an ice plug has formed in the production pipe. explain the procedure to get rid of the ice plug
​

The equation "Force = Mass x Acceleration" represents Newton's second law of motion. This law states that the force acting on an object is directly proportional to its mass and the acceleration it experiences. It can be mathematically expressed as F = ma, where F is the force, m is the mass of the object, and a is the acceleration.

Total distance travelled is 35m and displacement is 25m.

Distance: Distance is a scalar that expresses the total distance traveled by an object. It's a measure of physical distance that's covered and always good. The distance has nothing to do with the direction, only the magnitude of the change is determined.

Displacement: Displacement is the vector of change in the position of an object. It takes into account the magnitude and direction of change in position from the starting point to the ending point. Perception can be positive, negative or zero depending on the direction of movement.

Total distance = 15m + 20m

Total distance = 35m

Displacement = [tex]\sqrt{15^{2} +20^{2} \\}[/tex]         (as both are perpendicular to each other)

Displacement = 25m

Therefore, Total distance is 35m and displacement is 25m.

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The fan blades or propellers of an electric fan are examples of an inclined plane. The blades' frequently curved or angled shapes provide an inclined surface that effectively moves air.

Air is forced along the incline as the blades spin, creating airflow. An electric fan's motor assembly includes a wheel and an axle. The rotor, a revolving component, is connected to the motor's central shaft, also known as the axle.

Usually cylindrical in form, the rotor serves as the wheel. The motor spins around the fixed axle when electrical power is applied, which causes the fan blades to move and the air to circulate.

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Answer:

Let's use the snel's law.
Snell's Law states that the ratio of the sines of the angles of incidence and refraction is equal to the ratio of the refractive indices of the two media:

sin(i)/sin(r) = n2/n1

Where i is the angle of incidence, r is the angle of refraction, n1 is the refractive index of the first medium (in this case, vacuum), and n2 is the refractive index of the second medium (in this case, the dielectric).

Since vacuum has a refractive index of 1 and the dielectric constant of the medium is 1.25, the refractive index of the medium is also 1.25.

Plugging in the values we have:

sin(20)/sin(r) = 1.25/1

sin(r) = sin(20)/1.25

sin(r) = 0.321

r = sin^-1(0.321)

r = 18.6 degrees

Therefore, the angle of refraction within the medium is approximately 18.6 degrees.

Answer: The volume of the anchor is approx. 29.56 m^3.

               Its mass is approx. 228,511.72

Explanation: Archimedes' Law States that "When a body is submerged in a fluid, it experiences an upward buoyant force that is equal to the weight of the fluid displaced by the body".

Here Buoyant force = 290N i.e. the difference in weight due to fluid displaced.

Buoyant force = D*V*g

D= 1025 kg/m^3 for seawater

g = 9.81 m/s^2

V = 290/1025*9.81

(a) V = 0.02884 m^3

Mass of Anchor = Density of Anchor* V

Mass of Anchor = 7730*0.02884

Mass of Anchor = 222.94 kg

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Answer: Please see the attached image.

Explanation:

A diagram of the Lewis dot structure depicts the valence electrons of the atoms of a molecule. It makes use of dots to represent lone electron pairs and lines to represent atomic bonds.

Valence Electrons are the s and p subshells on the periodic table. You count the total s and p subshells of the corresponding atom to find how much valence electrons it has.

Wien's Law states that the wavelength at which a black body radiates the most energy is inversely proportional to its temperature.

To apply Wien's Law, you would need the wavelength at which the largest amount of energy is being emitted by the star's interior.

This corresponds to the peak of the star's continuum spectrum. However, without specific data or spectral information, I cannot determine the exact wavelength for the star you mentioned.

If you have access to the star's spectrum or the peak wavelength in meters, you can use Wien's Law to determine the effective surface temperature. The formula is as follows:

λ_max = (2.898 × 10^−3 m·K) / T

where λ_max is the peak wavelength in meters and T is the temperature in Kelvin.

To find the effective surface temperature, you can rearrange the formula:

T = (2.898 × 10^−3 m·K) / λ_max

Once you have the wavelength at which the largest amount of energy is being emitted, you can substitute it into the equation and solve for T. Comparing the calculated temperature to the given options, you can select the closest value.

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could not provide the exact answer.

The distance covered by the particle in 10 seconds is 0 meters.

Given that the particle starts from rest and moves with a constant acceleration of 0. Sms-s, we can use the equation of motion to determine the distance covered by the particle in 10 seconds.

