8.20 = 1/18.8 + 1/u

Multiplying both sides by -8.2018.8u, we get:

u = -8.20*18.8/(-8.20+18.8) = 10.4 cm

A concave mirror, also known as a converging mirror, is a curved mirror with a reflective surface that curves inward like the interior of a sphere. When light rays pass through the concave mirror, they converge and intersect at a point known as the focal point. This point is located on the principal axis, which is an imaginary line that passes through the center of the mirror and the focal point.

Concave mirrors have a variety of applications, including in telescopes, searchlights, and headlights. In a telescope, a concave mirror is used to gather and focus light from distant objects, making them appear closer and clearer. In a searchlight or headlight, a concave mirror is used to reflect light in a specific direction, creating a powerful beam of light.

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Among the options provided, option b) is true: the Sun's electromagnetic energy is indeed blocked by Earth's protective atmosphere.

This is evident in the way the atmosphere absorbs or scatters a significant portion of the Sun's electromagnetic radiation, including harmful ultraviolet (UV) rays.

However, options a) and c) are not true. Let's break them down:

Internal processes within the Moon do not produce light during the night. The Moon's illumination is derived from sunlight reflecting off its surface. The Moon does not possess an internal light source; it appears bright in the night sky because of the Sun's light reaching it and being reflected towards Earth.

Our massive Sun is not the only object that exerts a gravitational pull on Earth. While the Sun's gravitational pull is the most significant force affecting Earth's orbit, other celestial bodies, such as the Moon and other planets in our solar system, also exert gravitational forces on Earth.

The Moon, in particular, has a noticeable gravitational influence on Earth, leading to phenomena like ocean tides.

Therefore, the correct answer is not d) (all of the above), but rather only b) (Sun's electromagnetic energy is blocked by Earth's protective atmosphere).

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A lens with a diameter of 100 cm has a theoretical resolution limit of about 0.011 arcseconds for visible light observations.

The resolution of a telescope or lens is determined by its aperture size and the wavelength of the observed light. The theoretical limit of resolution is given by the Rayleigh criterion, which states that the smallest angular separation between two objects that can be resolved is approximately equal to the wavelength of the observed light divided by the aperture diameter.

For a lens of diameter 100 cm, the resolution can be estimated as:

resolution = wavelength / aperture diameter

Assuming a typical visible light arcseconds of 500 nm (5 x 10^-7 m), we can convert this to arcseconds using the formula:

1 radian = 206265 arcseconds

Therefore, the resolution in arcseconds is:

resolution = (wavelength / aperture diameter) * (180 / pi) * 3600 * 206265

resolution = (5 x 10^-7 m / 100 m) * (180 / pi) * 3600 * 206265

resolution ≈ 0.011 arcseconds

So a lens with a diameter of 100 cm has a theoretical resolution limit of about 0.011 arcseconds for visible light observations.

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The van't Hoff factor of Na3PO4 in this solution is 3.01.

The van't Hoff factor (i) can be calculated using the formula:

ΔTf = Kf * i * molality

where ΔTf is the freezing point depression, Kf is the freezing point depression constant, molality is the molal concentration, and i is the van't Hoff factor.

We know that ΔTf = -2.6°C and the molality of the solution is 0.40 m.

The freezing point depression constant (Kf) for water is 1.86°C/m.

Substituting these values in the equation, we get:

-2.6°C = (1.86°C/m) * i * 0.40 m

Solving for i, we get:

i = -2.6°C / [(1.86°C/m) * 0.40 m] = 3.01

Therefore, the van't Hoff factor of Na3PO4 in this solution is 3.01.

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the rocket will rise an additional height of 18.6 meters before it reaches its maximum height and begins to fall back down to Earth. By using formula of potential energy  = mgh. This calculation assumes that air resistance is negligible.

