Layer-by-Layer Enabled Nanomaterials for Chemical Sensing and Energy Conversion

Layer-by-Layer Enabled Nanomaterials for Chemical Sensing and Energy Conversion

The layer-by-layer (LbL) technique is a wet chemical method for the assembly of ultrathin films, with thicknesses up to 100 nm. This method is based on the successive transfer of molecular layers to a solid substrate that is dipped into cationic and anionic solutions in an alternating fashion. The a...

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Bibliographic Details
Published in:JOM (1989) Vol. 65; no. 6; pp. 709 - 719
Main Authors: Paterno, Leonardo G., Soler, Maria A. G.
Format: Journal Article
Language:English
Published: Boston Springer US 01-06-2013
Springer Nature B.V
Subjects:
Adsorption
Alternative energy
Chemistry/Food Science
Earth Sciences
Electricity generation
Electrolytes
Energy
Engineering
Environment
Enzymes
Fatty acids
Graphene
Information storage
Light emitting diodes
Nanomaterials
Nanoparticles
Photovoltaic cells
Physics
Polymers
Quantum dots
Sensors
Signal transduction
Spectrum analysis
Brazil
PANI
Active Layer
Electronic Nose
Redox Mediator
Transparent Conducting Oxide
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Summary:The layer-by-layer (LbL) technique is a wet chemical method for the assembly of ultrathin films, with thicknesses up to 100 nm. This method is based on the successive transfer of molecular layers to a solid substrate that is dipped into cationic and anionic solutions in an alternating fashion. The adsorption is mainly driven by electrostatic interactions so that many molecular and nanomaterial systems can be engineered under this method. Moreover, it is inexpensive, can be easily performed, and does not demand sophisticated equipment or clean rooms. The most explored use of the LbL technique is to build up molecular devices for chemical sensing and energy conversion. Both applications require ultrathin films where specific elements must be organized with high control of thickness and spatial distribution, preferably in the nanolength and mesolength scales. In chemical sensors, the LbL technique is employed to assemble specific sensoactive materials such as conjugated polymers, enzymes, and immunological elements onto appropriated electrodes. Molecular recognition events are thus transduced by the assembled sensoactive layer. In energy-conversion devices, the LbL technique can be employed to fabricate different device’s parts including electrodes, active layers, and auxiliary layers. In both applications, the devices’ performance can be fully modulated and improved by simply varying film thickness and molecular architecture. The present review article highlights the main features of the LbL technique and provides a brief description of different (bio)chemical sensors, solar cells, and organic light-emitting diodes enabled by the LbL approach.
ISSN:1047-4838
1543-1851
DOI:10.1007/s11837-013-0608-1