The crankshaft in a race car goes from rest to 3540rpm in 2.6s. What is the crankshaft's angular acceleration? How many revolutions does it make while reaching 3540rpm?

Answer:

A magnetic field

Explanation:

The velocity of the wrench 4 seconds after being dropped is -128 ft/sec, indicating it is moving downwards.

To determine the velocity of the wrench 4 seconds after it was dropped from the top of the building, we use the height function s(t) = -16[tex]t^2[/tex] + 375, which represents the wrench's position over time.

The velocity at any time t is given by the derivative of the position function, which is v(t) = s'(t).

Calculating the derivative, we get v(t) = -32t. Therefore, the velocity of the wrench at t = 4 seconds is v(4) = -32(4) = -128 ft/sec. The negative sign indicates that the wrench is moving downwards.

Final answer:

The mass attached to the elastic band travels approximately 12.04 centimeters from its equilibrium position, as calculated by the amplitude of the given motion equation.

Explanation:

To determine how far from its equilibrium position the mass travels, we must find the amplitude of the motion described by the given equation: s = 8 cos t + 9 sin t. The amplitude can be found by recognizing that the equation represents the sum of two simple harmonic motions, and we use the Pythagorean theorem to find the resultant amplitude.

The general formula for the amplitude, A, when given a cos t + b sin t is A = sqrt(a^2 + b^2). Substituting the given coefficients 8 and 9 into this formula gives us the amplitude A = sqrt(8^2 + 9^2) = sqrt(64 + 81) = sqrt(145), which is approximately A ≈ 12.04 cm.

Thus, the mass travels approximately 12.04 centimeters from its equilibrium position.

Answer:

a. 2.545 *10^8 J

b. 2.545 *10^8 J

c. 2.545 *10^8 J

d. 141.688 m/s

Explanation:

Data:

mass, m =  2.5*10^4 kg

Force, F = 5.00*10^5 N

distance, d = 509 m

a. Work, W = F*d = 5.00*10^5 N * 509 m = 2.545 *10^8 J

b. Change in kinetic energy, ΔKE = W = 2.545 *10^8 J

c. Change in kinetic energy = final kinetic energy - initial kinetic energy

If the train started from rest, initial kinetic energy = 0

Then, final kinetic energy, KEf = ΔKE = 2.545 *10^8 J

d. From the definition of kinetic energy we can get the final speed (vf) as follows:

KEf = (1/2)*m*vf^2

vf = √(KEf*2/m)

vf = √(2.545 *10^8*2/2.5*10^4 )

vf = 141.688 m/s

The decomposition of CaCO3 in a container with a piston results in the formation of CO2 gas, which increases the volume and hence work done is -2265 Joules. If the reaction was in an open container, the work done would be zero as there is no opposing force and volume change in the container.

The decomposition of Calcium carbonate i.e. CaCO3, leads to the formation of calcium oxide and carbon dioxide, as shown by the equation CaCO3(s) → CaO(s)+CO2(g). The process is a type of expansion work, which can be calculated using the formula W=PΔV, where W = work, P = pressure and ΔV = change in volume. Carbon dioxide being gas increases the volume. For 1 mole of CO2 at STP, the volume is approximately 22.4 liters or 22.4*10^-3 m^3. As we know Pressure = 1 atm = 1.01325*10^5 Pascals, work done = - PΔV = -1.01325*10^5 Pascals * 22.4*10^-3 m^3 = -2265 Joules.

Now if instead of a piston, the container was open to the atmosphere, the work done would be different as the work will depend on the volume change. In an open container, the system does work but due to no restriction or expansion against any opposing force, the work done is zero since the pressure outside and inside the container is same (atmospheric pressure) and there is no volume change in the container.

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The work done during the complete decomposition of 1.0 mol of CaCO3 at 800°C and 1.0 atm is -88.07 L·atm or -8920.3 J. This work would be the same if the container were open to the atmosphere.