To calculate the additional height the rocket will rise, we need to use the conservation of energy principle. The initial kinetic energy of the rocket, given as 1950 J, will be converted entirely to potential energy as the rocket rises.
We can use the formula for gravitational potential energy:
PE = mgh
where PE is potential energy, m is the mass of the rocket, g is the acceleration due to gravity (approximately 9.81 m/s^2), and h is the height the rocket rises.
Rearranging the formula, we get:
h = PE / (mg)
Substituting the given values, we get:
h = 1950 J / (10.5 kg x 9.81 m/s^2)
h = 18.6 meters
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The moon actually does rotate on its axis; however, it keeps one side facing the Earth due to a phenomenon called "tidal locking." Tidal locking occurs when the gravitational pull of a larger celestial body (in this case, Earth) causes the smaller body (the moon) to rotate at the same rate as its orbital period.

As a result, the same side of the moon always faces Earth, giving us the impression that it doesn't rotate on its axis. This process takes place over time and is due to the gravitational interaction between the two bodies.

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To answer this question, we can use the formula for centripetal acceleration, which is a = v²/r, where a is the centripetal acceleration, v is the velocity, and r is the radius of the curve.

We know that the velocity of the car is 20 m/s and the centripetal acceleration is 5 m/s².

Therefore, we can rearrange the formula to solve for r as r = v²/a.

Plugging in the values, we get r = (20 m/s)² / 5 m/s² = 80 m. So, the radius of the curve is 80 meters.

This means that the car needs to travel along a circular path with a radius of 80 meters to maintain a centripetal acceleration of 5 m/s².

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The period of a motion refers to the time it takes for one complete cycle of the vibration or oscillation. The frequency, on the other hand, is the number of cycles per second. Therefore, the period of the tuning fork's vibration is 0.0045 seconds. This means that it takes 0.0045 seconds for the tuning fork to complete one cycle of its vibration.

In this case, we are given that a tuning fork vibrates at a frequency of 222 Hz and has an amplitude of 0.894 mm at each tip of its two prongs. To find the period of this motion, we can use the formula:
Period = 1 / Frequency
Plugging in the given frequency of 222 Hz, we get:
Period = 1 / 222
Simplifying this expression, we get:
Period = 0.0045 seconds

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The weight of a typical froghopper with a mass of 12.3 mg is approximately 0.0001206 Newtons.

To calculate the weight of a typical froghopper in Newtons, you need to use the formula: weight (in Newtons) = mass (in kg) × gravity (9.81 m/s²).

1. First, convert the mass of the froghopper from milligrams (mg) to kilograms (kg): 12.3 mg = 0.0000123 kg (divide by 1,000,000).

2. Next, multiply the mass (in kg) by the acceleration due to gravity (9.81 m/s²):
Weight (Newtons) = 0.0000123 kg × 9.81 m/s².

3. Finally, calculate the weight:
Weight (Newtons) ≈ 0.0001206 N.

The weight of a typical froghopper with a mass of 12.3 mg is approximately 0.0001206 Newtons.

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To find the tree node at implicit position i in a binary heap represented using explicit links, we can use the following algorithm:

Convert i to its binary representation and ignore the first bit (which is always 1).

Traverse the binary heap starting from the root node, following the binary representation of i from left to right.

If a bit is 0, go to the left child; if a bit is 1, go to the right child.

When you reach the end of the binary representation, you will have arrived at the node at implicit position i.

This algorithm works because the binary representation of i corresponds to the path from the root node to the node at position i in the binary heap. By following this path, we can find the node at position i in O(log n) time, where n is the size of the binary heap.

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The stopping potential for electrons ejected from the sample by 7.0 x [tex]10^{14[/tex] Hz electromagnetic radiation is 0.6 V.

Stopping potential (V) = Energy of incident photons - Work function

The energy of incident photons can be calculated using the formula:

The energy of photon = Planck's constant x frequency

where Planck's constant is 6.626 x [tex]10^{-34[/tex] J s.

