Structure of the Thiolated Au<sub>130</sub> Cluster

Tlahuice‐Flores, Alfredo; Santiago, Ulises; Bahena, Daniel; Vinogradova, Ekaterina; Conroy, Cecil V.; Ahuja, Tarushee; Bach, Stephan B. H.; Ponce, Arturo; Wang, Gangli; José–Yacamán, Miguel; Whetten, Robert L.

doi:10.1021/jp406665m

Cited by 71 publications

(76 citation statements)

References 33 publications

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“…119 This type of structure has been confirmed recently by Whetten et al based on theoretical and experimental results. 124 In contrast, the XRD pattern of Au 187 (SC 12 H 25 ) 68 was different from that of Au 102 (SR) 44 and Au 130 (SR) 50 , 119 which suggests that the framework structure of Au 187 (SC 12 H 25 ) 68 is different from that of Au 102 (SR) 44 and Au 130 (SR) 50 . An accurate structural model for Au 187 (SC 12 H 25 ) 68 has not yet been established; however, based on these experimental results, its geometric structure is expected to be determined accurately in the future.…”

Section: Chemical Compositionmentioning

confidence: 96%

Toward the Creation of Functionalized Metal Nanoclusters and Highly Active Photocatalytic Materials Using Thiolate-Protected Magic Gold Clusters

Negishi

2013

Bulletin of the Chemical Society of Japan

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Advances in developments in nanotechnology have encouraged the creation of highly functionalized nanomaterials. Thiolate-protected gold clusters (Au n (SR) m ) less than 2 nm in size exhibit size-specific physical and chemical properties not observed in bulk metals. Therefore, they have attracted attention as functional units or building blocks in nanotechnology. The highly stable, magic Au n (SR) m clusters possess great potential as new nanomaterials. We are studying the following subjects related to magic Au n (SR) m clusters: (1) establishing methods to enhance their functionality, (2) developing high-resolution separation methods, and (3) utilizing the clusters as active sites in photocatalytic materials. Through these studies, we aim to create highly functional metal nanoclusters and apply them as highly active photocatalytic materials. The results of our efforts to date are summarized in this paper.

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Section: Chemical Compositionmentioning

confidence: 96%

Toward the Creation of Functionalized Metal Nanoclusters and Highly Active Photocatalytic Materials Using Thiolate-Protected Magic Gold Clusters

Negishi

2013

Bulletin of the Chemical Society of Japan

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“…17 The same structure model was also proposed by Tlahuice-Flores et al based on scanning transmission electron microscopy (STEM) imaging and density functional theory (DFT) calculation of Au 130 (SR) 50 . 33 There is actually a close relationship between the Au 130 (SR) 50 and the Au 102 (SR) 44 ( Figure S4); that is, both nanoclusters can be included in the family of decahedra, and the Au 130 (SR) 50 can be viewed as an elongated version of the Au 102 (SR) 44 . It is this elongation that creates an additional layer of "foot-holds" in the third shell ( Figure 1C, blue), which makes it possible to form ordered surface patterns of −S−Au−S− ripple stripes in Au 130 (SR) 50 .…”

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confidence: 93%

Crystal Structure of Barrel-Shaped Chiral Au₁₃₀(p-MBT)₅₀ Nanocluster

et al. 2015

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We report the structure determination of a large gold nanocluster formulated as Au130(p-MBT)50, where p-MBT is 4-methylbenzenethiolate. The nanocluster is constructed in a four-shell manner, with 55 gold atoms assembled into a two-shell Ino decahedron. The surface is protected exclusively by -S-Au-S- staple motifs, which self-organize into five ripple-like stripes on the surface of the barrel-shaped Au105 kernel. The Au130(p-MBT)50 can be viewed as an elongated version of the Au102(SR)44. Comparison of the Au130(p-MBT)50 structure with the recently discovered icosahedral Au133(p-TBBT)52 nanocluster (where p-TBBT = 4-tert-butylbenzenethiolate) reveals an interesting phenomenon that a subtle ligand effect in the para-position of benzenethiolate can significantly affect the gold atom packing structure, i.e. from the 5-fold twinned Au55 decahedron to 20-fold twinned Au55 icosahedron.

