J
John B. Pendry
Researcher at Imperial College London
Publications - 546
Citations - 94437
John B. Pendry is an academic researcher from Imperial College London. The author has contributed to research in topics: Metamaterial & Plasmon. The author has an hindex of 100, co-authored 536 publications receiving 88802 citations. Previous affiliations of John B. Pendry include University of California, San Diego & Duke University.
Papers
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Patent
Fabrication technique for replaceable optical corrective elements
Ken Caldeira,Peter L. Hagelstein,Roderick A. Hyde,Edward K. Y. Jung,Jordin T. Kare,Nathan P. Myhrvold,John B. Pendry,David Schurig,Clarence T. Tegreene,Charles Whitmer,Lowell L. Wood +10 more
TL;DR: In this article, a real-time adjustment of transformable optical elements is sometimes based on predetermined corrective optical parameters associated with a current user, such as a specified change in optical wavefront at an exit pupil.
Proceedings ArticleDOI
Quasiconformal Mapping in Transformation Optics
TL;DR: In this paper, the authors apply quasiconformal mapping in transformation optics and show that the anisotropy within the cloak remains a constant that can be made very small.
Journal ArticleDOI
Impact scattering calculation for angle-resolved EELS
Book ChapterDOI
Tensor LEED; New Prospects for Surface Structure Determination by LEED
P. J. Rous,John B. Pendry +1 more
TL;DR: Tensor LEED (TLEED) as mentioned in this paper is a perturbative scheme that allows the rapid evaluation of I/V spectra from a complex trial structure which is considered to be a distortion of a (simpler) reference surface.
Posted Content
Photonics of Time-Varying Media.
Emanuele Galiffi,Romain Tirole,Shixiong Yin,Huanan Li,Stefano Vezzoli,Paloma A. Huidobro,Mário G. Silveirinha,Riccardo Sapienza,Andrea Alù,John B. Pendry +9 more
TL;DR: A comprehensive review of the recent progress achieved with photonic metamaterials whose properties stem from their modulation in time can be found in this paper, where the basic concepts underpinning temporal switching and its relation with spatial scattering are discussed.