A ramp is 1.0 m high and 3.0 m long. What is the IMA of the ramp?

The atomic mass of caesium with atomic number of 55 and neutron of of 78 is 133 amu.

The atomic mass of an element is the sum of the proton number and the neutron number.

The proton and neutron contributes mostly to the weight of an atom. The proton and neutron are located in the nucleus an atom.

The atomic number of an element is the same as the proton number of an element. Therefore, since the atomic number of caesium is 55, the proton number is also 55.

The atomic mass of caesium can be computed as follows:

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Answer:

A ferromagnetic material is a temporary magnet. The domains in a ferromagnetic material are randomly arranged. Under certain actions, the domains align in a particular direction and the material acts as a magnet. The actions that can cause alignment of domains in a ferromagnetic material are:

Other actions like heating the material,  placing the material in a magnetic field of opposite polarity and hitting the material would lead to demagnetization of the magnetic material.

Answer:

2,3, and 5

Explanation:

Edg 2022

Final answer:

Adults should perform muscle-strengthening activities that work all major muscle groups at moderate to high intensity at least 2 days per week for additional health benefits.

Explanation:

Adults should engage in muscle-strengthening activities that involve all major muscle groups, performed on 2 or more days per week. These activities, such as push-ups, sit-ups, squats, and lifting weights, should be done at moderate or greater intensity to provide additional health benefits. Over time, the frequency and intensity of these workouts can be increased to further enhance muscle strength and endurance.

Answer:As the air bubbles rise to the surface, the pressure on them decreases. This decrease in pressure allows the air to expand and each bubble increases in size. Boyle’s law explains why this occurs.

Explanation:

The wavelength of the middle D note, with a frequency of 293.66 Hz and a speed of sound of 343.06 m/s, is approximately 116.8 cm. The calculation involves dividing the speed of sound by the frequency and converting the result from meters to centimeters.

To find the wavelength of the middle D note on a piano with a frequency of 293.66 Hz in air, where the speed of sound is 343.06 m/s, we can use the formula:

Wavelength (λ) = Speed of Sound (v) / Frequency (f)

First, let's perform the calculation:

Identify the given values:

Frequency (f) = 293.66 Hz

Speed of Sound (v) = 343.06 m/s

Calculate the wavelength:

[tex]\lambda = \frac{v}{f} = \frac{343.06 \, \text{m/s}}{293.66 \, \text{Hz}}[/tex]

  ≈ 1.168 m

Convert the wavelength from meters to centimeters:

1 meter = 100 centimeters

1.168 meters = 1.168 * 100 = 116.8 centimeters

Therefore, the wavelength of the middle D note is approximately 116.8 cm.

The iron filings sprinkled on a piece of paper demonstrate is "the pattern of the magnetic fields lines".

A magnetic field would be a vector field which thus explains the magnetic influence affecting electric charges, electric currents, as well as magnetic materials.

The chemical element iron has the atomic number 26 and also the symbol Fe. It is just a metal that would be found in group 8 of such periodic table and the very first transition series.

Therefore, the iron filings sprinkled on a piece of paper demonstrate is "the pattern of the magnetic fields lines".

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The average force acting on the blood as it is pumped into the aorta is [tex]\boxed{0.4\text{ N}}[/tex].

Explanation:

As the blood enters the aorta, the speed of the blood increases from zero to [tex]1\text{ m/s}[/tex] in a time of [tex]0.2\text{ s}[/tex]. It means that the blood moves under the acceleration as it passes through the aorta.

The acceleration produced in a body is due to the force experienced by the particular amount of blood as it enters the aorta.

Write the expression for the acceleration of the blood as its speed increases.

[tex]\boxed{a=\dfrac{v_{f}-v_{i}}{t}}[/tex]                                      ...... (1)

Here, [tex]v_{f}[/tex] is the final velocity of blood, [tex]v_{i}[/tex] is the initial velocity and [tex]t[/tex] is the time taken to accelerate.