The equation for distance covered (s) by an object with constant acceleration can be expressed as:

s = ut + (1/2)at²,

where u is the initial velocity (which is zero in this case), a is the constant acceleration, and t is the time taken.

In this scenario, the particle starts from rest, so its initial velocity (u) is 0 m/s. The acceleration (a) is given as 0 m/s². The time (t) is 10 seconds.

Substituting the given values into the equation, we have:

s = 0(10) + (1/2)(0)(10)² = 0 + 0 = 0.

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The magnitude of force on the small piston that will balance a 25 kN force on the large piston is approximately 2.126 kN.

To determine the magnitude of force on the small piston that will balance a 25 kN force on the large piston, we can use the principle of Pascal's law, which states that the pressure applied to a fluid in a closed system is transmitted equally in all directions.

According to Pascal's law, the pressure on the small piston will be the same as the pressure on the large piston. The pressure can be calculated using the formula:

Pressure = Force / Area

The area of a piston is given by the formula:

Area = π * (radius)^2

Given that the diameter of the small piston is 4.2 cm, we can calculate its radius as follows:

Radius of small piston = diameter / 2 = 4.2 cm / 2 = 2.1 cm = 0.021 m

The area of the small piston is:

Area of small piston = π * (0.021 m)^2

Given that the diameter of the large piston is 62 cm, we can calculate its radius as follows:

Radius of large piston = diameter / 2 = 62 cm / 2 = 31 cm = 0.31 m

The area of the large piston is:

Area of large piston = π * (0.31 m)^2

According to Pascal's law, the pressure on both pistons is the same:

Pressure on small piston = Pressure on large piston

Therefore, we can set up the following equation:

Force on small piston / Area of small piston = Force on large piston / Area of large piston

Solving for the force on the small piston, we have:

Force on small piston = (Force on large piston * Area of small piston) / Area of large piston

Substituting the given values:

Force on small piston = (25 kN * π * (0.021 m)^2) / (π * (0.31 m)^2)

Calculating this expression, we find:

Force on small piston ≈ 2.126 kN

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Answer:

I don't know if it right or not but it would be c

The resultant combination of the two wheels and the shaft will rotate at approximately half the initial angular speed, ω₀/2.

When the wheel with rotational inertia I₁, initially rotating with angular speed ω₀, is dropped onto the vertical shaft with negligible rotational inertia, the resulting combination of the two wheels and the shaft will rotate at a lower angular speed. The new angular speed can be calculated using the principle of conservation of angular momentum.

According to the conservation of angular momentum, the initial angular momentum of the system must be equal to the final angular momentum. The initial angular momentum is given by the product of the initial rotational inertia (I₁) and the initial angular speed (ω₀). Since the rotational inertia of the shaft is negligible, we can ignore its contribution.

When the wheel is dropped onto the shaft, the total rotational inertia of the system becomes the sum of the rotational inertia of the wheel (I₁) and the rotational inertia of the shaft (I₂), which is negligible. Therefore, the final angular momentum of the system is given by the product of the total rotational inertia and the final angular speed (ω).

Since the initial and final angular momenta must be equal, we have:

I₁ × ω₀ = (I₁ + I₂) × ω

As I₂ is negligible compared to I₁, we can approximate the equation as:

I₁ × ω₀ ≈ I₁ × ω

Simplifying the equation, we find:

ω ≈ ω₀/2

Therefore, the resultant combination of the two wheels and the shaft will rotate at approximately half the initial angular speed, ω₀/2.

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Answer:

83.13 degree Celsius folks!

Explanation:

Q = msdT

Here is how you do it fella's! First off Let us know abt the above terms shall we?

Where:

Q is the heat energy absorbed by the water,

m is the mass of the water,

s is the specific heat capacity of water,

dt is the change in temperature.

Given:

Q = 3.6 x 10^5 J

m = 2 kg

s= 4,186 J/kg°C (specific heat capacity of water)

Initial temperature, T_initial = 40°C

Rearranging the formula, we have:

dt = Q / (ms)

Substituting the given values:

dt = (3.6 x 10^5 J) / (2 kg * 4,186 J/kg°C)

Calculating:

dt ≈ 43.13°C

To find the final temperature, we add the change in temperature to the initial temperature:

Final temperature = T_initial + dT(above formed temp)

Final temperature = 40°C + 43.13°C

Final temperature = 83.13°C

Therefore, the correct final temperature of the water is approximately 83.13.

