Mechanisms of local stress sensing in multifunctional polymer films using fluorescent tetrapod nanocrystals

What is claimed is: 1. A nanocomposite comprising: a polymer film comprising a polymer; and a plurality of fluorescent tetrapod nanocrystals disposed in the polymer film, the fluorescent tetrapod nanocrystals comprising tetrapod quantum dots (tQDs), the plurality of fluorescent tetrapod nanocrystals forming aggregates, and a volume ratio of the tQDs to the polymer defined by a tQD aggregate fill fraction or a packing density in the aggregates being approximately 40%-50%±5% for a compression-sensing nanocomposite and 20%-30%±2% for a tension-sensing nanocomposite. 2. The nanocomposite of claim 1 , wherein a volume ratio of the tQDs to the polymer defined by a tQD aggregate fill fraction or a packing density in the aggregates is approximately 50%±5% for a compression-sensing nanocomposite and 25%±2% for a tension-sensing nanocomposite. 3. The nanocomposite of claim 1 , wherein the tQDs are approximately a factor of two farther apart in a tension-sensing aggregate than in a compression-sensing aggregate, and wherein the tension-sensing aggregate has approximately a factor of two times more polymer inside of the tension-sensing aggregate in terms of small-scale inter-tQD regions. 4. The nanocomposite of claim 1 , wherein a tensile stress applied to densely-packed tQDs in the polymer results in a blue-shift of a tQD photoluminescence emission maximum due to a uniform compression of tQD cores, and wherein a tensile stress applied to loosely-packed tQDs in the polymer results in a red-shift of a tQD photoluminescence emission maximum due to a net core tension. 5. The nanocomposite of claim 1 , wherein the aggregates for a compression-sensing nanocomposite exhibit a higher energy blue-shift of a tQD photoluminescence emission maximum under tensile stress due to a compression of tQD cores. 6. The nanocomposite of claim 1 , wherein the aggregates for a tension-sensing nanocomposite exhibit a lower energy red-shift of a tQD photoluminescence emission maximum under tensile stress due to a tension of tQD cores. 7. The nanocomposite of claim 1 , wherein a tQD comprises a cadmium selenide-cadmium sulfide (CdSe—CdS) core/shell tQD. 8. The nanocomposite of claim 7 , wherein a tQD has an arm length of approximately 26 nanometers ±3 nanometers. 9. The nanocomposite of claim 7 , wherein a zinc-blende CdSe core has a diameter of approximately 2.8 nanometers. 10. The nanocomposite of claim 7 , wherein a wurtzite CdS arm is approximately 4.2 nanometers in length and 1.9 nanometers in diameter. 11. The nanocomposite of claim 7 , wherein the CdSe—CdS core/shell tQD contains approximately 4245 atoms, and wherein the CdSe—CdS core/shell tQD has a chemical formula Cd 272 Se 297 /Cd 1132 S 1116 . 12. The nanocomposite of claim 1 , wherein the polymer comprises a block copolymer. 13. The nanocomposite of claim 12 , wherein the block copolymer comprises poly(styrene-ethylene-butylene-styrene) (SEBS). 14. The nanocomposite of claim 13 , wherein the SEBS comprises approximately 60% polystyrene (PS) and 40% poly(ethylene-butylene) (P-EB). 15. A nanocomposite comprising: a polymer film comprising a polymer; and a plurality of fluorescent tetrapod nanocrystals disposed in the polymer film, the fluorescent tetrapod nanocrystals comprising tetrapod quantum dots (tQDs), the plurality of fluorescent tetrapod nanocrystals forming aggregates, a tensile stress applied to densely-packed tQDs in the polymer resulting in a blue-shift of a tQD photoluminescence emission maximum due to a uniform compression of tQD cores, a tensile stress applied to loosely-packed tQDs in the polymer resulting in a red-shift of a tQD photoluminescence emission maximum due to a net core tension, the tQDs being approximately a factor of two farther apart in a tension-sensing aggregate than in a compression-sensing aggregate, and the tension-sensing aggregate having approximately a factor of two times more polymer inside of the tension-sensing aggregate in terms of small-scale inter-tQD regions. 16. The nanocomposite of claim 15 , wherein a volume ratio of the tQDs to the polymer defined by a tQD aggregate fill fraction or a packing density in the aggregates is approximately 40%-50%±5% for a compression-sensing nanocomposite and 20%-30%±2% for a tension-sensing nanocomposite. 17. A nanocomposite comprising: a polymer film comprising a polymer; and a plurality of fluorescent tetrapod nanocrystals disposed in the polymer film, the fluorescent tetrapod nanocrystals comprising tetrapod quantum dots (tQDs), a tQD comprising a cadmium selenide-cadmium sulfide (CdSe—CdS) core/shell tQD, a wurtzite CdS arm being approximately 4.2 nanometers in length and 1.9 nanometers in diameter, and the plurality of fluorescent tetrapod nanocrystals forming aggregates. 18. The nanocomposite of claim 17 , wherein the tQDs are approximately a factor of two farther apart in a tension-sensing aggregate than in a compression-sensing aggregate, and wherein the tension-sensing aggregate has approximately a factor of two times more polymer inside of the tension-sensing aggregate in terms of small-scale inter-tQD regions. 19. The nanocomposite of claim 17 , wherein a tensile stress applied to densely-packed tQDs in the polymer results in a blue-shift of a tQD photoluminescence emission maximum due to a uniform compression of tQD cores, and wherein a tensile stress applied to loosely-packed tQDs in the polymer results in a red-shift of a tQD photoluminescence emission maximum due to a net core tension. 20. The nanocomposite of claim 17 , wherein the CdSe—CdS core/shell tQD contains approximately 4245 atoms, and wherein the CdSe—CdS core/shell tQD has a chemical formula Cd 272 Se 297 /Cd 1132 S 1116 .