Force = mass x acceleration : __________.a. for any force, there is an equal and opposite reaction force. b. the orbit of each planet about the Sun is an ellipse with the Sun at one focus. c. a planet moves faster in the part of its orbit nearer the Sun and slower when farther from the Sun, sweeping out equal areas in equal times. d. an object moves at constant velocity if there is no net force acting upon it. e. more distant planets orbit the Sun at slower average speeds, obeying the precise mathematical relationship p2 =a3.

Answer:

0.83999 m

0.20999 m

Explanation:

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

s = 189 cm

[tex]s=ut+\frac{1}{2}at^2\\\Rightarrow 1.89=0t+\frac{1}{2}\times 9.81\times t^2\\\Rightarrow t=\sqrt{\frac{1.89\times 2}{9.81}}\\\Rightarrow t=0.62074\ s[/tex]

When the time intervals are equal, if four drops are falling then we have 3 time intervals.

So, the time interval is

[tex]t'=\dfrac{t}{3}\\\Rightarrow t'=\dfrac{0.62074}{3}\\\Rightarrow t'=0.206913\ s[/tex]

For second drop time is given by

[tex]t''=2t'\\\Rightarrow t''=2\times 0.2069133\\\Rightarrow t''=0.4138266\ s[/tex]

Distance from second drop

[tex]s=ut+\dfrac{1}{2}at^2\\\Rightarrow y''=ut''+\dfrac{1}{2}at''^2\\\Rightarrow s=0\times t+\dfrac{1}{2}\times 9.81\times 0.4138266^2\\\Rightarrow s=0.839993\ m[/tex]

Distance from second drop is 0.83999 m

Distance from third drop

[tex]s=ut+\dfrac{1}{2}at^2\\\Rightarrow y''=ut'+\dfrac{1}{2}at'^2\\\Rightarrow s=0\times t+\dfrac{1}{2}\times 9.81\times 0.206913^2\\\Rightarrow s=0.20999\ m[/tex]

Distance from third drop is 0.20999 m

Answer:

star A is hottest and star c is coldest

Explanation:

from WEIN'S LAW which relates stellar color to stellar temperature, the visible light output of very hot stars is dominated by blue color while the stars that are cool emit most of their visible light as red .

Star A, the blue star, is the hottest due to its blue color, which is a consequence of its high temperature. Meanwhile, Star C, the red star, is the coldest because red light has a longer wavelength than blue or white light.

The color of a star can give us an idea of its temperature thanks to a concept called black-body radiation. This concept tells us that the hotter a star is, the shorter the wavelength of light it will emit, which in turn defines its color. Blue stars are the hottest, as blue light has a shorter wavelength than red or white light. As for white stars, they are intermediate in temperature, since white light is a combination of many different colors (wavelengths). Finally, red stars are the coldest of the three, because red light has a longer wavelength than blue or white light.

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Answer:Gamma Photons

Explanation: Gamma photons are photons that are parts of the electromagnetic radiation,they are of a very short wave length of less than about 0.01nanometer.,which means they travel with a very high speed and a very high energy of about 100,00volts. Gamma photons can KILL HEALTHY AND LIVING CELLS, that is why it is mainly used to KILL CANCEROUS CELLS/TUMORS but in modern radiology the use of superconducting wire coils are not employed or used to create magnetic fields for Gamma photons.

Answer:

Yes! This sentence is correct.

Explanation:

So the complete question along with options is:

Q. Snowflakes begin to form when water in the atmosphere freezes it causes the water molecules to bond into a hexagonal shape.

a) no change

b) freezes, causing

c) freezes, it causes

d) freezes, this causes.

The coorect option is c.

Answer:

Highly structured or planned threat

Explanation:

This type of threat is an highly structured threat that is been planned using every available tools and machineries. The attack of this type consist of three phases, the preparation phase; where all the information and resources needed is been planned and source for. The execution phase; the attackers plane how to carry out the action, the techniques and technology needed for the success of the operation is carried out and tested. The post execution phase; the attackers planned there escape from any trouble that may arise and how not to leave any spot that will make them to be identified.

This type of threat requires to put the security outfit or the entire agency on red alert to ensure effective engagement before the attackers execute their actions.

Answer: 500metres

Explanation:

Wavelength is defined as the distance between two successive crest and troughs. The relationship between the wavelength (¶), frequency (f) and velocity of the wave(v) is given by v= f¶

Therefore wavelength ¶ = v/f

Given the velocity = 3×10^8m/s

frequency = 600kHz = 600,000Hz

Wavelength =3×10^8/600,000

Wavelength = 500meters

Their wavelength in meters is 500meters

Answer:

Tissues that are damaged or injured.

