Richard W. Ziolkowski. 2022. Antenna and Array Technologies for Future Wireless Ecosystems. Antenna and Array Technologies for Future Wireless Ecosystems
335
391
.
Richard W. Ziolkowski. (2022) Mixtures of Multipoles—Should They Be in Your EM Toolbox?. IEEE Open Journal of Antennas and Propagation 3, pages 154-188.
Crossref
Silvio Hrabar. (2018) First ten years of active metamaterial structures with “negative” elements. EPJ Applied Metamaterials 5, pages 9.
Crossref
Richard W. Ziolkowski. (2014) Metamaterials: The early years in the USA. EPJ Applied Metamaterials 1, pages 5.
Crossref
Silvio Hrabar, Zvonimir Sipus & Iva Malcic. 2014. Transformation Electromagnetics and Metamaterials. Transformation Electromagnetics and Metamaterials
349
394
.
R.W. Ziolkowski. (2008) FDTD absorbing boundary conditions: From global lookback schemes to metamaterial PMLs. FDTD absorbing boundary conditions: From global lookback schemes to metamaterial PMLs.
Jan Machac, Pavel Protiva & Jan Zehentner. (2007) Isotropic Epsilon-Negative Particles. Isotropic Epsilon-Negative Particles.
Lukas Jelinek, Jan Machac & Jan Zehentner. (2007) Metamaterials - A Challenge for Contemporary Advanced Technology. Metamaterials - A Challenge for Contemporary Advanced Technology.
Shicai Jiang, Li Ying Xing & Bin Tai Li. (2005) Study on a Novel Radar Absorbing Structure Composite. Materials Science Forum 475-479, pages 1023-1028.
Crossref
S.A. Tretyakov, S. Maslovski & P.A. Belov. (2003) An analytical model of metamaterials based on loaded wire dipoles. IEEE Transactions on Antennas and Propagation 51:10, pages 2652-2658.
Crossref
Richard W. Ziolkowski & Ching-Ying Cheng. (2003) Existence and design of trans-vacuum-speed metamaterials. Physical Review E 68:2.
Crossref
R.W. Ziolkowski. (2003) Design, fabrication, and testing of double negative metamaterials. IEEE Transactions on Antennas and Propagation 51:7, pages 1516-1529.
Crossref
F. L. Teixeira. (2003) On aspects of the physical realizability of perfectly matched absorbers for electromagnetic waves. Radio Science 38:2, pages n/a-n/a.
Crossref
N. Engheta. (2002) Electromagnetics of complex media and metamaterials. Electromagnetics of complex media and metamaterials.
S.A. Tretyakov, I.S. Nefedov, P.A. Belov & A.J. Viitanen. (2002) Recent developments in exotic materials: negative permittivity and permeability, nonreciprocal composites. Recent developments in exotic materials: negative permittivity and permeability, nonreciprocal composites.
N. Engheta. (2002) An idea for thin subwavelength cavity resonators using metamaterials with negative permittivity and permeability. IEEE Antennas and Wireless Propagation Letters 1, pages 10-13.
Crossref
N. Engheta. (2002) Thin absorbing screens using metamaterial surfaces. Thin absorbing screens using metamaterial surfaces.
S. A. Tretyakov, I. S. Nefedov, C. R. Simovski & S. I. Maslovski. 2002. Advances in Electromagnetics of Complex Media and Metamaterials. Advances in Electromagnetics of Complex Media and Metamaterials
99
122
.
S. A. Tretyakov. (2001) Meta‐materials with wideband negative permittivity and permeability. Microwave and Optical Technology Letters 31:3, pages 163-165.
Crossref
Richard W. Ziolkowski. (2001) Superluminal transmission of information through an electromagnetic metamaterial. Physical Review E 63:4.
Crossref
D.C. Wittwer & R.W. Ziolkowski. (2001) The effect of dielectric loss in FDTD simulations of microstrip structures. IEEE Transactions on Microwave Theory and Techniques 49:2, pages 250-262.
Crossref
D.C. Wittwer & R.W. Ziolkowski. (2000) Maxwellian material-based absorbing boundary conditions for lossy media in 3-D. IEEE Transactions on Antennas and Propagation 48:2, pages 200-213.
Crossref
D.C. Wittwer & R.W. Ziolkowski. (2000) Two time-derivative Lorentz material (2TDLM) formulation of a Maxwellian absorbing layer matched to a lossy medium. IEEE Transactions on Antennas and Propagation 48:2, pages 192-199.
Crossref
C.A. Moses & N. Engheta. (1999) An idea for electromagnetic "feedforward-feedbackward" media. IEEE Transactions on Antennas and Propagation 47:5, pages 918-928.
Crossref
Richard W. Ziolkowski. (1999) Maxwellian material based absorbing boundary conditions. Computer Methods in Applied Mechanics and Engineering 169:3-4, pages 237-262.
Crossref
F. Auzanneau & R.W. Ziolkowski. (1999) Artificial composite materials consisting of nonlinearly loaded electrically small antennas: operational-amplifier-based circuits with applications to smart skins. IEEE Transactions on Antennas and Propagation 47:8, pages 1330-1339.
Crossref
F. Auzanneau & R.W. Ziolkowski. (1998) Microwave signal rectification using artificial composite materials composed of diode-loaded electrically small dipole antennas. IEEE Transactions on Microwave Theory and Techniques 46:11, pages 1628-1637.
Crossref