Terahertz frequency tags and methods for their preparation and use

What is claimed is: 1. A tag comprising: a terahertz reflective material; and a saturated hygroscopic material positioned on the terahertz reflective material, wherein: the terahertz reflective material is configured to reflect incident electromagnetic waves, the saturated hygroscopic material is configured to absorb the incident electromagnetic waves, and a reflectance pattern is formed from the absorption of the incident electromagnetic waves by the saturated hygroscopic material and the reflection of the incident electromagnetic waves by the terahertz reflective material. 2. The tag of claim 1 , wherein the saturated hygroscopic material comprises hydrous calcium chloride, hydrous calcium sulfate, hydrous potassium carbonate, hydrous sodium sulfate, hydrous cobalt (II) chloride, hydrous lithium chloride, hydrous zinc chloride, hydrous magnesium sulfate, hydrous copper sulfate, hydrous sodium tetraborate, hydrous sodium acetate, hydrous aluminum sulfate, hydrous aluminum potassium sulfate, hydrous magnesium chloride, hydrous sodium potassium tartrate, hydrous sodium thiosulfate, hydrous sodium silicate, hydrous sodium metasilicate, saturated silica gel, saturated microporous clays, saturated zeolites, saturated activated alumina, saturated activated carbon, or a combination thereof. 3. The tag of claim 1 , wherein the terahertz reflective material comprises a metallic film. 4. The tag of claim 3 , wherein the metallic film comprises aluminum, gold, silver, copper, tin, silicon, zinc, nickel, chromium, an alloy of any of the foregoing, or a combination thereof. 5. The tag of claim 1 , wherein the terahertz reflective material is configured to be retro-reflective. 6. The tag of claim 1 , wherein the terahertz reflective material comprises retro-reflective wells, and wherein the saturated hygroscopic material is positioned in one or more of the retro-reflective wells. 7. The tag of claim 1 , wherein the terahertz reflective material is configured to reflect the incident electromagnetic waves at frequencies of about 0.3 terahertz to about 3 terahertz. 8. The tag of claim 1 , further comprising a polymer substrate on which the terahertz reflective material is disposed. 9. The tag of claim 1 , wherein the saturated hygroscopic material is configured to absorb the incident electromagnetic waves at frequencies of about 0.3 terahertz to about 3 terahertz. 10. The tag of claim 1 , wherein the reflectance pattern is translatable into readable data. 11. A tag identification system comprising: a tag comprising a saturated hygroscopic material positioned on a terahertz reflective material; and a tag identification device configured to transmit an incident signal towards the tag, and to receive a reply signal from the tag in response to the transmission of the incident signal, wherein: the saturated hygroscopic material is configured to absorb the incident signal, the terahertz reflective material is configured to reflect the incident signal, and the reply signal comprises a reflectance pattern formed from the absorbance of the incident signal by the saturated hygroscopic material and the reflection of the incident signal by the terahertz reflective material. 12. The tag identification system of claim 11 , wherein the incident signal comprises electromagnetic waves at frequencies of about 0.3 terahertz to about 3 terahertz. 13. The tag identification system of claim 11 , wherein the reply signal comprises electromagnetic waves at frequencies of about 0.3 terahertz to about 3 terahertz reflecting off the terahertz reflective material. 14. The tag identification system of claim 11 , wherein the saturated hygroscopic material comprises hydrous calcium chloride, hydrous calcium sulfate, hydrous potassium carbonate, hydrous sodium sulfate, hydrous cobalt (II) chloride, hydrous lithium chloride, hydrous zinc chloride, hydrous magnesium sulfate, hydrous copper sulfate, hydrous sodium tetraborate, hydrous sodium acetate, hydrous aluminum sulfate, hydrous aluminum potassium sulfate, hydrous magnesium chloride, hydrous sodium potassium tartrate, hydrous sodium thiosulfate, hydrous sodium silicate, hydrous sodium metasilicate, saturated silica gel, saturated microporous clays, saturated zeolites, saturated activated alumina, saturated activated carbon, or a combination thereof. 15. The tag identification system of claim 11 , wherein the terahertz reflective material comprises a metallic film. 16. The tag identification system of claim 15 , wherein the metallic film comprises aluminum, gold, silver, copper, tin, silicon, zinc, nickel, chromium, an alloy of any of the foregoing, or a combination thereof. 17. The tag identification system of claim 11 , wherein the terahertz reflective material is configured to be retro-reflective. 18. The tag identification system of claim 11 , wherein the terahertz reflective material comprises retro-reflective wells, wherein the saturated hygroscopic material is deposited in one or more of the retro-reflective wells. 19. The tag identification system of claim 11 , further comprising a polymer overlay disposed on the saturated hygroscopic material to seal the saturated hygroscopic material on the terahertz reflective material. 20. The tag identification system of claim 19 , wherein the polymer overlay is transmissive to the incident signal and to the reply signal. 21. The tag identification system of claim 19 , wherein the polymer overlay comprises polyethylene terephthalate, polyethylene, high-density polyethylene, acrylic polymer, or a combination thereof. 22. The tag identification system of claim 11 , wherein the tag identification device is further configured to translate the reflectance pattern into readable data. 23. A method to use a tag identification system, the method comprising: transmitting an incident signal towards a tag, wherein the tag comprises a saturated hygroscopic material deposited on a terahertz reflective material; and receiving a reply signal from the tag in response to the transmission of the incident signal, wherein the saturated hygroscopic material is configured to absorb the incident signal, wherein the terahertz reflective material is configured to reflect the incident signal, and wherein the reply signal comprises a reflectance pattern formed from the absorbance of the incident signal by the saturated hygroscopic material and the reflection of the incident signal by the terahertz reflective material. 24. The method of claim 23 , further comprising translating the reply signal into readable data. 25. The method of claim 23 , wherein transmitting the incident signal comprises transmitting an incident signal comprising electromagnetic waves at frequencies of about 0.3 terahertz to about 3 terahertz, and wherein receiving the reply signal comprises receiving a reply signal comprising electromagnetic waves at frequencies of about 0.3 terahertz to about 3 terahertz.