The radius of a potassium atom is 0.227 nanometer (nm). what is this radius in centimeters (cm)?

a. 2.27 Ã 10â8 cm

b. 2.27 Ã 106 cm

c. 2.27 Ã 10â10 cm

d. 2.27 Ã 10â11 cm check answer

Answer:

Companies will tend to seek lower costs by outsourcing labor

Explanation:

Globalization, in its current form, is led by the large multinationals and neoliberalism. Thus, large corporations settle in many underdeveloped countries in search of abundant raw material and cheap labor. This cheap labor has no alternative but to be subjected to low wages, which, in general terms, ends up shaping the source of misery worldwide. This has been worrying many workers, as the cheapness of mother labor results in lower quality of life for them and their families.

Answer:

Choice a

Explanation:

The weight is defined in formulaic terms as the mass *g

You know the mass to be 70 kg so multiply by g which gives choice (A)

A good way to check is that you know weight has the units newtons (N) and you know kg* m/s^2 qill yield newtons therefore choice A is correct

Hope this helps :)

Answer:

See image

Explanation:

Plato

Answer:

Explanation:

X-Rays are ''minor'' electromagnetic waves than Gamma Rays.

Gamma rays are the strongest waves in the electromagnetic spectrum with a length order of [tex]10^{-12}[/tex], which indicates a really intensive frequency, those characteristics allow to display a high energy amount.

The second most intense electromagnetic waves are X-Rays, stronger that ultraviolet, visible, infrared, microwaves and radio waves; but weaker than Gamma Rays.

Final answer:

It takes less force to accelerate a low mass object compared to a high mass object by the same amount because acceleration is inversely proportional to mass, as stated in Newton's second law of motion (F = ma).

Explanation:

Understanding Force and Acceleration

The student's question concerns why it takes less force to accelerate a low mass object compared to a high mass object by the same amount. This is explained by Newton's second law of motion, which states that the acceleration of an object is directly proportional to the net force acting on it and inversely proportional to its mass.

The law is usually written as F = ma, where F is the force applied, m is the mass of the object, and a is the acceleration. When you apply the same force to two objects of different masses, the object with lower mass will experience a greater acceleration because acceleration is inversely proportional to mass.

For example, applying a force to a basketball will result in a greater acceleration than applying the same force to a car, assuming all other factors such as friction are negligible. This is because the basketball has a smaller mass compared to the car.

Similarly, Newton's second law can be used to calculate how a person's weight, or the force of gravity on the person, changes when on a different planet like the Moon, which has a lower acceleration due to gravity compared to Earth. This principle not only applies to linear motion but also to rotational motion. The angular acceleration of an object is also inversely proportional to its mass, meaning a lighter object will spin faster when the same rotational force is applied to it.

Answer:

The upward velocity is 5.6 m/s.

(5) is correct option.

Explanation:

Given that,

Height = 1.6 m

We need to calculate the the upward velocity

Using equation of motion

[tex] v^2=u^2-2gh[/tex]

[tex]u=\sqrt{2gh}[/tex]

Here, g = acceleration due to gravity

v = final velocity

u = initial velocity

h = height

Put the value into the formula

[tex]u=\sqrt{2\times9.8\times1.6}[/tex]

[tex]u=5.6\ m/s[/tex]

Hence,  The upward velocity is 5.6 m/s.

In weather modification, the use of large fans to mix surface air with air aloft is referred to as forced convection. Forced convection, influenced by external forces like fans, allows for a cycling of air by bringing cooler higher altitude air down while propelling warmer surface air up. This is used to improve weather conditions such as reducing smog or fog.

The type of weather modification that involves the use of large fans to mix surface air with air aloft is called forced convection. In forced convection, the flow of air (or other matter) is encouraged by external forces like fans. To understand this, you need a certain knowledge of thermodynamics.

For instance, similar to the way a house fan works by moving cooler air in to replace warmer air, large fans in a weather modification context can be used to promote air movement on a larger scale. This is done by drawing cooler, higher altitude air down to the ground, while pushing warmer surface air up, thus creating a cycle of air called convection.

This process is used for various purposes such as reducing ground-level fog or smog. An interesting example of a natural occurrence of forced convection is shown in Figure 3.1, where a weak cold front of air pushes smog over the Yellow Sea, capturing by NASA's Terra satellite in 2012.

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Final answer:

Commonly, air pressure in weather reports is measured in millibars (mb) and inches of mercury (in. Hg), where average sea level pressure is about 1013.2 mb or 29.92 in. Hg.

Explanation:

The two units of air pressure that are commonly used in weather reports are millibars (mb) and inches of mercury (in. Hg). Under average sea level conditions, the atmospheric pressure is approximately 1013.2 millibars or 29.92 inches of mercury. When watching a weather forecast, you might hear meteorologists refer to high and low-pressure systems using these units. High pressure is associated with greater than 1013.2 millibars and is typically indicative of fair weather, while low pressure is lower than this value, often leading to more stormy conditions.

While fluid overload and dehydration are generally opposite conditions, they can coexist if there is a water and electrolyte balance disruption.

Fluid overload and dehydration are typically seen as opposite conditions, but they can coexist under certain circumstances such as when there is a disruption in water and electrolyte balance. Dehydration occurs when the loss of water exceeds the intake, substantially reducing the body's water content. Signs of dehydration include thirst, dizziness, headaches, and in severe cases, loss of consciousness or death.

