3. The timeline below shows the sequence of events leading to the
Constitutional Convention. (H)






March 1781 Sept. 1783 Aug. 1786 Sept.1786 May 1787

Which conclusion can be drawn from the timeline?

A. Americans realized their first national government was not strong enough.
B. Most Americans felt the national government under the Articles of
Confederation was too strong.
C. Shays’ Rebellion had no influence on the decision to strengthen the
national government.
D. The new government was unable to negotiate a peace with Britain.

Electromagnetic radiation consists of particles called photons, each of which has a discrete amount, or quantum, of energy. However, since electromagnetic radiation also has wave properties, each particle is also characterized by a specific wavelength(m) and frequency (s-1).

What is wavelength?

A periodic wave's wavelength is the distance that its shape repeats. It is a feature of both travelling and standing waves, as well as other spatial wave patterns. It is the distance between two successive points on a wave that belong to the same phase, such as two nearby crests, troughs, or zero crossings. The spatial frequency is the reciprocal of wavelength. Lambda (λ), a Greek letter, is typically used to represent wavelength. The term wavelength is occasionally used to refer to all modulated waves, their sinusoidal envelopes, or waves created by the interference of several sinusoids.

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Answer:

0.018 cm

Explanation:

The increase in length can be calculated using the formula:

ΔL = α * L * ΔT

where ΔL is the increase in length, α is the linear expansivity of iron, L is the original length of the rod, and ΔT is the change in temperature.

Plugging in the values, we get:

ΔL = 1.2 x 10^-5 * 30 * 50

ΔL = 0.018 cm

So, the iron rod increases in length by 0.018 cm when heated through 50 Kelvin.

Answer:

118,000 J

Explanation:

The law of conservation of energy states that the total energy in a system remains constant, it can be transformed from one form to another, but the total energy remains the same.

Given that the total energy of the object is 210,000 J, and its potential energy at a certain point along the track is 92,000 J, we can use the law of conservation of energy to find the kinetic energy of the object at that point.

The total energy of the object is equal to the sum of its kinetic energy (KE) and its potential energy (PE):

E_total = KE + PE

Substituting the given values:

210,000 J = KE + 92,000 J

Solving for KE:

KE = 210,000 J - 92,000 J = 118,000 J

So, the object has a kinetic energy of 118,000 J at the same point where its potential energy is 92,000 J.

This follows the law of conservation of energy because the total energy of the object remains constant, and the change in potential energy is equal to the change in kinetic energy.

Answer:

[tex]2\; {\rm \Omega}[/tex].

Explanation:

The lower case "[tex]r = 1\; {\rm \Omega}[/tex]" in the circuit diagram indicates that the internal resistance of this [tex]12\; {\rm V}[/tex]-battery is [tex]1\; {\rm \Omega}[/tex].

In practice, the rated [tex]12\; {\rm V}[/tex] voltage drop across this battery is split across not just the resistors in the external circuit, but also across the internal resistance of the battery.

The voltameter in this circuit measures the voltage drop across the [tex]3\; {\rm \Omega}[/tex] resistor and the unknown resistor [tex]R[/tex]. The voltage drop across the internal resistance and the other resistor (a total of [tex]1\; {\rm \Omega} + 4\; {\rm \Omega} = 5\; {\rm \Omega}[/tex]) would be [tex]12\; {\rm V} - 6\; {\rm V} = 6\; {\rm V}[/tex].

Divide the voltage drop by the resistance to find the current:

[tex]\begin{aligned}I &= \frac{V}{R} \\ &= \frac{6\; {\rm V}}{5\; {\rm \Omega}} = 1.2\; {\rm A}\end{aligned}[/tex].

Since this circuit is serial, current would be the same everywhere in the circuit. Given that voltage drop across the [tex]3\; {\rm \Omega}[/tex] resistor and the unknown resistor is [tex]6\; {\rm V}[/tex], the resistance of that part of the circuit would be:

[tex]\begin{aligned}\frac{6\; {\rm V}}{1.2\; {\rm A}} = 5\; {\rm \Omega}\end{aligned}[/tex].

