Chiral segregation driven by a dynamical response of the adsorption footprint to the local adsorption environment: bitartrate on Cu(110)

Darling, George R.; Forster, Matthew; Lin, Chia‐Chi; Liu, Ning; Raval, Rasmita; Hodgson, A.

doi:10.1039/c7cp00622e

Cited by 10 publications

(34 citation statements)

References 48 publications

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“…Molecules of life, such as proteins and sugars, come basically only in single handedness, meaning that their enantiomer does not appear. [8][9][10] At low coverage and after mild annealing, TA binds by deprotonation with both carboxylate end groups ("bitartrate") to the surface, but with increasing coverage, a transition to a single-carboxylate adsorbate mode ("mono-tartrate") was observed ( Figure 1). Examples are different action of chiral drugs and fragrances in the human body.…”

Section: Introductionmentioning

confidence: 99%

“…Previous work by Raval and co-workers performed with pure enantiomers revealed a transmission of molecular handedness into extended 2D domains, a coveragedependent polymorphism and two principle binding modes of the interaction of TA with the Cu(110) surface. [8][9][10] At low coverage and after mild annealing, TA binds by deprotonation with both carboxylate end groups ("bitartrate") to the surface, but with increasing coverage, a transition to a single-carboxylate adsorbate mode ("mono-tartrate") was observed ( Figure 1). For (R,S)-TA on Cu(110), it has been concluded that this diastereoisomer engages into similar adsorbate modes.…”

Section: Introductionmentioning

confidence: 99%

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Chiral molecules adsorbed on a solid surface: Tartaric acid diastereomers and their surface explosion on Cu(111)

et al. 2018

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The adsorption of diastereoisomers of tartaric acid, namely, meso (R,S)-tartaric acid, (R,R)-tartaric acid, and the racemic mixture of (R,R) and (S,S) tartaric acid on the (111) surface of a copper single crystal has been studied by means of reflection-absorption IR Spectroscopy, X-ray photoelectron spectroscopy, low-energy electron diffraction, and thermal desorption spectroscopy. Two distinct adsorption modes are identified for all three adsorbate systems. All molecules undergo an identical thermally induced autocatalytic decomposition reaction above 510 K. The pure enantiomers show 2D chiral long-range ordered structures of opposite handedness.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Chiral molecules adsorbed on a solid surface: Tartaric acid diastereomers and their surface explosion on Cu(111)

et al. 2018

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“…By recording STM images of low coverage regions, where aggregation into extended 2D structures is inhibited by the finite diffusion length, we are also able to identify isolated bitartrate trimers on the Cu(110) terraces, as shown in Figure 1 c. The appearance of isolated trimers, in preference to individual bitartrate molecules, indicates that the trimer is the thermodynamically stable unit, consistent with DFT structure calculations that find the trimer is held together by intermolecular H-bonds, with weak dispersion and through-surface interactions assembling the trimers into rows to form the 2D structure. 24 …”

Section: Resultsmentioning

confidence: 99%

“… 23 The bitartrate is strongly bound to Cu by two bidentate carboxylate ligands and ordered into linear structures by weak intermolecular hydrogen bonds, with a bare metal channel separating neighboring bitartrate rows. 24 We show that water initially decorates the metal channels, forming strong hydrogen bonds to the polar O ligands exposed along the edge of the bitartrate rows. Further adsorption forms water clusters along the exposed metal channels, but does not wet the bitartrate rows, which appear hydrophobic, despite the available OH group.…”

Section: Introductionmentioning

confidence: 88%

Hydration of a 2D Supramolecular Assembly: Bitartrate on Cu(110)

et al. 2020

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Hydration layers play a key role in many technical and biological systems, but our understanding of these structures remains very limited. Here, we investigate the molecular processes driving hydration of a chiral metal–organic surface, bitartrate on Cu(110), which consists of hydrogen-bonded bitartrate rows separated by exposed Cu. Initially water decorates the metal channels, hydrogen bonding to the exposed O ligands that bind bitartrate to Cu, but does not wet the bitartrate rows. At higher temperature, water inserts into the structure, breaks the existing intermolecular hydrogen bonds, and changes the adsorption site and footprint. Calculations show this process is driven by the creation of stable adsorption sites between the carboxylate ligands, to allow hydration of O–Cu ligands within the interior of the structure. This work suggests that hydration of polar metal–adsorbate ligands will be a dominant factor in many systems during surface hydration or self-assembly from solution.

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“…23,24 Steric effects in lateral interactions between adsorbed molecules are responsible for the segregation of different enantiomers of a racemic mixture into 2D domains of opposite handedness, 25,26 but the interaction with the substrate can also provoke deformations of the molecules influencing their arrangement on the surface. 27 Fabricating spatially uniform chiral thin films with atomic-scale control of their handedness is not only relevant for applications; it is also important to reach a profound understanding of the interactions between the chiral building blocks and the mechanisms allowing transmission of their chirality to long-scale arrangements because the details of these structures can have a substantial influence on their enantioselectivity. 28 In the last decades surface spectroscopies and scanning probe microscopies have provided important insights on chiral 2D assembly which complemented with advances in theoretical modeling have delivered understanding into the balance of interactions that determine the system behavior.…”

Section: Introductionmentioning

confidence: 99%

Enantiopure Supramolecular Motifs of Self-Assembled Diamine-Based Chiral Molecules on Cu(100)

et al. 2018

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The assembly of two Diphenylethylenediamine enantiomers, separately deposited on Cu(100), is investigated from the first stages of two-dimensional crystallization to the nucleation and growth of the second layer. By means of Scanning Tunneling Microscopy, we show that the chirality of the enantiomers is expressed at different levels of molecular organization. Below the monolayer completion, a disordered phase coexists with domains of a square lattice aligned with the principal crystallographic directions of the substrate. The intrinsic chirality of the molecules is only manifested through specific features contained within the corresponding unit cell. For increasing coverage, this arrangement is accompanied by a second square structure, which appears to be clockwise or counterclockwise rotated with respect to the Cu(100) directions depending on the enantiomer. The nucleation of molecular chains on top of the aligned square structure gives rise to a second layer exhibiting a striped-like configuration with remarkable left-or right-handed helicity that mirrors that of the particular enantiomer. The nearly flat configuration of the first layer molecules is confirmed by angular dependent X-ray absorption experiments and supported by molecular dynamics simulations.

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Chiral segregation driven by a dynamical response of the adsorption footprint to the local adsorption environment: bitartrate on Cu(110)

Cited by 10 publications

References 48 publications

Chiral molecules adsorbed on a solid surface: Tartaric acid diastereomers and their surface explosion on Cu(111)

Chiral molecules adsorbed on a solid surface: Tartaric acid diastereomers and their surface explosion on Cu(111)

Hydration of a 2D Supramolecular Assembly: Bitartrate on Cu(110)

Enantiopure Supramolecular Motifs of Self-Assembled Diamine-Based Chiral Molecules on Cu(100)

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