the photo at right was taken through a specroscope. what color was the pigment extract used to produce this spectrum? what colo(s) did this extract absorb?

The electric motor's efficiency is 51.06%.

The majority of electric motors are made to operate between 50% and 100% of rated load. Typically, maximum efficiency is within 75% of rated load. Hence, the allowable load range for a 10-horsepower (hp) motor is between 5 and 10 hp; its peak efficiency is at 7.5 hp. Below roughly 50% load, a motor's efficiency tends to decline significantly.

To calculate the effort required to raise the object, use the formula:

Work = Force x Distance

= m x g x h (where m is the mass of the object, g is the acceleration due to gravity, and h is the height lifted)

= 34 kg x 9.81 m/s² x 11 m

= 3,769.34 J

The energy consumed by the electric motor is given as 7.4 kJ.

Therefore, the input power is:

Input power = Energy consumed / time taken

= 7.4 kJ / t

Efficiency=(Output power/Input power) x 100%

Output power = Work done/time taken

= 3,769.34 J / t

As a result, the electric motor's efficiency is:

Efficiency=(Output power/Input power)x 100%

= [(3,769.34 J / t) / (7.4 kJ / t)] x 100%

= 51.06%.

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The speed of sound in pure helium is approximately 1006.4 m/s.

When a sound wave travels through a medium, it produces a series of compressions and rarefactions in the medium, which causes the particles of the medium to vibrate. The speed of sound in a particular medium depends on the physical properties of the medium, such as its density, elasticity, and temperature.

The speed of sound in helium can be calculated using the formula,

speed of sound = frequency x wavelength

Given that the frequency of the sound is 170 Hz and the wavelength is 5.92 m, we can plug in these values and get,

speed of sound = 170 Hz x 5.92 m

speed of sound = 1006.4 m/s

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The initial tension applied to the stationary belts is 1116 N.

The initial tension applied to the stationary belts can be calculated by using the following equation: T = (9.55 * P * n)/(π * D), where T is tension, P is power, n is rev/min, and D is diameter.

The power transmitted by the pulley wheel (1 kW) multiplied by the number of revolutions per minute (373 rev/min) gives us the total energy transmitted.

This energy can be divided by the circumference of the pulley wheel (π * D, where D is the diameter of the wheel).

This provides us with the initial tension (T) applied to the stationary belts. Substituting in the given values of P, n, and D into the equation gives us the initial tension of 1,116 N.

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When a pipe is filled with a liquid of higher density than air, the frequency of the normal modes of the pipe decreases.

This is due to the fact that the speed of sound is proportional to the square root of the ratio of the bulk modulus to the density of the medium in which it travels.

When the density of the medium inside the pipe increases, the velocity of sound decreases, causing the frequency of the normal modes to decrease.

he wavelength of the sound waves inside the pipe is shortened due to the increase in density, resulting in a lower frequency of the normal modes.

The frequency of the normal modes of a pipe is influenced by a variety of factors, including the diameter and length of the pipe, as well as the speed of sound in the medium inside the pipe. T

he frequency of the normal modes is inversely proportional to the length of the pipe, with longer pipes producing lower frequencies.

In the case of a pipe filled with a liquid of higher density than air, the frequency of the normal modes would be lower than if it were filled with air.

This is because the speed of sound in the liquid would be lower than in air, resulting in a decrease in the frequency of the normal modes.

When a pipe is filled with a liquid of higher density than air, the frequency of the normal modes of the pipe decreases.

This is due to the fact that the speed of sound in the liquid is lower than in air, resulting in a decrease in the frequency of the normal modes.

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The distance traveled by the object moving with an acceleration of 6.8 m/s² is 42.35 m.

Distance is the length between two points.

To calculate the distance traveled by the object, we use the formula below.

Formula:

Where:

From the question,

Given:

Substitute these values into equation 1 and solve for s

Hence, the distance traveled by the object is 42.35 m.

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Suppose we see the spectral lines to a distant star doppler shifted to smaller wavelengths. This tells us that the star is moving toward the observer.

