MicroED Structure of Au146(p-MBA)57 at Subatomic Resolution Reveals a Twinned FCC Cluster

Vergara, Sandra; Lukes, Dylan A.; Martynowycz, Michael W.; Santiago, Ulises; Plascencia-Villa, Germán; Weiß, Simon; Cruz, M. Jason de la; Black, David M.; Alvarez, Marcos M.; López-Lozano, Xóchitl; Barnes, Christopher O.; Lin, Guowu; Weissker, Hans‐Christian; Whetten, Robert L.; Gonen, Tamir; Yacamán, Miguel José; Calero, Guillermo

doi:10.1021/acs.jpclett.7b02621

Cited by 106 publications

(103 citation statements)

References 51 publications

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“…The decisive role of ligands on the kernel structure has also been exemplified by various Ag NCs . These and other inspiring discoveries in the field are excellent models for analyzing the interaction of ligands with metals and also are the key links for understanding the evolution from single atom to the bulk metal …”

Section: Introductionmentioning

confidence: 94%

Observation of Non‐FCC Copper in Alkynyl‐Protected Cu₅₃Nanoclusters

Zhang

Wang

et al. 2020

Angew Chem Int Ed

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The only feasible access to non‐face‐centered cubic (FCC) copper was by physical vapor deposition under high vacuum. Now, non‐FCC copper is observed in a series of alkynyl‐protected Cu53 nanoclusters (NCs) obtained from solution‐phase synthesis. Determined by single‐crystal X‐ray crystallography, the structures of Cu53(C≡CPhPh)9(dppp)6Cl3(NO3)9 and its two derivatives reveal an ABABC stacking sequence involving 41 Cu atoms. It can be regarded as a mixed FCC and HCP structure, which gives strong evidence that Cu can be arranged in non‐FCC lattice at ambient conditions when proper ligands are provided. Characterization methods including X‐ray absorption fine structure, XPS, ESI‐MS, UV/Vis, Auger spectroscopy, and DFT calculations were carried out. CuII was shown to successively coordinate with introduced ligands and changed to CuI after bonding with phosphine. The following addition of NaBH4 and the aging step further reduced it to the Cu53 NC.

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Section: Introductionmentioning

confidence: 94%

Observation of Non‐FCC Copper in Alkynyl‐Protected Cu₅₃Nanoclusters

Zhang

Wang

et al. 2020

Angew Chem Int Ed

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“…Electrons interact with matter more strongly than X-rays and they are affected by the charge (16). While it is extremely challenging to observe protons in X-ray structures, it is relatively common in MicroED data (17)(18)(19)(20). Several protons were observed in all structures.…”

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confidence: 99%

The CryoEM Method MicroED as a Powerful Tool for Small Molecule Structure Determination

Jones¹,

Martynowycz²,

Hattne³

et al. 2018

Preprint

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In the many scientific endeavors that are driven by organic chemistry, unambiguous identification of small molecules is of paramount importance. Over the past 50 years, NMR and other powerful spectroscopic techniques have been developed to address this challenge. While almost all of these techniques rely on inference of connectivity, the unambiguous determination of a small molecule’s structure requires X-ray and/or neutron diffraction studies. In practice, however, x-ray crystallography is rarely applied in routine organic chemistry due to intrinsic limitations of both the analytes and the technique. Here we report the use of the CryoEM method MicroED to provide routine and unambiguous structural determination of small organic molecules. From simple powders, with minimal sample preparation, we could collect high quality MicroED data from nanocrystals (~100x100x100 nm, ~10–15g) resulting in atomic resolution (<1 Å) crystal structures in minutes.

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“…A faster rotation with a shorter frame rate might reduce electron dosage while preventing spot overlap. Rotation speeds varied over experiments, from 0.1°/s (Vergara et al, 2017) to 0.29 o /s (de la Cruz et al, 2017), but Table 1 shows that resolution vs rotation speed (Fig. 6) and frame scope (the angle covered by a single frame, Fig.…”

Section: Reducing Electron Dosagecrystal Rotation Speedmentioning

confidence: 99%

Illuminating the Secrets of Crystals - Microcrystal Electron Diffraction in Structural Biology

Barringer

Meier²

2018

Preprint

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An exploration of the crystallographic theory of the relatively novel method of Microcrystal Electron Diffraction (MicroED), via comparison to X-ray crystallography at the theoretical and practical level as it applies to biological macromolecules. We then attempt to outline the limitations and challenges that the technique currently faces in structural biology, and suggest future areas of study that may improve and optimize the technique.

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MicroED Structure of Au₁₄₆(p-MBA)₅₇ at Subatomic Resolution Reveals a Twinned FCC Cluster

Cited by 106 publications

References 51 publications

Observation of Non‐FCC Copper in Alkynyl‐Protected Cu₅₃Nanoclusters

Observation of Non‐FCC Copper in Alkynyl‐Protected Cu₅₃Nanoclusters

The CryoEM Method MicroED as a Powerful Tool for Small Molecule Structure Determination

Illuminating the Secrets of Crystals - Microcrystal Electron Diffraction in Structural Biology

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MicroED Structure of Au146(p-MBA)57 at Subatomic Resolution Reveals a Twinned FCC Cluster

Cited by 106 publications

References 51 publications

Observation of Non‐FCC Copper in Alkynyl‐Protected Cu53Nanoclusters

Observation of Non‐FCC Copper in Alkynyl‐Protected Cu53Nanoclusters

The CryoEM Method MicroED as a Powerful Tool for Small Molecule Structure Determination

Illuminating the Secrets of Crystals - Microcrystal Electron Diffraction in Structural Biology

Contact Info

Product

Resources

About

MicroED Structure of Au₁₄₆(p-MBA)₅₇ at Subatomic Resolution Reveals a Twinned FCC Cluster

Observation of Non‐FCC Copper in Alkynyl‐Protected Cu₅₃Nanoclusters

Observation of Non‐FCC Copper in Alkynyl‐Protected Cu₅₃Nanoclusters