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Some solids, notably certain crystals, have permanent electric polarization. Other crystals become electrically polarized when subjected to stress. In electric polarization, the centre of positive charge within an atom, molecule, or crystal lattice element is separated slightly from the centre of negative charge. Piezoelectricity (literally “pressure electricity”) is observed if a stress is applied to a solid, for example, by bending, twisting, or squeezing it. If a thin slice of quartz is compressed between two electrodes, a potential difference occurs; conversely, if the quartz crystal is inserted into an electric field, the resulting stress changes its dimensions. Piezoelectricity is responsible for the great precision of clocks and watches equipped with quartz oscillators. It also is used in electric guitars and various other musical instruments to transform mechanical vibrations into corresponding electric signals, which are then amplified and converted to sound by acoustical speakers.
A crystal under stress exhibits the direct piezoelectric effect; a polarization P, proportional to the stress, is produced. In the converse effect, an applied electric field produces a distortion of the crystal, represented by a strain proportional to the applied field. The basic equations of piezoelectricity are P = d × stress and E = strain/d. The piezoelectric coefficient d (in metres per volt) is approximately 3 × 10−12  for quartz, 5 × −10−11  for ammonium dihydrogen phosphate, and 3 × 10−10  for lead zirconate titanate.
For an elastic body, the stress is proportional to the strain—i.e., stress = Ye × strain . The proportionality constant is the coefficient of elasticity Ye , also called Young’s modulus for the English physicist Thomas Young. Using that relation, the induced polarization can be written as P = dYe  × strain, while the stress required to keep the strain constant when the crystal is in an electric field is stress = dYeE . The strain in a deformed elastic body is the fractional change in the dimensions of the body in various directions; the stress is the internal pressure along the various directions. Both are second-rank tensors, and, since electric field and polarization are vectors, the detailed treatment of piezoelectricity is complex. The equations above are oversimplified but can be used for crystals in certain orientations.
The polarization effects responsible for piezoelectricity arise from small displacements of ions in the  crystal lattice. Such an effect is not found in crystals with a centre of symmetry. The direct effect can be quite strong; a potential V = Yedδ/ε0K is generated in a crystal compressed by an amount δ, where K is the dielectric constant. If lead zirconate titanate is placed between two electrodes and a pressure causing a reduction of only 1/20th of one millimetre is applied, a 100,000-volt potential is produced. The direct effect is used, for example, to generate an electric spark with which to ignite natural gas in a heating unit or an outdoor cooking grill. 
In practice, the converse piezoelectric effect, which occurs when an external electric field changes the dimensions of a crystal, is small because the electric fields that can be generated in a laboratory are minuscule compared to those existing naturally in matter. A static electric field of 106 volts per metre produces a change of only about 0.001 millimetre in the length of a one-centimetre quartz crystal. The effect can be enhanced by the application of an alternating electric field of the same frequency as the natural mechanical vibration frequency of the crystal. Many of the crystals have a quality factor Q of several hundred, and, in the case of quartz, the value can be 106 . The result is a piezoelectric coefficient a factor Q higher than for a static electric field. The very large Q of quartz is exploited in electronic oscillator circuits to make remarkably accurate timepieces. The mechanical vibrations that can be induced in a crystal by the converse piezoelectric effect are also used to generate ultrasound, which is sound with a frequency far higher than frequencies audible to the human ear—above 20 kilohertz. The reflected sound is detectable by the direct effect. Such effects form the basis of ultrasound systems used to fathom the depths of lakes and waterways and to locate fish. Ultrasound has found application in medical imaging (e.g., fetal monitoring and the detection of abnormalities such as prostate tumours). The use of ultrasound makes it possible to produce detailed pictures of organs and other internal structures because of the variation in the reflection of sound from various body tissues. Thin films of polymeric plastic with a piezoelectric coefficient of about 10−11  metres per volt have been developed and have numerous applications as pressure transducers.

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FAQs on Electric Properties Of Matter: Piezoelectricity - Basic Physics for IIT JAM

1. What is piezoelectricity?
Ans. Piezoelectricity is the property of certain materials to generate an electric charge in response to applied mechanical stress or pressure. This phenomenon occurs due to the rearrangement of the material's internal structure, resulting in the separation of positive and negative charges.
2. How does piezoelectricity work?
Ans. Piezoelectricity works based on the principle of the direct piezoelectric effect. When mechanical stress or pressure is applied to a piezoelectric material, such as quartz or certain ceramics, the material's crystal lattice structure deforms. This deformation causes the positive and negative charges within the material to separate, creating an electric field and generating an electric charge.
3. What are the applications of piezoelectricity?
Ans. Piezoelectricity has various applications in different fields. Some common applications include: - Piezoelectric sensors: Used in pressure sensors, accelerometers, and acoustic devices. - Piezoelectric actuators: Utilized in precision positioning systems, robotics, and microelectromechanical systems (MEMS). - Piezoelectric transducers: Found in ultrasound devices, sonar systems, and medical imaging equipment. - Piezoelectric energy harvesting: Used to convert mechanical vibrations or movements into electrical energy in devices like self-powered sensors and wearable electronics.
4. Which materials exhibit piezoelectricity?
Ans. Several materials exhibit piezoelectricity, including: - Quartz: Widely used in various applications due to its strong piezoelectric properties. - Rochelle salt: Known for its high piezoelectric coefficient. - Lead zirconate titanate (PZT): An important piezoelectric ceramic material. - Barium titanate: Exhibits both piezoelectric and ferroelectric properties. - Polyvinylidene fluoride (PVDF): A polymer material with piezoelectric characteristics.
5. Can piezoelectricity be utilized for renewable energy generation?
Ans. Yes, piezoelectricity can be harnessed for renewable energy generation. The concept of piezoelectric energy harvesting involves converting mechanical energy, such as vibrations or movements, into electrical energy using piezoelectric materials. This technology has the potential to power small electronic devices, self-powered sensors, and even generate electricity from ambient vibrations in the environment. However, the efficiency of piezoelectric energy harvesting is currently limited, and further research is being conducted to optimize its applications.
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