A Flexible Hydrogen Bonded Organic Framework That Reversibly Adsorbs Acetic Acid: γ Trimesic Acid

Sanchez‐Sala, Marta; Vallcorba, Oriol; Domingo, Concepción; Ayllón, José A.

doi:10.1021/acs.cgd.8b00858

Cited by 10 publications

(10 citation statements)

References 34 publications

(63 reference statements)

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“…The expense of searching the crystal packing space with multiple independent, conformationally exible molecules in the asymmetric unit limited us to predicting crystal structures with 1 and 2 molecules in the asymmetric unit (Z 0 ¼ 1 and 2). Hence, our landscape of predicted structures does not contain the known Z 0 ¼ 6 a-TMA, 43,44 nor the Z 0 ¼ 3 g-TMA structures. 42 For comparison to the CSP structures, the energies of aand g-TMA were calculated from ordered approximations of their high-Z 0 disordered structures (see Fig.…”

Section: Resultsmentioning

confidence: 97%

“…42 Herbstein also showed that TMA can be crystallised from the vapor, by condensation onto a cold surface, to produce a g-polymorph, 43 which was recently shown to adsorb acetic acid reversibly aer activation. 44 Zaworotko reported a 2 : 1 TMA : acetic acid solvate, which features triply inclined interpenetration between truncated 1D and hexagonal 2D nets. 45 The 2-D ordering of TMA on metal surfaces has also been investigated, 46 and TMA is an archetypal ligand for MOF synthesis (e.g., HKUST-1).…”

Section: Introductionmentioning

confidence: 99%

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Mining predicted crystal structure landscapes with high throughput crystallisation: old molecules, new insights

et al. 2019

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Organic molecules tend to close pack to form dense structures when they are crystallised from organic solvents. Porous molecular crystals defy this rule: they contain open space, which is typically stabilised by inclusion of solvent in the interconnected pores during crystallisation. The design and discovery of such structures is often challenging and time consuming, in part because it is difficult to predict solvent effects on crystal form stability. Here, we combine crystal structure prediction (CSP) with a robotic crystallisation screen to accelerate the discovery of stable hydrogen-bonded frameworks. We exemplify this strategy by finding new phases of two well-studied molecules in a computationally targeted way.Specifically, we find a new 'hidden' porous polymorph of trimesic acid, d-TMA, that has a guest-free hexagonal pore structure, as well as three new solvent-stabilized diamondoid frameworks of adamantane-1,3,5,7-tetracarboxylic acid (ADTA). Beyond porous solids, this hybrid computationalexperimental approach could be applied to a wide range of materials problems, such as organic electronics and drug formulation.

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Section: Resultsmentioning

confidence: 97%

Section: Introductionmentioning

confidence: 99%

Mining predicted crystal structure landscapes with high throughput crystallisation: old molecules, new insights

et al. 2019

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“…However, TMA was recently revisited from a fresh perspective, after CSP calculations revealed an energetically stable, low-density polymorphic form, referred to as the δ-polymorph, which remained hidden, despite many groups studying the crystallization behavior of this molecule over the last 50 years. [285][286][287][288][289][290][291][292][293][294] In this study, a high throughput crystallization workflow was developed to screen 280 binary solvent crystallization conditions, of which less than 2% either yielded this δ-polymorph directly, or gave a structure that transformed to this form after activation of the crystal pores. [295] Unlike the nonporous α-polymorph reported by Duchamp et al, the computationally-identified δpolymorph of TMA had a SA BET 910 m 2 g -1 at 77.3 K. CSP was also used by Hisaki et al (Tp-apo, Figures 13 and 16) [296] to predict the structure of a carboxylic acid-based HOF material, that could not be determined directly from X-ray data alone.…”

Section: Tuning Crystal Porosity By Controlling Molecular Packingmentioning

confidence: 99%

“…The structure Duchamp reported is nonporous due to the nonplanar hydrogen‐bonded interactions between TMA molecules causing the hydrogen‐bonded networks to interlock. However, TMA was recently revisited from a fresh perspective, after CSP calculations revealed an energetically stable, low‐density polymorphic form, referred to as the δ−polymorph, which remained hidden, despite many groups studying the crystallization behavior of this molecule over the last 50 years 285–294. In this study, a high throughput crystallization workflow was developed to screen 280 binary solvent crystallization conditions, of which less than 2% either yielded this δ‐polymorph directly, or gave a structure that transformed to this form after activation of the crystal pores 295.…”

Section: Tuning the Properties Of Porous Molecular Materialsmentioning

confidence: 99%

The Chemistry of Porous Organic Molecular Materials

Little

Cooper

2020

Adv Funct Materials

239

189

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Porous organic molecular materials are a subclass of porous solids that are defined by their modular, molecular structures, and the absence of extended covalent or coordination bonding in the solid-state. As a result, porous molecular materials are soluble and they can be processed into different forms, such as mixed matrix membranes. The structure of the porous modules can be fine-tuned for specific applications, such as gas isotope separations, and in some cases the solid-state properties of these materials can be defined by the structure of the porous molecule as viewed in isolation. In this review, the authors focus on the design of porous organic molecular materials and how their properties can be tuned for specific applications by using crystal engineering techniques. The authors distinguish between strategies where porosity is defined largely by the molecule itself, for example, in porous organic cages, and cases where porosity is generated by the solidstate crystalline assembly. They emphasize the importance of computational techniques in the de novo design of functional, porous organic molecular materials, and how molecular modeling is applied to understand the properties of these materials.

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“…Another application under study is the crystal structure refinement of -trimesic acid at high pressure inside a diamond anvil cell. -Trimesic acid (orthorhombic, I222) is a flexible porous material (Sanchez-Sala et al, 2018) and the structural evolution with pressure has been followed by applying the tts-XRD methodology [ Fig. 6(b)].…”

Section: Grain Analysismentioning

confidence: 99%

d2Dplot: 2D X-ray diffraction data processing and analysis for through-the-substrate microdiffraction

Vallcorba

Rius

2019

J Appl Cryst

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The d2Dplot computer program provides a set of tools for the visualization, processing and analysis of 2D X-ray diffraction (2DXRD) data. Among the operations available there are the sum/subtraction of 2DXRD images, conversion to 1D data (powder pattern), azimuthal plotting, calibration of instrumental parameters, background subtraction and a command-line mode to run operations inside data processing pipelines. The graphical user interface allows easy use of the program. It also includes two main features: (i) the possibility of creating a user compound database to help in the fast phase identification of similar samples, and (ii) a detailed peak analysis routine for the application of the through-the-substrate microdiffraction methodology.

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A Flexible Hydrogen Bonded Organic Framework That Reversibly Adsorbs Acetic Acid: γ Trimesic Acid

Cited by 10 publications

References 34 publications

Mining predicted crystal structure landscapes with high throughput crystallisation: old molecules, new insights

Mining predicted crystal structure landscapes with high throughput crystallisation: old molecules, new insights

The Chemistry of Porous Organic Molecular Materials

d2Dplot: 2D X-ray diffraction data processing and analysis for through-the-substrate microdiffraction

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