Explanation:

Dystrophic calcification involves the deposition of calcium in soft tissues despite no disturbance in the calcium metabolism, and this is often seen at damaged tissues.

Examples of areas in the body where dystrophic calcification can occur include atherosclerotic plaques and damaged heart valves.

Answer:

the correct answer is A Sherp-edged shadows

Explanation:

The wave model describes the path of light as the propagation of a cosenoidal wave, in this case when two beams of light interact, they do so through the supervision of the cosines of each one.

In the lightning model, the light wave characteristics are not taken into account, this model is used for the so-called geometric optics, which explains many phenomena, image formation, reflection phenomena and shadow formation defined in the corners , since in this model the light is nine rectilinear from one point to another.

With this explanation we see that the correct answer is to

Final answer:

Sharp-edged shadows can be understood without the wave model of light, as they can be explained by the ray model. Double-slit interference, thin-film interference, and single-slit diffraction require the wave model to account for light's wave properties, such as diffraction and interference.

Explanation:

The phenomena that can be understood without appealing to the wave model of light is sharp-edged shadows. This is because sharp-edged shadows can be explained using the ray model of light, which treats light as straight lines that travel from a source and create shadows when they are obstructed by an object. The other phenomena listed, including double-slit interference, thin-film interference, and single-slit diffraction, require an understanding of the wave properties of light, such as diffraction and interference, to be properly understood.

According to Huygens's principle, diffraction is the bending of waves around the edges of an object or through an opening. Interference occurs when waves superimpose and either constructively or destructively interfere with each other, giving rise to the various patterns seen in these phenomena. The ray model of light is insufficient to explain these effects because it does not account for the wave-like behaviors of light, such as bending and superposition of waves.

Answer:

The order is Star 3 < Star 2 < Star 1 < Star 4

Explanation:

Lets name the stars with their written order.

Star 1: 2.7 x 10^18 km3

Star 2: 6.9 x 10^12 km3

Star 3: 2.2 x 10^12 km3

Star 4: 4.9 x 10^21 km3

Star with lowest power of 10 has the least volume. Therefore, star 2 and star 3 would be the stars with least volume. Star 2's coefficient is better than Star 3. Thus, the order will be Star 3 < Star 2 < Star 1 < Star 4.

Explanation:

The work done on the stone is kinetic energy.

Kinetic energy = 80 J

We have

        Kinetic energy = 0.5 x Mass x Velocity²

        Mass = 1.30 kg

       80 = 0.5 x 1.30 x Velocity²

       Velocity = 11.09 m/s

We have equation of motion v² = u² + 2as

Initial velocity, u = 11.09 m/s  

Acceleration, a = -9.81 m/s²  

Final velocity, v = 0 m/s  

Substituting  

v² = u² + 2as

0² = 11.09² + 2 x -9.81 x s

s = 6.27 m  

Height it will go is 6.27 m

To find the height a 1.30-kg rock will reach when thrown vertically upwards after 80.0 J of work is done on it, convert the work into potential energy and use the formula PE = mgh. The rock will reach a height of about 6.14 meters.

Work-energy principle: The work done on an object when thrown vertically upwards is stored as potential energy at the highest point of the rock's trajectory. In this case, with 80.0 J of work done on a 1.30-kg rock, the rock will reach a height determined by the conversion from work to potential energy.

Calculating the height: By converting the work done into potential energy and using the formula PE = mgh, where PE is the potential energy, m is the mass, g is the acceleration due to gravity (9.81 m/s^2), and h is the height, you can calculate the height the rock will reach.

Answer: The rock will reach a height of approximately 6.14 meters from the point of release.

Answer:hjvuihi

Explanation:lk

The electric field produced at the surface of the body due to the sudden influx of charge in the axon can be calculated using Coulomb's law. If the charge that enters each meter of the axon is distributed uniformly along it, the total charge that enters a 0.100 mm length of the axon can be calculated. The electric field produced by the influx of Na+ ions is directed away from the axon.

1) The electric field produced at the surface of the body due to the sudden influx of charge in the axon can be calculated using Coulomb's law. The formula for electric field is E = k * (Q / r^2), where k is the electrostatic constant, Q is the charge, and r is the distance. By substituting the given values, we can find the magnitude and direction of the electric field.

