One liter (1000cm3) of oil is spilled onto a smooth lake. If the oil spreads out uniformly until it makes an oil slick just one molecule thick, with adjacent molecules just touching, estimate the diameter of the oil slick. Assume the oil molecules have a diameter of 2 × 10-10 m.

Answer:

d. supply of the most limited resources.

Explanation:

the carrying capacity of a species in an environment is determined by the number of individual in an environment that the limited resources can sustain indefinitely without fighting for food, vegetation, water and light to sustained themselves.

the carrying capacity can be determined by how much the limited resources in the environment can sustain the species. the resources needed by species in a particular environment varies from habitat to habitat.

for some species, the limiting resources needed is food which consequently affect the way they reproduced and affect the population size.

The carrying capacity of an environment for a specific species is defined by the availability of the most limited resources, and it indicates the maximum population size that the environment can sustain.

The carrying capacity of an environment for a particular species at a particular time is determined by the supply of the most limited resources. This refers to the maximum population size of a species that an environment can sustain indefinitely, given the availability of resources such as food, water, and space. It's not solely determined by the number of individuals in the species, the distribution of the population, or the reproductive potential of the species, rather it is driven by the resource which is in shortest supply.

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Answer:

True

Explanation:

True

Diffusion refers to that process through which concentration is transmitted from one place to another concentration i.e from higher concentration to lower concentration. Due to this only, characteristics able to spread all over the space.

it can only happen in fluid(liquid and gas) because their particle can move in a random direction

Answer: Option (C) is the correct answer.

Explanation:

As we know that metals are able to conduct electricity so, when a negatively charges rod is kept closer to the left sphere then electrons will enter the sphere.

Since, like charges repel each other. Hence, some of the negative changes from the rod will repel the negative charges of left sphere.

As both left and right spheres are touching each other so, the electrons will move towards the right sphere. As a result, there will be too many electrons (negative charge) present on the right sphere and very less electrons present in the left sphere.

Thus, we can conclude that the statement right sphere is negatively charged, another is charged positively, is true.

Answer:

Explanation: Peripherial arterial disease is a blood circulation disorder which occurs when the blood vessels outside the heart and brain to block or spasm. This is as a result of the pulse decreasing rather than increasing in amplitude.

Answer:

In the last six seconds the ball will fall 3 times the distance it fell in the first 3 seconds

Explanation:

t = Time taken

u = Initial velocity

v = Final velocity

s = Displacement

a = Acceleration

g = Acceleration due to gravity = 9.81 m/s² = a

Total distance

[tex]s=ut+\dfrac{1}{2}at^2\\\Rightarrow s_1=0\times t+\dfrac{1}{2}\times 9.81\times 6^2\\\Rightarrow s=176.58\ m[/tex]

At t = 3 seconds

[tex]s=ut+\dfrac{1}{2}at^2\\\Rightarrow s_1=0\times t+\dfrac{1}{2}\times 9.81\times 3^2\\\Rightarrow s_2=44.145\ m[/tex]

In the next 3 seconds it will fall

[tex]s_2=176.58-44.145=132.435\ m[/tex]

Dividing the equations

[tex]\dfrac{s_2}{s_1}=\dfrac{132.435}{44.145}\\\Rightarrow s_2=3s_1[/tex]

In the last six seconds the ball will fall 3 times the distance it fell in the first 3 seconds

Answer:

-[tex]29.2\times 10^{3} N[/tex]

Explanation:

We are given that

Mass of cars= m=1900 kg

Initial speed of car=u=20 m/s

Final speed of car=v=0

Time=[tex]\Delta t[/tex]=1.3 s

We have to find the average force exerted on the car.

Average force=[tex]\frac{change\;in\;momentum}{\Delta t}[/tex]

[tex]F_{avg}=\frac{mv-mu}{1.3}[/tex]

[tex]F_{avg}=\frac{1900(0)-1900(20)}{1.3}[/tex]

[tex]F_{avg}=\frac{-38000}{1.3}=-29.2\times 10^{3} N[/tex]

Hence, the average force exerted on the car that hits a line of water barrels=-[tex]29.2\times 10^{3} N[/tex]

Final answer:

Using the change in velocity and time, the acceleration of the car is calculated, followed by the application of Newton's second law to find the average force exerted on the car as 29,222 N.