The Doppler effect, also known as the Doppler shift, is a phenomenon in which waves, such as sound or light waves, shift in frequency when their source and observer are moving relative to one another. As a result, the wavelength appears to be altered when the source of the waves approaches or recedes from the observer.

In this situation, if we see the spectral lines to a distant star Doppler shifted to smaller wavelengths, it suggests that the star is moving towards the observer. It is caused by the Doppler effect, which alters the frequency of light when its source is moving relative to the observer.

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The gravitational force between two masses is inversely proportional to the square of the distance between them. This means that the two masses must be much closer together for the force to be 1.03 N. The masses 0.510 kg and 0.108 kg have to be 0.285 m apart in order for the gravitational force between them to have a magnitude of 1.03 N.

The equation for gravitational force is F=G*m1*m2/d^2, where G is the gravitational constant, m1 and m2 are the two masses, and d is the distance between them.

Assuming G=6.67*10^(-11) Nm^2/kg^2, m1=0.510 kg, and m2=0.108 kg, then d=0.285 m. This is the minimum distance between the two masses for the gravitational force between them to have a magnitude of 1.03 N.

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The time that passes in the car is approximately 70 years. when the sister returns from the trip, she would be approximately 319.15 years old according to Earth's reference frame.

a. To calculate the time that passes in the car, we can use the concept of time dilation in special relativity. The formula for time dilation is:

[tex]\[ \Delta t' = \frac{\Delta t}{\sqrt{1 - \left(\frac{v}{c}\right)^2}} \][/tex]

where [tex]\( \Delta t' \)[/tex] is the time experienced in the moving frame (car), [tex]\( \Delta t \)[/tex] is the time experienced in the stationary frame (house), [tex]\( v \)[/tex] is the velocity of the car, and [tex]\( c \)[/tex] is the speed of light.

Given:

Velocity of the car, [tex]\( v = 89 \, \text{km/hr} = \frac{89}{3.6} \, \text{m/s} \)[/tex]

Time experienced in the stationary frame (house), [tex]\( \Delta t = 70 \, \text{years} \)[/tex]

Converting the velocity to meters per second:

[tex]\[ v = \frac{89}{3.6} = 24.72 \, \text{m/s} \][/tex]

Substituting the given values into the time dilation formula:

[tex]\[ \Delta t' = \frac{70}{\sqrt{1 - \left(\frac{24.72}{299792458}\right)^2}} \][/tex]

Simplifying the expression:

[tex]\[ \Delta t' = \frac{70}{\sqrt{1 - 8.7203 \times 10^{-17}}} \][/tex]

Since the value inside the square root is extremely close to 1, we can approximate the square root as 1:

[tex]\[ \Delta t' \approx \frac{70}{\sqrt{1}} = 70 \, \text{years} \][/tex]

Therefore, the time that passes in the car is approximately 70 years.

b. Using the same formula for time dilation, we can calculate the time that passes on the spacecraft. Given that the speed of the spacecraft is 0.95c, where c is the speed of light, we have:

[tex]\[ \Delta t' = \frac{\Delta t}{\sqrt{1 - \left(\frac{v}{c}\right)^2}} \][/tex]

Given:

The velocity of the spacecraft, [tex]\( v = 0.95c \)[/tex]

Time experienced on Earth, [tex]\( \Delta t = 70 \, \text{years} \)[/tex]

Substituting the values:

[tex]\[ \Delta t' = \frac{70}{\sqrt{1 - (0.95)^2}} \][/tex]

Simplifying the expression:

[tex]\[ \Delta t' = \frac{70}{\sqrt{1 - 0.9025}} \\\\= \frac{70}{\sqrt{0.0975}} \]\\\\\ \Delta t' = \frac{70}{0.31224} \approx 224.33 \, \text{years} \][/tex]

Therefore, during a period of 70 years on Earth, approximately 224.33 years pass on the spacecraft. The clever student will perceive that her life span has been extended because more time has passed for her relative to the observers on Earth.

c. In this scenario, the twin sister is traveling to a distant star and back at a speed of 0.99c. The time experienced in the stationary frame (Earth) is given by [tex]\( \Delta t \)[/tex], which is 45 years. The time experienced in the moving frame (spaceship) is given by [tex]\( \Delta t' \)[/tex].

