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A THEORETICAL MODEL for MAGNETIC FIELD IMAGING with “SWISS ROLLS” STRUCTURES V. Yannopapas J. B. Pendry M. C. K. Wiltshire J. Hajnal.

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Presentation on theme: "A THEORETICAL MODEL for MAGNETIC FIELD IMAGING with “SWISS ROLLS” STRUCTURES V. Yannopapas J. B. Pendry M. C. K. Wiltshire J. Hajnal."— Presentation transcript:

1 A THEORETICAL MODEL for MAGNETIC FIELD IMAGING with “SWISS ROLLS” STRUCTURES V. Yannopapas J. B. Pendry M. C. K. Wiltshire J. Hajnal

2 “Swiss Roll” structure
Highly anisotropic (uniaxial) metamaterial: Finite slab of a “Swiss Roll” structure with finite (hexagonal) cross-section The period of the structure and the dimensions of the individual rolls are much smaller than the wavelength of the EM field: Effective-medium approximation

3 “Swiss Roll” structure
Important issues: Does the effective-medium approximation describe adequately the propagation properties of the system? How do the material-air boundaries affect the imaging of the magnetic field? How does the image of the magnetic field vary with frequency? Theoretical model: The periodic array of rolls is substituted by a uniaxial effective medium The air-material interfaces are treated as totally reflecting walls Near-field limit: the magnetic and electric-field components of the EM field are decoupled from each other

4 Propagation in a uniaxial medium
Maxwell’s equations in a uniaxial medium with Combining the above we obtain For a waveguide geometry:

5 EM modes in a uniaxial medium
Ordinary waves: Extraordinary waves: μz leads to the exotic magnetic effects Equivalent of the TE modes in a isotropic medium where in the near-field limit: H>>E

6 Uniaxial waveguiding The modes are normalized so that:

7 Transmission and reflection
In the extreme near-field limit, in free-space: By requiring the continuity of Ht and Bz at the interfaces:

8 Coupling of the waveguide modes
J S1 S2 C Using the identity: For a closed loop of total current I:

9 Experimental setup

10 Transmitted field Hz along a diameter of the hexagon
Incident field Hz along a diameter of the hexagon Frequency range: MHz Transmitted field

11 Transmitted field Input field of a magnetic dipole

12 Special frequencies Incident field Transmitted field

13 Frequency spectrum

14 Conclusions – Further work
Understand the nature of the resonances in the frequency spectrum Role of the finite size of the lens Comparison with experiment Corrections to the model

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