Explanation:

To determine the average force exerted on the car that hits a line of water barrels, we can use the equations of motion and Newton's second law of motion. The car goes from 20 m/s to rest, which means that its change in velocity is -20 m/s. Given the time of 1.3 seconds for this change, we can find the acceleration using the formula:

a = Δv / t

Where Δv is the change in velocity and t is the time taken. The acceleration a is therefore:

a = -20 m/s / 1.3 s = -15.38 m/s²

Now, using Newton's second law of motion, Force (F) = mass (m) × acceleration (a), we can find the force:

F = 1900 kg × -15.38 m/s² = -29222 N

The negative sign indicates that the force is in the opposite direction to the motion of the car. Thus, the average force exerted on the car is 29,222 N.

Final answer:

Using the change in velocity and time, the acceleration of the car is calculated, followed by the application of Newton's second law to find the average force exerted on the car as 29,222 N.

Explanation:

To determine the average force exerted on the car that hits a line of water barrels, we can use the equations of motion and Newton's second law of motion. The car goes from 20 m/s to rest, which means that its change in velocity is -20 m/s. Given the time of 1.3 seconds for this change, we can find the acceleration using the formula:

a = Δv / t

Where Δv is the change in velocity and t is the time taken. The acceleration a is therefore:

a = -20 m/s / 1.3 s = -15.38 m/s²

Now, using Newton's second law of motion, Force (F) = mass (m) × acceleration (a), we can find the force:

F = 1900 kg × -15.38 m/s² = -29222 N

The negative sign indicates that the force is in the opposite direction to the motion of the car. Thus, the average force exerted on the car is 29,222 N.

Explanation:

A classic instance of an isometric contraction would be to bear an object before you. The object's weight will be pulling down, but the movement of the object would be opposed by your arms and hands with equivalent force pushing up the object.

Assuming that your arms do not lift or fall, your biceps will contract isometrically. Isometric contraction generate force without changing the length of the muscle.

Answer:

Pushing a wall without bending or motion in the arm joints.

Explanation:

Isometric literally means that the measurement of a particular thing does not change.

Here isometric contraction is related with the contraction of the muscles without the movements of the joints. During the process the muscles feel the load and muscle fibers contract without change in length.

Every contraction of muscles in the skull is isometric.

Answer:

Explanation:

Given

launch velocity [tex]u=24.5\ m/s[/tex]

first ball launch angle [tex]\theta _1=70^{\circ}[/tex]

Suppose another ball is thrown at an angle of [tex]\theta _2[/tex]

Both ball have same range

Range of Projectile [tex]R=\frac{u^2\sin 2\theta }{g}[/tex]

[tex]R_1=\frac{u^2\sin 2\theta _1}{g}[/tex]

For second ball

[tex]R_2=\frac{u^2\sin 2\theta _2}{g}[/tex]

[tex]R_1=R_2[/tex]

[tex]\frac{u^2\sin 2\theta _1}{g}=\frac{u^2\sin 2\theta _2}{g}[/tex]

[tex]\sin 2\theta _1=\sin 2theta _2[/tex]

Either [tex]\theta _1=\theta _2[/tex] or

[tex]2\theta _1=180-2\theta _2[/tex]

I.e. [tex]\theta _2=90-\theta _1[/tex]

[tex]\theta _2=90-70=20^{\circ}[/tex]

so another ball must be thrown at [tex]20^{\circ}[/tex]

Answer:

b

Explanation:

Final answer:

The correct term for the physical act of moving air into and out of the lungs is pulmonary ventilation, which is option d in the provided choices.

Explanation:

The physical act of moving air into and out of the lungs is called ventilation. This process is part of respiration, which is much more than just breathing. Respiration also includes the exchange of gases between the blood and the cells of the body, not just the action of breathing itself. Breathing, or ventilation, involves two primary steps: inhaling, which is an active process driven by the contraction of the diaphragm, and exhaling, which is typically a passive process caused by the lungs' elasticity when the diaphragm relaxes.