Potential at C with respect to B is +65 volts (C with respect to ground) - +80 volts (B with respect to ground) is -15 volts with respect to B.

To find the potentials at B, C, and D with respect to the ground:

Potential at B with respect to ground:

Since A is at +100 volts with respect to ground and +20 volts with respect to B, we can deduce that B is 100 - 20 = +80 volts with respect to ground.

Potential at B = +80 volts with respect to ground.

Potential at C with respect to ground:

C is at +15 volts with respect to D, and D is at +50 volts with respect to E. Since E is at ground potential (0 volts), we can calculate the potential at C with respect to ground by adding the potentials:

Potential at C = +50 volts (D with respect to E) + 15 volts (C with respect to D) = +65 volts with respect to ground.

Potential at D with respect to ground:

D is at +50 volts with respect to E, and E is at ground potential (0 volts). Therefore, the potential at D with respect to ground is:

Potential at D = +50 volts (D with respect to E) + 0 volts (E with respect to ground) = +50 volts with respect to ground.

Now, let's calculate the potential at C with respect to B and D:

Potential at C with respect to B:

We know that A is at +20 volts with respect to B. Combining this information with the potential at A (+100 volts with respect to ground), we can determine the potential at B with respect to ground:

Potential at B = +100 volts with respect to ground - +20 volts (A with respect to B) = +80 volts with respect to ground.

Since we already calculated the potential at C with respect to ground as +65 volts, we can find the potential at C with respect to B:

Potential at C with respect to B = +65 volts (C with respect to ground) - +80 volts (B with respect to ground) = -15 volts with respect to B.

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Hooke's Law can be given as follows sometimes:

The restoring force of a spring is equal to the spring constant multiplied by the displacement from its normal position:

F = -kx

Where, F = Restoring force of a spring (Newtons, N)

k = Spring constant (N/m)

x = Displacement of the spring (m)

The negative sign relates to the direction of the applied force and by convention, the minus or negative sign is present in F = -kx. The restoring force F is directly proportional to the displacement (x), according to Hooke's law. When the spring is compressed, the displacement (x) is negative. It is zero when the spring is at its original length and positive when the spring is extended.

Practically, Hooke's Law is applicable only within a limited frame of reference, and through experimenting, this statement proves to be true. Because materials cannot be compressed beyond a certain size or expanded beyond a certain size without some permanent deformation or change of their original state.

The law only applies under some conditions such as a limited amount of force or deformation. Factually, many materials will noticeably deviate from Hooke's law even before those elastic limits are reached.

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The match is going to be as follow:

1 -  a

2 - b

3 - d

4 - c

5 - b

6 - e

1 - Crest : The crest is the highest point or crest of the wave. This is the point at which the wave reaches its maximum positive change or amplitude.

2- Wavelength : Wavelength is the distance between two consecutive points of a wave that have the same phase. It is usually represented by the symbol λ (lambda) and is usually measured in units of length such as meters (m), centimeters (cm), or nanometers (nm).

3- Trough : A trough is the lowest point or valley in a wave. This is the point at which the wave reaches its maximum negative displacement or amplitude.

4- Amplitude : Amplitude refers to the maximum displacement or magnitude of a wave at its equilibrium or resting point. In other words, it represents the maximum distance at which the wave oscillates or deviates from its position or zero.

5-Wavelength : Wavelength is the distance between two consecutive points of a wave that have the same phase. It is usually represented by the symbol λ (lambda) and is usually measured in units of length such as meters (m), centimeters (cm), or nanometers (nm).

6-Amplitude : Amplitude refers to the maximum displacement or magnitude of a wave at its equilibrium or resting point. In other words, it represents the maximum distance at which the wave oscillates or deviates from its position or zero.

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The two objects must be 0.0001488 meters apart in order for the eye to resolve them when using 550 nm light.

The ability of the eye to resolve two objects depends on the angular resolution, which is determined by the wavelength of light and the diameter of the aperture (in this case, the diameter of the eye's pupil).

To calculate the minimum resolvable angle, we can use the formula:

θ = 1.22 * (λ / D)

where

θ = angular resolution

λ = wavelength of light

D = diameter of the aperture.