Subtract the [tex]3\; {\rm \Omega}[/tex] from the resistance to find the value of [tex]R[/tex]:

[tex]R = (5\; {\rm \Omega} - 3\; {\rm \Omega}) = 2\; {\rm \Omega}[/tex].

The bullet will hit the ground approximately 164.25 meters away from the base of the building.

Assuming no air resistance, we can use the equations of motion to solve this problem.

First, we need to find the time it takes for the bullet to hit the ground. We can use the equation:

h = 1/2 * g * t^2

where h is the height of the building, g is the acceleration due to gravity (approximately 9.81 m/s²), and t is the time taken for the bullet to hit the ground.

Plugging in the values, we get:

30 = 1/2 * 9.81 * t²

Solving for t, we get:

t = √(30 / (1/2 * 9.81)) = 2.19 seconds

Now that we know the time, we can find the horizontal distance traveled by the bullet using the equation:

d = v * t

where d is the horizontal distance, v is the initial velocity of the bullet, and t is the time taken for the bullet to hit the ground.

Plugging in the values, we get:

d = 75 * 2.19 = 164.25 meters

Therefore, the bullet will hit the ground approximately 164.25 meters away from the base of the building.

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Answer:

11.33 km/min

Explanation:

170km ÷ 15min = 11.33km/min

To obtain the lowest power at the detector, move the ideal mirror to the right by 86.2 nm; the lowest power is 0.225 mW.

We can divide a laser beam into two pathways using a 50-50 beam splitter, bounce one route off a perfect mirror, and bounce the other path off a mirror that does not reflect all light to form an interferometer.

In this configuration, interference between the two laser light streams can result in a pattern of both constructive and destructive interference that can be picked up by a detector.

We can adjust the ideal mirror to the right to create a minimal power at the detector if the measured power is initially at its maximum. This is due to the fact that shifting the mirror can alter the interference pattern by changing the distance between the two pathways taken by the laser light.

We may utilize the fact that the measured power is highest when the two laser light streams are in phase and minimum when they are out of phase to calculate how far we need to move the ideal mirror. The power measured at the detector when just the vertical arm is blocked is 2.25 mw, and when only the horizontal arm is blocked, it is 2.025 mw.

Power detected at detector is:

P = (1/2) * [tex]P_in[/tex] * (1 +- [tex]cos(Δφ)[/tex]))

where [tex]P_in[/tex] : incident power, Δφ : light phase difference and the ± sign depends on whatever path is blocked.

When power: maximum, phase difference :integral multiple of [tex]2\pi[/tex], i.e., Δφ = [tex]2\pi n[/tex]. When the power is minimum, the phase difference is an odd multiple of π, i.e., Δφ = [tex](2n+1)\pi /2.[/tex]

Solve phase difference:

Δφ = [tex]arccos[(4P_min/P_in) - 1][/tex]

[tex]P_min[/tex] :min power at detector =  2.025 mw.

Substitute values:

Δφ = [tex]arccos[(4*2.025/9) - 1] = 2.18 radians[/tex]

To find detector power, change the phase difference to [tex](2n+1)\pi /2[/tex]. Move perfect mirror by a distance Δx :

Δφ = [tex](2n+1)\pi /2 = 1.57, 4.71, 7.85, ...[/tex]

We use laser wavelength to find distance Δx:

Δx = Δφ * λ / [tex]2\pi[/tex]

λ: laser wavelength wavelength which is 400 nm

Substitute values:

Therefore,

Δx = 86.2 nm

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The energy associated with movement is Kinetic Energy, while energy that is stored is Potential Energy.

Two types of energy—kinetic energy and potential energy—describe the condition of a system. While potential energy is the energy stored in an object or system based on its location or configuration, kinetic energy is the energy of motion.

The energy that an object has as a result of motion is known as kinetic energy. The formula KE=1/2mv2 can be used to calculate an object's kinetic energy, which depends on its mass and speed. In this instance, m stands for the object's mass and v for its speed. An object has more kinetic energy the faster it moves. For instance, a moving vehicle has more kinetic energy than a vehicle that is stationary.

