Phototransport in networks of tetrapod-shaped colloidal semiconductor nanocrystals
(2010) In Nanoscale 2(10). p.2171-2179- Abstract
Tetrapod-shaped CdSe(core)/CdTe(arms) colloidal nanocrystals, capped with alkylphosphonic acids or pyridine, were reacted with various small molecules (acetic acid, hydrazine and chlorosilane) which induced their tip-to-tip assembly into soluble networks. These networks were subsequently processed into films by drop casting and their photoconductive properties were studied. We observed that films prepared from tetrapods coated with phosphonic acids were not photoconductive, but tip-to-tip networks of the same tetrapods exhibited appreciable photocurrents. On the other hand, films prepared from tetrapods coated with pyridine instead of phosphonic acids were already highly photoconductive even if the nanocrystals were not joined... (More)
Tetrapod-shaped CdSe(core)/CdTe(arms) colloidal nanocrystals, capped with alkylphosphonic acids or pyridine, were reacted with various small molecules (acetic acid, hydrazine and chlorosilane) which induced their tip-to-tip assembly into soluble networks. These networks were subsequently processed into films by drop casting and their photoconductive properties were studied. We observed that films prepared from tetrapods coated with phosphonic acids were not photoconductive, but tip-to-tip networks of the same tetrapods exhibited appreciable photocurrents. On the other hand, films prepared from tetrapods coated with pyridine instead of phosphonic acids were already highly photoconductive even if the nanocrystals were not joined tip-to-tip. Based on the current-voltage behavior under light we infer that the tunneling between tetrapods is the dominant charge transport mechanism. In all the samples, chemically-induced assembly into networks tended to reduce the average tunneling barrier. Additionally, pyridine-coated tetrapods and the tip-to-tip networks made out of them were tested as active materials in hybrid photovoltaic devices. Overall, we introduce an approach to chemically-induced tip-to-tip assembly of tetrapods into solution processable networks and demonstrate the enhancement of electronic coupling of tetrapods by various ligand exchange procedures.
(Less)
- author
- publishing date
- 2010-10
- type
- Contribution to journal
- publication status
- published
- in
- Nanoscale
- volume
- 2
- issue
- 10
- pages
- 9 pages
- publisher
- Royal Society of Chemistry
- external identifiers
-
- pmid:20680226
- scopus:77957908195
- ISSN
- 2040-3364
- DOI
- 10.1039/c0nr00308e
- language
- English
- LU publication?
- no
- id
- 2fabf7ff-1dfa-49ff-8c2e-7d0316db8c69
- date added to LUP
- 2023-01-18 09:38:28
- date last changed
- 2024-01-03 13:14:45
@article{2fabf7ff-1dfa-49ff-8c2e-7d0316db8c69, abstract = {{<p>Tetrapod-shaped CdSe(core)/CdTe(arms) colloidal nanocrystals, capped with alkylphosphonic acids or pyridine, were reacted with various small molecules (acetic acid, hydrazine and chlorosilane) which induced their tip-to-tip assembly into soluble networks. These networks were subsequently processed into films by drop casting and their photoconductive properties were studied. We observed that films prepared from tetrapods coated with phosphonic acids were not photoconductive, but tip-to-tip networks of the same tetrapods exhibited appreciable photocurrents. On the other hand, films prepared from tetrapods coated with pyridine instead of phosphonic acids were already highly photoconductive even if the nanocrystals were not joined tip-to-tip. Based on the current-voltage behavior under light we infer that the tunneling between tetrapods is the dominant charge transport mechanism. In all the samples, chemically-induced assembly into networks tended to reduce the average tunneling barrier. Additionally, pyridine-coated tetrapods and the tip-to-tip networks made out of them were tested as active materials in hybrid photovoltaic devices. Overall, we introduce an approach to chemically-induced tip-to-tip assembly of tetrapods into solution processable networks and demonstrate the enhancement of electronic coupling of tetrapods by various ligand exchange procedures.</p>}}, author = {{Franchini, Isabella R. and Cola, Adriano and Rizzo, Aurora and Mastria, Rosanna and Persano, Anna and Krahne, Roman and Genovese, Alessandro and Falqui, Andrea and Baranov, Dmitry and Gigli, Giuseppe and Manna, Liberato}}, issn = {{2040-3364}}, language = {{eng}}, number = {{10}}, pages = {{2171--2179}}, publisher = {{Royal Society of Chemistry}}, series = {{Nanoscale}}, title = {{Phototransport in networks of tetrapod-shaped colloidal semiconductor nanocrystals}}, url = {{http://dx.doi.org/10.1039/c0nr00308e}}, doi = {{10.1039/c0nr00308e}}, volume = {{2}}, year = {{2010}}, }