Using the time dilation formula:

[tex]\[ \Delta t' = \frac{\Delta t}{\sqrt{1 - \left(\frac{v}{c}\right)^2}} \][/tex]

Given:

The velocity of the spaceship, [tex]\( v = 0.99c \)[/tex]

Time experienced on Earth, [tex]\( \Delta t = 45 \, \text{years} \)[/tex]

Substituting the values:

[tex]\[ \Delta t' = \frac{45}{\sqrt{1 - (0.99)^2}} \][/tex]

Simplifying the expression:

[tex]\[ \Delta t' = \frac{45}{\sqrt{1 - 0.9801}} \\\\= \frac{45}{\sqrt{0.0199}} \]\\\\\ \Delta t' = \frac{45}{0.141} \approx 319.15 \, \text{years} \][/tex]

Therefore, when the sister returns from the trip, she would be approximately 319.15 years old according to Earth's reference frame.

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The amount of charge transferred is 4.5C (coulombs). This is calculated by dividing 45 J (joules) of work by 9.0 V (volts) of voltage.

We can use the equation W = qV, where W is the work done, q is the charge transferred, and V is the potential difference (voltage) across the battery.

Rearranging the equation to solve for q, we get q = W/V.

Plugging in the values given, we have:

q = 45 J / 9.0 V

q = 5.0 C

Therefore, the battery transfers 5.0 coulombs of charge from the negative to the positive terminal while doing 45 J of work.

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Answer:

320 km/hr = 320000 / 3600 = 88.9 m/s

(1 - v^2  / c^2) = (1 - 88.9^2 / 100^2)^1/2 = .46

Since L = L0 (1 - v^2  / c^2)^1/2

L = .46 L0 = 20.7 m

The airplane will appear to be only 20.64 m long to an observer at rest in this universe, even though its actual length is 45 m when at rest.

In this universe, the speed of light is only 100 m/s, which is much slower than in our universe, where the speed of light is approximately [tex]3 \times 10^8 m/s[/tex]. This means that the effects of special relativity will be much more noticeable in this universe.

We can use the formula for length contraction to calculate the apparent length of the airplane as seen by an observer at rest:

[tex]L' = L / \gamma[/tex]

where L is the length of the airplane at rest, L' is the apparent length of the airplane as seen by the observer, and γ is the Lorentz factor given by:

[tex]\gamma = \frac{1}{\sqrt{1 - v^2/c^2}}[/tex]

where v is the speed of the airplane relative to the observer, and c is the speed of light in the given universe.

Converting the airplane's speed from km/h to m/s, we have:

[tex]v = (320 \ km/h) \times (1000 \ m/km) / (3600 \ s/h) = 88.89 \ m/s[/tex]

Substituting this value and c = 100 m/s into the expression for γ, we get:

[tex]\gamma = \frac{1}{\sqrt{1 - (88.89 m/s)^2 / (100 m/s)^2}} = 2.18[/tex]

Substituting this value of γ and L = 45 m into the expression for L', we get:

[tex]L' = L / \gamma = 45 \ m / 2.18 = 20.64 \ m[/tex]

Therefore, the length of the plane will appear to be 20.64 m. This significant length contraction is due to the low speed of light in this universe.

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When energy waves pass through the valley and reach the mountain, the waves will be reflected back, the material that you can expect to find in valleys are generally soil and rock formations.

The Energy waves are also formed by

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When we look into a mirror, a process called reflection occurs with the light.

What happens to the light:
1. Light source: The process begins with a light source, such as the sun or a light bulb, emitting light waves in all directions.
2. Light traveling: The light waves travel through the air and reach the mirror.
3. Mirror's surface: Mirrors have a smooth, reflective surface made of glass with a thin layer of metal, usually aluminum or silver, on the back.
4. Incident light: The light waves that strike the mirror's surface are called incident light.
5. Reflection: The mirror's smooth surface causes the incident light waves to bounce off, or reflect, at the same angle at which they arrived.