Substituting the given values, we get:

Energy of photon = (6.626 x [tex]10^{-34[/tex] J s) x (7.0 x [tex]10^{14[/tex] Hz) = 4.64 x [tex]10^{-19[/tex] J

Converting the energy of a photon to electron volts (eV), we get:

Energy of photon = (4.64 x [tex]10^{-19[/tex] J) / (1.6 x [tex]10^{-19[/tex] J/eV) = 2.90 eV

Now we can calculate the stopping potential:

Stopping potential = Energy of incident photons - Work function

Stopping potential = 2.90 eV - 2.3 eV = 0.6 V

Electromagnetic radiation refers to the energy that is propagated through space in the form of oscillating electromagnetic waves. These waves are created when electric charges are accelerated and are characterized by their frequency or wavelength.

Electromagnetic radiation includes a wide range of phenomena, including radio waves, microwaves, infrared radiation, visible light, ultraviolet radiation, X-rays, and gamma rays. Each of these types of radiation has a different frequency and wavelength, and they interact with matter in different ways.

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The stopping potential of the ejected electrons can be found by applying Einstein's photoelectric equation. The energy of the ejected electrons (in Joules) is calculated by subtracting the work function from the product of Planck's constant and the frequency of incident light. This is then converted back to electron-volts, which is the stopping potential.

The problem is about finding the stopping potential for electrons that are ejected from a sample by an electromagnetic radiation frequency, given the work function. This problem can be solved using the photoelectric effect principle, particularly Einstein's photoelectric equation: E = hv - W, where W is the work function (2.3 eV in this case), h is Planck's constant, v is the frequency of the incident light (7.0 x 1014 Hz in this case), and E is the energy of the ejected electron.

First, convert the work function from eV to J (joules) using the conversion factor 1.6 x 10-19 J/eV. Then, calculate E by multiplying h (6.63 x 10-34 Js) and v. Subtract W from E which gives the kinetic energy of the electron, K. K should then be converted back to eV and this gives the stopping potential for the electron.

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The threshold frequency (f0) for sodium metal, at which electrons are just barely ejected, can be estimated based on the observation that no electrons are ejected at 540 nm. Since frequency (f) and wavelength (λ) are inversely proportional, we can calculate the threshold frequency using the equation f = c/λ, where c is the speed of light. By substituting the given wavelength (540 nm) into the equation, we can determine an approximate value for the threshold frequency of sodium metal.

To find the threshold frequency (f0), we can use the equation f = c/λ, where f represents the frequency, c is the speed of light (approximately 3 x 10^8 meters per second), and λ is the wavelength. Since no electrons are ejected at a wavelength of 540 nm, we can substitute this value into the equation to calculate the corresponding frequency.

Converting the wavelength to meters (λ = 540 x 10^(-9) meters), we can substitute it into the equation: f = (3 x 10^8 meters per second) / (540 x 10^(-9) meters). Simplifying this expression yields a threshold frequency of approximately 5.56 x 10^14 Hz.

Therefore, the estimated threshold frequency for sodium metal is approximately 5.56 x 10^14 Hz. It represents the minimum frequency required to overcome the binding energy of electrons in sodium metal and cause their ejection.

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Water droplets or ice crystals that are so tiny and light that can float in the air make up clouds.

In the form of water vapour (gaseous form), the water and ice that creates the clouds are carried into the sky by air.

Evaporation is the major process by which the water vapour enters the atmosphere. From the sea, lakes, and rivers, some liquid water evaporates and moves through the atmosphere.

The pressure on the air decreases as it rises in the atmosphere, thus becoming cooler.

Some water vapour condenses as air cools. Some water vapour condenses together with the decrease in air pressure. Small water droplets are generated from the vapour, and as a result a cloud is created.

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The semicircular canals are specialized to assess rotational acceleration of the head, while the otolith organs are specialized to detect linear acceleration and static position of the head relative to the gravitational axis. The semicircular canals contain fluid-filled channels arranged in three perpendicular planes, allowing them to detect angular movements of the head. On the other hand, the otolith organs consist of small calcium carbonate crystals suspended in gelatinous fluid, which respond to linear accelerations and changes in head position relative to gravity.

