Gesetzt Synthese von CdSe / CdS-Nanokristalle Rod und Tetrapod

Please consult all relevant material safety data sheets (MSDS) before use. Several of the chemicals used in these syntheses are acutely toxic and carcinogenic. Nanomaterials may have additional hazards compared to their bulk counterpart. Please use all appropriate safety practices when performing a nanocrystal reaction including the use of engineering controls (fume hood, glovebox) and personal protective equipment (safety glasses, gloves, lab coat, full-length pants, closed-toe shoes). Portions of the following procedures involve standard air-free handling techniques15. 1. Preparation of Molecular Precursors Preparation of cadmium (II) myristate Cadmium myristate can be synthesized in either an ex situ or in situ method, achieving similar results. Ex situ preparation of cadmium myristate16 Dissolve 0.240 g sodium hydroxide and 1.370 g myristic acid in 240 ml methanol. Separately, dissolve 0.617 g cadmium nitrate tetrahydrate in 40 ml methanol. Add the cadmium nitrate solution drop-wise (~1 drop/sec) to the stirring (800 rpm) sodium myristate solution using an addition funnel. Filter the solution. Wash the resulting white precipitate with methanol three times. Dry the precipitate under vacuum overnight. In situ preparation of cadmium myristate6 Combine 39 mg cadmium oxide (CdO) with 0.137 g myristic acid in 5 ml 1-octadecene (ODE) in a 50 ml 3-neck round bottom flask with a stir bar. Heat the solution to 250 °C under inert gas while stirring (800 rpm) until the solution becomes a pale yellow color. Carefully swirl the solution as necessary to remove excess CdO from the sidewalls of the flask. Leaving this solution at elevated temperature beyond this point will cause it to become an undesired black color. Cool the solution to room temperature for use in subsequent reactions. Preparation of TOP:Se precursor Combine 58 mg selenium powder with 0.360 g tri-n-octylphosphine (TOP) under an inert atmosphere. Sonicate until the selenium powder is fully dissolved, yielding an optically clear solution. Alternatively, the solution can also be heated to 100 °C in order to fully dissolve the selenium. Use proper glassware or a glove box to prevent exposure of the solution to air during sonication or heating. Preparation of TOP:S precursor Combine 0.160 g elemental sulfur with 1.853 g TOP. Heat to 50 °C under an inert atmosphere until the solution is optically clear. Cool to room temperature for future use. 2. Synthesis of CdSe Seeds Synthesis of wurtzite CdSe (w-CdSe) nanocrystals5 Combine 3.0 g trioctylphosphine oxide (TOPO), 280 mg n-octadecylphosphonic acid (ODPA), and 60 mg CdO with a stir bar in a 25 ml 3-neck round bottom flask equipped with a thermocouple (inserted in a custom glass adapter or punctured through a rubber septum), a reflux condenser, and a rubber septum. Inspect all glassware for defects prior to use due to the high temperature of reaction and potential need for rapid cooling. Assemble all glass-to-glass joints with high temperature vacuum grease. Degas the mixture at 150 °C under vacuum for 1 hr while stirring (800 rpm). Heat the solution to 300 °C under inert gas to form an optically clear solution. Carefully swirl the solution to remove excess CdO from the sidewalls of the flask. Allow the solution to become optically clear again. Add 1.5 g TOP drop-wise to the solution and raise the temperature to 370 °C. Rapidly inject TOP:Se solution using a syringe with a large diameter (14 G) needle. The rapid injection will create a sharp nucleation event, promoting a narrow size distribution. Let the reaction proceed for the desired duration, as the size of the w-CdSe nanocrystal can be tuned by adjusting the reaction time. Immediately cooling after the injection will yield nanocrystals of ~2-2.5 nm in diameter whereas reacting the solution for 3 and 5 min will yield ~3 nm and ~4 nm diameter nanocrystals, respectively. Remove the heating mantle and rapidly cool the flask using a stream of compressed air. Care should be taken