This is known as the law of reflection, which states that the angle of incidence is equal to the angle of reflection.

6. Reflected light: The light waves that bounce off the mirror are called reflected light.
7. Image formation: As the reflected light waves travel away from the mirror, they converge at a point and form an image of the object you see in the mirror.
8. Observing the image: Your eyes detect the reflected light waves, and your brain processes this information to create the perception of the image you see in the mirror.
In summary, when you look into a mirror, the light emitted from a source travels towards the mirror, strikes its reflective surface, and bounces off at the same angle, following the law of reflection.

The reflected light then forms an image, which you observe as the reflection in the mirror.

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It would take approximately 19.2 years for the asteroid to orbit once around the sun. But that none of the answer choices match the calculated value of approximately 19.2 years.

The period (T) of an orbit of a celestial body with semimajor axis (a) around the sun can be calculated using Kepler's third law:

T² = (4π² / GM) * a³

where G is the gravitational constant and M is the mass of the sun.

Plugging in the given value for the semimajor axis (a = 4 AU), we get:

T² = (4π² / (6.674 × 10⁻¹¹ m³/(kg s²) * 1.989 × 10³⁰ kg)) * (4 AU)³

T² = 3.652 × 10¹⁶ s²

Taking the square root of both sides, we get:

T = 6.04 × 10⁸ s

We can convert this time to years by dividing by the number of seconds in a year:

T = (6.04 × 10⁸ s) / (31,536,000 s/year)

T ≈ 19.2 years

Therefore, it would take approximately 19.2 years for the asteroid to orbit once around the sun. The closest answer choice is 16 years.

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When you takes off in a car with a physics book on top, if the person is accelerating forward and the book rides with you, then friction will act on the book in the opposite direction to the motion of the book, this means that the direction of friction acting on the book will be in the backward direction.

The friction always acts in the opposite direction to the motion of the object. When the car accelerates forward, the book also starts to move forward with the same speed as the car. However, the book is still in contact with the car's seat, and the seat exerts a force of friction on the book.

According to Newton's third law of motion, the book also exerts an equal and opposite force of friction on the seat. Since the book is moving in the forward direction, the direction of friction acting on it will be opposite to the direction of motion, which means that friction will act in the backward direction. Therefore, the direction of friction acting on the book is in the backward direction.

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Filling the space between a capacitor's plates with a dielectric material will increase the capacitance of the capacitor.

1. A dielectric material is inserted between the plates of the capacitor.

This material has the property of reducing the electric field between the plates.
2. The relationship between electric field (E) and voltage (V) is given by E = V/d, where d is the distance between the plates.

Since the electric field is reduced by the presence of the dielectric material, the voltage (potential difference) between the plates also decreases.

3. The relationship between capacitance (C), voltage (V), and charge (Q) is given by C = Q/V.

As the voltage decreases due to the presence of the dielectric material, the capacitance increases for a given charge on the plates.

4. The dielectric material has a property called dielectric constant (K), which is a measure of how effectively it reduces the electric field between the plates.

The capacitance of the capacitor with the dielectric material is given by C = K * C0,

where C0 is the capacitance without the dielectric material.

Since K is always greater than 1 for dielectric materials, the capacitance with the dielectric material is always higher than without it.
In conclusion, filling the empty (vacuum) space between a capacitor's plates with dielectric material will increase the capacitance of the capacitor.

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The phases of Venus show that the solar system is in a heliocentric model instead of a geocentric model because the heliocentric model states that the Sun is at the center of the solar system, while the geocentric model states that Earth is at the center of the universe.

The phases of Venus can only be explained in the heliocentric model because the planet is orbiting the Sun.The phases of Venus are an important piece of evidence supporting the heliocentric model proposed by Nicolaus Copernicus. The geocentric model was the widely accepted model of the universe until the 16th century when Copernicus proposed the heliocentric model, which suggested that the Sun is at the center of the solar system and the Earth and other planets orbit around it.

The phases of Venus show that it orbits the Sun and not the Earth because, as it orbits the Sun, different portions of the planet's sunlit side are visible from Earth. This can only occur in a heliocentric model because Venus is between the Earth and the Sun in its orbit, which causes it to pass through phases. Therefore, the phases of Venus are not consistent with a geocentric model, which suggests that Venus orbits the Earth.