On the other hand, potential energy is the energy that an object has as a result of its position or configuration. It is frequently referred to as the energy that a thing possesses as a result of its capacity for labor. Gravitational potential energy, or the energy an item has as a result of its position with respect to a reference point like the ground, is the most typical illustration of potential energy. A lower-altitude item has less gravitational potential energy than a higher-altitude object. PE=mgh, where m is the object's mass, g is the acceleration brought on by gravity, and h is the object's height above the reference point, is the formula for gravitational potential energy.

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The orbit of the Earth around the Sun is an elliptical, or oval-shaped, path that takes approximately 365.25 days to complete one full revolution.

The Earth's orbit is not perfectly circular, but rather slightly elongated, with the Sun located at one of the two foci of the ellipse.

During its orbit, the Earth's distance from the Sun varies, with the closest approach occurring in early January and the farthest distance occurring in early July. This variation in distance, along with the Earth's axial tilt, is responsible for the changing seasons on Earth.

The orbit of the Earth around the Sun is governed by the gravitational pull of the Sun, as well as the gravitational interactions between the Earth and other planets in the solar system. Despite the complex forces at play, the Earth's orbit remains remarkably stable over long periods of time.

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The number of electrons that corresponds to the number of charges is 2.71 × 10¹⁰ electrons.

The breakdown field strength of air is 3 × 10⁶ N/C, and the distance between the fingertip and the doorknob is 2 cm, so the electric field between the two is given by:

E = 3 × 10⁶ N/C

The electric field causes the charge on the fingertip to be drawn towards the doorknob, so we can calculate the charge on the fingertip using the formula:

q = 4π ε_0 x Er²

where;

r is the radius of the fingertip (0.71 cm) and

ε_0 is the permittivity of free space (8.854 × 10^-12 C^2/Nm²).

q = 4  x π  x 8.854 × 10⁻¹² x 3 × 10⁶  x  0.71²

q = 2.17 × 10⁻⁸ C

The charge on the doorknob is equal and opposite to the charge on the fingertip, so the total charge on both is calculated as;

Q_total =  2  x 2.17 × 10⁻⁸ C

= 4.34 × 10⁻⁸ C.

The number of electrons is calculated as follows;

number of electrons = q / e

where;

number of electrons = ( 4.34 × 10⁻⁸ C / 1.60218 × ⁻¹⁹ C )

number of electrons = 2.71 × 10¹⁰ electrons

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Vega and Sirius are both well-known stars that are often mentioned in astronomical and popular culture.

Vega is a bright, blue-white star located 25 light-years from Earth. It is one of the brightest stars in the night sky and is often used as a reference star in various astronomical studies.

Sirius, also known as the Dog Star, is the brightest star in the night sky and is located approximately 8.6 light-years from Earth. It is a binary star system, consisting of a main-sequence star (Sirius A) and a white dwarf star (Sirius B).

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The value of the point charge is zero.

What do you mean by charge?

Charge, also known as electric charge, electrical charge, or electrostatic charge and denoted by the symbol q, is a property of a unit of matter that indicates how many more or fewer electrons than protons it contains.

When a subatomic particle is exposed to an electric and magnetic field, its electric charge causes it to feel a force. There are two sorts of electric charges: positive and negative. The electric field outside the sphere is the same as the field from a point charge with a net charge of Q, according to Gauss' law, whereas the electric field inside the sphere is zero. For a solid or hollow sphere, this conclusion holds valid.

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It might be useful to be able to turn the electromagnet on and off so as to latch onto and let go of objects.

Electromagnets are incredibly useful because they can be used to create a magnetic field on demand. This means they can be used to quickly switch a device or system on or off. They can be used to quickly pick up and move objects, to switch circuits, and to control the flow of electricity in a device. They are also used in many industrial and scientific applications such as manufacturing, motors, generators, and MRI machines. While you cannot feel electromagnetic radiation, it does release specific pulses that have an impact on your physical and emotional well-being. It's a good idea to turn off anything that could actually cause some of your organs to shrink.

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The car has 50,000,000 J of kinetic energy when it's halfway to the ground.

The energy that an object has as a result of motion is known as kinetic energy. Kinetic energy, which may be transferred to other objects or changed into other kinds of energy, is present in every moving item.

According to question:

At the top of the cliff, the total energy of the car is purely potential energy, which is given by:

PE = mgh

where m is the mass of the car, g is the acceleration due to gravity (approximately 9.81 m/s²), and h is the height of the cliff relative to the ground.