During fluid overload, the body may hold onto too much water, possibly leading to conditions like hyponatremia, where sodium levels are abnormally low. In contrast, during dehydration, the concentration of electrolytes becomes greater outside of cells, leading to water leaving cells and making them shrink. Both conditions can have severe consequences if not properly managed.

Severe cases of dehydration can lead to electrolyte imbalances and the body's inability to function correctly due to insufficient water. This can happen due to factors such as prolonged physical activity with excessive sweating and insufficient fluid intake, especially in hot weather conditions or during endurance sports. Such imbalances need to be treated promptly to restore the body's fluid and electrolyte balance.

Answer:

A. Any object that has motion has kinetic energy, while any object not in motion but with the potential to do work has potential energy.

Explanation:

Kinetic energy is associated to the motion energy in which object moves with certain speed.

It is given by the formula

[tex]E_k = \frac{1}{2}mv^2[/tex]

Now similarly we can define potential energy as the energy stored in an object which is due to its position and the object must be at rest.

It may be of gravitational potential energy or spring potential energy or any other type

Gravitational potential energy is given as

[tex]E_p = mgh[/tex]

both kinetic energy and potential energy is part of mechanical energy

so correct answer would be

A. Any object that has motion has kinetic energy, while any object not in motion but with the potential to do work has potential energy.

Yes, an object can have both kinetic energy and potential energy at the same time, such as a ball during its flight. These forms of energy can transform into each other without external work in a closed system.

An object can indeed have both kinetic energy and potential energy at the same time. For instance, a ball thrown in the air has kinetic energy due to its motion and potential energy due to its height above the ground. As it rises, its kinetic energy decreases while its potential energy increases, and vice versa when it falls back down. Energy transformation between kinetic and potential energy occurs without the need for external work if no friction or air resistance is present. In a closed system where no energy is lost to the environment, the sum of potential and kinetic energy remains constant according to the conservation of energy principle.

Answer: The heavy truck

Explanation: Momentum is defined as the amount of movement.

It can be written as P = m*v

Where P is the momentum, m is the mass of the object and v is the velocity.

So you can see that if the mass increases, also does the momentum, so if both trucks move at the same velocity, then the truck with the bigger mas will have a bigger momentum.

Then the correct answer is the heavy truck

Which of the following is known as the pulse of a wave?

A non-recurrent wave and one cycle of a wave motion.

Answer:

A non-recurrent wave and one cycle of a wave motion.

Explanation:

Final answer:

The centripetal accelerations of two identical cars rounding banked curves at the same speed, radius, and angle on Earth and the Moon are the same since the formula for centripetal acceleration, which is velocity squared divided by radius, does not depend on the local acceleration due to gravity.

Explanation:

When comparing the centripetal accelerations of two identical cars rounding banked curves with the same speed, radius, and angle, one on Earth and one on the Moon, an important factor to consider is the acceleration due to gravity on each body. The formula for centripetal acceleration (ac) is ac = v²/r, where v is the velocity of the car and r is the radius of the circular path.

Given that both cars have the same speed (v) and radius (r), and that the centripetal acceleration is not directly dependent on gravity, the centripetal accelerations will be the same for both cars. It is essential to note that the gravitational force would affect the normal force and the friction available, but this does not change the centripetal acceleration required to keep the cars on their paths. Therefore, the correct answer is: c. the centripetal accelerations are the same for both cars.

The example of positive feedback is, " warmer temperatures on earth's surface decrease the evaporation of water."

     Warmer temperature on the earth's surface decreases the evaporation of water.

Because, the temperature of the earth will become hot , cold, warm etc.. this happens due to the evaporation of water.

Hence, Option A is the correct answer.

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Answer:

Interferometer

Explanation:

The scientist Kepler was known to have relied on observations and data of Tycho Brahe to formulate his laws of planetary motion.

Kepler is the scientist who is credited with the three laws of planetary motion. These laws set the tone fro the advances in the study of astronomy today.

However, the scientist Kepler was known to have relied on observations and data of Tycho Brahe to formulate his laws of planetary motion.

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According to the principle of conservation of momentum, two bowling balls of different masses can maintain the same momentum as long as the product of their mass and velocity is identical. Essentially, a lighter ball would need to move faster and a heavier ball slower to achieve the same momentum.

The subject matter of your question is fundamentally linked to the principle of conservation of momentum which states that the total momentum of a closed system remains constant if no external forces act upon it. Momentum, denoted as 'p', is the product of an object's mass 'm' and its velocity 'v' (p=mv).

Therefore, even if two bowling balls have different masses, they can still have the same momentum if their velocities compensate for the difference in mass. For instance, a lighter ball (smaller m) would need to be moving faster (higher v), while a heavier ball (larger m) would need to be moving slower (smaller v).

Consider this example: a 5 kg bowling ball moving at 2 m/s and a 10 kg bowling ball moving at 1 m/s. Even though the balls have different masses, their momenta are the same (5 kg * 2 m/s = 10 kg * 1 m/s = 10 kg m/s).

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The coefficient of the balanced chemical equation always express the ratio of moles of reactants and the products as before performing the stoichiometric calculations, the equation should be balanced and the stoichiometric coefficient of the given reactant or product is the number of molecules participating in that equation. The stoichiometric calculations are mostly done in moles rather than in molecules.