Tuning the adsorption and fluorescence properties of aminal‐linked porous organic polymers through N‐heterocyclic group decoration

Weng, Junying; Xu, Yueling; Song, Wei‐Chao; Zhang, Yinghui

doi:10.1002/pola.28028

Cited by 45 publications

(42 citation statements)

References 55 publications

(93 reference statements)

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“…The nitrogen adsorption/desorption analysisw as performed to analyze the specific surface area with architecturalr igiditya nd permanent porosity of TrzMOP.T he N 2 adsorption/desorption isotherm of TrzMOP and recycled TrzMOP matrix were represented in Figure 2a nd ESI, Figure S4 which displayed the features of both type Ia nd IV isotherms according to IUPAC nomenclature. [47] At the very low pressure region isotherm shows as harpi ncrease of adsorbed N 2 volume which indicates the presenceo fm icroporosity in the polymeric material. Further,a t very high pressure region as mall hysteresis loop together with large nitrogen uptake suggested the existence of mesoporosity in this material.…”

Section: Porosity and Surface Area Analysismentioning

confidence: 95%

N‐rich Porous Organic Polymer as Heterogeneous Organocatalyst for the One‐Pot Synthesis of Polyhydroquinoline Derivatives through the Hantzsch Condensation Reaction

et al. 2018

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Incorporation of nitrogen functionality onto the high surface area porous polymeric network are very demanding in designing suitable heterogeneous organocatalyst having surface basicity. Here we report the synthesis of a new N‐rich triazine based microporous organic polymer (TrzMOP) through a simple and efficient condensation pathway involving the reaction between 1,4‐bis(4,6‐diamino‐s‐triazin‐2‐yl)‐benzene (SL‐1) and 2,5‐thiophene dicarboxaldehyde. The material has been characterized by using powder XRD, FTIR spectroscopy, solid state magic‐angle spinning 13C NMR, CHN analysis, FESEM, HRTEM, CO2‐TPD and N2 adsorption/desorption techniques. This nitrogen‐rich new porous organic polymer showed very high catalytic efficiency for one‐pot proficient synthesis of polyhydroquinoline derivatives via microwave assisted condensation reaction. As little as 8 mg of catalyst was found to be effective under the optimum reaction conditions. In addition, TrzMOP catalyzed synthesis of biologically active polyhydroquinoline derivatives are very cost effective, scalable, less time consuming, and environmentally benign compared to those of currently used as heterogeneous catalysts.

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Section: Porosity and Surface Area Analysismentioning

confidence: 95%

N‐rich Porous Organic Polymer as Heterogeneous Organocatalyst for the One‐Pot Synthesis of Polyhydroquinoline Derivatives through the Hantzsch Condensation Reaction

et al. 2018

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“…The moderate capacity originated from the low surface area. It was found that nitrogen-rich polymer favored the sorption toward iodine owing to the stronger interaction between nitrogen atom and electron-deficient I2 [4,[32][33]. The inserted images in Figure 4 showed the color change of I2-cyclohexane (1 mg ml -1 ) solution after adding 25 mg of CMOP-1 and CMOP-2.…”

Section: Gas Sorption Capacitymentioning

confidence: 99%

“…Zhang et al synthesized polymers with N-heterocyclic groups (NAPOPs). NAPOP-1 and NAPOP-3 exhibit high adsorption toward iodine (>240 wt%) and moderate CO2 adsorption [32]. Geng et al constructed novel triazine-based TCMPs by Friedel-Crafts polymerization reaction [33].…”

Section: Introductionmentioning

confidence: 99%

Synthesis of nitrogen-rich polymers by click polymerization reaction and gas sorption property