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Therefore, the mass of Jupiter is approximately 1.898 × 1027 kg.

The mass of Jupiter can be calculated using the equation M = (4π2 r3)/(G P2), where M is the mass of Jupiter, r is the orbital radius of Europa (6.708 105 km), G is the gravitational constant (6.674 × 10-11 m3 kg-1 s-2), and P is the orbital period of Europa (3.551 days).

The circular orbit of Europa is given as, r = 6.708 × 105 km. The period of Europa is given as, T = 3.551 days are supposed to calculate the mass of Jupiter. In order to calculate the mass of Jupiter, we need to use Kepler's 3rd law. Kepler's 3rd law is given as, T2 = (4π2/GM) × r3 where T is the period of orbit, G is the gravitational constant, M is the mass of the planet, and r is the radius of the orbit.

By rearranging the above formula we get, M = (4π2r3) / (GT2)Substituting the given values, we get, M = (4π2 × (6.708 × 105)3) / ((6.67430 × 10-11) × (3.551 × 24 × 60 × 60)2) ≈ 1.898 × 1027 kg. Therefore, the mass of Jupiter is approximately 1.898 × 1027 kg.

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The speed of a point 6.0 cm from the center axle is approximately 4.524 cm/s, and the acceleration of this point on the disk is approximately 3.408 cm/s².

The first step to solving this problem is to convert the rotational speed from revolutions per minute (rpm) to radians per second (rad/s):

ω = (7200 rpm) * (2π rad/rev) / (60 s/min) ≈ 753.98 rad/s

The speed of a point 6.0 cm from the center axle can be found using the formula:

v = r * ω

where r is the distance from the center axle to the point of interest. Substituting the given values, we get:

v = (6.0 cm) * 0.75398 rad/s ≈ 4.524 cm/s

To find the acceleration of this point on the disk, we can use the formula for centripetal acceleration:

a = r * ω²

where r is the distance from the center axle to the point of interest, and ω is the angular velocity in radians per second. Substituting the given values, we get:

a = (6.0 cm) * (0.75398 rad/s)² ≈ 3.408 cm/s²

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The fraction of the engine power used to make the airplane climb is 83% to two significant figures.

The power generated by the engine is given by the equation P=W/t, where P is power, W is work, and t is time.

The work done in lifting the airplane can be calculated as W=mgh, where m is mass, g is the gravitational constant, and h is the altitude gained.

Therefore, the power used to make the airplane climb can be calculated as P=mgh/t, where t is the time taken to gain the altitude.

Since the rate of climb is given as 2.5 m/s, the time taken to gain the altitude can be calculated as t=h/2.5, where h is the altitude gained.

Substituting the values into the equation, the power used to make the airplane climb can be calculated as P=750*9.8*h/2.5, where h is the altitude gained.

Therefore, the fraction of the engine power used to make the airplane climb is

P/(80*1000)=750*9.8*h/(2.5*80*1000).

Finally, the fraction of the engine power used to make the airplane climb expressed as a percentage is

(750*9.8 h/(2.5*80*1000))*100=83%.

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2.48 × 10⁻¹² C charge can be packed onto a green pea before the pea spontaneously discharges.

The electric field at the surface of the sphere is given by the formula:

E = k × Q / r²

where:

k is the Coulomb's constant (8.99 × 10^9 N m²/C²),

Q is the charge on the sphere, and

r is the radius of the sphere.

Given:

Electric field strength for the breakdown, E = 2.85 × 10^6 N/C

Diameter of the pea, d = 0.620 cm = 0.0062 m

the electric field at the surface of the pea using the formula:

E = k × Q / r²

Q = E × r² / k

Q = 2.85 × 10⁶ ×  0.0062²/ 8.99 × 10⁹

Q = 2.48 × 10⁻¹² C

Therefore, 2.48 × 10⁻¹² C charge can be packed onto a green pea before the pea spontaneously discharges.