Pulmonary ventilation is the term that accurately describes the act of breathing, involving the precise movement of air into and out of the lungs. Therefore, the correct answer to the question is option d. pulmonary ventilation.

statement accurately describes something that Yolanda can do as a part of her study She can use destructive interference to generate a wave with an amplitude of 2.8 m.

The correct option is (c).

To determine the resulting amplitude of waves under interference, we consider the principles of constructive and destructive interference.

1. Constructive Interference: When two waves meet crest to crest or trough to trough, they add up to produce a wave with an amplitude equal to the sum of the individual amplitudes.

  For Yolanda's waves:

[tex]\[ \text{Amplitude} = 2 \, \text{m} + 3 \, \text{m} = 5 \, \text{m} \][/tex]

  Option b. She can use constructive interference to generate a wave with an amplitude of 1.5 m is incorrect because the resulting amplitude from constructive interference must be greater than or equal to the sum of the individual amplitudes.

2. Destructive Interference: When two waves meet crest to trough, they cancel each other out partially or completely. The resulting amplitude is the absolute difference between the amplitudes of the individual waves.

  For Yolanda's waves:

[tex]\[ \text{Amplitude} = |2 \, \text{m} - 3 \, \text{m}| = |-1 \, \text{m}| = 1 \, \text{m} \][/tex]

  Option a. She can use destructive interference to generate a wave with an amplitude of 3.1 m is incorrect because the resulting amplitude from destructive interference must be less than or equal to the difference between the individual amplitudes.

Option d. She can use constructive interference to generate a wave with an amplitude of 3.5 m is incorrect because the resulting amplitude from constructive interference must be greater than or equal to the sum of the individual amplitudes.

Therefore, option c. She can use destructive interference to generate a wave with an amplitude of 2.8 m is the accurate statement.

Answer:

3035281543986.976 mi

Explanation:

g = Acceleration due to gravity = 9.81 m/s²

a = Acceleration = g

Time taken

[tex]t=1\ y\\\Rightarrow t=365.25\times 24\times 60\times 60[/tex]

u = Initial velocity = 0

[tex]s=ut+\dfrac{1}{2}at^2\\\Rightarrow s=0\times t+\dfrac{1}{2}\times 9.81\times (365.25\times 24\times 60\times 60)^2\\\Rightarrow s=4.8848\times 10^{15}\ m[/tex]

Converting to mi

[tex]1\ m=\dfrac{1}{1609.34}\ mi[/tex]

[tex]4.8848\times 10^{15}\ m=4.8848\times 10^{15}\times \dfrac{1}{1609.34}\ mi\\ =3035281543986.976\ mi[/tex]

Number of miles travelled in one year is 3035281543986.976 mi

Answer:

electric force of attraction, The work  is zero

Explanation:

Between a positive and a negative charge there is an electric force of attraction, as in this case the particle moves in an orbit circulates at a certain velocity at an angle between the displacement and the force is 90, consequently the work defined by

                   W = F d cos θ

The work  is zero, therefore the elective force does not create work on the load.

Both scenarios involve work done by forces - the electric force in the first scenario causes a charged particle to move, changing its potential energy. In the second scenario, a magnetic force does work on an iron nail, resulting in its displacement.

In the provided scenarios, there are two primary forces at play which are the electric force and the magnetic force.

The first scenario considers a positively charged particle moving in a circle at a fixed distance from a negatively charged particle. Here, the force present is an electric force. The electric force causes the positively charged particle to move in a direction of the force field lines. As a result of the force field, work is indeed done. This is because the electrical field does work on the charge, altering its potential energy.

In the second scenario, an iron nail is being pulled from a magnet. Here, the force is magnetic. The movement or displacement of the nail from the magnet is a clear indication that work has been done, since work is done when a force moves an object. The force exerted by the magnet does work on the nail by overcoming the magnetic force that initially held the nail in place.