Song

Duan

2018

Preprint

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Microporous organic polymers (MOPs) are promising materials for gas sorption because of the intrinsic and permanent porosity, designable framework and low density. The introduction of nitrogen-rich building block in MOPs will greatly enhance the gas sorption capacity. Here, we report the synthesis of MOPs from the 2,4,6-tris(4-ethynylphenyl)-1,3,5-triazine unit and aromatic azides linkers via click polymerization reaction. FTIR and solid state 13 C CP-MAS NMR confirm the formation of the polymers. CMOP-1 and CMOP-2 exhibit microporous networks with BET surface area of 431 and 406 m 2 g -1 and narrow pore size distribution under 1.2 nm. Gas sorption isotherms including CO2 and H2 were measured. CMOP-1 stores superior CO2 level of 8.2 wt% (1.88 mmol g -1 ) at 273 K/1.0 bar and H2 uptake up to 0.6 wt% at 77 K/1.0 bar, while CMOP-2 with smaller surface area shows lower CO2 adsorption capacity of 7.3 wt% (1.66 mmol˙g -1 ) and H2 uptake (0.5 wt%). In addition, I2 vapor adsorption was tested at 353 K. CMOP-1 shows higher gravimetric load of 160 wt%. Despite of the moderate surface area, the CMOPs display excellent sorption ability for CO2 and I2 due to the nitrogen-rich content in the polymers.

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“…Most of the studies on the separationo fC O 2 concerned new adsorbents such as metal-organic frameworks (MOFs), [29][30][31][32][33][34] N-doped porous carbons (NPCs), [35] microporous coordination polymers (MCPs), [36] covalento rganic polymers (COPs), [37][38][39] and porous organic polymers (POPs) [40][41][42] compared to commercial adsorbents (i.e., molecular sieves,a ctivated carbons,a nd silica gel) [43][44][45][46] and relied on theoretical selectivity analysis.E ven with the wide range of utilization in this field, there is still al ack of information on the characteristic behavior of CO 2 adsorption in multicomponent mixtures.T here are no detailed studies for comparison between these types of commercial adsorbents, which are still pioneering materials for CO 2 removal, [47][48][49] related to their partialc omponent uptake performances for awide range of mixturec ombinations and conditions. Molecular sieve zeolite (MSZ) adsorbents are one of the most popular solid adsorbents utilizedn ormally for the separation and purification of multicomponent mixtures.T hese adsorbents have low Si/Al ratios (e.g.,1 3X and 5A zeolite), which results in higher uptake amounts of CO 2 at low pressures ( % 2.5 mmol g À1 at 298 Ka nd 0.1 bar).…”

Section: Introductionmentioning

confidence: 99%

Experimental and Neural Network Modeling of Partial Uptake for a Carbon Dioxide/Methane/Water Ternary Mixture on 13X Zeolite

et al. 2017

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In this work, GERG2008 EoS embedded in a volumetric–gravimetric technique was utilized to measure multicomponent partial uptakes into the mixture. The sophisticated combination may overlap recent theoretical measurements and replace it with real‐time and experimental selective adsorption analysis. 13X zeolite was utilized as a solid adsorbent for the adsorption of binary and ternary CO2/CH4/H2O mixtures. Premixed and preloaded water vapor was studied at 323 K temperature and up to 10 bar pressure. The isotherms of individual components within the mixture were identified and compared to the adsorption data of the pure components for assured benchmarking and validation. Artificial neural network (ANN) modeling was used to predict ternary mixtures. The ANN results showed a good agreement with the experimental data. Moreover, simulated configurations by utilizing an ANN model reflected the high consistency. We identified the behavior of the single components in ternary and higher multicomponent mixtures.

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Tuning the adsorption and fluorescence properties of aminal‐linked porous organic polymers through N‐heterocyclic group decoration

Cited by 45 publications

References 55 publications

N‐rich Porous Organic Polymer as Heterogeneous Organocatalyst for the One‐Pot Synthesis of Polyhydroquinoline Derivatives through the Hantzsch Condensation Reaction

N‐rich Porous Organic Polymer as Heterogeneous Organocatalyst for the One‐Pot Synthesis of Polyhydroquinoline Derivatives through the Hantzsch Condensation Reaction

Synthesis of nitrogen-rich polymers by click polymerization reaction and gas sorption property

Experimental and Neural Network Modeling of Partial Uptake for a Carbon Dioxide/Methane/Water Ternary Mixture on 13X Zeolite

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