The stone, thrown upward with an initial speed of 128 feet per second, will reach a maximum height of 256 feet before gravity causes it to fall back to the ground.
Explanation:In the given problem, the stone is thrown upward from the ground with an initial speed of 128 feet per second. We can use the equations of motion to determine how high the stone will go. The height, h, reached by the stone can be calculated using the formula h = (v^2) / (2g), where v is the initial velocity and g is the acceleration due to gravity which is approximately 32.2 feet per second per second in standard units. Subbing in the values, h = (128^2) / (2*32.2) = 256 feet.
Therefore, the stone will reach a maximum height of 256 feet. This is the maximum height the stone reaches before it starts falling back to the ground due to gravity.
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The stone will reach a maximum height of 256 feet.
A stone is thrown upward from ground level with an initial speed of 128 feet per second. To determine how high it will go, we can use the kinematic equation:
v² = u² + 2as
where:
v is the final velocity (0 ft/s at the highest point)
u is the initial velocity (128 ft/s)
a is the acceleration (-32 ft/s² due to gravity)
s is the displacement (height)
Rearranging the equation to solve for s:
0 = (128)² + 2(-32)s
0 = 16384 - 64s
64s = 16384
s = 256 feet
Therefore, the stone will reach a maximum height of 256 feet.
Two cars start from rest at a red stop light. When the light turns green, both cars accelerate forward. The blue car accelerates uniformly at a rate of 3.8 m/s2 for 4.6 seconds. It then continues at a constant speed for 9.2 seconds, before applying the brakes such that the car’s speed decreases uniformly coming to rest 257.71 meters from where it started. The yellow car accelerates uniformly for the entire distance, finally catching the blue car just as the blue car comes to a stop.
How fast is the blue car going 2.8 seconds after it starts?
The blue car accelerates at 3.8 m/s² from rest. After 2.8 seconds, its speed is calculated using the formula v = u + at. The car's speed at that moment is 10.64 m/s.
Explanation:To determine how fast the blue car is going 2.8 seconds after it starts, we use the formula for final velocity in uniformly accelerated motion, which is v = u + at, where v is the final velocity, u is the initial velocity, a is the acceleration, and t is the time.
Here, the initial velocity u is 0 m/s since the car starts from rest, the acceleration a is given as 3.8 m/s2, and the time t is 2.8 seconds.
Plugging the values into the formula gives us:
v = 0 m/s + (3.8 m/s2)(2.8 s) = 10.64 m/s.
Thus, the blue car is traveling at a speed of 10.64 meters per second after 2.8 seconds from the start.
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What is the volume of a rock with a density of 3.00 g/cm3 and a mass of 600g?
What is the thinnest soap film (excluding the case of zero thickness) that appears black when illuminated with light with a wavelength of 500 nm ? the index of refraction of the film is 1.32, and there is air on both sides of the film?
If you drop a ball, and then one second later drop a ball identical in mass, size and shape, what happens to the distance between them as they fall?
Final answer:
As two identical balls are dropped with a one-second interval, the distance between them increases because the first ball accelerates for a longer time and achieves a higher velocity than the second ball at the instant it is dropped.
Explanation:
The question involves the concepts of gravity and acceleration as related to two identical falling objects. When a ball is dropped and then a second identical ball is dropped one second later, the distance between them increases as they fall. This is because the first ball has already been accelerating due to gravity for one second longer than the second ball, and thus it has a higher velocity at the moment the second ball is released. Therefore, the first ball continues to pull away from the second ball as they both fall towards the Earth.
Wich element is likely to be the most reactive
Answer:
Fluorine
Explanation:
Fluorine is the most reactive and most electronegative element in the periodic table. It can react with glass so it is impossible to find fluorine in its pure form. It exists in gaseous form even at room temperature and it is the most oxidizing agent. It is a non metal, in metals cesium is the most reactive.
The element that is likely to be the most reactive is hydrogen. The correct option is A.
The most reactive element of the ones listed is probably hydrogen (H). It is extremely reactive due to the fact that its outermost shell contains just one electron.
Oxygen, halogens, and metals are just a few of the substances that hydrogen can interact with quickly.
Covalent bonds can be formed with nonmetals like oxygen, resulting in substances like water. In redox reactions, such as the synthesis of acids and bases, hydrogen also takes part.
Its low atomic mass, which permits quicker diffusion and more frequent collisions with other atoms, further increases its reactivity.
Overall, the electrical structure of hydrogen and its capacity to create stable bonds with other elements are what cause it to be so reactive.