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Answer: B

Explanation:

The y component of the vector is given by the formula:

y component = magnitude of the vector x sin(angle between the vector and the y-axis)

In this case, the magnitude of the vector is 120 N and the angle between the vector and the y-axis is 50 degrees. So we have:

y component = 120 N x sin(50°) ≈ 92 N

Therefore, the answer is (B) 92 N.

On june 9, 1988, Sergei Bubka broke the world pole-vaulting record for the 8th time in four years by attaining a height of 6.10 m. It took Bubka 1.11 seconds to return to the ground from the highest part of his vault.

Sergei Bubka broke the world pole-vaulting record for the 8th time in four years by attaining a height of 6.10 m on June 9, 1988. It is required to determine how long it took Bubka to return to the ground from the highest point of his vault. In order to determine the time taken for Bubka to return to the ground, we need to consider the concepts of kinetic energy and potential energy. The pole vaulter gains potential energy during the ascent phase of the vault as he gains altitude. When he reaches the highest point, he has the maximum potential energy. During the descent phase of the vault, the potential energy is converted into kinetic energy.

Based on this principle, we can use the conservation of energy equation to find the time taken by Bubka to return to the ground. The equation for conservation of energy is given as: Potential energy (P.E) = Kinetic energy (K.E)

P.E = mgh where m is the mass of the object, g is the acceleration due to gravity, and h is the height of the object above the ground.

K.E = 1/2 mv² where v is the velocity of the object.

The velocity of Bubka when he reached the highest point can be assumed to be zero since he had to come to a stop before starting his descent. Therefore, the initial kinetic energy is zero.

P.E at the highest point = K.E at the lowest point

Let t be the time taken by Bubka to return to the ground. We can assume that Bubka moves with uniform acceleration. Using the kinematic equation, we have: v = u + at where u is the initial velocity and a is the acceleration.

When Bubka reaches the ground, his final velocity is zero.

Therefore, we have: v = 0u = at

Substituting the value of u in the equation for K.E, we have: K.E = 1/2 mv² = 1/2 ma²t²

Substituting the value of P.E and K.E in the equation for conservation of energy, we have:

mgh = 1/2 ma²t²

Simplifying, we get: t = sqrt(2h/g)

Substituting the values of h and g, we have:

t = sqrt(2 x 6.10 / 9.81)t = sqrt(1.240)t = 1.11 seconds

Therefore, it took Bubka 1.11 seconds to return to the ground from the highest part of his vault.

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If the frequency of the incoming light is decreased, the energy of the ejected electrons will decrease.

The frequency of the incoming light will affect the energy of the ejected electrons. This is because the energy of the ejected electrons is proportional to the frequency of the incoming light.

The energy of the electrons can be determined using the equation:

E = h * f,

where E is the energy, h is Planck’s constant, and f is the frequency of the incoming light. This equation shows that the energy of the electrons is directly proportional to the frequency of the incoming light.

Therefore, if the frequency of the incoming light is decreased, the energy of the ejected electrons will also decrease.

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The charges of the spheres after connection will be the same as the charge of the left sphere. The total charge of the two spheres after connection is equal to the initial charge of the left sphere.

To understand this, it is important to know that electric charge is a conserved quantity. This means that the net charge of a system cannot change. Therefore, if two objects with opposite charges (like the two spheres) are connected, the charges of the two objects will become equal and the total charge of the two spheres will remain the same as the initial charge of the left sphere.
To further understand this concept, consider two spheres with opposite charges. If the two spheres are not connected, then the total charge of the two spheres is equal to the sum of the charges of each sphere. However, if the two spheres are connected, the net charge of the system cannot change. Therefore, the charge of each sphere will become equal and the total charge of the two spheres after the connection will remain the same as the initial charge of the left sphere.

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To store 12.0 C of charge, you would need a capacitor with capacitance of 1.20 F.

Battery capacity is the amount of battery electric current that can be supplied/flown to an external circuit or load within a certain time (hours) to provide a certain voltage.