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Answer:

Your friend is 2.143 blocks from the restaurant.

You are 2.857 blocks from the restaurant.

Explanation:

Let t be the time both you and your friend take to walk to the restaurant.

The distance (m) from your building to the restaurant is your walking time t times your speed v1

[tex]s_1 = v_1t = 1.6t[/tex]

Similarly the distance (m) from your friend building to the restaurant:

[tex]s_2 = v_2t = 1.2t[/tex]

Let b be the length (in m) of a block, the total distance of 5 blocks is 5b

[tex]s_1 + s_2 = 5b[/tex]

[tex]1.6t + 1.2t = 5b[/tex]

[tex]2.8t = 5b[/tex]

[tex]t = 5b/2.8 = 25b/14[/tex]

[tex]s_2 = 1.2t = 1.2(25b/14) = 2.143b[/tex]

So your friend are 2.143b meters from the restaurant, since each block is b meters long, 2.143b meters would equals to 2.143b/b = 2.143 blocks. And you are 5 - 2.143 = 2.857 blocks from the restaurant.

Answer:

Percolation of water through the soil.

Explanation:

When a tray containing a mixture of dough and sand is propped on one end of the tray with bricks then there is a slope from one end of the tray to the other end of the tray.

When water is poured on the higher end of the tray then the it tries to flow from the higher altitude to the lower altitude of the tray by the process of percolation through the granular spaces created due to the mixing of sand in the dough. Sand being granular in structure is easily permeable to water and passes water easily through its tiny pores.

Similar is the process of percolation of water through the layers of soil on the earth which also contains granular particles in them.

Final answer:

To calculate the spring force constant k in this problem, we can use Hooke's Law. By substituting the given values, we can calculate the spring force constant as approximately 124.97 N/m.

Explanation:

To calculate the spring force constant k, we can use Hooke's Law, which states that the force exerted by a spring is directly proportional to the displacement of the spring from its equilibrium position. In this case, the ball compresses the spring to a maximum displacement of 4.68317 cm, so we can use this value in our calculation.

Hooke's Law can be written as F = k × x, where F is the force exerted by the spring, k is the spring force constant, and x is the displacement of the spring.

Given that the mass of the ball is 60.3 g, the acceleration of gravity is 9.8 m/s², and the displacement of the spring is 4.68317 cm, we can calculate the force exerted by the ball using the equation F = m × g, where m is the mass of the ball and g is the acceleration of gravity.

Substituting the values, we have F = (60.3 g) × (9.8 m/s²). Now, we can solve for k by dividing both sides of the equation F = k × x by x. This gives us k = F / x.

Substituting the values, we have k = (60.3 g × 9.8 m/s²) / (4.68317 cm).

Converting the values to SI units, we have k = (0.0603 kg × 9.8 m/s²) / (0.0468317 m).

Calculating k, we find that the spring force constant is approximately 124.97 N/m.

The spring force constant k,  is approximately 289.6 N/m.

To find the spring force constant k, we use the principle of conservation of energy. Here’s the step-by-step solution:

First, convert the given values to meters and kilograms:
Mass of the ball, m = 60.3 g = 0.0603 kg
Height from which the ball is dropped, h = 53.7 cm = 0.537 m
Maximum spring displacement, x = 4.68317 cm = 0.0468317 m

Calculate the potential energy at the initial height:
Potential Energy, PE = m × g × h
PE = 0.0603 kg × 9.8 m/s² × 0.537 m = 0.317 J

When the ball compresses the spring, all the potential energy converts into the elastic potential energy of the spring:

Elastic Potential Energy, EPE = (1/2) × k × x²
0.317 J = (1/2) × k × (0.0468317 m)²

Solve for k:
k = 2 × 0.317 J / (0.0468317 m)²
k ≈ 289.6 N/m

Therefore, the spring force constant k is approximately 289.6 N/m.

