AI Article Synopsis
- - The text presents a novel nanopatterning technique utilizing dynamic coordination bonds between polyphenols and metal ions (like Fe and Cu) to create customizable surface structures with diverse properties.
- - By applying this method under acidic conditions and post-treating with ammonia, researchers can develop stable metal-phenolic nanopatterns on various substrates that can be fine-tuned for size, shape, and composition.
- - Additionally, these nanopatterns can serve as nanoreactors for synthesizing metal nanoparticles and modifying surfaces with biological molecules, making the approach valuable for applications in catalytic, chemical, and biological sensing.
Article Abstract
We report a general nanopatterning strategy that takes advantage of the dynamic coordination bonds between polyphenols and metal ions (e.g., Fe and Cu) to create structures on surfaces with a range of properties. With this methodology, under acidic conditions, 29 metal-phenolic complex-based precursors composed of different polyphenols and metal ions are patterned using scanning probe and large-area cantilever free nanolithography techniques, resulting in a library of deposited metal-phenolic nanopatterns. Significantly, post-treatment of the patterns under basic conditions (i.e., ammonia vapor) triggers a change in coordination state and results in the in situ generation of more stable networks firmly attached to the underlying substrates. The methodology provides control over feature size, shape, and composition, almost regardless of substrate (e.g., Si, Au, and silicon nitride). Under reducing conditions (i.e., H) at elevated temperatures (180-600 °C), the patterned features have been used as nanoreactors to synthesize individual metal nanoparticles. At room temperature, the ammonia-treated features can reduce Ag to form metal nanostructures and be modified with peptides, proteins, and thiolated DNA via Michael addition and/or Schiff base reaction. The generality of this technique should make it useful for a wide variety of researchers interested in modifying surfaces for catalytic, chemical and biological sensing, and template-directed assembly purposes.
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| http://dx.doi.org/10.1021/jacs.2c13515 | DOI Listing |
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