Thus, the correct option is A.
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Your question seems incomplete, the probable complete question is:
Which of the following elements is likely to be the most reactive?
A) Hydrogen (H)
B) Oxygen (O)
C) Neon (Ne)
D) Argon (Ar)
A machine has an efficiency of 80%. How much work must be done on the machine so to make it do 50,000 J of output work?
Answer:
62,500 Joules
Explanation:
A spelunker is surveying a cave. she follows a passage 170 m straight west, then 250 m in a direction 45â east of south, and then 280 m at 30â east of north. after a fourth unmeasured displacement, she finds herself back where she started.
An infant's pulse rate is measured to be 127 ± 4 beats/min. what are the uncertainty and the percent uncertainty in this measurement?
The uncertainty in the measurement is ± 4 beats/min, and the percent uncertainty is approximately 3.15%.
The reported pulse rate for an infant is 127 ± 4 beats/min. Here, "± 4 beats/min" refers to the degree of uncertainty of the measurement.
1. Uncertainty: The uncertainty of a measurement is the range of values in which the true value is expected to fall. In this example the uncertainty is ± 4 beats/min.
2.Percent Uncertainty: Uncertainty as a percentage is calculated by multiplying the ratio of the uncertainty in the measured value by 100. Uncertainty is expressed as a fraction of the measured value.
Percent Uncertainty = (Uncertainty / Measured Value) × 100
Using the given values:
Uncertainty = ± 4 beats/min
Measured Value = 127 beats/min
Percent Uncertainty = (4 / 127) × 100 ≈ 3.15%
So, the uncertainty in the measurement is ± 4 beats/min, and the percent uncertainty is approximately 3.15%.
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Final answer:
The uncertainty in the infant's pulse rate measurement is ± 4 beats/min. To calculate the percent uncertainty, divide the uncertainty by the measured value (127 beats/min), giving a percent uncertainty of 3.15%.
Explanation:
The uncertainty in the infant's pulse rate is given as ± 4 beats/min. The percent uncertainty can be calculated by dividing the uncertainty by the measured value and then multiplying by 100 to get the answer in percent.
To calculate the percent uncertainty:
Divide the absolute uncertainty by the measured value: 4 beats/min ÷ 127 beats/min. Multiply the result by 100 to convert it to a percentage: (4 beats/min ÷ 127 beats/min) × 100.
Performing these calculations:
(4 ÷ 127) × 100 = 3.15%
Therefore, the percent uncertainty in the measurement of the infant's pulse rate is 3.15%.
The position function x(t) of a particle moving along an x axis is x 4.0 6.0t 2 , with x in meters and t in seconds. (a) at what time and (b) where does the particle (momentarily) stop? at what (c) negative time and (d) positive time does the particle pass through the origin?
The particle crosses the origin at t = 2.0 seconds, and the displacement from t = 3.0 s to t = 6.0 s is -6 meters.
The position function of a particle moving along an x-axis is described as x(t) = 4.0 - 2.0t meters. To determine (a) when the particle crosses the origin, we set the position function equal to zero (x(t) = 0) and solve for t, which gives us t = 2.0 seconds. For part (b), the displacement of the particle between t = 3.0 s and t = 6.0 s is calculated by finding the difference in position at these two times: x(6.0) - x(3.0), which results in a displacement of -6 meters.
How do aerobic and anaerobic respiration compare?
Alright well aerobic respiration is very efficient and produces a large amount of energy while in the other hand anaerobic respiration is not very efficient and produces a large amount of energy.
Well Hope this helps have a nice day :)
A Federation starship (8.5 ✕ 106 kg) uses its tractor beam to pull a shuttlecraft (1.0 ✕ 104 kg) aboard from a distance of 14 km away. The tractor beam exerts a constant force of 4.0 ✕104 N on the shuttlecraft. Both spacecraft are initially at rest. How far does the starship move as it pulls the shuttlecraft aboard?
By applying conservation of momentum and kinematic equations, we find the distance the starship moves as a result of exerting a force on the shuttlecraft via a tractor beam. The steps involve calculating the acceleration of the shuttlecraft, determining the time to cover the initial distance, and then using the momentum relation to find the velocity and distance moved by the starship.