Answer:

46%  (0.46)

Explanation:

temperature of hot reservoir (Th) = 1.3 kJ

temperature of COLD reservoir (Tc) = 0.7 kJ

Efficiency = 1 - (Tc/Th)

Efficiency = 1 - (0.7/1.3) = 0.46 = 0.46 x 100 = 46 %

Answer:

46.2 %

Explanation:

heat in (Q_in) = 1.3kJ

heat out (Q_out) = 0.7kJ

work out = heat in - heat out = 1.3 - 0.7 = 0.6 kJ

efficiency = work out / heat in * 100%

                = 0.6/1.3 * 100 % = 46.2 %

Answer:

4.2 m

Explanation:

Note: If energy is conserved, i.e no work is done against friction

Work input = work output.

Work output = Force output × distance,

Work input = force input × distance moved moved.

Therefore,

input force×distance moved = output force × distance moved........................Equation 1

Given: input force = 80 N, output force = 240 N, output distance = 1.4 m

Let input distance = d

Substitute into equation 1

80×d = 240×1.4

80d = 336

d = 336/80

d = 4.2 m.

Thus the rope around the pulley must be pulled 4.2 m

To convert the concentration of carbon monoxide from g/L to lb/ft3, we need to perform two unit conversions: from grams to pounds and from liters to cubic feet. The concentration of carbon monoxide in lb/ft3 is approximately 2.7248 x 10-10 lb/ft3.

To convert the concentration of carbon monoxide from g/L to lb/ft3, we can use unit conversion factors. First, we need to convert grams to pounds using the given conversion factor 1.00 lb = 454 g. Then, we can convert liters to cubic feet by using the conversion factor 1 L = 0.0353 ft3. Let's perform the calculations:

Therefore, the concentration of carbon monoxide in lb/ft3 is approximately 2.7248 x 10-10 lb/ft3.

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Answer:

3.14 m/s^2 is the acceleration

Explanation:

You must use the formula Fnet=ma

So the total forces acting on the system are the 450N push force and the 35N friction force, which acts in the opposite direction.

Thus, the sum of the forces is 450 -35= 415N

Also you know the mass is 132 kg, so to find the acceleration divide the previously calculated net force by the mass

So 415/132 =3.14 m/s^2

Hope this helped:)

The bobsled with a mass of 132 kg and a net force of 415 N after factoring in friction accelerates at about 3.14 meters per second squared.

To determine the acceleration of the bobsled, we will use Newton's second law, which states that the acceleration of an object is equal to the net force acting on it divided by its mass. The net force in this scenario is the combined push minus the force of friction. Therefore, the equation to use is:

Net force = Total push - Force of friction

Net force = 450.0 N - 35 N = 415 N

Now, we use this net force to find the acceleration:

Acceleration (a) = Net force / Mass

a = 415 N / 132 kg

a ≈ 3.14 m/s2

The bobsled will accelerate at approximately 3.14 meters per second squared when the net force acting on it is 415 N.

Answer:

[tex]\displaystyle \theta' =0.24\ rad/s[/tex]

Explanation:

Rate Of Change

Let some variable y depend on time t. we can express y as a function of t as

[tex]y=f(t)[/tex]

The instant rate of change of y respect to t is the first derivative, i.e.

[tex]y'=f'(t)[/tex]

The balloon, the ground and the observer form a right triangle (shown below) where the height of the balloon y, the horizontal distance x, and the angle of elevation are related with the trigonometric formula

[tex]\displaystyle tan\theta =\frac{y}{x}[/tex]

Since x is constant, we take the derivative with respect to time  by using the chain rule:

[tex]\displaystyle sec^2\theta \ \theta' =\frac{y'}{x}[/tex]

Solving for [tex]\theta'[/tex]

[tex]\displaystyle \theta' =\frac{y'}{xsec^2\theta}[/tex]

Let's compute the actual angle with the initial conditions y=9 feet, x=12 feet

[tex]\displaystyle tan\theta =\frac{y}{x}[/tex]

[tex]\displaystyle tan\theta =\frac{9}{12}=\frac{3}{4}[/tex]

Knowing that

[tex]\sec^2\theta=1+tan^2\theta[/tex]

[tex]\displaystyle \sec^2\theta=1+\left(\frac{3}{4}\right)^2[/tex]

[tex]\displaystyle \sec^2\theta=\frac{25}{16}[/tex]

The balloon is rising at y'=8 feet/sec, thus we compute the change of the angle of elevation:

[tex]\displaystyle \theta' =\frac{8}{12\ \frac{25}{16}}[/tex]

[tex]\displaystyle \theta' =\frac{32}{75}\ rad/s[/tex]

[tex]\boxed{\displaystyle \theta' =0.43\ rad/s}[/tex]

Answer:

= 2 beats per seconds

Explanation:

These also shows how to get the period of the tuning forks.

