Pyroelectricity ferroelectrics

These materials are piezoelectric and pyroelectric ferroelectricity has not been clearly proven [443]. 

C. M. Hanson, Hybrid Pyroelectric-Ferroelectric Bolometer Arrays... 

Figure 11.6 Schematic relationship between dielectric solids (E is an applied electric field, and a is an applied stress), (a) Dielectric (i) E — 0, (ii) E is finite a dielectric, normally unpolarised, becomes polarised is an electric field), (b) Piezoelectric (i) cr = 0, (ii) a is finite (a piezoelectric, normally unpolarised, developes a polarisation when subjected to stress, even is no electric field), (c) Pyroelectric and ferroelectric E — 0, a — 0. (d) Anti-ferroelectric E = 0,

From the standpoint of crystal structure, ferroelectric materials are a further subset of pyroelectric and piezoelectric materials. As with pyroelectrics, ferroelectrics also display a spontaneous polarization in the absence of an applied electric field. The... 

Lang SB (2005) Guide to the literature of piezoelectricity and pyroelectricity. Ferroelectrics 321 91-204... 

In this chapter, however, are considered pyroelectric, ferroelectric and piezoelectric effects owing to which the dielectrics are increasingly exploited in recent years. 

Concepts like piezoelectric, pyroelectric, ferroelectric, ferrielectric, antiferroelectric, paraelectric, electrostrictive, and several more, relate to distinct phenomena and are themselves interrelated. They are bound to appear in the description of liquid crystals and liquid crystal polymers, as they do in normal polymers and crystalline solids. Presently, great confusion is created by the uncritical use of these terms. For example, in the latest edition of the Encyclopedia Britannica [4] it is stated that pyroelectric-... 

Hanson (1997) Hybrid Pyroelectric-Ferroelectric Bolometer Arrays by C. M. Hanson, This is Chapter 4 in Kruse and Skatrud (1997) Uncooled Infrared... 

The most important materials among nonlinear dielectrics are ferroelectrics which can exhibit a spontaneous polarization PI in the absence of an external electric field and which can spHt into spontaneously polarized regions known as domains (5). It is evident that in the ferroelectric the domain states differ in orientation of spontaneous electric polarization, which are in equiUbrium thermodynamically, and that the ferroelectric character is estabUshed when one domain state can be transformed to another by a suitably directed external electric field (6). It is the reorientabiUty of the domain state polarizations that distinguishes ferroelectrics as a subgroup of materials from the 10-polar-point symmetry group of pyroelectric crystals (7—9). 

At the temperatures of the phase transitions, maxima of the dielectric constant up to 10,000 are found. Moreover, ia the ferroelectric state below T the material becomes pyroelectric and shows high piezoelectric activity. 

Polymer Ferroelectrics. In 1969, it was found that strong piezoelectric effects could be induced in the polymer poly(vinyhdene fluoride) (known as PVD2 or PVDF) by apphcation of an electric field (103). Pyroelectricity, with pyroelectric figures of merit comparable to crystalline pyroelectric detectors (104,105) of PVF2 films polarized this way, was discovered two year later (106.)... 

Both antimony tribromide and antimony ttiiodide are prepared by reaction of the elements. Their chemistry is similar to that of SbCl in that they readily hydroly2e, form complex haUde ions, and form a wide variety of adducts with ethers, aldehydes, mercaptans, etc. They are soluble in carbon disulfide, acetone, and chloroform. There has been considerable interest in the compounds antimony bromide sulfide [14794-85-5] antimony iodide sulfide [13868-38-1] ISSb, and antimony iodide selenide [15513-79-8] with respect to their soHd-state properties, ferroelectricity, pyroelectricity, photoconduction, and dielectric polarization. 

Ferroelectrics. Ferroelectrics, materials that display a spontaneous polarization ia the abseace of an appHed electric field, also display pyroelectric and piezoelectric behavior. The distinguishing characteristic of ferroelectrics, however, is that the spontaneous polarization must be re-orientable with the appHcation of an electric field of a magnitude lower than the dielectric breakdown strength of the material. 

The main categories of electrical/optical ceramics are as follows phosphors for TV, radar and oscilloscope screens voltage-dependent and thermally sensitive resistors dielectrics, including ferroelectrics piezoelectric materials, again including ferroelectrics pyroelectric ceramics electro-optic ceramics and magnetic ceramics. 

Tantalum and niobium are added, in the form of carbides, to cemented carbide compositions used in the production of cutting tools. Pure oxides are widely used in the optical industiy as additives and deposits, and in organic synthesis processes as catalysts and promoters [12, 13]. Binary and more complex oxide compounds based on tantalum and niobium form a huge family of ferroelectric materials that have high Curie temperatures, high dielectric permittivity, and piezoelectric, pyroelectric and non-linear optical properties [14-17]. Compounds of this class are used in the production of energy transformers, quantum electronics, piezoelectrics, acoustics, and so on. Two of... 

Crystals with one of the ten polar point-group symmetries (Ci, C2, Cs, C2V, C4, C4V, C3, C3v, C(, Cgv) are called polar crystals. They display spontaneous polarization and form a family of ferroelectric materials. The main properties of ferroelectric materials include relatively high dielectric permittivity, ferroelectric-paraelectric phase transition that occurs at a certain temperature called the Curie temperature, piezoelectric effect, pyroelectric effect, nonlinear optic property - the ability to multiply frequencies, ferroelectric hysteresis loop, and electrostrictive, electro-optic and other properties [16, 388],... 

Ferroelectric properties - piezoelectric, pyroelectric and related properties... 

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