Explanation:The question involves applying the concept of conservation of momentum to find out how far the starship moves as it pulls a shuttlecraft on board. Since both spacecraft are initially at rest and the force is exerted for the same amount of time on both, their momenta are equal and opposite. We can set up the equation based on conservation of momentum:
m1⋅v1 = m2⋅v2
Where m1 and v1 are the mass and velocity of the starship, and m2 and v2 are the mass and velocity of the shuttlecraft, respectively. Because the tractor beam exerts a constant force, we can calculate the acceleration of the shuttlecraft (a = F/m), and then using the kinematic equation, determine the time (t) it takes for the shuttle to cover the distance:
s = 0.5⋅a⋅t^2
With t known, we can calculate the velocity of the shuttlecraft (v2) at the moment it reaches the starship:
v2 = a⋅t
Using the velocities and rearranging the conservation of momentum equation, we find:
m1⋅v1 = m2⋅(a⋅t)
Finally, we solve for the distance the starship moves (d1) using the velocity we found for v1, and the time:
d1 = 0.5⋅(v1⋅t)
This provides the answer to how far the starship moves as a result of pulling in the shuttlecraft with its tractor beam.
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state and explain guass law?
Final answer:
Gauss's Law is a fundamental principle in Physics that relates the electric flux through a closed surface to the net electric charge enclosed by the surface. It states that the electric flux is proportional to the total charge enclosed by the surface divided by the permittivity of free space.
Explanation:
Gauss's Law is a fundamental principle in Physics that relates the electric flux through a closed surface to the net electric charge enclosed by the surface. It states that the electric flux is proportional to the total charge enclosed by the surface divided by the permittivity of free space. Mathematically, it can be written as:
Σi E⟀Ai = Γenclosed / ε0
Where Σi E⟀Ai is the sum of the dot products of the electric field and the area vectors of small surface elements, Γenclosed is the net electric charge enclosed by the surface, and ε0 is the permittivity of free space.
Does the force of kinetic friction depend on the weight of the block? explain.
The force of kinetic friction is determined by surface properties and the normal force, not the weight of the object. Thus, objects with different weights experience the same kinetic friction on the same surface.
The force of kinetic friction does not depend on the weight of the block. Kinetic friction is the force that opposes the relative motion of two surfaces in contact when they are sliding past each other. It is determined by the nature of the surfaces and the normal force, which is the force exerted by a surface to support the weight of an object resting on it.
The weight of an object (or the force of gravity acting on it) affects the normal force, but it does not directly impact the coefficient of kinetic friction between the surfaces. The coefficient of kinetic friction remains constant for a given pair of materials, regardless of the weight of the object.
In simpler terms, if you have two objects made of the same material and they are sliding on the same surface, the force of kinetic friction will be the same for both objects, even if they have different weights. This is because the frictional force depends on the properties of the surfaces in contact, not the mass or weight of the objects involved.
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The expression CaCO3 → CaO + CO2 is an example of a reactant. product. chemical equation. chemical progression.
By definition, the expression CaCO₃ → CaO + CO₂ is an example of a chemical equation.
Definition of chemical reactionA chemical reaction is any process in which at least the atoms, molecules, or ions of one substance are changed into atoms, molecules, or ions of another chemical substance.
Definition of chemical equationA chemical equation is a symbolic description used to describe the identities and relative quantities of the reactants and products involved in a chemical reaction.
The information contained in the chemical equation allows us to determine the substances that are transformed or modified in a reaction, called reactants or reagents, and the new substances that originate in a chemical reaction, called products.
In order to represent what happens in a chemical reaction by means of an equation, it must comply with the Law of conservation of matter and with the Law of conservation of energy. That is, the equation must indicate that the number of atoms of the reactants and products is equal on both sides of the reaction and that the charges are also equal. In other words, you must have a balanced equation.
SummaryFinally, the expression CaCO₃ → CaO + CO₂ is an example of a chemical equation.
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Answer:
chemical equation
Explanation:
Describing Chemical Reactions quiz on edg
walt ran 5 kilometers in 25 minutes, going eastward. What was his average velocity?
If walt ran 5 kilometers in 25 minutes, going eastward. His average velocity is: 0.2 kilometers per minute.
What is the average velocity?
To determine Walt's average velocity divide the distance traveled by the time it took him.
We can use the formula:
Average velocity = Distance / Time
Plugging in the values:
Average velocity = 5 kilometers / 25 minutes
Average velocity = 0.2 kilometers per minute
Therefore Walt's average velocity is 0.2 kilometers per minute, meaning that he was running at a speed of 0.2 kilometers every minute in the eastward direction.
A laser pulse with wavelength 520 nm contains 4.40 mj of energy. how many photons are in the laser pulse?