Answer:

Vx = 350m/s

Vy  = 656.99 m/s

Explanation:

at the time of drop, the horizontal velocity of the object is same as of plane.

Since friction is ignored, horizontal velocity remains unchanged.

Vx = 350m/s  

but the Vy increases due to gravitational acceleration

V^2 - U^2 = 2as

V: FINAL VELOCITY

U: INITIAL VELOCITY

U = 0 m/s

[tex]v=\sqrt{2as}= \sqrt{2(9.81)(22000)} = 656.99 m/s[/tex]

Answer: 3.02kg

Explanation:

According to the law of conservation of momentum, the sum of momentum of bodies before collision is equal to the sum of momentum of the bodies after collision.

Note that this bodies will move with a common velocity after collision.

Since momentum = mass of a body × its velocity

Let m1 and m2 be the masses of the spheres

u1 and u2 be their velocities

v be their common velocity after collision

Mathematically

m1u1 + m2u2 = (m1+m2)v

From the question, the second sphere is initially at rest i.e u2 = 0m/s and the composite system moves with a speed equal to one-third the original speed of 1st sphere i.e V = u1/3

Substituting this conditions into the formula, we have;

m1u1 + m2(0) = (m1+m2)u1/3

m1u1 = u1/3(m1+m2)

Given m1 = 1.51kg

m1 = 1/3(m1+m2)

m1 = m1/3 + m2/3

m1-m1/3 = m2/3

2m1/3 = m2/3

2m1 = m2

2(1.51) =m2

m2 = 3.02kg

The mass of the second sphere is 3.02kg

Answer: ∆L = 0.49cm ≈ 0.50cm

Therefore there should be 0.5 cm gap between each piece of steel.

Explanation:

Thermal expansion of steel is the increase in size of steel as a result of increased temperature. It can be represented by the mathematical expression:

∆L = L(k)∆T .....1

Where;

∆L is the change in length

L is the initial length

∆T is the change in temperature

k is the specific Linear expansion coefficient.

Given;

L = 12m

∆T = 50°C - 16°C = 34°C

k (for steel) = 1.2 × 10^-6 /C

Substituting the values into the equation 1

∆L = 12 × 34 × 12×10^-6

∆L = 4896 × 10^-6 m

∆L = 0.49cm ≈ 0.50cm

Therefore there should be 0.5 cm gap between each piece of steel.

There should be a gap of 0.5 cm between each of the piece of steel.  

Based on the given information,  

• The initial length of the tracks is 12 m.

• The laying of the tracks was done at the temperature of 16 °C (Initial temperature), the final temperature is 50 °C.  

• The increase in the size of the steel as an outcome of enhanced temperature is known as the thermal expansion of steel.  

The mathematical representation of thermal expansion is,  

ΔL = L(k)ΔT

• Here ΔL refers to the change in length, L is the initial length, k is the specific linear expansion, which is 1.2 × 10⁻⁶/C for steel, and ΔT is the change in temperature, which is 50 °C - 16 °C = 34 °C.  

Now putting the values we get,  

ΔL = 12 × 34 × 12 × 10⁻⁶

ΔL = 4896 × 10⁻⁶ m

ΔL = 0.49 cm or 0.5 cm

Thus, the gap between each piece of steel should be 0.5 cm.

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Answer: A proton would experience the same magnitude of force.

Explanation: The equation relating Force F charge Q and Electric Field E, is given as

E = F/Q

The magnitude of the force felt would be the same since + and - charge as same magnitude from the question (-1C and +1C). But the direction of force of the proton which as a positive charge would be towards/same direction as the Electric Field.