In this case, the potential energy of the car is given as 100 MJ. However, we need to convert this to joules in order to use it in the kinetic energy calculation later.

1 MJ = 1,000,000 J, so

PE = 100 MJ = 100,000,000 J

Now, when the car falls halfway to the ground, it has lost half of its potential energy, which means it now has:

PE = 0.5 * 100,000,000 J = 50,000,000 J

At this point, the car has also gained some kinetic energy due to its motion. The total energy (potential + kinetic) must still be conserved, so we can use the law of conservation of energy to find the kinetic energy of the car when it's halfway to the ground:

PE(initial) = KE(final)

where KE is the kinetic energy of the car at the final point (when it's halfway to the ground).

So, substituting the values we have:

50,000,000 J = KE

We now know that the car has 50,000,000 J of kinetic energy when it's halfway to the ground.

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Different substances also have different specific heat capacities, which is the amount of energy needed to increase the temperature of an object by a certain amount.

Specific heat is defined as the amount of heat energy required to raise the temperature of one unit of mass of a substance by one degree Celsius (or one Kelvin). It is a physical property that depends on the chemical composition and molecular structure of the substance. Substances with a high specific heat capacity require more heat energy to increase their temperature than substances with a low specific heat capacity. For example, water has a very high specific heat capacity, which means that it takes a large amount of heat energy to raise its temperature by even a small amount. This is why water is often used as a coolant in industrial processes, as it can absorb a large amount of heat without increasing in temperature significantly. On the other hand, metals have low specific heat capacities, which means that they require relatively less heat energy to increase their temperature. This is why metals are often used in cooking utensils, as they can be quickly heated up and used to cook food. Specific heat is an important property in various fields of science and engineering, as it affects the way heat is transferred between different substances, such as in thermal insulation, heating and cooling systems, and chemical reactions.

In summary, specific heat capacity is a property of a substance that determines the amount of heat energy needed to increase the temperature of the substance by a certain amount. Different substances have different specific heat capacities due to differences in their chemical composition and molecular structure.

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The acceleration of the elevator is [tex]2.19 m/s^2[/tex], calculated using Newton's second law and the forces on the hanging mass.

The acceleration of the elevator can be determined by analyzing the forces acting on the hanging mass. When the elevator is in motion, the hanging mass is subjected to two forces: its weight (mg), which always points downward, and the tension force in the spring scale, which is equal in magnitude but opposite in direction to the weight (since the mass is not accelerating vertically).

Using Newton's second law of motion (F=ma), we can set up the following equation:

T - mg = ma

where T is the tension force in the spring scale, m is the mass of the hanging mass (10.0 kg), and a is the acceleration of the elevator (which we want to find).

Substituting the given values, we get:

120 N - (10.0 kg)[tex](9.81 m/s^2)[/tex] = (10.0 kg) a

Simplifying and solving for a, we get:

a = (120 N - 98.1 N) / (10.0 kg) =[tex]2.19 m/s^2[/tex]

Therefore, the acceleration of the elevator is [tex]2.19 m/s^2[/tex].

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(8) The critical angle of a boundary of two materials is the angle of incidence, measured from the normal to the surface.

The critical angle equation can be derived from Snell's law of refraction, which states that the ratio of the sine of the angle of incidence to the sine of the angle of refraction is equal to the ratio of the refractive indices of the two materials.

(9) Total internal reflection can be applied to optical fibers by using it to confine light inside the fiber.

(10) Three advantages of using optical fibers for communication are:

Low attenuation, Immunity to electromagnetic interference and Large bandwidth.

(11. a) The critical angle for the boundary is  67 degrees.

(11. b) The angle of incidence is 90 degrees.

The critical angle for the boundary can be found by using the critical angle equation derived from Snell's law.

Setting the refractive index of the first material (core) to 1.52 and the refractive index of the second material (cladding) to 1.40, we have:

sin(critical angle) = (1.40)/(1.52) = 0.92

The critical angle can be found using the inverse sine function:

critical angle = sin^-1(0.92) = 67.3 degrees

The angle of incidence at which total internal reflection occurs can be found by setting the angle of refraction to 90 degrees in Snell's law:

sin(90) = (1.52)/sin(angle of incidence)

Solving for the angle of incidence:

angle of incidence = sin^-1((1.52)/(1.40)) = 90 degrees.