Given:

Wavelength of light = 550 nm = 550 *[tex]10^{-9}[/tex] m

Diameter of the aperture (D) = 0.00220 m

Let's calculate the angular resolution:

θ = 1.22 * (550 * [tex]10^{-9}[/tex] m / 0.00220 m)

≈ 3.072 * [tex]10^{-6}[/tex] radians

Now, to determine the distance between the objects (d) required for the eye to resolve them, we can use the formula:

d = r * θ

where

r = distance from the eye to the objects.

Given:

Distance from the eye (r) = 48.4 m

Let's calculate the distance between the objects:

d = 48.4 m * 3.072 * [tex]10^{-6}[/tex] radians

≈ 0.0001488 m

Therefore, the two objects must be approximately 0.0001488 meters (or 0.1488 mm) apart in order for the eye to resolve them when using 550 nm light.

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Gravitation, in the context of class 10, refers to the natural force of attraction between objects that have mass. It is the force that pulls objects towards each other. Gravitation is responsible for various phenomena, such as keeping objects on the ground, causing celestial bodies like planets and moons to orbit, and influencing the motion of objects in the universe. This fundamental force is described by Newton's law of universal gravitation and plays a crucial role in understanding the behavior of objects in the universe.

~~~Harsha~~~

a. Directly connecting the voltmeter to the battery terminals bypasses circuit components, resulting in a reading closer to zero due to the low voltage drop in a short circuit. b. Removing the lightbulb decreases resistance, leading to an increased current flow according to Ohm's Law.

a. The reading on the meter would be closer to the second reading shown. This is because when the student reconnects the wires from the voltmeter to touch the positive and negative ends of the battery directly, it essentially bypasses the lightbulb and other components in the circuit. This creates a short circuit, allowing the current to flow with minimal resistance. In a short circuit, the voltage drop across the circuit elements is very low, resulting in a reading on the voltmeter that approaches zero. Therefore, the reading would be closer to the second reading, which indicates a lower voltage.

b. If the lightbulb were removed from the circuit, the current would increase. This is because the lightbulb acts as a resistance in the circuit, impeding the flow of current. When the resistance is removed (in this case, by removing the lightbulb), Ohm's Law states that the current in the circuit would increase. Ohm's Law states that current (I) is equal to the voltage (V) divided by resistance (R)

I = V/R.

With the resistance (R) being reduced to zero (since the lightbulb is removed), the current (I) would increase. So, the absence of the lightbulb would lead to an increase in current in the circuit.

Therefore, a. When the voltmeter wires are connected directly to the battery terminals, bypassing the circuit components, the reading on the meter would be closer to the second reading shown, approaching zero due to the low voltage drop in the short circuit. b. Removing the lightbulb from the circuit would decrease the resistance, causing an increase in current according to Ohm's Law, as the absence of resistance allows for a greater flow of current.

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De acuerdo con la información podemos inferir que la rapidez media de la anciana es de 0.03 km/min.

Para calcular la rapidez media, dividimos la distancia recorrida por el tiempo empleado. En este caso, la anciana caminó 0.30 km en 10 minutos. Para obtener la rapidez media, dividimos 0.30 km entre 10 minutos, lo que nos da un valor de 0.03 km/min. Por lo tanto, la anciana tiene una rapidez media de 0.03 km/min.

La rapidez media se expresa en unidades de distancia divididas por unidades de tiempo. En este caso, la anciana recorrió una distancia de 0.30 km en un tiempo de 10 minutos, lo que nos da una rapidez media de 0.03 km/min. Esto significa que en promedio, la anciana camina 0.03 kilómetros por minuto durante su recorrido alrededor del centro comercial.

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Answer:

A simple example would be where the motions of both bodies are in the same straight line - for instance, two cars travelling along a motorway. If both cars are travelling in the same direction, one at 25 ms-1 and the other at 35 ms-1 then their relative velocity is 10 ms-1 (by vector addition).

One notable athlete who has been associated with the use of performance-enhancing drugs (PEDs) is the American professional cyclist Lance Armstrong.

Armstrong gained worldwide recognition for his unprecedented seven consecutive victories in the Tour de France from 1999 to 2005. However, his remarkable achievements were tarnished when it was revealed that he had engaged in systematic doping throughout his career.

In 2012, after years of denial, Armstrong finally admitted to using banned substances, including erythropoietin (EPO), testosterone, corticosteroids, and blood transfusions, to enhance his performance. These substances boosted his endurance and oxygen-carrying capacity, providing him with an unfair advantage over his competitors. Armstrong's confession came after substantial evidence, including testimonies from teammates and extensive investigations, exposed his involvement in one of the most elaborate and sophisticated doping schemes in sports history.