Final answer:

The actual distance from Albuquerque to Santa Fe is 90 km.

Explanation:

To find the actual distance between Albuquerque and Santa Fe, we first need to find the scale factor. The scale on the map tells us that 1 cm represents 45 km. Since the distance on the map is 2 cm, we can multiply it by the scale factor to get the actual distance: 2 cm * 45 km/cm = 90 km.

Therefore, the actual distance from Albuquerque to Santa Fe is 90 km, so the correct answer is option A.

Answer:

15 MPH or less than that

Explanation:

You shouldn't drive faster than 15 MPH so if a truck unexpectedly pulls out you'll have time to stop.

When parked cars, branches of the tree, fences, houses, or other things block your vision of an open intersection, you can pause before approaching the junction and move slowly ahead until you can see if there is cross-traffic before moving through the junction.

Answer:

Explanation: Metals with close-packed structures such as copper, gold, silver, zinc, magnesium, etc. are more malleable than those with the bcc structure (tungsten, vanadium, chromium, etc.).

In the close-packed structure,  the planes can slip past each other relatively easily. In the bcc structure, there are no close-packed planes, and much greater corrugation between atoms at different levels. This makes it much harder for one row to slide past another.

Answer:

46.67 N/m

Explanation:

mass, m = 0.1 kg

distance, y = 2.1 cm = 0.021 m

Let K be the spring constant.

F = mg = Ky

0.1 x 9.8 = K x 0.021

K = 46.67 N/m

Thus, the spring constant of the spring is 46.67 N/m.

Answer:

k = 46.67 N/m

Explanation:

given,

mass, m = 0.10 Kg

Length, x = 2.1 cm = 0.021 m

spring constant, k = ?

we know,

spring force

F = k x

and also

F = m g

computing both the equation

k x = m g

[tex]k = \dfrac{mg}{x}[/tex]

[tex]k = \dfrac{0.1\times 9.8}{0.021}[/tex]

k = 46.67 N/m

Spring constant for the spring is equal to k = 46.67 N/m

Answer:

M = 9.71 x 10³⁰ Kg

Explanation:

given,

Time period of the planet ,T = 3.31 x 10⁷ s

distance from the star, r = 2.62 x 10¹¹ m

mass of the star = ?

using Kepler third law

[tex]T^2 = \dfrac{4\pi^2}{GM}r^3[/tex]

now,

[tex]M = \dfrac{4\pi^2}{GT^2}r^3[/tex]

where as, G = 6.67 x 10⁻¹¹ m³/kg.s²

[tex]M = \dfrac{4\pi^2}{6.67\times 10^{-11}\times (3.31\times 10^7)^2}\times (2.62\times 10^{11})^3[/tex]

M = 9.71 x 10³⁰ Kg

The mass of the star is equal to M = 9.71 x 10³⁰ Kg.

Kepler's third law can be used to calculate the mass of a star from the orbit of a planet. Given the values for the period and distance of the planet from the star, the calculation results in an estimated mass of 1.2 times the mass of the Sun.

To calculate the mass of a star from the orbit of a planet, we need to use Kepler's third law as reformulated by Newton. The equation is D³ = (M₁ + M₂)P² , where D is the semi-major axis (distance of the planet from the star), M₁ is the mass of the star, M₂ is the mass of the planet, and P is the period of the planet's orbit. In this case, because the mass of the planet is so small compared to the star, we can ignore M₂ and rearrange the formula to solve for M₁: M₁ = D³ / P² .

To plug in the values given, first, take note that D is given in meters and P in seconds. So first we have to convert D from meters to astronomical units (AU) since 1 AU = 1.496 × 10^11 m. So, D = 2.62×10^11 m / 1.496 × 10^11 m/AU = 1.75 AU.

Now we substitute these in our equation, we have M₁ = (1.75)³ AU³ / (3.31 × 10^7 s)² = 1.2 times the mass of the Sun (since the unit of star mass in Kepler's law is a solar mass).

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