Substitute the values of the velocities and the time taken by the blood in equation (1).

[tex]a&=\dfrac{1-0}{0.2}\text{ m}\text{/s}^2}\\&=\dfrac{1}{0.2}\text{ m}\text{/s}^2}\\&=5\text{ m}\text{/s}^2}[/tex]

The net force acting on the blood is given by:

[tex]F=m\times{a}[/tex]                                         ...... (2)

Substitute the values of mass and acceleration in the above expression.

[tex]\begin{aligned}F&=80\text{ g}\left(\dfrac{1 \text{ kg}}{1000\text{ g}}\right)\times\left(5\text{ m/s}^2\right)\\&=0.08\times5\text{ N}\\&=0.4\text{ N}\end{aligned}[/tex]

Therefore, the average force acting on the blood as it is pumped into the aorta is [tex]\boxed{0.4\text{ N}}[/tex].

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Answer Details:

Grade: High School

Subject: Physics

Chapter: Force and acceleration

Keywords:

heartbeat, average force, aorta, blood, rest, speed up, acceleration, initial speed, final speed, time, accelerated, 80 g, blood is pumped.

Final answer:

The average force on the blood during this time is 0.4 Newtons.

Explanation:

The average force on the blood can be calculated using the equation:

F = m * a

where F is the force, m is the mass, and a is the acceleration.

In this case, the mass of the blood is given as 80 g (or 0.08 kg) and the acceleration is the change in velocity divided by the time taken.

Given that the blood is accelerated from rest to 1 m/s in 0.2 s, the acceleration is calculated as:

a = (v-u)/t

Substituting the given values:

a = (1-0)/0.2 = 5 m/s²

Plugging the values back in the original equation:

F = 0.08 kg * 5 m/s² = 0.4 N

So, the average force on the blood during this time is 0.4 Newtons.

In transverse waves, particles move perpendicularly to the wave's direction, while in surface water waves, they follow circular orbits due to a combination of longitudinal and transverse motions. The size of these orbits decreases with depth, and a slight horizontal movement called Stokes drift occurs after each wave crest passes.

Particle Movement in Different Waves

In transverse waves, particles move in a direction perpendicular to the propagation of the wave. Examples of transverse waves include vibrations in a stretched string or ripples on the surface of water when viewed from the side. However, the surface water waves present a more complex motion. Particles in these waves move in circular orbits, which is a combination of longitudinal (back and forth) and transverse (up and down) motions.

Water waves are created when wind transfers energy to the water surface, leading to the oscillatory motion of water particles. The size of these circular orbits decreases as the depth increases. In deep water, particles move in closed circular paths, whereas in shallow water, their motion is elliptical due to the compression of the wave's energy.

Moreover, water waves display a phenomenon called Stokes drift, where particles are slightly displaced horizontally after the passage of each wave crest. This accounts for the small forward movement observed alongside the predominant up and down movement of the particles in the wave.

The downward force of the water on the beaker's bottom is its weight, calculated using the beaker's volume, the density of water, and acceleration due to gravity.

The question is asking about the downward force exerted by water on the bottom of a cylindrical beaker. This situation relates to principles in physics around fluid dynamics and specifically Pascal's principle. According to Pascal's principle and the equation for fluid pressure, the downward force exerted by the water (F) is its weight, which can be calculated as the product of the volume of the water, the density of the water, and the acceleration due to gravity (g).

Since the beaker is filled to the brim, the volume (V) of the water is equal to the volume of the cylinder, which can be calculated by the formula V = π(r^2)h, where r is the radius and h is the height of the beaker. The radius can be obtained from the given diameter. If we have the density (ρ) of water and the value for g, we can substitute these in the mentioned equation to get the force F = ρVg.

Finally, using the calculated volume, the known density of water (approximately 1000 kg/m³ for standard conditions), and the standard gravity (approximately 9.8 m/s²), we can find F, which is the downward force from the water on the beaker's bottom.