Following his admission, Armstrong was stripped of his Tour de France titles and received a lifetime ban from professional cycling. The revelations surrounding his drug use had a profound impact on the sport, shaking its credibility and raising concerns about the prevalence of doping in cycling.

Armstrong's story serves as a cautionary tale, highlighting the ethical and moral dilemmas associated with doping in sports. His case underscores the importance of maintaining the integrity of athletic competition, the significance of stringent anti-doping measures, and the need for education and awareness regarding the risks and consequences of performance-enhancing substances.

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Answer:

the answer is 191.7

Explanation:

i dont know the math for it

Answer:

192.6N

Explanation:

Let's consider the forces acting on the beam:

Weight of the beam (W): It acts vertically downward and has a magnitude of W = mass * gravitational acceleration = 39.4 kg * 9.8 m/s^2.

Force exerted by the link on the beam (F_link): It acts at an angle of 90 degrees with respect to the beam and has two components: the vertical component and the horizontal component.

Tension in the cable (T): It supports the far end of the beam and acts at an angle of 90 degrees with respect to the beam. Since the angle between the beam and the cable is 90 degrees, the tension in the cable only has a vertical component.

Let's break down the forces acting on the beam:

Vertical forces:

W (weight of the beam) - T (vertical component of tension) = 0

T = W

Horizontal forces:

F_link (horizontal component of the force exerted by the link) = ?

To find the magnitude of the horizontal component of the force exerted by the link on the beam (F_link), we need to consider the equilibrium of forces in the horizontal direction.

Since the beam is inclined at an angle of θ = 33.1 degrees with respect to the horizontal, the horizontal equilibrium equation can be written as:

F_link = W * sin(θ)

Let's substitute the given values:

W = 39.4 kg * 9.8 m/s^2

θ = 33.1 degrees

F_link ≈ (39.4 kg * 9.8 m/s^2) * sin(33.1 degrees)

Using a calculator, we find that the magnitude of the horizontal component of the force exerted by the link on the beam (F_link) is approximately 192.6 N.

If An echo-type depth sounder uses ultrasonic pulses. They take 25 ms to pass down, reflect from the sea floor, and return to the ship. If the speed of sound in water is 1600 m/s, then the depth of the seabed is 20 meters.

A sound wave is a mechanical disturbance that propagates through a medium, such as air or water, as a series of compressions and rarefactions, carrying energy and producing the sensation of hearing when detected by the human ear. It consists of oscillations in pressure that result from the vibrations or movements of a sound source.

To determine the depth of the seabed, we can use the formula:

Depth = (Speed of Sound × Time) / 2

Given that the speed of sound in water is 1600 m/s and the time it takes for the ultrasonic pulse to travel down and back is 25 ms (0.025 seconds), we can substitute these values into the formula:

Depth = (1600 m/s × 0.025 s) / 2

Depth = (40 m) / 2

Depth = 20 meters

Therefore, the depth of the seabed is 20 meters.

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Thandeka's identity formation is influenced by factors such as family, personal interests, peers, and sexuality exploration, while adolescent friendships differ in intensity, self-disclosure, peer acceptance, and social comparison, and social media impacts connectivity, identity expression, peer influence, and potential negative effects, with teachers playing a role in supporting identity formation through creating a safe environment, offering diverse opportunities, encouraging self-expression, promoting acceptance, and providing access to resources.

4.1 Factors that may contribute to Thandeka's identity formation:

Family influence: Thandeka's parents' beliefs about practical career choices may impact her perception of what is considered acceptable or successful. Their views can influence her decisions and self-perception.

Personal interests and passions: Thandeka's interest in art and music can be significant factors in her identity formation. These activities may provide her with a sense of purpose and fulfillment.

Peer influence: Thandeka's friends and social circle can play a role in shaping her identity. Their opinions, values, and behaviors may influence her choices and self-perception.

Sexuality exploration: Thandeka's struggle with her sexuality is a crucial aspect of her identity formation. Exploring and understanding her sexual orientation is a common process during adolescence.

4.2 Adolescent friendship relationships differ from previous phases in several ways:

Intensity and importance: Friendships become more significant and emotionally intense during adolescence. Peers play a crucial role in identity formation and provide emotional support.

Self-disclosure: Adolescents often share personal thoughts, feelings, and experiences with their friends, which helps them explore and understand their own identity.

Peer acceptance: Peer acceptance becomes increasingly important during adolescence, and friends' opinions and approval can strongly influence self-esteem and self-perception.

Social comparison: Adolescents may compare themselves to their peers to evaluate their own identity and determine where they fit in socially.

4.3 Social media's role in peer interactions and friendships:

