Controlled Synthesis of Au Chiral Propellers from Seeded Growth of Au Nanoplates for Chiral Differentiation of Biomolecules

Ma, Yongjie; Cao, Zhaozhen; Hao, Jinjie; Zhou, Jun‐Hao; Yang, Zhijie; Yang, Yanzhao; Wei, Jingjing

doi:10.1021/acs.jpcc.0c07046

Cited by 40 publications

(38 citation statements)

References 36 publications

(43 reference statements)

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“…[83][84][85] In most cases, a chiral molecule or biomolecule, such as an amino-acid, is used as a template to induce the chiral shape during nanoparticle synthesis. 86 For example, H. Lee et al employed amino-acids and peptides to guide the growth of chiral gold helicoids on a cubic or octahedral seed (Fig. 4A).…”

Section: Chiral Nanostructures Obtained By Wet Chemistrymentioning

confidence: 99%

Chiral plasmonic nanostructures: recent advances in their synthesis and applications

Pauly

2022

Mater. Adv.

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Section: Chiral Nanostructures Obtained By Wet Chemistrymentioning

confidence: 99%

Chiral plasmonic nanostructures: recent advances in their synthesis and applications

Pauly

2022

Mater. Adv.

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“…[ 27 ] Ma and Wei et al reported the Au chiral propellers by a seed‐mediated growth approach from Au nanotriangles using enantiomeric cysteine as the directing agents. [ 28 ] Previously, we obtained a helically grooved gold nanoarrows (HeliGNAs) and found that the introduction of cysteine or glutathione (GSH) as the shaping modifiers could lead to the formation of nanoarrows with helical grooves. [ 29 ] Depending on the strong AuS bond, chirality could be transferred from the molecular level to plasmonic level.…”

Section: Introductionmentioning

confidence: 99%

Selenocystine and Photo‐Irradiation Directed Growth of Helically Grooved Gold Nanoarrows

Wen

Wang

Liu

et al. 2021

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The fabrication of discrete nanostructures with both plasmonic circular dichroism (PCD) and chiral features is still a challenge. Here, gold nanoarrows (GNAs) with both chiroptical responses and chiral morphologies are achieved by using L‐selenocystine (L‐SeCys2) as a chiral inducer. While L‐SeCys2 generates GNAs with a weak PCD signal, the irradiated L‐SeCys2 (irr‐L‐SeCys2) leads to GNAs with featured helical grooves (HeliGNAs) accompanying with a strong PCD signal. It is revealed that when L‐SeCys2 is photo‐irradiated, the emergence of selenyl radicals plays an important role in the formation of HeliGNAs and enhancement of the chiroptical signal. In comparison with L‐SeCys2 and the other kinds of sulfur‐containing amino acids, the formation mechanism of helical grooves on the surface of GNAs is proposed. Both HeliGNAs and GNAs are used to discriminate amino acids by utilizing surface enhanced Raman scattering (SERS) effect. In the presence of either GNAs or HeliGNAs as the substrate, Fmoc‐L‐Phe shows more significant SERS than Fmoc‐D‐Phe. This study may advance the design of discrete plasmonic nanomaterials with both chiral morphology and potential applications in discrimination of chiral molecules.

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“…Chiral metamaterials have been widely studied for biology, living science, ultrasensitive chiral sensing, and enantiomer separation. − The chiroptical properties were mainly produced by structure asymmetry − and chiral molecules. − Current studies are focused on chiral plasmonic metamaterials with structural asymmetry, such as 3D stacked-patch plasmonic metamaterials, chiral plasmonic nanostructure, chiral Au nanohook, etc ., exhibiting markedly improved chiroptical responses and tunability within the visible wavelength due to the surface plasmon resonance. Moreover, Au chiral propellers and chiral nanostructured Au films were synthesized with the addition of chiral ligands and molecules, which were proven to be surface-enhanced Raman scattering (SERS) substrates for achieving chiral differentiation of chiral biomolecules.…”

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confidence: 99%

Plasmonic Chiral Metamaterials with Sub-10 nm Nanogaps

Zhang

et al. 2021

ACS Nano

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Sub-10 nm nanogaps are enantioselectively fabricated between two nanocrescents based on nanoskiving and show tailored circular dichroism (CD) activity. The mirror symmetry of the nanostructure is broken by subsequent deposition with different azimuthal angles. Strong plasmonic coupling is excited in the gaps and at the tips, leading to the CD activity. The dissymmetry g-factor of the chiral nanogaps with 5 nm gap-width is −0.055, which is 2.5 times stronger than that of the 10 nm gap-width. Moreover, the surface-enhanced Raman scattering (SERS) performance of L/D-cysteine absorbed on chiral nanogaps manifests as the emergence of enantiospecific Raman peaks and the appearance of distinct changes in SERS intensities, which affirms that chiral nanogaps can recognize specific cysteine enantiomers via standard Raman spectroscopy in the absence of circularly polarized light source and a chiral label molecule. The sub-10 nm chiral nanogaps with tailored chiroptical responses show great potential in a class of chiral applications, such as chiral sensing, polarization converters, labelfree chiral recognition, and asymmetric catalysis.

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Controlled Synthesis of Au Chiral Propellers from Seeded Growth of Au Nanoplates for Chiral Differentiation of Biomolecules

Cited by 40 publications

References 36 publications

Chiral plasmonic nanostructures: recent advances in their synthesis and applications

Chiral plasmonic nanostructures: recent advances in their synthesis and applications

Selenocystine and Photo‐Irradiation Directed Growth of Helically Grooved Gold Nanoarrows

Plasmonic Chiral Metamaterials with Sub-10 nm Nanogaps

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