To calculate the number of photons in a laser pulse, use the formula energy per photon = Planck's constant x speed of light / wavelength. Plugging in the values and dividing the total energy by the energy per photon, we find that the laser pulse contains approximately 2.65 x 10^19 photons.
Explanation:To calculate the number of photons in a laser pulse, we can use the formula:
energy per photon = Planck's constant x speed of light / wavelength
In this case, the energy per photon is 4.40 mJ = 4.40 x 10-3 J, the wavelength is 520 nm = 520 x 10-9 m, Planck's constant is 6.63 x 10-34 J·s, and the speed of light is 3.00 x 108 m/s. Plugging these values into the formula, we can find the energy per photon. Then, we can divide the total energy of the laser pulse (4.40 mJ) by the energy per photon to calculate the number of photons in the pulse.
The number of photons in the laser pulse is approximately 2.65 x 1019 photons.
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A 30 kg child sitting 5.0 m from the center of a merry-go-round has a constant speed of 5.0 m/s. while she remains seated in the same spot and travels in a circle, the work the seat performs on her in one complete rotation is
In a circular motion with constant speed, such as a child on a merry-go-round, the work done over one complete rotation is zero, as there is no change in kinetic energy.
Explanation:The question is regarding the concept of work done in a circular motion in the context of a merry-go-round. In the system described, the child has a constant speed on the circular path which indicates that the net work done by the forces acting on the child, including the seat, over a complete round of the merry-go-round is zero. This is consistent with the fact that work done is change in kinetic energy and since the child's speed is constant, there is no change in kinetic energy.
The child's inertia plays a role in maintaining her circular path but it does not contribute to work done, as it is a quantity of mass' resistance to change in motion and does not imply a force.
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The gas tank of a certain luxury automobile holds 22.3 gallons according to the owner’s manual. if the density of gasoline is 0.8206 g/ml, determine the mass in kilograms and pounds of the fuel in a full tank.
The mass of the fuel in the tank can be calculated by multiplying the volume in full tank to the density of the gasoline. First convert 22.3 gallons to ml by multiplying it with 3785.412 since the conversion factor is 1 gallon= 3785.412 ml. Then multiply the volume with the density. Since the density is in g/ml, you would get a value in grams so convert it to kg by dividing it with 1000. The convert the value in kg to lb multiply the value by 2.2. The values are 69.27 kg and 152.72 lb.
The mass of the fuel in a full 22.3-gallon tank of gasoline, given a density of 0.8206 g/mL, is approximately 69.211 kg or 152.497 lb.
Explanation:To determine the mass of the fuel in a full tank, you first need to convert the volume from gallons to milliliters (mL), since the density of gasoline is given in grams per mL.
One gallon is approximately 3785.41 mL. Therefore, a 22.3-gallon tank would hold 22.3 * 3785.41 = 84392.263 mL of fuel.
The mass of the fuel can then be calculated using the formula density = mass/volume. Rearranging the formula gives mass = density * volume. By subbing in the values, we get mass = 0.8206 g/mL * 84392.263 mL = 69211.294528 g.
To convert the mass to kilograms, we divide by 1000 (since there are 1,000 grams in a kilo). This gives us approximately 69.211 kg.
To convert the mass to pounds, we multiply by 2.20462 (since there are 2.20462 pounds in a kilo). This gives us approximately 152.497 lb.
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Jennifer works for an automaker and tests the safety performance of cars. She watches a 2,000-kilogram car crash into a wall with a force of 30,000 newtons. What’s the acceleration of the car at impact? Use .
Answer:
15 meters/second^2
Explanation:
I got this question on a test and this was the right answer
What radius should the satellite move at in its orbit? (measured frrom the center of mars.)?
To determine the radius at which a satellite should move in its orbit around Mars, you can use Newton's Law of Universal Gravitation and the centripetal force equation. By setting the gravitational force equal to the centripetal force, you can solve for the radius of the orbit.
Explanation:The radius at which a satellite should move in its orbit around Mars can be determined using Newton's Law of Universal Gravitation and the centripetal force equation. The centripetal force required for the satellite to stay in orbit is provided by the gravitational force between the satellite and Mars. To find the radius, you can set the gravitational force equal to the centripetal force and solve for the radius.
