Influences of Deprotonation and Modulation on Nucleation and Growth of UiO-66: Intergrowth and Orientation

Shan, Bohan; James, Joshua B.; Armstrong, Mitchell R.; Close, Emily C; Letham, Portia A.; Nikkhah, Kassandra; Lin, Jerry Y S; Mu, Bin

doi:10.1021/acs.jpcc.7b11012

Cited by 51 publications

(50 citation statements)

References 29 publications

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“…Although the seesaw model at present does not offer predictions of particle morphologies, we expect that its foundation in acid-base and metal-ligand chemistry can help explain the dependence of morphology on solution acidity and modulator composition. Although previous reports have used modulators in combination with manipulation of pH, 27,33 this report is the rst to systematically manipulate particle sizes with a buffer.…”

Section: Details Of the Synthetic Conditions Can Be Found In The Exmentioning

confidence: 99%

Experimental evidence for a general model of modulated MOF nanoparticle growth

et al. 2020

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Section: Details Of the Synthetic Conditions Can Be Found In The Exmentioning

confidence: 99%

Experimental evidence for a general model of modulated MOF nanoparticle growth

et al. 2020

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“…To circumvent this problem, we added a deprotonating agent triethylamine (i.e., N(CH 2 CH 3 ) 3 ) in the upper hexane phase (Figure d, pink phase) which has been successfully shown to be effective in increasing the reaction speeds (Section S.1.3, Supporting Information). As TEA diffuses into the bottom phase, it governs the quantity of proton in a direction where TEA diffuses . Here, hexane also buffers the contact between formic acid and TEA, in that way we have the high crystallinity and yield all at the same time, and optimizing the hexane amount is of paramount importance in the growth process as shown in Section S.1.4 (Supporting Information).…”

Section: Description Of Atomic Vibrations Involving Raman Active Modementioning

confidence: 99%

Ultimate Control over Hydrogen Bond Formation and Reaction Rates for Scalable Synthesis of Highly Crystalline vdW MOF Nanosheets with Large Aspect Ratio

et al. 2018

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Large‐scale synthesis of van der Waals (vdW) metal–organic framework (MOF) nanosheets with controlled crystallinity and interlayer coupling strength is one of the bottlenecks in 2D materials that has limited its successful transition to large‐scale applications. Here, scalable synthesis of mBDC (m = Zn and Cu) 2D MOFs at large scales through a biphase method is demonstrated. The results show replacing water molecules with pyridine eliminates hydrogen bond formation at metal cluster sites. This prohibits tight coupling across adjacent MOF layers and sustains controllable 2D vdW MOF growth. It is further shown that control over the growth speed, crystallinity, and thickness can be achieved by addition of a controlled amount of triethylamine and formic acid to achieve highly crystalline vdW MOF nanosheets with extraordinarily high aspect ratio. The described synthesis route can easily be scaled up for large‐scale production either by deposition onto desired substrates or in crystalline layered powder form. Owing to its large lateral size, vdW nature, and high crystallinity, it is possible to perform atomic force microscopy, Kelvin probe force microscopy, and Raman measurements on the 2D MOFs. The results not only establish their vibrational properties and layer‐dependent responses but also show striking differences from other 2D inorganic materials.

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“…The resultant membrane showed an excellent permeability by possessing a flux value of 265 L/m 2 h MPa with efficient rejection of methylene blue (MB). In spite of promising performance, a key issue is that the nucleation and growth of MOFs usually requires hours under thermal treatment and/or in the presence of a harsh solvent [25], and this severely limits the combination between an MOF and a polymeric support that can form a uniform selective layer before damaging the polymeric support. Moreover, as the nucleation of MOF crystals likely occurs in a solution rather than on a substrate surface, it is not easy to control the thickness of the selective layer in in situ processes unless a cyclic layer-by-layer technique is employed [24,26].…”

Section: Introductionmentioning

confidence: 99%

Design of a Semi-Continuous Selective Layer Based on Deposition of UiO-66 Nanoparticles for Nanofiltration

et al. 2018

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Deposition of UiO-66 metal–organic framework nanoparticles onto a porous polymer support is a promising approach to designing highly-permeable, size-selective, flexible, and stable membranes for water filtration. In this article, a series of UiO-66 nanoparticles having different particle sizes were synthesized and employed to prepare UiO-66-deposited composite membranes. It was found that the size of the UiO-66 nanoparticles had great influences on the performance of the composite membranes for the filtration of a methylene blue aqueous solution. The deposition of smaller nanoparticles afforded a selective layer having a greater external surface area and narrower interparticle voids. These features made the deposition of smaller nanoparticles more advantageous in terms of the flux and rejection, while the deposition of greater nanoparticles afforded a selective layer more tolerant for fouling. Bimodal composite membranes were prepared by depositing mixed UiO-66 nanoparticles of smaller and bigger sizes. These membranes successfully combined the advantages of nanoparticles of a distinct size.

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Influences of Deprotonation and Modulation on Nucleation and Growth of UiO-66: Intergrowth and Orientation

Cited by 51 publications

References 29 publications

Experimental evidence for a general model of modulated MOF nanoparticle growth

Experimental evidence for a general model of modulated MOF nanoparticle growth

Ultimate Control over Hydrogen Bond Formation and Reaction Rates for Scalable Synthesis of Highly Crystalline vdW MOF Nanosheets with Large Aspect Ratio

Design of a Semi-Continuous Selective Layer Based on Deposition of UiO-66 Nanoparticles for Nanofiltration

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