2) If the charge that enters each meter of the axon is distributed uniformly along it, we can calculate the total charge that enters a 0.100 mm length of the axon by multiplying the charge per meter by the length in meters.

3) Since the excess of Na+ ions enter the axon, the electric field produced by them will be directed away from the axon.

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Answer:

Mirrors

Explanation:

In Solar thermal power generation system, mirrors are used to collect and focus sunlight  onto a fluid pipe to produce high temperature required to generate electricity.

There are two main components: mirrors capture and focus light onto a receiver. The heat transfer fluid is circulated in the receiver. Steam is produced which is converted to mechanical energy in a turbine. It powers a generator and electricity is produced.

In solar thermal electric generation, concave mirrors are used to concentrate sunlight onto a pipe in a system known as a parabolic trough. The heat is transferred via heat exchanger to produce steam, which generates electricity through a steam turbine-generator setup.

In solar thermal electric generation, the sun's energy is concentrated by concave mirrors or reflectors to heat the fluid in a pipe that is used to generate electricity. These mirrors are often part of a system known as a parabolic trough or concentrating collector, which has the approximate shape of a section of a cylinder, specifically one-quarter of a full cylinder. The mirrors focus sunlight onto a blackened pipe containing a special fluid.

Once this fluid is heated, it is then pumped through a heat exchanger where its thermal energy is transferred to water to produce steam. This steam drives a turbine connected to a generator, producing electricity through a conventional steam cycle. This entire process is a part of larger solar thermal power plants, which utilize solar collectors with two components: mirrors to collect and focus sunlight, and a receiver to collect the heat transferred to the fluid.

Answer:

q = 3.703*10^-9

dipole moment = 3.703*10^-11

E @ (10,0) = 331.977 N/C

Explanation:

Given:

Coordinates

+ q = (0,-0.5) cm

- q = (0,0.5) cm

E = 360 N/C @ (0,10)

Solution:

[tex]Electric Field Strength @ (0,10) = \frac{k*q}{R^2}\\[/tex]

Note: +q (away from charge) and -q (towards the charge)

[tex]E = k*q*(\frac{1}{R^2_{1}} - \frac{1}{R^2_{2} })\\ 360 = (9*10^9)*q*(\frac{1}{0.095^2} - \frac{1}{0.105^2 })\\\\q =1.99 *10^-9[/tex]

Dipole moment = q.(space between two charges)

= (3.703*10^-9 * 0.01)

= 3.703*10^-11

Electric Field Strength @ (10,0)

[tex]E = 2*k*q*(\frac{1}{R^2})*cos(Q)\\ \\Q = arctan(\frac{10}{0.5}) = 87.138 degrees\\R = \sqrt{10^2 + 0.5^2} = 10.01249 cm\\E = 2* (9*10^9)*(3.703*10^-9)*\frac{cos (87.138)}{0.1001249^2}\\E = 331.977 N/C[/tex]

Answer:

a. dipole moment = 2.003 × 10⁻¹³ Cm, charge = 2.003 × 10⁻¹¹ C b. 8.96 N/C

Explanation:

a. The electric field due to a dipole is given by

E = p/2πεy³ where p = dipole moment and y = distance of dipole to point of electric field = 10 cm = 0.10 m. E = electric field strength at (0,10) = 360 N/C

So, E = p/2πεy³

p = 2πεy³E = 2π × 8.854 × 10⁻¹² × (0.10 m)³ × 360 N/C = 2.003 × 10⁻¹³ Cm

Also, p = qd where q = charge and d = distance of charges apart = 1.0 cm = 0.01 m

q = p/d = 2.003 × 10⁻¹³ Cm/0.01 m = 2.003 × 10⁻¹¹ C

b. The electric field at point (10,0)

E = qx/[πε√(d² + 4x²)]³ which is the electric field at an axis perpendicular to the dipole where x = 10 cm = 0.10 m

E = 2.003 × 10⁻¹¹ C × 0.10/π × 8.854 × 10⁻¹²√(0.01² + 4×(0.1)²)³  = 8.96 N/C.

Answer:

A wind turbine turns wind energy into electricity using the aerodynamic force from the rotor blades.

Explanation:

Answer:

(a)  13.795 m/s.

(b) -3140.28 N.

Explanation:

(a) Using newton's  equation of motion,

v² = u² + 2gs.......................... Equation 1

Where v = final velocity, u = initial velocity, s = height of the tower, g = acceleration due to gravity.