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The initial mass of the Bismuth-212 sample is 10.56 grams.

To find the initial mass of the Bismuth-212 sample, we can use the concept of half-life. The half-life of Bismuth-212 is given as 60.5 seconds. Since the sample has a mass of 2.64 grams after 121 seconds, we can calculate the number of half-lives that have passed.

The number of half-lives is given by the formula:     Number of Half-lives = Total Time / Half-life

So, the number of half-lives = 121 s / 60.5 s = 2 half-lives.

Since each half-life results in half the initial mass remaining, after 2 half-lives, the remaining mass would be (1/2)(1/2) = 1/4 of the initial mass.

If we let the initial mass be x grams, then after 2 half-lives, the remaining mass is (1/4)x grams.

Given that the remaining mass is 2.64 grams, we can solve for the initial mass:

(1/4)x = 2.64 grams

Simplifying, x = 2.64 grams * 4 = 10.56 grams.

Therefore, the initial mass of the sample of Bismuth-212 is 10.56 grams.

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Answer : Resistance of the dishwasher is 6.67 ohms.

Explanation :

It is given that,

Total voltage flowing in a house, V = 120 V

Current flowing, I = 18 A

According to Ohm's law :

V = I R ...........(1)

R is the resistance of the circuit.

Putting all values in (1) we get :

[tex]R=\dfrac{V}{I}[/tex]

[tex]R=\dfrac{120\ V}{18\ A}[/tex]

[tex]R=6.666\ \Omega[/tex]

or

[tex]R=6.67\ \Omega[/tex]

So, the resistance of the dishwasher is [tex]R=6.67\ \Omega[/tex].

the speed and direction the object is moving.

The Answer is A)

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In this exercise we have to use the block knowledge in a system, thus we find that:

1) 33.4 J

2) 0J

3) 2.84 m/s

4) 14.1 J

5) 19.9 N

6) 19.3 J

So with the knowledge of force and energy we can calculate what is required, like this:

1) We have to calculate the value of work in the system which will be:

[tex]W=FS\\W=0.71 m * 9.8 m/s^2 * 4.8kg\\ = 33.3984 kg*m^2/s^2 \\= 33.3984 J \\=33.4 J[/tex]

2) As we are dealing with the work of the normal force, we will have to be zero, since the force will not have a distance, so:

[tex]W=FS\\W=35*0\\W=0J[/tex]

3) We want to calculate the final speed of the system as a whole, so:

[tex]E = 0.5MV^2 \\E = 33.3984 J\\ 33.3984 = 0.5*(3.5 + 4.8 )V^2\\ 33.3984 = 0.5*8.3 *V^2\\ 33.3984 = 4.15*V^2\\ 8.047807229 = V^2\\V= 2.83686574 m/s\\V=2.84 m/s[/tex]

4) We want to find the work of the voltage in this way we have:

[tex]E = 0.5MV^2\\ E = 0.5*3.5kg* (2.84 m/s)^2\\ E = 0.5*3.5kg* 8.0656 m^2/s^2\\ E = 14.1148 kg*m^2/s^2\\ E = 14.1 J[/tex]

5) Now calculating the value of the string tension, we have:

[tex]T= 14.1 J / 0.71 m \\= 19.88 J/m\\= 19.88 kg*m/s^2\\ = 19.88 N[/tex]

6) Calculating the value of work on top of block 2 we have:

[tex]E = 0.5MV^2\\ E = 0.5*4.8 kg * (2.84 m/s)^2\\ E = 0.5*4.8 kg * 8.0656 m^2/s^2\\ E = 19.35744 kg*m^2/s^2\\ E = 19.4 J[/tex]

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Answer:

4.0

Explanation:

Answer:

Electric energy from the outlet transforms to radiant energy and thermal energy in the lightbulb.

