Engineering Physics PHY-109 Waves-1
Transcript of Engineering Physics PHY-109 Waves-1
Engineering PhysicsPHY-109Waves-1
ELECTROMAGNETIC THEORY
LASER
FIBER OPTICS
QUANTUM MECHANICS
WAVES
SOLID STATE PHYSICS
Dr. Jeeban Pd GewaliDepartment of Physics
Lovely Professional UniversityPhagwara, Punjab-144411
Syllabus
Interference phenomenon and Concept of resonance
Audible, ultrasonic and infrasonic waves. Production of ultrasonicwaves by magnetostriction method.
Production of ultrasonic waves by piezoelectric method, ultrasonictransducers and their uses, applications of ultrasonic waves,detection of ultrasonic waves (Kundt's tube method, sensitive flamemethod and piezoelectric detectors),
Absorption and Dispersion of ultrasonic waves.
Superposition of two waves, sound wave and its velocity, standingwaves, Formation of beats, Supersonic and shock waves.
Wave Motion
Awave is the propagation of disturbance in a medium which carries the energy along with its motion.
Wave can be mainly of three types Mechanical Electromagnetic Matter wave
The equation governing the propagation of disturbance in a classical wave is π2π
ππ₯2=
1
π2π2π
ππ‘2
In general wave motion is propagating, however there are waves in which, over a period of time no net energy is carried in any direction. These are called the stationary waves.
The shape of the wave can vary widely depending on the situation. A short and sharp jerk to the free end of a string anchored to the wall at the other end, creates a hump to propagate through the string. Such a wave is called a pulse.
Classical Waves
Non Classical Waves
Wave Motion
If two sound waves of slightly different frequencies mix with each other, the resulting profile is called beats.
Again, the wave of an earthquake may have a very complicated profile of pressure as shown in the figure.
The simplest function which is the solution of the wave equation is
π2π
ππ₯2=
1
π2π2π
ππ‘2Wave Equation in Differential Form
π = π΄ sin(π π₯ β ππ‘ + π)
** It can be easily shown that this solution satisfies the differential equation by integrating it twice with respect to space (x) and time (t).
Wave Motion
Amplitude: The maximum size of the disturbance is known as theAmplitude (A).
Phase Angle: The argument of the function on the right hand side isknown as the phase of the disturbance. It is expressed either indegrees or in radians. The constant π is called the initial phase.
Wave front: A wave front is defined as the locus of the points whichare in the same phase. According to Huygens's theory, each pointon a wave front acts as a source of secondary disturbance. Thewaves emanating from these secondary sources are known as thewavelets. Thus,
Point source Spherical Wave Front
Line Source Cylindrical Wave Front
Plane Source Plane Wave Front
π2π
ππ₯2=
1
π2π2π
ππ‘2π = π΄ sin(π π₯ β ππ‘ + π)
Wave Motion
Wave length: It is the distance the wave has totravel along the direction of propagation to changethe phase by 2π. It is usually denoted by π. It is thenormal distance between two consecutive wavefronts of the same phase i.e. whose phase differ by2π.
Time Period: It is the time required for the wave totravel a distance of one wavelength so that
π = ππ
Frequency: The quantity 1/T is called the frequency.It represents the number of cycles completed persecond.
π =1
πAngular Frequency: It represents the radian anglechange in the phase of the wave per second.
π = 2ππ
Wave Number and Wave Vector: The is the spatialfrequency of a wave, either in cycles per unit distance orradians per unit distance. It can be envisaged as thenumber of waves that exist over a specified distance.
Wave number is the magnitude of the wave vector (k).Thus,
π =2π
πVelocity: The velocity or the phase velocity of a wave isdefined as the velocity of its wave fronts. Let the wavefront move a distance Ξπ₯in time Ξt.Then,
π π₯, π‘ = π(π₯ + Ξπ₯, π‘ + Ξπ‘)Therefore,
π =Ξπ₯
Ξπ‘=π
π= ππ
Mechanical Wave: Transverse Wave
Examplesβ’ Light wavesβ’ Waves on a stringβ’ Slinky wavesβ’ Television wavesβ’ microwaves
Mechanical Wave: Longitudinal Wave
SOUND WAVESIn a longitudinal wave the particle displacement is parallel to the directionof wave propagation. The animation at right shows a one-dimensionallongitudinal plane wave propagating down a tube. The particles do notmove down the tube with the wave; they simply oscillate back and forthabout their individual equilibrium positions. Pick a single particle and watchits motion. The wave is seen as the motion of the compressed region (i.e., itis a pressure wave), which moves from left to right.
The animation shows the difference between the oscillatory motion ofindividual particles and the propagation of the wave through the medium.The animation also identifies the regions of compression and rarefaction.
P-Wave (Primary) wave in earthquake is An example of longitudinal wave.