Given: s = 9.7 m, u = 0 m/s ( jump from a height), g = 9.81 m/s².

Substitute into equation 1

v² = 0² + 2×9.81×9.7

v² = 190.314

v = √(190.314)

v = 13.795 m/s.

Hence the velocity of the driver when he hits the water = 13.795 m/s.

(b)

F = ma.................... Equation 2

Where F = force exerted on the diver, m = mass of the diver, a = acceleration of the diver below the water surface.

Also using

v² = u² + 2as ............ Equation 3

Note: At the point when the diver enters the water, u = 13.795 m/s, and at the point when the diver comes to a complete stop, v = 0 m/s

Given: s = 2.0 m, u = 13.795 m/s, v = 0 m/s

Substitute into equation 3

0² = 13.795²+2(2a)

0 = 190.30203 + 4a

-4a = 190.30203

a = 190.30203/-4

a = -47.58 m/s²

Also given: m = 66 kg,

Substitute into equation 3

F = (-47.58)(66)

F = -3140.28

Note: The Force is negative because it act against the motion of the diver.

Hence the net force exerted on the diver while in the water = -3140.28 N.

Answer: The answer is 3 either physical or chemical properties

Explanation:

because all properties of matter are either physical or chemical

Hope this helps :)

Intensive properties, which are characteristic of a substance and do not depend on the amount of material, can be either physical or chemical properties. For example, boiling point and density are physical intensive properties, whereas flammability is a chemical intensive property.

The correct answer is 3, intensive properties can be either physical or chemical properties. In chemistry, intensive properties are those that do not depend on the amount of the material present. They are characteristic of the substance and help us identify it. Examples of intensive properties include density, boiling point, or color. These can be either physical properties like boiling point and density, which do not alter the chemical composition of the substance, or chemical properties like flammability, which do involve a chemical reaction.

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Answer:

Option A and B

Explanation:

In the parallel connection, the capacitors that are connected in parallel have the same potential difference across each capacitor as the battery. Therefore, statement A is correct.

Charge (Q), capacitance (C) and voltage across capacitor (V) is related with each other as follows:

Q = C ×V

As capacitance is not same for all the capacitors, therefore each capacitor carries different charge. Therefore, statement C is incorrect.

As potential difference across each capacitor is same, therefore, capacitor with the largest capacitance carry the most charge. Therefore, statement B is correct.

Therefore, statements A and B are correct.

Answer:

Option A and B is correct

Explanation:

When two or more capacitors are connected in parallel, the equivalent capacitance of the circuit is the sum of capacitance of all the capacitors.

C = C₁ + C₂+ C₃+....

The potential difference across each capacitor is equal. Thus, option A is correct.

The total charge is the sum of the charge on stored in each capacitor.

Q = Q₁ + Q₂+ Q₃+....

Q = CV

Since the voltage is same across each capacitor, the capacitor which has largest capacitance has the most charge. Thus, option B is correct.

Answer:

He travel for 2 h at the first part and 2 h for the second part.

Explanation:

given information:

business trip's distance, [tex]s_{tot}[/tex] = 214 miles

v₁ = 53 mph

v₂ = 54 mph

t₁ = t

t₂ = 4 - t

now lets find the distance of each speed

s₁ = v₁ t₁ = 53 t₁

s₂ = v₂ t₂ = 54 t₂

[tex]s_{tot}[/tex] = s₁ + s₂

214 = 53 t₁ + 54 t₂

214 = 53t + 54 (4-t)

214 = 53t + 216 - 54 t

t = 216 - 214

 = 2 h

t₁ = t = 2 h

t₂ = 4 - t = 4 -2 = 2h

Final answer:

You are not harmed by a charged metal ball or by fireworks sparks because the actual exposure (amount of charge and duration for the ball, and size and duration for the sparks) is insufficient to cause injury.

Explanation:

The reason you are not harmed by contact with a charged metal ball, even if its voltage may be very high, is similar to why you are not harmed by the hotter-than-1000°C sparks from a fireworks sparkler. In both cases, it is the amount of charge and the duration of the contact that determine the danger of the electric shock, not just the voltage alone. For the metal ball, even though the voltage is very high, the resulting current is usually very low because the charge moves to the outer surface and is quickly neutralized by surrounding materials. Consequently, the exposure to the charge is so brief that it doesn't cause harm. Similarly, with the sparks from a sparkler, they may be extremely hot, but they are small and lose their heat quickly upon contact with the skin, so they don't transfer enough energy to cause a burn.