To find the work done during the complete decomposition of 1.0 mol of calcium carbonate (CaCO3), we follow these steps:

Using the ideal gas law (PV = nRT) at 800°C (which is 1073 K):

Since work done is calculated by w = -PΔV:

Conclusion: The work done during the complete decomposition of 1.0 mol of CaCO3 at 800°C and 1.0 atm is -88.07 L·atm or -8920.3 J. This work would be the same if the container were open to the atmosphere because the external pressure remains 1.0 atm.

Answer: Atmosphere can be broadly divided into four distinct layers based on their altitude and temperature.

These layers are- Troposphere, Stratosphere, Mesosphere, and Thermosphere.

1) Troposphere ( extends upto 18 km from earth surface)- a layer that is closest to the surface of earth. It is called zone of weather as all the weather phenomenon ( such as storm, wind, precipitation, formation of clouds) occur in this layer. Temperature decreases with altitude in this layer.

2) Stratosphere (extends from 18 km to 50 km) - a layer above troposphere, where temperature increases with increase in altitude.

A boundary between stratosphere and mesosphere where temperature remains constant as elevation increases  is called Stratopause.

3) Mesosphere (extends 50 km upto 85 km) - a layer above stratosphere, where temperature decreases with increase in altitude.

A boundary between mesosphere and thermosphere, where temperature remains constant as elevation increases  is called Mesopause.

4) Thermosphere (extends from 85 km upto 600 km)-  a layer above mesosphere, where temperature again increases with increase in altitude. It is an extremely hot layer because of absorption of X rays and UV rays.

Thus, correct match for the question is-  

Troposphere -A) Layer closest to the Earth where all weather occurs.

Mesosphere- E) begins between 50-60km and decreases in temperature as elevation increases.

Mesopause- C) temperature remains constant as elevation increases.

Stratosphere -B) temperature increases as elevation increases.

Stratopause -D) temperature remains at a constant zero degrees Celsius as elevation increases.

Final answer:

The layers of the atmosphere can be matched with their descriptions based on the temperature profile as follows: Troposphere - layer closest to the Earth where all weather occurs. Mesosphere - begins between 50-60 km and decreases in temperature as elevation increases. Stratosphere - temperature increases with an increase in elevation. Stratopause - temperature remains constant as elevation increases. Mesopause - temperature remains at a constant zero degrees Celsius as elevation increases.

Explanation:

The layers of the atmosphere can be matched with their descriptions based on the temperature profile as follows:

Refraction is the bending of light rays as they pass through different mediums due to a change in speed, explained by the refractive index and described by Snell's law. It's observable in everyday phenomena and is crucial for the functionality of optical instruments like telescopes.

Refraction refers to the change in direction of a light ray as it passes through variations in matter, such as moving from air into water or glass. This bending occurs due to a change in the light's speed between different mediums. Each material has a refractive index, which dictates how much the light will bend. This index is the ratio of the speed of light in a vacuum to that in the material. For example, when looking into a pond, a stick that is partially submerged in water appears bent at the water's surface; this visual effect is due to refraction.

The extent of refraction follows Snell's law, which relates the angle of incidence to the angle of refraction, keeping in mind the refractive indices of the two media. This law is the foundational principle behind the design of lenses, prisms, and various optical instruments like refracting telescopes.

In astronomy, refraction is observed when light from celestial bodies enters Earth's atmosphere at various angles. Due to the atmosphere's density variations, stars appear slightly higher in the sky than they truly are, as the light they emit is refracted. The amount of this refraction can be calculated, and is negligible near the zenith but increases towards the horizon.

The answer is option a.

During a washing machine's spin cycle, the force that acts on the clothes is directed outward, which is a result of the centrifugal force.

In the context of a washing machine's spin cycle, the force that acts on the clothes is directed outward. This is due to the principle of centrifugal force, a type of inertial force that acts on an object moving in a circular path. The centrifugal force pushes the clothes against the wall of the washing machine drum when it rotates, effectively helping to draw water out of the clothes.

This centrifugal force pushes the clothes away from the center of rotation, causing them to stick to the drum's inner surface during the spin cycle.

Therefore, the answer is option a.

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The two cars have equal speeds at approximately t = 3.85 seconds. The speeds of the cars at that time are approximately 3.15 cm/s and 5.2 cm/s, respectively. The cars pass each other at approximately t = 1.83 seconds.

To determine the time when the two cars have equal speeds, we need to find the time when their velocities are equal. The velocity of the first car is given by the equation v = u + at, where v is the final velocity, u is the initial velocity, a is the acceleration, and t is the time. Setting the velocities of the two cars equal to each other, we have:

-4.2 + 2.6t = 5.2

Solving for t, we find:

t = (5.2 + 4.2) / 2.6

t ≈ 3.85 seconds

So, at approximately t = 3.85 seconds, the two cars have equal speeds.

(b) To find their speeds at that time, we substitute the value of t into the equation for velocity:

V1 = -4.2 + 2.6(3.85)

V1 ≈ 3.15 cm/s

V2 = 5.2

So, at t = 3.85 seconds, the speeds of the cars are approximately 3.15 cm/s and 5.2 cm/s, respectively.

(c) To find the time(s) when the cars pass each other, we can compare their positions. The position of the first car is given by the equation:

x1 = x1o + u1t + (1/2)at^2

x1 = 13.5 - 4.2t + (1/2)(2.6)t^2

The position of the second car is given by:

x2 = 8.5 + 5.2t

Setting these two equations equal to each other and solving for t, we have:

13.5 - 4.2t + (1/2)(2.6)t^2 = 8.5 + 5.2t

Simplifying, we get:

(1.3)t^2 + 9.4t - 5 = 0

Using the quadratic formula, we find two possible values of t:

t ≈ -2.43 seconds, t ≈ 1.83 seconds

Since time cannot be negative, we discard t = -2.43 seconds. Therefore, the cars pass each other at approximately t = 1.83 seconds.

By definition, the law of conservation of energy states that:

Ei = Ef

Where,

Ei: initial energy

Ef: final energy

Therefore, no matter the type of energy, always the final energy is equal to the final energy.

Energy can be transformed into another type of energy. For example, the potential energy can be transformed into kinetic energy.

Also, energy is not created, nor destroyed.

Answer:

The following is not true about the Law of Conservation of Energy:

A. It states that the total energy in the universe keeps increasing.

The officer conclude that the driver exceeded the speed limit as the speed was 69mph.

speed = distance /time

speed  = 30 miles / 26 minute

speed = 30 miles /26 minute x 60 minutes/1 hour

speed = 900 miles/13 hours

speed = 69 mph.

the prevailing maximum pace limit for cars on expressways is a hundred and twenty km and on national highways, the maximum velocity restriction is 100 mph.

Velocity limits in India vary by way of nation and car type. In April 2018, the Union Ministry of street shipping and Highways constant the most velocity limit on expressways at a hundred and twenty km/h, for national highways at one hundred km/h, and for urban roads at 70 km/h for the M1 class of vehicles.

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Final answer:

Snell's Law is the physical principle that defines the relationship between the angles of incidence and refraction when light transitions between two different media, mathematically expressed as n1 sin θ1 = n2 sin θ2.

Explanation:

Snell's Law, also known as the law of refraction, describes the relationship between the angles of incidence and refraction when a light ray passes through the interface between two different media. This fundamental physical principle is expressed mathematically as n1 sin θ1 = n2 sin θ2, where 'n1' and 'n2' are the indices of refraction of the first and second media, respectively, and 'θ1' and 'θ2' are the angles of incidence and refraction. Snell's Law is crucial for understanding phenomena such as the bending of light, and it has applications in fields like optics and engineering.

The answer is A. Acceleration.

Answer:

c

Explanation:

B. Valence Electrons

_________________

Reason:

The valence electrons are the number of electrons in an outer shell of an atom that can participate in forming chemical bonds with other atoms. Atoms with a relatively empty outer shell will want to give up electrons.

Answer:

The correct answer is option D

Explanation:

Wave Energy is given by

[tex]= \frac{1}{2} M(w^2 *A^2*\frac{1}{2})\\[/tex]

Wave energy is directly proportional to the square of the amplitude.

thus,

[tex]\frac{E1}{E2} = \frac{A1^2}{A2^2} \\\frac{3}{E2} = \frac{2^2}{4^2} \\E2 = 12 units\\[/tex]

To find the force that the boy is exerting on the stuffed animal, subtract the net force from the girl's force. The boy is exerting a force of 3N.