The capacitance required to store 12.0 C of charge in a capacitor connected to a single 10.0 V battery can be calculated using the formula,

Q = CV

where Q is the charge, C is the capacitance, and V is the voltage. Rearranging this equation, we get,

C = Q/V

Plugging in the given values, we get,

C = 12.0C/10.0V = 1.20 F

Therefore, the capacitance required to store 12.0 C of charge is 1.20 F (to three significant figures).

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A proton that has been accelerated from rest through a potential difference of -800 V has a speed of: 2.60 x 10⁶ m/s.

When a particle is accelerated through a potential difference, its potential energy is transformed into kinetic energy, resulting in an increase in velocity.

To calculate the velocity of a proton that has been accelerated through a potential difference of -800 V, we may use the equation: v = √(2qV/m)

where: v is the speed of the proton,

q is the charge of the proton (1.6 x 10⁻¹⁹ C),

V is the potential difference (-800 V)

m is the mass of the proton (1.67 x 10⁻²⁷ kg)

Using these values, we may calculate the velocity:

v = √(2(1.6 x 10⁻¹⁹C)(-800 V)/(1.67 x 10⁻²⁷kg))= 2.60 x 10⁶ m/s

Therefore, the velocity of a proton that has been accelerated from rest through a potential difference of -800 V is 2.60 x 10⁶ m/s.

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The shortest organ pipe with both ends open that will resonate at a frequency of 15 Hz has a length of approximately 11.43 meters.

The wavelength of a sound wave is related to its frequency by the formula,

λ = v/f

where λ is the wavelength, v is the velocity of sound, and f is the frequency.

For a pipe with both ends open, the fundamental frequency (the lowest resonant frequency) is given by,

f = v/2L

where L is the length of the pipe.

We can combine these two equations to find the shortest length of an open pipe that will resonate at a frequency of 15 Hz,

λ = v/f = v/(v/2L) = 2L

L = λ/2 = v/(2f) = 343/(2*15) = 11.43 m

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Answer: Two objects collide and stop. Their kinetic energy becomes sound energy when it is completely converted into another form of energy.

Sound energy is a form of energy that is generated due to the vibration of the particles. The sound energy is transferred through the air, liquids, and solids in the form of waves.

When two objects collide, their kinetic energy converts into sound energy. This sound energy is due to the collision of the objects. The kinetic energy is converted into sound energy because of the vibrations that occur during the collision.

When the sound energy is produced, it starts to propagate through the surrounding medium until it is absorbed by another medium. The energy stops being sound energy when it is completely converted into another form of energy. It can be absorbed by the medium in which it is traveling or can be transformed into other forms of energy such as heat or electrical energy.

Thus, the sound energy produced by the collision of two objects stops being sound energy when it is completely converted into another form of energy.

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The length of runway needed for a light plane to take off with a constant acceleration of 3.0 m/s2 and a speed of 35 m/s is 203.7 meters.

The time taken for a light plane to reach 35 m/s from 0 m/s is given by using the formula,

v = u + at

where, v = final velocity, u = initial velocity, a = acceleration, and t = time

Here, the initial velocity of the plane is u = 0 m/s.

The final velocity of the plane is v = 35 m/s.

The acceleration of the plane is a = 3.0 m/s².

The time taken to reach the final velocity can be calculated as,

35 = 0 + (3.0)t

t = 35 / 3.0

t = 11.67 s

Therefore, the plane takes 11.67 s to reach a speed of 35 m/s for takeoff.

The distance traveled by plane during this time can be calculated as,

s = ut + 1/2 at²

s = 0 x 11.67 + 1/2 x 3.0 x (11.67)²

s = 203.7 m

Therefore, the runway should be at least 203.7 meters long if the acceleration is constant at 3.0 m/s².

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The longest possible wavelength for a standing wave on a string is: the length of the string itself

This is because, in order to create a standing wave, two traveling waves must interfere with one another and create a wave pattern that is fixed in space.

As the wavelength of the traveling waves increases, the nodes (points of zero displacements) of the standing wave become closer together. Therefore, if the wavelength is equal to the length of the string, the nodes of the standing wave are located at the two ends of the string and the wave pattern remains stationary.

This means that any longer wavelength traveling wave would not be able to interfere and form a standing wave on the string.

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