The semicircular canals are responsible for detecting rotational acceleration of the head. They are three fluid-filled canals positioned in different planes: the horizontal canal, anterior (superior) canal, and posterior (inferior) canal. Each canal has a bulge at one end called the ampulla, which contains hair cells that detect fluid movement. When the head rotates, the fluid within the canals also moves, bending the hair cells and signaling the brain about the rotational acceleration.

The otolith organs, consisting of the utricle and saccule, are specialized in detecting linear acceleration and static position of the head relative to the gravitational axis. These organs contain small calcium carbonate crystals called otoliths that are embedded in a gelatinous layer. When the head accelerates linearly or changes position relative to gravity, the otoliths move, causing the gelatinous layer to shift and stimulating the hair cells. This signals the brain about changes in linear acceleration and head position, including tilting or linear movements such as walking or riding in a vehicle.

In summary, the semicircular canals are designed to detect rotational acceleration, while the otolith organs are specialized in detecting linear acceleration and static position changes of the head relative to the gravitational axis. This division of sensory functions allows for a comprehensive assessment of different types of head movements and orientations in space.

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The wavelength (in meters) of a wave traveling along the x-axis, with a given y-displacement, can be found by analyzing the equation provided. Unfortunately, you did not provide the equation in your question. If you can provide the equation, I would be happy to help you determine the wavelength of the wave traveling along the x-axis.

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Assume that the wave is a simple sinusoidal wave, then we can use the equation: wavelength = speed of wave / frequency of wave

To determine the wavelength of the wave, we need to first identify its wave pattern. The equation provided only gives us information about the y-displacement of the wave, but we need to know how the wave behaves in the x-direction as well. Without this information, we cannot determine the wavelength.

To determine the wavelength of a wave traveling along the x-axis, you need the equation for the wave's y-displacement. However, the equation you intended to provide seems to be missing. Typically, a wave's displacement is described by a sinusoidal function, such as y(x) = A * sin(kx - ωt), where A is amplitude, k is the wave number (2π/λ), λ is the wavelength, ω is the angular frequency, and t is time.

Once you have the equation, you can find the wavelength (λ) by determining the wave number (k) and using the relationship λ = 2π/k.

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Answer:

A) What is the moment of inertia of the bowling ball?

The moment of inertia of a bowling ball is 2/5mr

2

, where m is the mass of the ball and r is the radius. In this case, m=6 kg and r=10.8 cm=0.108 m. Therefore, the moment of inertia of the bowling ball is:

I=

5

2

​

(6 kg)(0.108 m)

2

=0.023328 kg m

2

B) What is the translational kinetic energy of the bowling ball?

The translational kinetic energy of a bowling ball is  

2

1

​

mv

2

, where m is the mass of the ball and v is the velocity. In this case, m=6 kg and v=8 m/s. Therefore, the translational kinetic energy of the bowling ball is:

KE

t

​

=

2

1

​

(6 kg)(8 m/s)

2

=192 J

C) What is the initial rotational kinetic energy of the bowling ball?

The initial rotational kinetic energy of a bowling ball is  

2

1

​

Iω

2

, where I is the moment of inertia of the ball and ω is the angular velocity. In this case, I=0.023328 kg m

2

 and ω=v/r=8 m/s/0.108 m=74.074 rad/s. Therefore, the initial rotational kinetic energy of the bowling ball is:

KE

r

​

=

2

1

​

(0.023328 kg m

2

)(74.074 rad/s)

2

=119.36 J

D) The bowling ball comes to the bottom of a ramp that is inclined 20 degrees with respect to the horizontal. What maximum height will the ball reach up this ramp?