To find the force that the boy is exerting, we first need to determine the net force acting on the stuffed animal. The net force is equal to the mass of the stuffed animal multiplied by its acceleration. In this case, the mass is 0.2 kg and the acceleration is 2.5 m/s^2. So the net force is 0.2 kg * 2.5 m/s^2 = 0.5 N.

Since the girl exerts a force of 3.5 N, and the net force is 0.5 N, the boy's force must be equal to the difference between these two forces. Therefore, the boy is exerting a force of 3.5 N - 0.5 N = 3 N.

As the time to run up the stairs increases, the power developed decreases..

When analyzing the relationship between time and power, it's essential to consider the fundamental definition of power as the rate at which work is done.

This can also be understood using the formula for power -

Power (P) = Work (W) / Time (t)

When the time (t) increases and the work (W) remains constant, the power output (P) decreases.

Thus, as the time required to run up the stairs increases, the power developed by that person decreases.

Final answer:

To eliminate the parameter t and find a rectangular equation for the plane curve defined by the parametric equations x = 6 cos t, y = 6 sin t; 0 ≤ t ≤ 2π, we can square both equations and then add them together. The rectangular equation for the plane curve is x^2 + y^2 = 36.

Explanation:

To eliminate the parameter t and find a rectangular equation for the plane curve defined by the parametric equations x = 6 cos t, y = 6 sin t; 0 ≤ t ≤ 2π, we can square both equations and then add them together. This will eliminate the parameter t and give us a rectangular equation. Let's do the calculations:

x^2 = (6 cos t)^2 = 36 cos^2 t

y^2 = (6 sin t)^2 = 36 sin^2 t

Adding the two equations together: x^2 + y^2 = 36 (cos^2 t + sin^2 t) = 36

So, the rectangular equation for the plane curve is x^2 + y^2 = 36. This means that option C is the correct answer.

Explanation:

Given that,

Force of gravity acting on the person, F = mg = 850 N

The roof is on the 20 degrees slope with the surface. We need to find the magnitude of normal force of the roof on the worker. It can be calculated as :

[tex]F_N=mg\ cos\theta[/tex]

[tex]F_N=850\times \ cos20[/tex]

[tex]F_N=798.73\ N[/tex]

So, the normal force of the roof on the worker is 798.73 N. Hence, this is the required solution.

The magnitude of the normal force of the roof worker is 798.66 N

The parameters given in the question are

Weight= 850 N

angle=  20°

The formula for calculating the magnitude of the normal force of the roof worker is

= mg cos 20°

= 850 × 0.9396

= 798.66

Hence the magnitude of the normal force of the roof worker is 798.66 N

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Using basic kinematics and trigonometry in projectile motion, we find the horizontal and vertical velocity components, time to reach the highest point, and the maximum height. We then determine the range of the projectile and the acceleration and velocity components at the highest point.

Let's solve the question step by step:

(a) Horizontal and Vertical Components of Velocity

To find the components of the shell's initial velocity, we can use trigonometry:

• Horizontal component (vx): vx = v * cos(θ) = 70.0 m/s * cos(60.0°)

• Vertical component (vy): vy = v * sin(θ) = 70.0 m/s * sin(60.0°)

(b) Time to Reach the Highest Point

The time to reach the highest point can be determined using the formula: t = vy / g, where g is the acceleration due to gravity (9.8 m/s2).

(c) Maximum Height

The maximum height is given by H = (vy2) / (2g).

(d) Horizontal Range

The horizontal range can be calculated once we have the total time of flight and the horizontal velocity: range = vx * total time of flight.

(e) Components of Acceleration and Velocity at the Highest Point

At the highest point:

• Horizontal velocity component remains unchanged: same as initial vx.

• Vertical velocity component is 0 m/s because the projectile stops rising and is about to start falling.

• Horizontal acceleration is 0 m/s2 because no forces are acting in the horizontal direction.

• Vertical acceleration remains -9.8 m/s2 (negative because it is directed downwards).