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Answer:

The critical angle of a boundary of two materials is defined as the angle of incidence at which the angle of refraction becomes 90°, causing total internal reflection to occur. In other words, it is the minimum angle of incidence required for light to be completely reflected back into the material with the higher refractive index.

The concept of total internal reflection can be applied to optical fibres by using them to guide light through a core with a higher refractive index surrounded by a cladding with a lower refractive index. The light is completely reflected at the core-cladding boundary and guided along the fiber, allowing it to be transmitted over long distances without significant loss of signal. This is the basic principle behind optical fiber communication.

The advantages of using optical fibers for communication are:

High bandwidth: Optical fibers have a much larger bandwidth compared to traditional copper wires, allowing for much faster and more efficient communication.

Immunity to Electromagnetic Interference (EMI): Optical fibers are immune to EMI and do not emit electromagnetic radiation, making them more secure and reliable for communication.

Immunity to environmental factors: Optical fibers are less susceptible to environmental factors such as temperature, humidity, and water damage compared to copper wires, leading to fewer signal disruptions and failures.

a) The critical angle for the boundary can be found using the equation:

sin(Θc) = n2/n1

where n1 is the refractive index of the core (1.52) and n2 is the refractive index of the cladding (1.40). Plugging in these values, we find:

sin(Θc) = 1.40/1.52 = 0.921

Taking the inverse sine of both sides, we find the critical angle:

Θc = sin^-1(0.921) = 63.7°

b) For total internal reflection to happen at the boundary, the angle of incidence must be greater than the critical angle. Thus, the angle of incidence required for total internal reflection to occur is:

Θ = Θc = 63.7°

Azimuth is the angle measured from the horizon's north or south pole to the bottom of the vertical circle around a celestial body. The star's azimuth is 180 degrees if it is south of the zenith and facing south. The star's altitude is 90-10 = 80° if it is 10° from the zenith. Because the sky appears to change from East to West as the Earth spins, you do need to let your companions know what time it is.

Azimuth is the angle measured from the horizon's north or south pole to the bottom of the vertical circle around a celestial body. A horizontal direction's azimuth is defined as how much it deviates from north or south. heavenly coordinates, a group of numbers used to identify where in the sky (sometimes called the celestial sphere) a celestial object is located. The horizon system (altitude and azimuth), galactic coordinates, the ecliptic system (measured relative to the orbital plane of Earth), and the equatorial system are among the coordinate systems utilized (right ascension and declination, directly analogous to terrestrial latitude and longitude).

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Given voltage drop across

EDLED is 1.8V in forward bias.

1.8 1.8 1.8

100

if

3.1kn

Applying Kirchhoff's voltage law to the circuit,

we get 10-1.8-1.8-1.8 - EXLOUD

<= 0=)46= 8×1000 [= 4.6 MA.

It is safe current level for a LED-for typical Current is arand power LED maximum forward 20 mA.

Voltage is the pressure from an electrical circuit's power source that pushes charged electrons (current) through a conducting loop, enabling them to do work such as illuminating a light. In brief, voltage = pressure, and it is measured in volts (V).

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Civilian los activities are often carried out on the9.15  mhz, 2.45 ghz, or 5.8ghz radio frequencies.

The oscillation rate of an alternating electric current or voltage, or of a magnetic, electric, or electromagnetic field, or of a mechanical system in the frequency range of roughly 20 kHz to around 300 GHz, is referred to as radio frequency (RF). This is about between the upper and lower limits of audio and infrared frequencies; these are the frequencies at which energy from an oscillating current may radiate into space as radio waves. Different sources offer different upper and lower frequency limitations.

The flow of electricity

Electric currents that oscillate at radio frequencies (RF currents) have particular features not shared by direct current or lower audio frequency alternating current, such as the 50 or 60 Hz current utilized in electrical power distribution. RF currents in conductors can radiate energy into space as electromagnetic waves (radio waves). This is the fundamental principle of radio technology.

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When a circuit is finished and current can flow, it is said to be in a closed-circuit condition. In the closed position, the current has a clear passage.

The light bulb turns on when the switch is closed because current passes through the circuit. The bulb receives its full 120 volts and the intended current flow, which allows it to operate at maximum brightness.

There is a closed (or full) circuit with the bulb when the circuit's wires are attached to the metal casing and metal tip of the lightbulb. The filament will be able to conduct electricity, which will result in the bulb lighting up.

Therefore, in this case, both bulbs receive the same amount of electricity both before and after the switch is closed. Consequently, the brightness doesn't change.

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The age of the rock is 3.512 billion years.

What are 3 types of rocks?

1. Igneous rocks

2. Sedimentary rocks

3. Metamorphic rocks

For the first rock, the number of potassium-40 atoms is equal to the number of argon-40 atoms. That can only happen when when one half life cycle has elapsed. Therefore the age of this rock is indeed 1.25×109 years. Now let us calculate the age of the second rock sample. Let us say that the number of potassium-40 at the beginning was N​​​​​​0 and the number of potassium-40 after a particular time t us N. There after 1.25 billion years, N= N​​​​​​0 /2.  Now we know the decay constant. This means that every second,5.54×10-10 atoms of potassium-40 decay into argon-40. We can use this decay constant to calculate the time required for the number of argon-40 to be 7 times as much as potassium-40. We want the time required to get the condition N​​​​​ = N​​​​​​0/7. So the correct answer is 3.512 billion years.

Therefore,  the age of the rock is 3.512 billion years.

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The age of the rock is approximately 42 million years, calculated using the equation (7/8) = (1 - [tex]e^{-kt}[/tex] ) with k = ln(2)/1.25 billion years and solving for t.

What is the dating of rock?

The dating of rocks refers to the process of determining the age of rocks or geological events using various techniques, such as radiometric dating, relative dating, and stratigraphy. Radiometric dating involves measuring the ratio of parent and daughter isotopes in a rock, while relative dating involves determining the order of events in geological history. Stratigraphy involves analyzing the layers of sedimentary rocks to determine the relative age of the rocks and the events they represent. These techniques are used by geologists to study the history of the Earth and the processes that have shaped it over time.

The ratio of argon-40 to potassium-40 in a rock can be used to determine the age of the rock based on the half-life of potassium-40. The equation for the decay of potassium-40 to argon-40 is:

K-40 --> Ar-40 + e-

where e- represents an electron and a neutrino.

The half-life of potassium-40 is 1.25 billion years, which means that half of the original amount of potassium-40 will decay to argon-40 in 1.25 billion years. After another 1.25 billion years, half of the remaining potassium-40 will decay, and so on.

If a rock contains seven times as much argon-40 as potassium-40, that means the ratio of argon-40 to potassium-40 is 7:1. We can set up the following equation to solve for the age of the rock:

(7/8) = (1 - [tex]e^{-kt}[/tex])

where k is the decay constant for potassium-40, t is the age of the rock, and e is the mathematical constant approximately equal to 2.71828.

The decay constant for potassium-40 can be calculated using the following formula:

k = ln(2)/t1/2

where ln represents the natural logarithm and t1/2 is the half-life of potassium-40.

Plugging in the values, we get:

k = ln(2)/1.25 billion years = 0.00055 [tex]years^{-1}[/tex]

Substituting k into the first equation and solving for t, we get:

t = -ln(7/8)/0.00055 [tex]years^{-1}[/tex] = 42 million years

Therefore, the age of the rock is approximately 42 million years.

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The longest wavelength of the light that is capable to remove an electron from the potassium metal is 68 nm

The binding energy of the electron in potassium = 1.76 x 10⁶ J/mol

The longest wavelength required to remove the electron from the potassium can be found using the formula,

            E = hc / λ

where E is the binding energy of the potassium

           h is Planck's constant

           c is the speed of light

           λ is the wavelength of the light.

The energy required for one electron is

      1.76 × 10⁶  / 6.02× 10²³ = 2.92 × 10⁻¹⁸

Let us substitute the known values in the above equation, we get

            2.92 × 10⁻¹⁸ = 6.63 x 10⁻³⁴ x 3 x 10⁸ / λ

                             λ = 6.63 x 10⁻³⁴ x 3 x 10⁸ / 2.92 × 10⁻¹⁸

                                =  6.82 x 10⁻⁸

                                = 68.2 nm

Therefore, the wavelength of the light is 68.2 nm

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In a vacuum, the Velocity of ALL forms of electromagnetic radiation remains constant. In contrast to mechanical waves, electromagnetic waves may travel without a medium.

This indicates that electromagnetic waves are capable of passing not just through solid objects like air and rock but also through a vacuum like space.

At the speed of light (2.998 108 m/s), electromagnetic radiation is an electric and magnetic disturbance that travels through space. It moves in radiant energy packets called photons or quanta and has neither mass nor charge. X-rays, infrared, ultraviolet, gamma, and radio waves are all types of electromagnetic radiation. The sun and other celestial bodies, radioactive substances, and man-made gadgets are some examples of sources of EM radiation. EM displays both a wave and a particle nature.

The medium's electric and magnetic characteristics affect the velocity of electromagnetic waves.

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According to the statistic, 3% of drivers with a license are in collisions each year. Not all drivers with licences actually drive. As a result, more than 3% of drivers who are now on the road are involved in accidents.

You have a 1 in 366 risk of being involved in an automobile accident for every 1000 kilometers you drive. Every 17.9 years, the average driver will submit an insurance claim for a car accident. According to this, the typical person is involved in three to four auto accidents over their lives.

According to a poll, 77% of drivers had been in one or more collisions. In addition, the typical person can anticipate participating throughout three to four auto accidents in their lifetime.

Therefore, you're likely to experience an automobile accident of some kind at some time in your life.

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According to the question, the distance between the particle and the cloth are: 2.7 m.

What is distance?

Distance is a numerical measurement of the amount of space between two points. It is usually measured in units such as meters, kilometers, feet, or miles. Distance can be used to measure the length of a path, the size of an area, or the length of a journey. Distance is also used to compare the size of two objects, such as the distance between two cities or the distance between two planets. Distance is an important concept in many fields, including mathematics, physics, engineering, geography, navigation, and astronomy.

The force between two charged particles can be calculated using Coulomb's Law, which states that the force between two charges is equal to the product of the charges divided by the square of the distance between them. In this case, we can rearrange the equation to solve for the distance between the two particles:

distance = (charge1 * charge2) / (force)

distance = (3.2 E−7 C * 6.7 E−7 C) / (4.8 E−4 N)

distance = 2.7 m

So, D is correct.

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The brightness of a star increases as it becomes bigger. It stands to reason that a larger star would have a larger surface. The larger surface area allows for the emission of more light and energy. The temperature of a star also affects its luminosity. Thus option E is correct.

The amount of light emitted from a star's surface, on the other hand, is referred to as brightness. The relationship between apparent brightness and luminosity changes with distance.

The size and effective temperature of a star can be used to calculate its brightness. The former is often expressed in terms of solar radii, whilst the latter is typically expressed in kelvins, but neither is typically physically measurable.

Therefore, 1/9 as bright. So it must appear fainter. Since brightness scales as 1/d^2 it will appear 3^2=9 times fainter.

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Answer:

he gravitational potential energy of the snowboarder is 2532.5 J.

Explanation:

The gravitational potential energy of an object is given by the formula:

PE = mgh

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

In this case, the mass of the snowboarder is 55.0 kg, the acceleration due to gravity is 9.8 m/s^2, and the height of the snowboarder is 4.50 m. So, the gravitational potential energy of the snowboarder can be calculated as:

PE = (55.0 kg)(9.8 m/s^2)(4.50 m) = 2532.5 J

So, the gravitational potential energy of the snowboarder is 2532.5 J.

Answer:

2425.5 J

Explanation:

The gravitational potential energy of an object can be calculated using the formula:

PE = m * g * h

where PE is the potential energy, m is the mass of the object, g is the acceleration due to gravity (9.8 m/s^2 on the surface of the Earth), and h is the height of the object above a reference point.

Plugging in the values, we get:

PE = 55.0 kg * 9.8 m/s^2 * 4.50 m = 2425.5 J

So the gravitational potential energy of the snowboarder is 2425.5 J (joules).