The maximum height that the ball will reach up the ramp can be found using the following equation:

h=

2g

v

2

​

sin

2

(θ)

where v is the initial velocity of the ball, g is the acceleration due to gravity, and θ is the angle of the ramp. In this case, v=8 m/s, g=9.8 m/s

2

, and θ=20

∘

. Therefore, the maximum height that the ball will reach up the ramp is:

h=

2(9.8 m/s

2

)

(8 m/s)

2

​

sin

2

(20

∘

)=1.53 m

Explanation:

Different types of radiation are arranged along the electromagnetic spectrum by the amount of energy they carry. The electromagnetic spectrum is a range of different types of radiation that vary in wavelength and frequency.

one end of the spectrum, there are radio waves, which have the longest wavelength and lowest frequency, and at the other end, there are gamma rays, which have the shortest wavelength and highest frequency.

The various types of radiation in the electromagnetic spectrum are arranged in the following order, from low to high energy: radio waves, microwaves, infrared radiation, visible light, ultraviolet radiation, X-rays, and gamma rays. This arrangement is based on the amount of energy carried by each type of radiation.

The energy of a photon of radiation is directly proportional to its frequency and inversely proportional to its wavelength. Therefore, the higher the frequency and shorter the wavelength of a type of radiation, the more energy it carries.

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Statement about the medium spiny neurons in the caudate and putamen

The false statement among the given options is: "They outnumber their target neurons in the globus pallidus by about a factor of 1,000."

Medium spiny neurons in the caudate and putamen are GABAergic, meaning they release the neurotransmitter gamma-aminobutyric acid (GABA). They do receive input from dopaminergic neurons, which play a crucial role in regulating the activity of medium spiny neurons. Additionally, medium spiny neurons are the major output neurons of the striatum, projecting their axons to various target areas.

However, it is incorrect to state that medium spiny neurons outnumber their target neurons in the globus pallidus by about a factor of 1,000. In reality, the connectivity and ratios between these neurons can vary, and the specific ratio mentioned here is not accurate. The connectivity and ratios between medium spiny neurons and their target neurons in the globus pallidus can be more complex and depend on various factors.

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D. luminosity and surface temperature are the two physical parameters of stars that are plotted in the Hertzsprung-Russell (H-R) diagram. The H-R diagram is a graph that plots the luminosity (or brightness) of stars against their surface temperature (or color).

It allows astronomers to classify stars based on their properties and evolutionary stages. The luminosity is usually represented on the vertical axis, while the surface temperature is represented on the horizontal axis. The H-R diagram is an essential tool for understanding stellar evolution, and it shows the relationship between a star's temperature, luminosity, and evolutionary stage.

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Using Coulomb's law, the magnitude of the force (|FE|) between the two charged clouds can be calculated as:

|FE| = k * (|q1| * |q2|) / r^2

where k is Coulomb's constant, |q1| and |q2| are the magnitudes of the charges on the two clouds, and r is the distance between them.

Substituting the given values, we get:

|FE| = (9 x 10^9 N m^2/C^2) * (|-1.0 C| * |5.0 C|) / (1.5 x 10^3 m)^2

|FE| = (9 x 10^9 N m^2/C^2) * (5.0) / (1.5 x 10^3 m)^2

|FE| = 15 x 10^6 N

To express this answer in scientific notation with two significant figures, we can write:

|FE| = 1.5 x 10^7 N (rounded to two significant figures)

Therefore, the magnitude of the force between the two charged clouds is 1.5 x 10^7 N.

The repulsive force between the two pith balls is 0.098 N.

The repulsive force between two charged objects can be calculated using Coulomb's law:

F = k * (q1 * q2) / r^2

where F is the force, k is Coulomb's constant (9.0 x 10^9 N * m^2 / C^2), q1 and q2 are the charges of the objects, and r is the distance between them.

In this case, both pith balls have equal charges of -20.0 nC, so q1 = q2 = -20.0 nC. The distance between them is 7.00 cm = 0.07 m. Plugging these values into Coulomb's law gives:

F = (9.0 x 10^9 N * m^2 / C^2) * [(-20.0 x 10^-9 C) * (-20.0 x 10^-9 C)] / (0.07 m)^2

F = 0.098 N

Therefore, the repulsive force between the two pith balls is 0.098 N.

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Answer:

what is the question

Explanation: