Shape‐Controlled Nanostructures in Heterogeneous Catalysis

Zaera, Francisco

doi:10.1002/cssc.201300398

Cited by 144 publications

(126 citation statements)

References 337 publications

(778 reference statements)

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“…DNA nanotechnology seeks to deploy molecules at an atomic and small molecule scale, as illustrated, for example by (Zaera, 2013). Other techniques in biophysics and biochemistry do not need to address the issue of the true structure of the nucleic acids at an atomic level but, rather, at a macro-atomic level such as in genetics and in immunology, for example.…”

Section: Resultsmentioning

confidence: 99%

Extending the Repertoire of Structures in DNA Nanotechnology

Delmonte¹

2015

American Journal of Nanotechnology

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DNA nanotechnology remains an active area of research and advances have been reviewed recently. DNA nanotechnology seeks to deploy molecules at an atomic level and on a small molecule scale. Other techniques in biophysics and biochemistry do not need to address the issue of the true structure of the nucleic acids at an atomic level but, rather, at a macro-atomic level such as in genetics and in immunology, for example. Accordingly, DNA nanotechnology is perhaps uniquely dependent upon exact clarity in the secondary and tertiary structures of the nucleic acids, as well as that can ever be achieved. Challenges include expanding the use of DNA in medicine, and the construction of detectors with higher sensitivity for biological and chemical settings. Though increasingly complex architectures have been constructed, novel approaches to a greater rôle in biological computation and data storage remain important goals. Here a repertoire of structures for DNA at an atomic level is described which offers a new conjecture with which to move forward. The DNA double helix model faces many problems which have become apparent in the 62 years of research in molecular biology that have elapsed since it was formulated by Watson and Crick in 1953. Experimental evidence is set out seeking to show that the only truly side-by-side alternative, the paranemic model, accounts better for the wide range of phenomena otherwise inexplicable with the double helix model. This paranemic model can engage in a repertoire of structural options denied to the DNA double helix model. Without the requirement to postulate unwinding of the DNA strands, the nucleotide base sequence is immediately accessible to complementary DNA sequences to promote rapid detection of specific molecules in biological and medical settings. Rapid switching between Watson-Crick and Hoogsteen base pairing and four-stranded structures can allow greater complexity in the construction of molecular switches and digital programming.

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Section: Resultsmentioning

confidence: 99%

Extending the Repertoire of Structures in DNA Nanotechnology

Delmonte¹

2015

American Journal of Nanotechnology

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“…Recent years have seen remarkable progress in the synthesis of engineered catalysts with distinct shapes and compositions tailored for achieving optimum selectivity and activity in chemical reactions [3][4][5]. Rare earth oxides have been widely used as structural and electronic promoters to improve activity, selectivity, and thermal stability of catalysts [2].…”

Section: Introductionmentioning

confidence: 99%

Ceria Nanoshapes—Structural and Catalytic Properties

Agarwal

Mojet

Lefferts

et al. 2015

Catalysis by Materials With Well-Defined Structures

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“…The NP shape/morphology is known to have a dramatic influence on catalytic properties [15], but retaining the morphology under catalytic operating conditions remains challenging. Embedding the shape-controlled NPs in a porous matrix could be a way to achieve that goal.…”

Section: Introductionmentioning

confidence: 99%