Open-ended hollow coaxial cable resonator sensor

What is claimed is: 1. An open-ended hollow coaxial cable resonator probe comprising: a coaxial structure comprising an inner conductor and an outer conductor, the coaxial structure having an open input end configured to receive an aerosol sample for analysis; an internal conducting member electrically connecting the inner conductor to the outer conductor to produce a short circuit therebetween; an external conducting surface substantially parallel to a plane defined by the input end of the coaxial structure and spaced apart from the input end of the coaxial structure by a dielectric layer, the dielectric layer containing the received aerosol sample; and interrogator circuitry coupled to the coaxial structure for transmitting an electromagnetic wave within the coaxial structure, the transmitted electromagnetic wave generating an electric field at the input end of the coaxial structure and the interrogator circuitry responsive to the generated electric field for determining a resonance frequency and an impedance of the coaxial structure when the aerosol sample is present in the dielectric layer, wherein the interrogator circuitry is configured to identify virus particles in the aerosol sample as a function of the determined resonance frequency and impedance of the coaxial structure. 2. The open-ended hollow coaxial cable resonator probe as set forth in claim 1 , further comprising a mouthpiece coupled to the open input end of the coaxial structure through which a subject expels breath into the coaxial structure, wherein the aerosol sample comprises the expelled breath. 3. The open-ended hollow coaxial cable resonator probe as set forth in claim 1 , wherein the external conducting surface comprises a porous metal plate. 4. The open-ended hollow coaxial cable resonator probe as set forth in claim 1 , further comprising an annular spacer positioned between the input end of the coaxial structure and the external conducting surface, the annular spacer defining a gap between the input end of the coaxial structure and the external conducting surface. 5. The open-ended hollow coaxial cable resonator probe as set forth in claim 4 , wherein the annular spacer has a thickness of less than about 300 mm. 6. The open-ended hollow coaxial cable resonator probe as set forth in claim 4 , wherein the annular spacer comprises a gasket. 7. The open-ended hollow coaxial cable resonator probe as set forth in claim 1 , wherein the dielectric layer comprises air in the gap between the input end of the coaxial structure and the external conducting surface. 8. The open-ended hollow coaxial cable resonator probe as set forth in claim 1 , wherein the dielectric layer comprises polytetrafluoroethylene. 9. The open-ended hollow coaxial cable resonator probe as set forth in claim 1 , wherein the coaxial structure is configured for installation in a return air duct. 10. The open-ended hollow coaxial cable resonator probe as set forth in claim 1 , wherein the internal conducting member is located within 100 mm of the input end of the coaxial structure. 11. A portable aerosol analyzer comprising; an open-ended hollow coaxial cable resonator; a mouthpiece coupled to the resonator through which a subject expels a breath sample into an open end of resonator; interrogator circuitry coupled to the resonator for transmitting an electromagnetic wave within the resonator, the transmitted electromagnetic wave generating an electric field at an input end of the resonator and the interrogator circuitry responsive to the generated electric field for determining a resonance frequency and an impedance of the resonator when the breath sample is present in a dielectric layer at the open end of the resonator, wherein the interrogator circuitry is configured to identify virus particles in the breath sample as a function of the determined resonance frequency and impedance of the resonator. 12. The portable aerosol analyzer as set forth in claim 11 , further comprising a fan for producing a negative air pressure in the resonator to draw the breath from the subject into the resonator. 13. The portable aerosol analyzer as set forth in claim 11 , further comprising a filter configured for trapping the virus particles in the breath sample, the filter positioned between the mouthpiece and the open end of the resonator. 14. The portable aerosol analyzer as set forth claim 13 , wherein the filter comprises polytetrafluoroethylene. 15. The portable aerosol analyzer as set forth in claim 11 , wherein the resonator comprises: a coaxial structure having an inner conductor and an outer conductor; an internal conducting member electrically connecting the inner conductor to the outer conductor to produce a short circuit therebetween; and an external conducting surface substantially parallel to a plane defined by the open end of the coaxial structure and spaced apart from the open end of the coaxial structure by the filter. 16. The portable aerosol analyzer as set forth in claim 15 , wherein the external conducting surface comprises a porous metal plate. 17. The portable aerosol analyzer as set forth in claim 15 , wherein the internal conducting member is located within 100 mm of the input end of the coaxial structure. 18. A method of detecting virus particles in an aerosol sample comprising: receiving an aerosol sample at an open input end of an open-ended hollow coaxial cable resonator, the resonator comprising: an inner conductor and an outer conductor, an internal conducting member electrically connecting the inner conductor to the outer conductor to produce a short circuit therebetween, and an external conducting surface substantially parallel to a plane defined by the input end of the resonator and spaced apart from the input end of the coaxial structure by a dielectric layer; containing the received aerosol sample in the dielectric layer; transmitting an electromagnetic wave within the resonator to generate an electric field at the input end of the resonator; responsive to the generated electric field, determining a resonance frequency and an impedance of the resonator when the aerosol sample is present in the dielectric layer; and identifying virus particles in the aerosol sample as a function of the determined resonance frequency and impedance of the resonator. 19. The method as set forth in claim 18 , further comprising introducing selected antibodies against the virus particles in the aerosol sample, wherein the selected antibodies are tethered to a high-permittivity nanoparticle beacon and bind to the virus particles to enhance permittivity thereof in the dielectric layer. 20. The method as set forth in claim 19 , further comprising confirming the virus particles in the aerosol sample based on the enhanced permittivity of a gold or barium titanate nanoparticle beacon tethered to the anitbody.