when rapidly cooling a flask from elevated temperatures as the thermal shock may break the glassware. For this reason, the use of a water bath for rapid cooling is strongly discouraged. Add 10 ml of anhydrous methanol to the solution when the temperature is below 60 °C to flocculate the nanocrystals. Transfer the solution to a vial under inert gas and centrifuge. Decant the solution. Discard the supernatant and redisperse the precipitate in anhydrous toluene. Add anhydrous methanol until the solution becomes turbid and centrifuge. Repeat a similar cleaning procedure (step 2.1.9) using a different solvent/nonsolvent pair: hexane/isopropanol. This helps prevent situations in which the nanocrystals and precursors precipitate simultaneously. Disperse the cleaned precipitate in a small volume (a few milliliters) of anhydrous toluene. The use of a small volume of solvent here will avoid the need to concentrate the particles as an additional step prior to their use in the seeded growth of CdS. Confirm the wurtzite crystal structure of the CdSe nanocrystals by X-ray diffraction. This step is strongly encouraged due to the polymorphism of CdSe and the strong dependence on the structure of the CdSe seed for the resulting heterostructures. Dilute a small aliquot of the w-CdSe stock solution by a known dilution factor and acquire a UV-Vis absorption spectrum. Determine the w-CdSe nanocrystal diameter and extinction coefficient based upon the first exciton absorbance according to the following formulas17: D = (1.6122×10-9)λ4 - (2.6575×10-6)λ3 + (1.6242×10-3)λ2 – (0.4277)λ + 41.57 ε = 5857(D)2.65 where D is the diameter (nm) of the w-CdSe nanocrystal, λ is the wavelength (nm) of the first excitonic absorption peak, and ε is the extinction coefficient (L/mol•cm) of nanocrystals at the first exciton. Determine the concentration of the w-CdSe nanocrystal stock solution using the absorbance at the first excitonic absorption peak in accordance with Beer-Lambert’s Law and the appropriate dilution factor. To prepare w-CdSe for the growth of seeded rods, combine 0.5 g TOP with a volume of the w-CdSe nanocrystal stock solution corresponding to 10-8 mol of w-CdSe nanocrystals. Sonicate briefly if needed to redisperse the w-CdSe nanocrystals in TOP. The use of a small volume of toluene for the w-CdSe stock solution in a prior step (2.1.11) should lead to only a small amount of toluene, on the order of microliters, in the seed solution used for the injection. The injection of larger volumes of volatile organic solvents, such as toluene, at temperatures substantially above their boiling point poses a safety hazard and will adversely affect the nanocrystal product due to large drops in reaction temperatures. Synthesis of zinc-blende CdSe (zb-CdSe) nanocrystals16,18,19 Combine 0.17 g cadmium myristate and 37 ml ODE with a stir bar in a 50 ml 3-neck round bottom flask equipped with a thermocouple (inserted in a custom glass adapter or punctured through a rubber septum), a reflux condenser, and a rubber septum. Inspect all glassware for defects prior to use due to the high temperature of reaction. Assemble all glass-to-glass joints with high temperature vacuum grease. Degas the solution under vacuum at 90 °C for 1 hr while stirring (800 rpm). Subsequently, cool the solution to room temperature under inert gas. Briefly remove the rubber septum and add 33 mg selenium dioxide powder to the flask. Replace the septum. Degas the solution under vacuum at 50 °C for 15 min. Heat to 240 °C at a ramp rate of approximately 10 °C/min under inert gas. As the temperature rises, the solution will begin to change color, progressing from yellow to red. Add a previously degassed solution of 1 ml oleic acid and 1 ml oleylamine in 4 ml ODE drop-wise when the solution reaches 240 °C. React the solution for 30 min at 240 °C. The size of the zb-CdSe nanocrystals can be tuned by modifying the reaction time. Take aliquots for absorption and photoluminescence spectra to monitor particle growth if desired. Remove the heating mantle and cool to