Self-assembly for electronics

Abstract: Abstract

“… 21 , 23 , 44 , 46 − 49 The self-assembly process is self-limited, providing the opportunity to control AuNP coverage, and is potentially compatible with NPs of different sizes, compositions, and shapes. 21 , 23 , 50 However, the preparation of substrates with homogeneous AuNP assemblies providing uniform E-field enhancements over large areas remains a challenge. 23 , 26 To prepare such AuNPs@Si substrates, silanes containing amino- or mercapto-groups have been previously used to form siloxane bonds with the Si surface and to direct the assembly of AuNPs at the Si surface either via electrostatic interaction or covalent bonding.…”

“…Top-down methods, such as electron-beam or nanoimprint lithography, have been successfully used for preparing well-defined Au or other metallic nanostructures on Si. ,− They require, however, expensive and elaborated lab equipment and clean-room conditions. ,,, Densely packed AuNP films can be formed via self-assembly at a liquid/liquid interface, which can be later transferred to a planar substrate. − However, the postfunctionalization of the AuNPs with a structure-directing molecule, such as mercapto-polyethylene glycol, 1-dodecanethiol, acrylamide molecules, or perfluorodecanethiol, complicates the approach, while the deposition of the resulting AuNP monolayers on substrates with complex topographies, such as VA-SiNW arrays, has not been successfully demonstrated. − The self-assembly of presynthesized AuNPs on functionalized Si, on the other hand, offers a low-cost and simple route that is amenable for mass-production and is compatible with the coating of nanostructured silicon. ,,,− The self-assembly process is self-limited, providing the opportunity to control AuNP coverage, and is potentially compatible with NPs of different sizes, compositions, and shapes. ,, However, the preparation of substrates with homogeneous AuNP assemblies providing uniform E-field enhancements over large areas remains a challenge. , To prepare such AuNPs@Si substrates, silanes containing amino- or mercapto-groups have been previously used to form siloxane bonds with the Si surface and to direct the assembly of AuNPs at the Si surface either via electrostatic interaction or covalent bonding. ,− Both the Si functionalization and the AuNP assembly step are sensitive to the experimental conditions. Among others, the quality of the silane layer is highly affected by the presence of water, temperature, heating speed, reaction time, and silane concentration, as well as the storage conditions after the functionalization itself has been completed. ,− The AuNP assembly on the Si surface is also sensitive to the pH and ionic strength of the solution, AuNP size and capping ligand, and immersion time in the AuNP solution. ,,, This self-assembly process is further complicated if topographically structured substrates, such as SiNWs, are to be uniformly coated because geometric restrictions may cause changes in accessibility and concentration profiles of the NPs to be deposited.…”

Self-Assembled Au Nanoparticle Monolayers on Silicon in Two- and Three-Dimensions for Surface-Enhanced Raman Scattering Sensing

“… 21 , 23 , 44 , 46 − 49 The self-assembly process is self-limited, providing the opportunity to control AuNP coverage, and is potentially compatible with NPs of different sizes, compositions, and shapes. 21 , 23 , 50 However, the preparation of substrates with homogeneous AuNP assemblies providing uniform E-field enhancements over large areas remains a challenge. 23 , 26 To prepare such AuNPs@Si substrates, silanes containing amino- or mercapto-groups have been previously used to form siloxane bonds with the Si surface and to direct the assembly of AuNPs at the Si surface either via electrostatic interaction or covalent bonding.…”

“…Top-down methods, such as electron-beam or nanoimprint lithography, have been successfully used for preparing well-defined Au or other metallic nanostructures on Si. ,− They require, however, expensive and elaborated lab equipment and clean-room conditions. ,,, Densely packed AuNP films can be formed via self-assembly at a liquid/liquid interface, which can be later transferred to a planar substrate. − However, the postfunctionalization of the AuNPs with a structure-directing molecule, such as mercapto-polyethylene glycol, 1-dodecanethiol, acrylamide molecules, or perfluorodecanethiol, complicates the approach, while the deposition of the resulting AuNP monolayers on substrates with complex topographies, such as VA-SiNW arrays, has not been successfully demonstrated. − The self-assembly of presynthesized AuNPs on functionalized Si, on the other hand, offers a low-cost and simple route that is amenable for mass-production and is compatible with the coating of nanostructured silicon. ,,,− The self-assembly process is self-limited, providing the opportunity to control AuNP coverage, and is potentially compatible with NPs of different sizes, compositions, and shapes. ,, However, the preparation of substrates with homogeneous AuNP assemblies providing uniform E-field enhancements over large areas remains a challenge. , To prepare such AuNPs@Si substrates, silanes containing amino- or mercapto-groups have been previously used to form siloxane bonds with the Si surface and to direct the assembly of AuNPs at the Si surface either via electrostatic interaction or covalent bonding. ,− Both the Si functionalization and the AuNP assembly step are sensitive to the experimental conditions. Among others, the quality of the silane layer is highly affected by the presence of water, temperature, heating speed, reaction time, and silane concentration, as well as the storage conditions after the functionalization itself has been completed. ,− The AuNP assembly on the Si surface is also sensitive to the pH and ionic strength of the solution, AuNP size and capping ligand, and immersion time in the AuNP solution. ,,, This self-assembly process is further complicated if topographically structured substrates, such as SiNWs, are to be uniformly coated because geometric restrictions may cause changes in accessibility and concentration profiles of the NPs to be deposited.…”

Self-Assembled Au Nanoparticle Monolayers on Silicon in Two- and Three-Dimensions for Surface-Enhanced Raman Scattering Sensing

“…The versatility of bionic nanocoatings that we can build using diverse Retinin-like proteins and waxes/fatty acids [ 11 , 12 ] has been multiplied in this study, by the diversity of metallic armaments. In the future, further means of derivatization of bionic nanocoatings can be conceivable, encompassing metallic layering or multi-layering ( Figure 1 e), as well as incorporation of other types of objects of the nanoscale ( Figure 1 f), for diverse applications in photonics, electronics, and medicine [ 51 , 52 , 53 , 54 ].…”

Bactericidal and Antiviral Bionic Metalized Nanocoatings

“…168 By integrating colloidal nanocrystals with metallic, semiconducting, and insulating properties, highperformance devices such as field-effect transistors can be constructed that could be the basis for developing flexible, low-cost electronics. [169][170][171][172] Potential device applications of nanocrystal mesostructures also include lightemitting diodes, photodetectors, solar cell components, and memory elements. 173 Future applications of nanocrystal assemblies will also explore their quantum optical properties, such as singlephoton emission, optical and spin coherence, and spinphoton interfaces.…”

Soft matter crystallography -- complex, diverse, and new crystal structures in condensed materials on the mesoscale