Connectivity: Social media platforms provide opportunities for adolescents to connect and communicate with their friends, expanding their social networks beyond physical boundaries.

Identity expression: Adolescents can use social media to express their identity, interests, and opinions, allowing them to explore and experiment with different aspects of themselves.

Peer influence: Social media platforms expose adolescents to the thoughts, behaviors, and trends of their peers, which can impact their self-perception and decision-making processes.

Cyberbullying and negative impact: Social media can also contribute to negative experiences, such as cyberbullying or unhealthy comparisons, which may affect self-esteem and well-being.

4.4 How a teacher can support the identity formation process of an adolescent:

Create a safe and inclusive classroom environment: Foster an atmosphere where students feel comfortable expressing themselves and discussing their identities without fear of judgment or discrimination.

Offer diverse learning opportunities: Provide a range of activities and subjects that allow students to explore different interests and passions, including art and music.

Encourage self-reflection and self-expression: Assign projects or assignments that require students to reflect on their identities, interests, and goals. Allow them to express themselves creatively and personally.

Promote understanding and acceptance: Incorporate discussions and lessons on diversity, inclusivity, and acceptance of different identities, including sexual orientation. Encourage empathy and respect for others.

Provide access to supportive resources: Make students aware of resources within the school or community that can provide guidance and support for their identity exploration, such as counseling services or LGBTQ+ support groups.

Therefore, It's important to note that individual experiences may vary, and a holistic and sensitive approach is necessary when supporting students' identity formation.

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The correct statement is that the speed of the particle increases by 4 m/s during each second.

The correct answer is Option C.

The statement that accurately describes the motion of the particle is:

"The speed of the particle increases by 4 m/s during each second."

Given that the particle is accelerated at a constant rate of 4 m/s², its speed (velocity magnitude) increases by 4 m/s every second. This means that after the first second, the particle will have a speed of 4 m/s. After the second second, the speed will be 8 m/s, and so on. The rate of increase in speed is constant at 4 m/s per second.

The other statements are not accurate:

The final velocity of the particle will not be proportional to the distance covered. The final velocity depends on the time of acceleration, not the distance covered.

The particle does not necessarily travel exactly 4 meters during the first second or each second. The distance traveled depends on the initial conditions, such as the starting position and time of observation.

The acceleration of the particle remains constant at 4 m/s². It does not increase by 4 m/s² during each second.

The correct answer is Option C.

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The basic force of gravity between two things is described by Sir Isaac Newton's universal law of gravitation.

The law states that every particle in the cosmos is drawn to every other particle with an attraction force that is inversely proportional to the square of the distance between them and directly proportional to the product of their masses.

The gravitational force is mathematically defined as F = G * (m1 * m2) / r2, where m1 and m2 are the objects' masses, and r is the distance between their centres.

This rule is essential to the study of astronomy and astrophysics because it offers a mathematical explanation of the force that controls celestial body motion.

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The universal law of gravitation, formulated by Sir Isaac Newton, describes the force of gravitational attraction between two objects. The law states that:

Every particle in the universe attracts every other particle with a force that is directly proportional to the product of their masses. It is inversely proportional to the square of the distance between their centers.

Mathematically, the equation for the universal law of gravitation is expressed as:

F = G (m1 m2) / r^2

Where:

F represents the gravitational force between the two objects.

G is the gravitational constant, approximately equal to 6.67430 × 10^-11 N m^2/kg^2.

M1 and M2 are the masses of the two objects.

R is the distance between the centers of two objects.

Key points to remember about gravitation's universal law:

Gravitational force pulls objects towards each other.

The force of gravity is directly proportional to the product of the masses of objects. If each mass increases, gravity force will also increase.

Gravity's force is inversely proportional to the square of the distance between objects. As the distance between objects increases, gravity force decreases.

The universal law of gravitation applies to all objects with mass, regardless of their size or location in the universe.

This law provides a fundamental understanding of the force that governs celestial motions, such as the orbits of planets, moons, and other celestial bodies. It is a fundamental principle in physics and has wide-ranging applications in various scientific fields.