Conjugated organic framework with three-dimensionally ordered stable structure and delocalized π clouds

Guo, Jia; Xu, Yanhong; Jin, Shangbin; Чэн, Лонг; Kaji, Tatsuru; Honsho, Yoshihito; Addicoat, Matthew A.; Kim, Jangbae; Saeki, Akinori; Ihee, Hyot Cherl; Seki, Shu; Irle, Stephan; Hiramoto, Masahiro; Gao, Jia; Jiang, Donglin

doi:10.1038/ncomms3736

Cited by 596 publications

(569 citation statements)

References 71 publications

Supporting

Mentioning

533

Contrasting

Unclassified

Order By: Relevance

“…1) that features high surface area with densely populated yet highly accessible Hg(II) binding sites thereby affording high Hg(II) adsorption capacity; strong Hg(II) chelating groups that are well dispersed throughout the single-walled pore surface thus rendering high affinity for Hg(II) and efficient utilization of Hg(II) binding sites; large yet tunable pore size to enable fast yet controllable kinetics of Hg(II) adsorption; Hg(II) chelating groups that are covalently anchored to the backbone thus avoiding the leaching of binding sites; exceptional water/chemical stability facilitating regeneration/recyclability. Such mercury 'nano-trap' can be targeted by grafting desired Hg(II) chelating groups to the highly robust porous organic polymers (POPs) [35][36][37][38][39][40][41][42][43][44] that exhibit high surface areas, tunable pore sizes and high water/ chemical stabilities, via stepwise post-synthetic modification 45 of the phenyl rings of their structural components using various established organic reactions. Herein we demonstrate such a POP-based mercury 'nano-trap' that exhibits an exceptional mercury saturation uptake capacity of over 1,000 mg g À 1 and can effectively reduce Hg(II) concentration from 10 p.p.m.…”

mentioning

confidence: 99%

Mercury nano-trap for effective and efficient removal of mercury(II) from aqueous solution

et al. 2014

View full text Add to dashboard Cite

Highly effective and highly efficient decontamination of mercury from aqueous media remains a serious task for public health and ecosystem protection. Here we report that this task can be addressed by creating a mercury 'nano-trap' as illustrated by functionalizing a high surface area and robust porous organic polymer with a high density of strong mercury chelating groups. The resultant porous organic polymer-based mercury 'nano-trap' exhibits a recordhigh saturation mercury uptake capacity of over 1,000 mg g À 1 , and can effectively reduce the mercury(II) concentration from 10 p.p.m. to the extremely low level of smaller than 0.4 p.p.b. well below the acceptable limits in drinking water standards (2 p.p.b.), and can also efficiently remove 499.9% mercury(II) within a few minutes. Our work therefore presents a new benchmark for mercury adsorbent materials and provides a new perspective for removing mercury(II) and also other heavy metal ions from contaminated water for environmental remediation.

show abstract

mentioning

confidence: 99%

Mercury nano-trap for effective and efficient removal of mercury(II) from aqueous solution

et al. 2014

View full text Add to dashboard Cite

show abstract

“…Note that the broadness of the PXRD peaks for the β-ketoenamine-linked COFs is a well-established phenomenon, which likely originates from stacking faults or dislocations, displaying an inter-layer distance estimated at~3.4 Å. 40 It is also noteworthy that this series of COFs has not yet shown very high crystallinity in comparison to COFs with reversible imine or boronateester linkages. 41 The high-resolution TEM images revealed parallelaligned, stacked sheets 40 composed of crystalline domains with sizes of 10-40 nm (Supplementary Figures S5 and S6).…”

Section: Resultsmentioning

confidence: 99%

“…40 It is also noteworthy that this series of COFs has not yet shown very high crystallinity in comparison to COFs with reversible imine or boronateester linkages. 41 The high-resolution TEM images revealed parallelaligned, stacked sheets 40 composed of crystalline domains with sizes of 10-40 nm (Supplementary Figures S5 and S6). Accordingly, we observed improved nanoscale crystallinity with slightly enhanced short-range ordering, when compared to the β-ketoenamine-linked COFs obtained by conventional solvothermal methods.…”

Section: Resultsmentioning

confidence: 99%

Intensified synthesis and post-synthetic modification of covalent organic frameworks using a continuous flow of microdroplets technique

et al. 2018

View full text Add to dashboard Cite

Covalent organic frameworks (COFs) are two-dimensional/three-dimensional crystalline polymeric materials with diverse molecular backbones and topologies and are strong candidates for numerous applications. However, the ready availability of these materials is a challenge. The key issues are slow production rates, harsher and longer reaction conditions, and a need for post-synthetic modification to obtain desired molecular functionalities. Only a few studies, including those using microfluidic techniques, have focused on refining these factors, but these reports lack synthetic continuity and scalability. Herein, we present a fast, intensified and continuous synthesis and post-synthetic modification of β-ketoenamine-linked COFs by confining organic building units into moving microdroplets in a transparent capillary. This study introduces a one-step, facile approach to serially modify NO 2 -to NH 2 -substituted COFs in a fraction of the time, effort and cost of traditional methods. These results may stimulate the development of novel COFs with unique chemistries and functions for various applications.

show abstract

“…Unlike the reaction that occurred in solution, fabricating low dimensional COF at the liquid/solid or gas/solid interface through self-condensation of boronic acids is a novel method to form a series of nanomaterials equipped with functional characteristics such as sensing [38,39], energy storage [40], optoelectronic devices [41,42], and catalysis [43,44]. The building blocks of the condensation equipped with more than two functional groups, hydroxide radical, is a basic precondition to trigger the reaction, and the ambient environment around the reaction monomers can obviously decide the quality of the surface covalent organic framework (SCOF).…”

Section: Self-condensation Of Boronic Acidsmentioning

confidence: 99%

Recent Progress in the Fabrication of Low Dimensional Nanostructures via Surface-Assisted Transforming and Coupling

Liang

Shen

et al. 2017

Journal of Nanomaterials

View full text Add to dashboard Cite

Polymerization of functional organics into covalently cross-linked nanostructures via bottom-up approach on solid surfaces has attracted tremendous interest recently, due to its appealing potentials in fabricating novel and artificial low dimensional nanomaterials. While there are various synthetic approaches being proposed and explored, this paper reviews the recent progress of on-surface coupling strategies towards the synthesis of low dimensional nanostructures ranging from 1D nanowire to 2D network and describes their advantages and drawbacks during on-surface process and phase transformations, for example, from molecular self-assembly to on-surface polymerization. Specifically, Ullmann reaction is discussed in detail and the mechanism governing nanostructures' transforming effect by surface treatment is exploited. In the end, it is summarized that the hierarchical polymerization combined with Ullmann coupling makes it possible to realize the selection of different synthetic pathways and phase transformations and obtain novel organometallic nanowire with metalorganic bonding.

show abstract

Conjugated organic framework with three-dimensionally ordered stable structure and delocalized π clouds

Cited by 596 publications

References 71 publications

Mercury nano-trap for effective and efficient removal of mercury(II) from aqueous solution

Mercury nano-trap for effective and efficient removal of mercury(II) from aqueous solution

Intensified synthesis and post-synthetic modification of covalent organic frameworks using a continuous flow of microdroplets technique

Recent Progress in the Fabrication of Low Dimensional Nanostructures via Surface-Assisted Transforming and Coupling

Contact Info

Product

Resources

About