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“…Recently, significant experimental advances have been made in the structure determination of several magic-sized Au n (SR) m clusters in the size region of about 0.5−2 nm. The atomic structures of Au 133 (SPh-t-Bu) 52 , 12,13 Au 130 (SC 12 H 25 ) 50 , 14,15 Au 102 (p-MBA) 44 , 16 Au 68 (3-MBA) 31−34 (3-MBA = 3-mercaptobenzoic acid), 17 Au 52 (TBBT) 32 (TBBT = 4-tert-butylbenzenethiol), 10 Au 40 (o-MBT) 24 (o-MBT = mercaptobenzothiazole), 18 Au 38 (SCH 2 CH 2 Ph) 24 , 19 Au 25 (SCH 2 CH 2 Ph) 18 − , 20,21 Au 36 (SPht-Bu) 2 4 , 2 2 Au 3 0 S(S-t-Bu) 1 8 , 2 3 Au 2 8 (SPh-t-Bu) 2 0 , 2 4 Au 24 (SCH 2 Ph-t-Bu) 20 , 25 Au 24 (SAdm) 16 , 26 Au 23 (SPh) 16 − , 27 Au 20 (SPh-t-Bu) 16 , 28 and Au 18 (SC 6 H 11 ) 14 29, 30 were determined by single X-ray crystallography and powerful single-particle transmission electron microscopy (SP-TEM). Based on the resolved cluster structures, a generic structural rule denoted as the "divide-and-protect" concept has been summarized.…”

Section: Introductionmentioning

confidence: 99%

“…According to this concept, 31,32 any Au n (SR) m nanoclusters can be divided into a symmetric gold core covered by interfacial staple motifs (i.e., −SR[AuSR] x −, x = 1, 2, 3, ...). Over the past few years, the "divide-and-protect" concept combined with density functional theory (DFT) computations has led to predictions of a number of cluster structures, including Au 187 (SR) 68 , 33 Au 144 (SR) 60 , 34 Au 68 (SR) 34 , 35 Au 67 (SR) 35 2− , 36 Au 44 (SR) 28 , 37 Au 40 (SR) 24 , 38 Au 38 (SR) 24 , 39,40 Au 25 (SR) 18 − , 41 Au 24 (SR) 20 , 42 Au 20 (SR) 16 , 43 Au 18 (SR) 14 , 44 Au 15 (SR) 13 , 45,46 and Au 12 (SR) 9 + . 47 Although tremendous research efforts have been made on the characterization of atomic structures, an important issue about the structural evolution of Au n (SR) m clusters in the size range 1−2 nm remained elusive.…”

Section: Introductionmentioning

confidence: 99%

Correlating the Structure and Optical Absorption Properties of Au₇₆(SR)₄₄ Cluster

Ma¹,

Wang²,

Zhou³

et al. 2016

J. Phys. Chem. C

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The atomic structure of recently synthesized thiolate-protected Au 76 cluster is theoretically predicted via a simple structural rule summarized from the crystal structures of thiolateprotected Au 44 (SR) 28 , Au 36 (SR) 24 , and Au 52 (SR) 32 clusters. We find that Au 76 (SR) 44 (N = 7) and recently reported Au 52 (SR) 32 (N = 4), Au 44 (SR) 28 (N = 3), Au 36 (SR) 24 (N = 2), and Au 28 (SR) 20 (N = 1) belong to a family of homologous Au 20+8N (SR) 16+4N clusters whose Au cores follow a one-dimensional polytetrahedral growth pathway. The Au 76 (SR) 44 cluster is predicted to contain an anisotropic facecentered-cubic (fcc) Au core, which can be viewed as combination of two helical tetrahedra Au 4 chains and is remarkably different from the well-known spherical Au core in ligand-protected gold clusters in the size region of 1−2 nm. The intense near-infrared (NIR) absorption of Au 76 (SR) 44 is attributed to the synergistic effect of anisotropic Au core structure and ligand protections. A plausible cluster-to-cluster transformation mechanism is further suggested.

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Structure of the Thiolated Au₁₃₀ Cluster

Cited by 71 publications

References 33 publications

Toward the Creation of Functionalized Metal Nanoclusters and Highly Active Photocatalytic Materials Using Thiolate-Protected Magic Gold Clusters

Toward the Creation of Functionalized Metal Nanoclusters and Highly Active Photocatalytic Materials Using Thiolate-Protected Magic Gold Clusters

Crystal Structure of Barrel-Shaped Chiral Au₁₃₀(p-MBT)₅₀ Nanocluster

Correlating the Structure and Optical Absorption Properties of Au₇₆(SR)₄₄ Cluster

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Structure of the Thiolated Au130 Cluster

Cited by 71 publications

References 33 publications

Toward the Creation of Functionalized Metal Nanoclusters and Highly Active Photocatalytic Materials Using Thiolate-Protected Magic Gold Clusters

Toward the Creation of Functionalized Metal Nanoclusters and Highly Active Photocatalytic Materials Using Thiolate-Protected Magic Gold Clusters

Crystal Structure of Barrel-Shaped Chiral Au130(p-MBT)50 Nanocluster

Correlating the Structure and Optical Absorption Properties of Au76(SR)44 Cluster

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Structure of the Thiolated Au₁₃₀ Cluster

Crystal Structure of Barrel-Shaped Chiral Au₁₃₀(p-MBT)₅₀ Nanocluster

Correlating the Structure and Optical Absorption Properties of Au₇₆(SR)₄₄ Cluster