Answer:

Explanation:

Given

initial velocity of motorcycle [tex]u=6.3\ m/s[/tex]

final velocity [tex]v=1.9\ m/s[/tex]

time taken [tex]t=4.6\ s[/tex]

radius of wheel [tex]r=0.68\ m[/tex]

using v=u+at

where a=acceleration

[tex]1.9=6.3+a\times 4.6[/tex]

[tex]a=-0.956\ m/s^2[/tex]

angular acceleration [tex]\alpha =\frac{a}{r}[/tex]

[tex]\alpha =\frac{-0.956}{0.68}=-1.406\ rad/s^2[/tex]

[tex]Displacement=average\ velocity\times time[/tex]

[tex]Displacement=\frac{u+v}{2}\times t[/tex]

[tex]Displacement=\frac{1.9+6.3}{2}\times 4.6=18.86\ m[/tex]

Angular displacement [tex]\theta =\frac{Linear\ displacement}{radius}[/tex]

Angular displacement [tex]\theta =\frac{18.86}{0.68}=27.73\ rad[/tex]

Answer:

Explanation:

initial velocity, u = 6.3 m/s

final speed, v = 1.9 m/s

time, t = 4.6 s

radius, r = 0.68 m

(a)

initial angular velocity, ωo = u / r = 6.3 / 0.68 = 9.26 rad/s

final angular velocity, ω = v / r = 1.9 / 0.68 = 2.79 rad/s

Let α be the angular acceleration

Use first equation of motion

ω = ωo + αt

2.79 = 9.26 + α x 4.6

α = - 1.41 rad/s²

(b) Let Ф be the angular displacement

Use third equation of motion

ω² = ωo² + 2 αФ

2.79² = 9.26² - 2 x 1.41 x Ф

Ф = 27.6 rad

Answer:

Option B is correct ( difficulty in recovering from a stalled condition.)

Explanation:

Option B is correct ( difficulty in recovering from a stalled condition.)

If you load airplane in such manners CG has changed then it will have huge impact on the longitudinal stability. Due to this airplane would face  difficulty in recovering from a stalled condition.

Stall is the phenomena in which air resistance is increased on the wings which causes decrease in lift. So it is important to remain with in CG limit put by manufacturer to avoid stall condition.

One undesirable flight characteristic a pilot might experience with this plane is  : ( B ) difficulty in recovering from a stalled condition.

When loading an aircraft the CG limit should not be exceeded as stated by the manufacturer, this is  because when the aircraft is loaded above the limit the longitudinal stability of the aircraft will be affected because more air resistance will be exerted on the wings of the plane which leads to a condition known as stall

Hence we can conclude that one undesirable flight characteristic a pilot might experience with this plane is  difficulty in recovering from a stalled condition.

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Explanation:

Consider the horizontal motion of ball

We have equation of motion s = ut + 0.5 at²

        Initial velocity, u = 44.7 m/s

        Acceleration, a = 0 m/s²  

        Displacement, s = 16.1 m      

     Substituting

                      s = ut + 0.5 at²

                      16.1 = 44.7 x t + 0.5 x 0 x t²

                      t = 0.36 s

      Time taken to travel 16.1 m is 0.36  seconds

Now we need to find how much ball travel vertically during this 0.36 seconds.

We have equation of motion s = ut + 0.5 at²

        Initial velocity, u = 0 m/s

        Acceleration, a = 9.81 m/s²  

        Time, t = 0.36 s      

     Substituting

                      s = ut + 0.5 at²

                      s = 0 x 0.36 + 0.5 x 9.81 x 0.36²

                      s = 0.64 m

     The baseball drops by 0.64 meter.

Answer:

7.92 s

Explanation:

Power: This can be defined as the rate at which energy is used. The S.I unit of

Watt (W).

Mathematically power can be represented as,

P = E/t

Pt = E............................. Equation 1

Where P = power of the engine, t = time, E = Energy.

But,

E = 1/2m(Δv)²................. Equation 2

Where m = mass of the automobile, Δv = change in velocity of the car = final velocity - initial velocity.

Substitute the value of E in equation 2 into equation 1

Pt = 1/2m(Δv)²................................. Equation 3

making t the subject of the equation,

t = 1/2m(Δv)²/P ........................ Equation 4

Given: m = 1540 kg, P = 75 kW = 75000 W, Δv = 100-0 = 100 km/h (initial velocity of the car = 0 km/h)

100(1000/3600) m/s = 27.78 m/s

Substitute into equation 4

t = 1/2(1540)(27.78)²/75000

t = 594230.87/75000

t = 7.92 second.

