Frequency selective structures for EMI mitigation

What is claimed is: 1. A multilayered frequency selective structure for shielding or mitigating electromagnetic interference (EMI) without completely blocking an airflow therethrough, the multilayered frequency selective structure comprising multiple layers of frequency selective surfaces. 2. The multilayered frequency selective structure of claim 1 , wherein the multiple layers of frequency selective surfaces are configured to be collectively operable for energy blockage across a broad band frequency range. 3. The multilayered frequency selective structure of claim 1 , wherein the multilayered frequency selective structure is configured to be operable for energy blockage across a frequency range. 4. The multilayered frequency selective structure of claim 3 , wherein the multilayered frequency selective structure is configured to be operable for energy blockage across a frequency range from about 20 Gigahertz to about 35 Gigahertz. 5. The multilayered frequency selective structure of claim 1 , wherein the multilayered frequency selective structure is configured to be operable across a frequency range from about 20 Gigahertz to about 35 Gigahertz with a shielding effectiveness of at least about 20 decibels. 6. The multilayered frequency selective structure of claim 1 , wherein the multilayered frequency selective structure is configured to be operable with a shielding effectiveness of at least 60 decibels and/or a maximum shielding effectiveness at a frequency of about 30 Gigahertz. 7. The multilayered frequency selective structure of claim 1 , wherein each of the multiple layers of frequency selective surfaces includes at least one opening therethrough aligned with at least one opening through the other multiple layers of frequency selective surfaces such that an airflow may flow through the aligned openings of the multiple layers of frequency selective surfaces, whereby the multilayered frequency selective structure is configured to be operable for shielding or mitigating electromagnetic interference (EMI) without completely blocking an airflow therethrough. 8. The multilayered frequency selective structure of claim 1 , wherein: each of the multiple layers of frequency selective surfaces has an annular shape with an opening that is aligned with the opening of each of the other multiple layers of frequency selective surfaces; and the aligned openings of the multiple layers of frequency selective surfaces allow a ventilating airflow through the multilayered frequency selective structure. 9. The multilayered frequency selective structure of claim 1 , wherein the multiple layers of frequency selective surfaces include first, second, and third layers of frequency selective surfaces in a stacked arrangement with the second layer disposed between the first and third layers. 10. The multilayered frequency selective structure of claim 9 , wherein: each of the first, second, and third layers of frequency selective surfaces have an annular rectangular shape with an opening; and the openings of the first, second, and third layers of frequency selective surfaces allow an airflow through the multilayered frequency selective structure. 11. The multilayered frequency selective structure of claim 9 , wherein the second layer is adhesively attached to the first and third layers. 12. The multilayered frequency selective structure of claim 1 , wherein each of the multiple layers of frequency selective surfaces comprises: electrically-conductive members; or electromagnetic energy absorptive members; or electrically-conductive, electromagnetic energy absorptive members; or electrically-conductive members and electromagnetic energy absorptive members. 13. The multilayered frequency selective structure of claim 1 , wherein each of the multiple layers of frequency selective surfaces comprises electrically-conductive members and electromagnetic energy absorptive material applied to the electrically-conductive members. 14. A method comprising stacking multiple layers of frequency selective surfaces to thereby provide a multilayered frequency selective structure configured for shielding or mitigating electromagnetic interference (EMI) without completely blocking an airflow through the multilayered frequency selective structure. 15. The method of claim 14 , wherein stacking multiple layers of frequency selective surfaces includes aligning at least one opening through each of the multiple layers of frequency selective surfaces with at least one opening of each of the other multiple layers of frequency selective surfaces such than an airflow may flow through the aligned openings of the multiple layers of frequency selective surfaces. 16. The method of claim 14 , wherein each of the multiple layers of frequency selective surfaces comprises: electrically-conductive members; or electromagnetic energy absorptive members; or electrically-conductive, electromagnetic energy absorptive members; or electrically-conductive members and electromagnetic energy absorptive members. 17. The method of claim 14 , wherein each of the multiple layers of frequency selective surfaces comprises electrically-conductive members and electromagnetic energy absorptive material applied to the electrically-conductive members. 18. A method comprising positioning a multilayered frequency selective structure including multiple layers of frequency selective surfaces relative to one or more electronic components such that the multilayered frequency selective structure is operable for shielding or mitigating electromagnetic interference (EMI) without completely blocking a ventilating airflow for helping reduce heat buildup in the one or more electronic components. 19. The method of claim 18 , wherein each of the multiple layers of frequency selective surfaces includes at least one opening aligned with at least one opening of each of the other multiple layers of frequency selective surfaces such than an airflow may flow through the aligned openings of the multiple layers of frequency selective surfaces. 20. The method of claim 18 , wherein each of the multiple layers of frequency selective surfaces comprises electrically-conductive members and electromagnetic energy absorptive material applied to the electrically-conductive members.