room temperature. Transfer the crude solution to an inert atmosphere glove box and split the reaction mixture into 20 ml fractions in centrifuge vials. Add 10 ml anhydrous acetone to each vial and centrifuge solutions to isolate the nanocrystals. Pour off the supernatant and redisperse the precipitate in anhydrous toluene. Add acetone until the solution becomes turbid and centrifuge. Repeat a similar cleaning procedure (step 2.2.9) using a different solvent/nonsolvent pair: chloroform/methanol. This helps prevent situations in which the nanocrystals and precursors precipitate simultaneously. Disperse the cleaned precipitate in a small volume (a few milliliters) of anhydrous chloroform. The use of a small volume of solvent here will avoid the need to concentrate the particles as an additional step prior to their use in the seeded growth of CdS. After cleaning the particles, confirm the zinc-blende crystal structure of the CdSe nanocrystals by X-ray diffraction. This step is strongly encouraged due to the polymorphism of CdSe and the strong dependence on the structure of the CdSe seed for the resulting heterostructures. Dilute a small aliquot of the zb-CdSe stock solution by a known dilution factor and acquire a UV-Vis absorption spectrum. Determine the zb-CdSe nanocrystal diameter and extinction coefficient based upon the first exciton absorbance according to the following formulas20: ε = 19300 (D)3 where D is the diameter (nm) of the zb-CdSe nanocrystal, Eg the band gap energy (eV) corresponding to the first excitonic absorption peak, and ε is the extinction coefficient (L/mol•cm) of nanocrystals at 340 nm. Determine the concentration of the zb-CdSe nanocrystal stock solution using the absorbance at 340 nm in accordance with Beer-Lambert’s Law and the appropriate dilution factor. Combine 0.5 g TOP with a volume of the zb-CdSe nanocrystal stock solution corresponding to 10-8 mol of zb-CdSe nanocrystals to prepare zb-CdSe injection for the growth of seeded tetrapods. Sonicate briefly if needed to redisperse the zb-CdSe nanocrystals in TOP. The use of a small volume of chloroform for the zb-CdSe stock solution in a prior step (2.2.11) should lead to only a small amount of chloroform, on the order of microliters, in the seed solution used for the injection. The injection of larger volumes of volatile organic solvents, such as chloroform, at temperatures substantially above their boiling point poses a safety hazard and will adversely affect the nanocrystal product due to large drops in reaction temperatures. 3. Synthesis of CdSe/CdS Heterostructures Synthesis of CdSe/CdS seeded nanorods6 Combine 207 mg CdO, 1.08 g ODPA, 3.35 g TOPO, and 15 mg propylphosphonic acid (PPA) with a stir bar in a 25 ml 3-neck round bottom flask equipped with a thermocouple (inserted in a custom glass adapter or punctured through a rubber septum), a reflux condenser, and a rubber septum. Inspect all glassware for defects prior to use due to the high temperature of reaction. Assemble all glass-to-glass joints with high temperature vacuum grease. Degas the solution under vacuum at 120 °C for 30 min while stirring (800 rpm). Heat the solution to 320 °C under inert gas to form an optically clear solution. Carefully swirl the solution to remove excess CdO from the sidewalls of the flask. Allow the solution to become optically clear again. Cool the solution to 120 °C. Degas the solution under vacuum for 1 hr at 120 °C. After degassing and complexing the reaction solution, heat the mixture to 340 °C under inert gas. Inject 1.5 g TOP drop-wise and let the temperature recover to 340°C. Rapidly inject 0.65 g TOP:S using a syringe with a large diameter (14 G) needle. 