Thus The time required to accelerate the car = 7.92 seconds.

It is not realistic period the time period is too short.

The car takes approximately 7.8 seconds to accelerate from rest to a speed of 100 km/h, given the power rating and mass that was provided in the question.

The process to solve this physics problem involves steps in calculating the work done on the car and then the time required for this work at the given power. To begin with, we can translate the speed of 100 km/h to m/s, which would be 27.8 m/s. Afterward, using the kinetic energy formula (K.E = 1/2 * m * v²), the work done on the car to achieve this speed can be calculated, which is 585840 Joules.

The next step is to compute the time. We know that Power = Work Done / Time, where power has been provided (75 kW = 75000 Watts) and we just computed the work done, so we can rearrange this equation to solve for time. This gives a resulting time of approximately 7.8 seconds. This may seem a short amount of time, but it's plausible for a high-powered sports car to reach 100 km/h in around this time frame.

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Answer:

E. The force on A is exactly equal to the force on B.

Explanation:

The force between two charges is given by

[tex]F=\dfrac{kq_1q_2}{r^2}[/tex]

where

[tex]q_1[/tex] = Charge on particle 1

[tex]q_2[/tex] = Charge on particle 2

r = Distance between the charges

k = Coulomb constant = [tex]8.99\times 10^{9}\ Nm^2/C^2[/tex]

[tex]F=\dfrac{8.99\times 10^9\times 10\times 10^{-9}\times 1\times 10^{-9}}{(25\times 10^{-2})^2}\\\Rightarrow F=0.0000014384\ N[/tex]

This force will be exerted on both the charges equally.

So, The force on A is exactly equal to the force on B

Explanation:

Johannes Kepler, working with the data carefully collected by Tycho Brahe without the help of a telescope, especially those related to the retrograde motion of Mars, realized that the motion of the planets could not be explained by his model of perfect polyhedra. Coming to the conclusion that all the planets move in elliptical orbits, with the Sun in one of the foci.

Answer:

40.645 m/s²

Explanation:

Acceleration: This can be defined as the rate of change of velocity. The S.I unit of acceleration is m/s². Mathematically,

a = (v-u)/t................................. Equation 1

Where a = acceleration, v = velocity, u = initial velocity, t = time.

Given: v = 25.2 m/s, u = 0 m/s, t = 0.62 s.

Substituting into equation 1

a = (25.2-0)/0.62

a = 25.2/0.62

a = 40.645 m/s²

Hence the average acceleration of the drag-star = 40.645 m/s²

Answer:

2. Friction

3. Momentum

Explanation:

For elastic collision, the total kinetic energy before and after collision are same while for inelastic collision, kinetic energy is converted to other forms apart from kinetic energy for example we get sound energy or rotational energy. Since in this case there's no diagram, we can't make a conclusion. However, in real life, all collisions are inelastic

2

Work is always done against frictional force

3

The law of conservation of momentum is used in an inelastic collision

Answer:

1) Inelastic

2) Friction

3)Momentum

Explanation:

USATestprep

Answer:

(a) lowest frequency=577 Hz

(b) highest frequency=608 Hz

Explanation:

Given data

f(whistle frequency)=592 Hz

ω(angular speed)=13.8 rad/s

r(radius)=64.7 cm=0.647 m

To find

(a) Lowest frequency

(b) highest frequency

Solution

From Doppler effect

f=f×{(v±vd)/(v±vs)}

Where

v is speed of sound

Vd is speed detector relative to the medium(vd=0)

Vs is the speed of the source

Since

v=rω

For (a) lowest frequency

[tex]f^{i}=f(\frac{v}{v+rw} )\\f^{i}=(592Hz)(\frac{343m/s}{343m/s+(0.647m)(13.8rad/s)} )\\f^{i}=577Hz[/tex]

For (b) highest frequency

[tex]f^{i}=f(\frac{v}{v-rw} )\\f^{i}=(592Hz)(\frac{343m/s}{343m/s-(0.647m)(13.8rad/s)} )\\f^{i}=608Hz[/tex]

Answer:

option B

Explanation:

given,

Force = F

angle of inclination, = θ

distance = d

coefficient of friction = μ

work done =frictional Force x displacement

W = f. s

friction force on the incline will be equal to horizontal of force component. so,

f = - F cos θ

Work done will be equal to

W = - F d cos θ

Hence, the correct answer is option B