Explanation:

Final answer:

To find the minimum stopping distance, we use the formula d = v² / (2 · μ_s · g), considering the speed and the coefficient of static friction. For wet conditions (μ_s = 0.102), the stop distance is 27.8 meters, and for dry conditions (μ_s = 0.603), it is 4.6 meters.

Explanation:

To calculate the minimum stopping distance of a car traveling at 52.0 mi/h (which converts to approximately 23.2 m/s) on a horizontal highway, we can use the formula for stopping distance based on the coefficient of static friction ( μ_s ) and the deceleration rate:

d = v² / (2 · μ_s · g), where v is the initial speed in m/s, μ_s is the coefficient of static friction, and g is the acceleration due to gravity (9.8 m/s²).

(a) On wet concrete, where μ_s = 0.102, the minimum stopping distance is:

d = (23.2²) / (2 · 0.102 · 9.8) = 27.8 meters

(b) On dry concrete, where μ_s = 0.603, the minimum stopping distance is:

d = (23.2²) / (2 · 0.603 · 9.8) = 4.6 meters

These calculations provide an understanding of the significance of road conditions on stopping distances, emphasizing the increased risk associated with wet roads.

The power rating of the lightbulb is mathematically given as

P=  60 watts

Question Parameters:

An incandescent lightbulb operating at 120 volts draws a current of 0.50 ampere for 240 seconds.

Generally, the equation for the Power  is mathematically given as

P=VI

Therefore

P= (20 x 0.5

P=  60 watts

In conclusion, the power rating of the lightbulb

P=  60 watts

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The image distance from the lens is 22.5 cm, and the height of the image is -6.25 cm indicating it is inverted.

To determine the distance of the image from the lens and the height of the image, we use the lens formula and magnification formula.

Lens formula:

[tex]1/f = 1/d_o + 1/d_i[/tex]

Given:

Substitute the values:

[tex]1/10 = 1/18 + 1/d_i[/tex]

[tex]1/d_i = 1/10 - 1/18 = 0.1 - 0.0556 = 0.0444[/tex]

[tex]d_i = 22.5 cm[/tex]

So, the image distance from the lens is 22.5 cm.

Next, we calculate the height of the image using the magnification formula:

Magnification (m) = [tex]-d_i/d_o = h_i/h_o[/tex]

Given:

[tex]h_i = h_o * (-d_i/d_o)[/tex]

Substitute the values:

[tex]h_i[/tex] = 5 * (-22.5/18)

[tex]h_i[/tex] = -6.25 cm

Therefore, the height of the image is -6.25 cm which indicates the image is inverted.

Answer:

Awanita's power output is 8watts

Explanation:

First we find workdone= Force × distance

Given: F=20N , d= 200cm converting to meter: (200/100)m=2m

W= 20×2=40Joules

Power,P= workdone/ time

Given: time=5seconds

P= 40/5= 8 watts

Final answer:

To find the number of revolutions a bicycle wheel makes over 3.0 km, we calculate the wheel's circumference, convert total distance to meters, and then divide the distance by the circumference. The result is approximately 1194 revolutions.

Explanation:

The student is asking about the number of revolutions each wheel of a bicycle makes when it travels a certain distance. Given that the radius of each wheel is 0.400 meters and the bicycle travels a distance of 3.0 kilometers, we can use the relationship between the circumference of the wheel and the total distance traveled to calculate the number of revolutions.

To find the number of revolutions, we first calculate the circumference of the wheel using the formula C = 2πr, where r is the radius of the wheel. Then, we convert the total distance traveled from kilometers to meters. Finally, we divide the total distance traveled by the circumference of the wheel to get the number of revolutions.

Step-by-step calculation:

Calculate the circumference of the wheel: C = 2π(0.400 m) = 2.513 m

Convert the distance traveled to meters: 3.0 km = 3000 m

Calculate the number of revolutions: (3000 m) / (2.513 m/revolution) ≈ 1194 revolutions

Each wheel makes approximately 1194 revolutions as the bicycle travels 3.0 kilometers.