Water Surface Waves
Water waves are an example of waves that involve acombination of both longitudinal and transversemotions. As a wave travels through the waver, theparticles travel in clockwise circles. The radius of thecircles decreases as the depth into the water increases.The animation at right shows a water wave travellingfrom left to right in a region where the depth of thewater is greater than the wavelength of the waves. Ihave identified two particles in orange to show thateach particle indeed travels in a clockwise circle as thewave passes.
Interference
While material particles such as rock will not share its space withanother rock, more than one vibration or wave can exist at thesame time in the same space.
When more than one wave occupies the same space at the sametime, the displacements add at every point. This is called theprinciple of superposition of waves.
If we drop two rocks in water simultaneously, maintaining a certaindefinite distance, then the water waves generated thereby overlapwith each other and creates a pattern called the interference.
Within the zone of interference, wave effects may be increased,decreased or neutralized based on the fact whether theinterference is constructive or destructive.
Wave interference occurs throughout physics, from mechanicalwaves to light waves and even with the quantum-mechanicalwaves that describe matter at the atomic scale.
Zone of InterferenceCreated by the superposition of waves
Interference
Interference
Let us consider, there are two waves approaching eachother, shown in fig (a).
As shown in the figure (b), the wave crests coincide andso do the troughs. The resulting wave is momentarilytwice as big. This is called the constructiveinterference-two waves superposing to produce largerwave displacements.
In figure (c) the crest of one wave meets the trough ofanother wave. As a result they cancel each other andthe resulting amplitude is zero. This is called thedestructive interference.
Path Difference and Phase Difference
β’ Let's assume that, two stones are thrown at two points which are very near,then you will see the pattern as shown in the figure.
β’ let's mark the first point of disturbance as S1 and the other as S2, then waveswill be emanated as shown above. By having a cross-sectional view, you will seethe same waves as shown in the figure below (in the below explanationwavelengths of waves emanated from two different disturbances is assumed tobe the same).
β’ The waves emanating from S1 has arrived exactlyone cycle earlier than the waves from S2. Thus, wesay that, there is a path difference between the twowaves of about Ξ» (wavelength). If the distancetraveled by the waves from two disturbance is same,then path difference will be zero. Once you knowthe path difference, you can find the phasedifference using the formula given below:
ππ‘ππ¬π ππ’ππππ«ππ§ππ =ππ
πΓ ππππ‘ ππ’ππππ«ππ§ππ
Interference of waves going in the same directionβ’ Suppose two identical sources send sinusoidal waves of same angular frequency π in the positive x-direction. The
wave velocity and the wave number is same for the two waves.β’ One source may be started a little later than the other or the two sources may be situated at different points.
Thus, the two waves arriving at a point differ in phase. Let A1 and A2 be the amplitudes of the two waves and πΏ be the difference in phase angle.
β’ The two waves are then represented by the equationπ¦1 = π΄1sin(ππ₯ β ππ‘)
π¦1 = π΄2 sin(ππ₯ β ππ‘ + πΏ)
β’ According to the principle of superposition, the resultant wave is π¦ = π¦1 + π¦2
Applying, π¬π’π§ π¨ + π© = ππππ¨ππ¨π¬π© + ππ¨π¬ π¨ π¬π’π§π© we get,
π¦ = π΄1 sin ππ₯ β ππ‘ + π΄2 sin ππ₯ β ππ‘ cos πΏ + cos ππ₯ β ππ‘ sin πΏπ¦ = sin ππ₯ β ππ‘ π΄1 + π΄2πππ πΏ + cos(ππ₯ β ππ‘)(π΄2π πππΏ)
β’ If we write π΄1 + π΄2πππ πΏ = π΄ cos(π) πππ π΄2π πππΏ = π΄ sin(π)
Then we get,π¦ = π΄ sin ππ₯ β ππ‘ cos π + cos ππ₯ β ππ‘ π ππ π
π¦ = π΄ sin(ππ₯ β ππ‘ + π)
Interference of waves going in the same direction
Thus the resultant is indeed a sine wave of amplitude A and with a phase difference π with thefirst wave. Thus,
π΄2 = π΄2 cos2 π + π΄2 sin2 π
π΄2 = π΄1 + π΄2πππ πΏ2 + π΄2π πππΏ
2
π΄2 = π΄12 + π΄2
2 + 2π΄1π΄2πππ πΏ
π΄ = π΄12 + π΄2
2 + 2π΄1π΄2πππ πΏ
Also ,
tan π =π΄ π πππ
π΄ πππ π=
(π΄2sin πΏ)
π΄1 + π΄2 cos πΏ
Condition for Constructive and Destructive Interference
Constructive Interference:
β’ The resultant amplitude is maximum when πππ πΏ = +1. β’ Thus, πΏ = 2ππ. β’ This implies π΄ = π΄1 + π΄2
Destructive Interference:
β’ The resultant amplitude is minimum when πππ πΏ = β1. β’ Thus, πΏ = (2π + 1)π. β’ This implies π΄ = |π΄1 β π΄2|