20 seconds after the TOP:S injection, rapidly inject w-CdSe solution (10-8 mol w-CdSe nanocrystals in 0.5 g TOP) using a syringe with a large diameter (14 G) needle. Adjust the reaction temperature to 320 °C. After 10 min at 320 °C, remove the heating mantle and cool the solution. Add ~10 ml anhydrous toluene to the flask when the temperature is around 100 °C to prevent solidification of the TOPO. Transfer the crude solution to a centrifuge vial. The purification of the crude solution of seeded rods can be performed in an inert atmosphere glovebox or ambient conditions, if desired, as the overgrowth of CdS enhances the environmental stability of the nanocrystals. Add an equal volume of anhydrous ethanol to flocculate the nanocrystals and centrifuge. Pour off the supernatant and redispersed the precipitate in hexane/octylamine (8:1 by volume). Add anhydrous ethanol until the solution appears turbid and centrifuge. Redisperse precipitate in anhydrous toluene. Occasionally, solutions of seeded rods will form a gel during the cleaning process. If this occurs, add a few drops of octylamine to dissolve the gel and continue the cleaning procedure. Note: The length of the nanorods can be tuned by changing the concentration of injected CdSe seeds; higher seed concentrations lead to shorter rods. Adjusting the TOP:S concentration will vary the rod diameter and length; higher TOP:S concentration produces longer, thinner rods. See reference6 for further details. Synthesis of CdSe/CdS seeded tetrapods6,17 Combine 207 mg CdO, 1.08 g ODPA, 3.35 g TOPO, and 50 mg PPA with a stir bar in a 25 ml 3-neck round bottom flask equipped with a thermocouple (inserted in a custom glass adapter or punctured through a rubber septum), a reflux condenser, and a rubber septum. Inspect all glassware for defects prior to use due to the high temperature of reaction. Assemble all glass-to-glass joints with high temperature vacuum grease. Degas the solution under vacuum at 120 °C for 1 hr while stirring (800 rpm). Heat the solution to 280 °C under inert gas to form an optically clear solution. Carefully swirl the solution to remove excess CdO from the sidewalls of the flask. Allow the solution to become optically clear again. Cool the solution to 120 °C. Degas the solution under vacuum for 1 hr at 120 °C. After degassing and complexing the reaction solution, heat the mixture to 300 °C under inert gas. Inject 1.5 g TOP drop-wise and let the temperature recover to its initial value. Rapidly inject 0.65 g TOP:S using a syringe with a large diameter (14 G) needle. 40 seconds after the TOP:S injection, rapidly inject zb-CdSe solution (10-8 mol zb-CdSe nanocrystals in 0.5 g TOP) using a syringe with a large diameter (14 G) needle. Raise the reaction temperature to 315 °C at a rate of 1 °C/min. After 20 min at 315 °C, remove the heating mantle and cool. Add anhydrous toluene to the flask when the temperature is around 100 °C to prevent solidification of the TOPO. Transfer the crude solution to a centrifuge vial. The purification of the crude solution of seeded tetrapods can be performed in an inert atmosphere glovebox or ambient conditions, if desired, as the overgrowth of CdS enhances the environmental stability of the nanocrystals. Add anhydrous acetone until the solution becomes turbid and centrifuge. Pour off the supernatant and redisperse the precipitate in hexane/octylamine (8:1 by volume). Add anhydrous acetone until the solution becomes turbid and centrifuge. Repeat the purification of the tetrapods twice more using toluene and acetone as the solvent and nonsolvent, respectively. Store the tetrapods in toluene. Separate tetrapods from undesired nanorod byproducts by centrifuging toluene solutions at 12,000 x g for 30 min to develop a concentration gradient due to the mass difference between rods and tetrapods. Carefully remove and discard the upper layers, which contain mainly rods. Combine and dissolve the lower layers, which contain mostly tetrapods, in toluene. Note: The length of the tetrapod arms can be tuned by changing the injection seed concentration; higher seed concentrations produce shorter arms. The growth time can be used to adjust the arm diameter; longer growth times increase the diameter of the arms. See reference6 for details. The yield of tetrapods can be varied by using different amounts of PPA in the initial reaction mixture. See reference19 for further details.