Abstract: Disclosed herein is a method of purifying and doping a population of semiconductor nanocrystals. The method includes mixing the population of semiconductor nanocrystals having a first material system and a first ligand with a set of particles in the presence of a first solvent, the set of particles having a second material system which is different from the first material system and a second ligand which is different from the first ligand, to form a mixture. The method also includes facilitating a ligand exchange and an ionic exchange in the mixture, altering the first material system of the population of semiconductor nanocrystals to a third material system, different from the first material system and the second material system. The method includes sonicating the mixture and isolating the population of semiconductor nanocrystals having the third material system and the second ligand from the mixture.

Abstract: Disclosed herein is a thermoelectric module and a method of producing a thermoelectric module via printing techniques. The method can include providing a first ink, the first ink including a first population of n-material semiconductor nanomaterials suspended in a solvent, and providing a second ink, the second ink including a second population of p-material semiconductor nanomaterials suspended in a solvent. Further, the method can include printing the first ink and the second ink on a substrate and applying a conducting layer electronically contacting both the first ink and the second ink printed on the substrate.

Abstract: Disclosed herein is a method of crystallizing a semiconductor nanocrystal population including suspending the semiconductor nanocrystal population in a high boiling point solvent to form a solution and heating the solution to a temperature of approximately 100° C. to approximately 400° C. Further disclosed is a method of crystallizing a semiconductor nanocrystal population including drying the semiconductor nanocrystal population into a powder, placing the powder into a ball mill, and ball milling the powder for a duration of time.

Abstract: Disclosed herein is a method of purifying and doping a population of semiconductor nanocrystals. The method includes mixing the population of semiconductor nanocrystals having a first material system and a first ligand with a set of particles in the presence of a first solvent, the set of particles having a second material system which is different from the first material system and a second ligand which is different from the first ligand, to form a mixture. The method also includes facilitating a ligand exchange and an ionic exchange in the mixture, altering the first material system of the population of semiconductor nanocrystals to a third material system, different from the first material system and the second material system. The method includes sonicating the mixture and isolating the population of semiconductor nanocrystals having the third material system and the second ligand from the mixture.

Abstract: Disclosed herein is a method of synthesizing a nanocrystal. The method can include reacting a bismuth material, an antimony material, and a ligand together with a heat source. The method may also include injecting a sulfur precursor at a predetermined temperature and maintaining the predetermined temperature for a predetermined amount of time to form a plurality of precursor nanocrystals. The precursor nanocrystals may include Bi0.5Sb1.5S3 nanocrystals.

Abstract: Disclosed herein is a method of synthesizing a nanocrystal. The method can include reacting a bismuth material, an antimony material, and a ligand together with a heat source. The method may also include injecting a sulfur precursor at a predetermined temperature and maintaining the predetermined temperature for a predetermined amount of time to form a plurality of precursor nanocrystals. The precursor nanocrystals may include Bi0.5Sb1.5S3 nanocrystals.