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Ferroelectrics Volume 49, 1983 - Issue 1
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Session 4A—Pyroelectrics

High performance, conducting pyroelectric ceramics

R. W. Whatmore Allen Clark Research Centre, Plessey Research (Caswell) Ltd., Towcester, Northants, England
Pages 201-210 | Published online: 07 Feb 2011

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B. Ploss. (2006) Improving the Pyroelectric Coefficient of Ceramic/Polymer Composite by Doping the Polymer Matrix. Ferroelectrics 338:1, pages 145-151.
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B. Ploss, Y.W. Wong & F.G. Shin. (2005) Pyroelectric Ceramic/Polymer Composite with Electrically Conducting Matrix Material. Ferroelectrics 325:1, pages 165-169.
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R. Watton & M.A. Todd. (1991) Induced pyroelectricity in sputtered lead scandium tantalate films and their merit for IR detector arrays. Ferroelectrics 118:1, pages 279-295.
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R.W. Whatmore. (1991) Pyroelectric ceramics and devices for thermal infra-red detection and imaging. Ferroelectrics 118:1, pages 241-259.
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R.W. Whatmore, A. Patel, N.M. Shorrocks & F.W. Ainger. (1990) Ferroelectric materials for thermal ir sensors state-of-the-art and perspectives. Ferroelectrics 104:1, pages 269-283.
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R. Watton. (1989) Ferroelectric materials and devices in infrared detection and imaging. Ferroelectrics 91:1, pages 87-108.
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R. W. Whatmore, P. C. Osbond & N. M. Shorrocks. (1987) Ferroelectric materials for thermal IR detectors. Ferroelectrics 76:1, pages 351-367.
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Articles from other publishers (26)

Roger W. Whatmore & Samuel J. Ward. (2023) Pyroelectric infrared detectors and materials—A critical perspective. Journal of Applied Physics 133:8.
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Satiye Korkmaz & İ. Afşin Kariper. (2021) Pyroelectric nanogenerators (PyNGs) in converting thermal energy into electrical energy: Fundamentals and current status. Nano Energy 84, pages 105888.
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Vincent Ming Hong Ng, Ling Bing Kong, Wenxiu Que, Chuanhu Wang, Sean Li & Tianshu Zhang. 2018. Comprehensive Energy Systems. Comprehensive Energy Systems 720 759 .
Hui Wei & Yongjun Chen. (2014) Synthesis and properties of Pb(Zn1/3Nb2/3)O3 modified Pb(Zr0.95Ti0.05)O3 pyroelectric ceramics. Ceramics International 40:6, pages 8637-8643.
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Ling Bing Kong, Tao Li, Huey Hoon Hng, Freddy Boey, Tianshu Zhang & Sean LiLing Bing Kong, Tao Li, Huey Hoon Hng, Freddy Boey, Tianshu Zhang & Sean Li. 2014. Waste Energy Harvesting. Waste Energy Harvesting 405 480 .
Roger Whatmore. 2014. Characterisation of Ferroelectric Bulk Materials and Thin Films. Characterisation of Ferroelectric Bulk Materials and Thin Films 65 86 .
Christopher P. Shaw, Roger W. Whatmore & Jeffrey R. Alcock. (2006) Porous, Functionally Gradient Pyroelectric Materials. Journal of the American Ceramic Society 90:1, pages 137-142.
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Roger W. Whatmore. Recent Advances in Pyroelectric Ceramics and Thin Films for Applications in Uncooled Infra-Red Sensor Arrays. Recent Advances in Pyroelectric Ceramics and Thin Films for Applications in Uncooled Infra-Red Sensor Arrays.
Roger W. Whatmore. (2004) Pyroelectric Arrays: Ceramics and Thin Films. Journal of Electroceramics 13:1-3, pages 139-147.
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Sun Hee Kang, Dae Su Lee, Sun Young Lee, Ill Won Kim, Jin Soo Kim, Eun Chul Park & Jae Shin Lee. (2004) Pyroelectric and piezoelectric properties of yttrium-doped 0.15[Pb(Ni1/3Nb2/3)O3]–0.85[Pb(Zr1/2Ti1/2)O3] ceramics. Ceramics International 30:7, pages 1453-1457.
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M. Es-Souni, S. Iakovlev & C.-H. Solterbeck. (2004) Processing and characterization of PZFNT and PZFNT/PET thin films for pyroelectric applications. Journal of the European Ceramic Society 24:6, pages 985-988.
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R.W. Whatmore, O. Molter & C.P. Shaw. (2003) Electrical properties of Sb and Cr-doped PbZrO3–PbTiO3–PbMg1/3Nb2/3O3 ceramics. Journal of the European Ceramic Society 23:5, pages 721-728.
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C.P. Shaw, S. Gupta, S.B. Stringfellow, A. Navarro, J.R. Alcock & R.W. Whatmore. (2002) Pyroelectric properties of Mn-doped lead zirconate–lead titanate–lead magnesium niobate ceramics. Journal of the European Ceramic Society 22:13, pages 2123-2132.
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S.B. Stringfellow, S. Gupta, C. Shaw, J.R. Alcock & R.W. Whatmore. (2002) Electrical conductivity control in uranium-doped PbZrO3–PbTiO3–Pb(Mg1/3Nb2/3)O3 pyroelectric ceramics. Journal of the European Ceramic Society 22:4, pages 573-578.
Crossref
Robert Schwartz. 2001. Kirk-Othmer Encyclopedia of Chemical Technology. Kirk-Othmer Encyclopedia of Chemical Technology.
Haitao Huang & Peter Hing. (1999) The relationship between the mechanical properties and microstructures of sintered PZT. Journal of Materials Processing Technology 89-90, pages 538-543.
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W. Osak, K. Tkacz-Śmiech & A. Osak. (1997) Electrical transport in Pb[(Ni1/3Sb2/3)xTiyZrz]O3 + 0.3% MnO. Materials Science and Engineering: B 45:1-3, pages 1-8.
Crossref
Jorg Arndt. 1995. Sensors Set. Sensors Set 247 278 .
R.B. Liu, S.W. Lin, C.F. Qu, C.H. Yao & Y.H. Jin. (1994) Pyroelectric ceramics with low resistivity. Pyroelectric ceramics with low resistivity.
A. Patel, P.C. Osbond, N.M. Shorrocks, R.C. Twiney, R. Whatmore & R. Watton. (1994) Ferroelectric ceramics and thin films for uncooled thermal imaging arrays. Ferroelectric ceramics and thin films for uncooled thermal imaging arrays.
A. S. Bhalla & S. T. Liu. 1993. Piezoelectric, Pyroelectric, and Related Constants. Piezoelectric, Pyroelectric, and Related Constants 425 435 .
R.W. Whatmore, N.W. Shorrocks, P.C. Osbond, S.B. Stringfellow, C.F. Carter & R. Watton. (1992) Modified lead scandium tantalate for uncooled LWIR detection and thermal imaging. Modified lead scandium tantalate for uncooled LWIR detection and thermal imaging.
T. Takenaka, H. Komiya & K. Sakata. (1991) PbZrO/sub 3/-based composite pyroelectric ceramics. PbZrO/sub 3/-based composite pyroelectric ceramics.
Jorg Arndt. 1989. Sensors. Sensors 247 278 .
R W Whatmore. (1986) Pyroelectric devices and materials. Reports on Progress in Physics 49:12, pages 1335-1386.
Crossref
Ahmed Amin. (1986) Computer-controlled system for measuring bulk resistivity of insulating solids as a function of temperature. Review of Scientific Instruments 57:7, pages 1442-1444.
Crossref

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