Step-by-step:
Identify the known quantities: the mass of Mars (M), the radius of Mars (r), and the period of the satellite's orbit (T).Use the centripetal force equation: Fc = (mv2)/r, where Fc is the centripetal force, m is the mass of the satellite, v is the satellite's velocity, and r is the radius of the orbit.Use Newton's Law of Universal Gravitation: Fg = (GMm)/r2, where Fg is the gravitational force between the satellite and Mars, G is the gravitational constant, and M is the mass of Mars.Set the centripetal force equal to the gravitational force: (mv2)/r = (GMm)/r2.Cancel out the common factors: v2/r = (GM)/r2.Solve for r: v2 = GM/r.Substitute the known values and solve for r: r = (GM/v2).Learn more about Satellite orbit around Mars here:https://brainly.com/question/33396540
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"what shape are the pebble-sized particles that make up the rock?"
An airplane went from 120 m/s to 180 m/s in 4.0 seconds. What was its acceleration?
A primitive air-conditioning unit for the use in places where electrical power is unavailable can be made by hanging up strips of linen soaked in water. the evaporation of the water cools the air. calculate the heat required to evaporate 5.00 l of water at 0c
Final answer:
The heat required to evaporate 5.00 liters of water at 0°C is 11300 kJ, calculated by multiplying the mass of the water (5.00 kg) by the heat of vaporization (2260 kJ/kg).
Explanation:
The student is asking about the heat required to evaporate 5.00 liters of water at 0°C. This is a question related to thermochemistry, specifically the heat of vaporization of water. The heat of vaporization is the amount of energy required for liquid water to turn into water vapor. To calculate the heat required, we use the formula:
Q = m × hv
where Q is the heat required, m is the mass of water, and hv is the heat of vaporization. The heat of vaporization for water is approximately 2260 kJ/kg at 0°C.
First, we convert 5.00 liters to kilograms as the density of water is about 1 kg/L, which makes the mass 5.00 kg. Then we calculate the heat required:
Q = 5.00 kg × 2260 kJ/kg = 11300 kJ
Therefore, the heat required to evaporate 5.00 liters of water at 0°C is 11300 kJ.
What is another name for the introitus? psych 230?
The introitus, or vaginal opening, is the external entrance to the vagina in the female reproductive system.
The term "introitus" specifically refers to an opening or entrance into a canal or cavity of the body. In the context of human anatomy, particularly in discussions of human sexuality and reproduction, another name for the «introitus» is the vaginal opening. This is the external opening to the vagina, which is part of the female reproductive system.
A 2300 kg truck has put its front bumper against the rear bumper of a 2500 kg suv to give it a push. with the engine at full power and good tires on good pavement, the maximum forward force on the truck is 18,000 n.
Answer:
Acceleration = a = 3.75 m/s^2
Explanation:
Mass of truck1 = m1 = 2300 kg
Mass of truck2 = m2 = 2500 kg
Total mass = m = m1 + m2 = 2300 + 2500 = 4800 kg
Force exerted by truck1 = F = 18000 N
As both trucks are joint together so, behaving as single object. The acceleration can be found by Newton’s second law of motion.
F = ma
a = F/m = 18000/4800
a = 3.75 m/s^2
What is the earth's average velocity for one year?
True or False A scientific theory generally is accepted as false until it is proved?
Light from the sun reaches earth in about 8.3 minutes the speed of light is 3.00×10^8 m/s what is the distance from the sun to earth?
What potential difference is needed to accelerate a he+ ion (charge +e, mass 4u) from rest to a speed of 1.8×106 m/s ?
Final answer:
The potential difference needed to accelerate a He+ ion to a specific speed can be calculated using kinetic energy and charge, with the equation V = ½mv² / q, where m is the mass of the ion, v is the velocity, and q is the charge.
Explanation:
The student has asked what potential difference is needed to accelerate a He+ ion (charge +e, mass 4u) from rest to a speed of 1.8×106 m/s. The kinetic energy gained by the ion when it's accelerated through a potential difference (V) is equal to the charge of the ion (q) times the potential difference (V). Thus, we use the equation KE = qV and also know that KE can be expressed as ½mv2. Therefore, we can set these equations equal to solve for V:
V = ½mv2 / q
Where m is the mass of the He+ ion, v is the final velocity, and q is the charge of the ion. For He+ ion, q is +e, which is 1.602×10−19 C because it has one fewer electron than a normal helium atom. The mass of a He+ ion can be converted to kilograms by multiplying the atomic mass unit (u) with the conversion factor (1 u = 1.6605×10−27 kg), so for 4u, it would be 4×1.6605×10−27 kg.
Plugging these values into the equation, we can calculate the required potential difference to achieve the given speed.
The value of the electrical charge on particles is never a whole number true or false