CO2在氨基改性MIL-101(Cr)中吸附的分子模拟

采用实验与分子模拟结合的方法研究298 K下CO₂在氨基改性得到的MIL-101（Cr）-NH₂和MIL-101（Cr）-ED（ED：乙二胺）上的吸附性能。比较MIL-101（Cr）、MIL-101（Cr）-NH₂和MIL-101（Cr）-ED的吸附等温线与吸附热的结果,表明采用直接合成改性法得到的MIL-101（Cr）-NH₂比采用合成后再改性得到的MIL-101（Cr）-ED有更高的CO₂吸附容量。进一步比较密度分布图和径向密度分布曲线,分析CO₂在氨基改性MIL-101（Cr）中的吸附位,表明在低压下CO₂首先吸附在MIL-101（Cr）微孔的超级四面体中,随着吸附压力的增大逐渐填充到更大的孔中。氨基的存在增加了CO₂的吸附位点,使MIL-101（Cr）-NH₂具有较高CO₂吸附容量;同时MIL-101（Cr）-ED中的ED分子的存在增加了CO₂的吸附位点,使MIL-101（Cr）-ED也具有较高CO₂吸附容量;但是MIL-101（Cr）-ED中的ED分子占据了MIL-101（Cr）中Cr的吸附位点,使Cr对CO₂的吸附强度减弱,同时可吸附位点少于MIL-101（Cr）-NH₂,导致其对CO₂的吸附容量少于MIL-101（Cr）-NH₂。     

从《世阿弥传书》到《匠明》:能乐观演空间尺度体系的传承与演变

利用酰胺化反应在2,2,6,6-四甲基哌啶-1-氧自由基(TEMPO)分子的4位引入乙酰氨基和异烟酰氨基分别获得Acet-TEMPO和isoNTA-TEMPO分子.将Acet-TEMPO、 isoNTA-TEMPO和TEMPO分别与MIL-101(Fe)组成共催化体系,以苯甲醇选择性氧化为苯甲醛做模型反应,研究上述3种催化体系的催化性能.催化结果表明3种催化体系的催化活性顺序为:MIL-101(Fe)/isoNTA-TEMPO MIL-101(Fe)/Acet-TEMPOMIL-101(Fe)/TEMPO.通过对比实验和吸附实验表明isoNTA-TEMPO的吡啶官能团与MIL-101(Fe)的Fe簇配位作用是提高体系催化性能的关键因素.MIL-101(Fe)/isoNTA-TEMPO催化体系对各种芳香醇均表现出较好的催化性能,且催化剂能循环回收利用.     

CO2在氨基改性MIL-101(Cr)中吸附的分子模拟

采用实验与分子模拟结合的方法研究298 K下CO_2在氨基改性得到的MIL-101(Cr)-NH_2和MIL-101(Cr)-ED(ED:乙二胺)上的吸附性能。比较MIL-101(Cr)、MIL-101(Cr)-NH_2和MIL-101(Cr)-ED的吸附等温线与吸附热的结果,表明采用直接合成改性法得到的MIL-101(Cr)-NH_2比采用合成后再改性得到的MIL-101(Cr)-ED有更高的CO_2吸附容量。进一步比较密度分布图和径向密度分布曲线,分析CO_2在氨基改性MIL-101(Cr)中的吸附位,表明在低压下CO_2首先吸附在MIL-101(Cr)微孔的超级四面体中,随着吸附压力的增大逐渐填充到更大的孔中。氨基的存在增加了CO_2的吸附位点,使MIL-101(Cr)-NH_2具有较高CO_2吸附容量;同时MIL-101(Cr)-ED中的ED分子的存在增加了CO_2的吸附位点,使MIL-101(Cr)-ED也具有较高CO_2吸附容量;但是MIL-101(Cr)-ED中的ED分子占据了MIL-101(Cr)中Cr的吸附位点,使Cr对CO_2的吸附强度减弱,同时可吸附位点少于MIL-101(Cr)-NH_2,导致其对CO_2的吸附容量少于MIL-101(Cr)-NH_2。     

Pt/MIL-101(Cr)在肉桂醛选择性加氢反应中的催化性能

采用简单易行的浸渍法将Pt纳米粒子负载到MIL-101(Cr)上, 制备了Pt/MIL-101(Cr)催化剂, 并对其在肉桂醛选择性加氢反应的催化性能进行了研究。XRD、N₂吸附、TEM和催化性能的研究结果表明, Pt的负载量对负载于MIL-101(Cr)上Pt纳米粒子的尺寸及所制备催化剂对肉桂醇的选择性有很大影响。低Pt负载量(1.0wt%)的Pt/MIL-101(Cr)较其他MOFs和无机材料在肉桂醛选择性加氢反应中表现出了高的催化性能, 在优化的反应条件下肉桂醛转化率和对肉桂醇的选择性可分别达96.5%和86.2%。Pt/MIL-101(Cr)催化剂具有良好的稳定性。Pt/MIL-101(Cr)所表现出的优良的催化性能同MIL-101(Cr)载体的孔道结构及其表面性质密切相关。     

Pt/MIL-101(Cr)在肉桂醛选择性加氢反应中的催化性能

采用简单易行的浸渍法将Pt纳米粒子负载到MIL-101(Cr)上,制备了Pt/MIL-101(Cr)催化剂,并对其在肉桂醛选择性加氢反应的催化性能进行了研究。XRD、N₂吸附、TEM和催化性能的研究结果表明,Pt的负载量对负载于MIL-101(Cr)上Pt纳米粒子的尺寸及所制备催化剂对肉桂醇的选择性有很大影响。低Pt负载量(1.0%)的Pt/MIL-101(Cr)较其他MOFs和无机材料在肉桂醛选择性加氢反应中表现出了高的催化性能,在优化的反应条件下肉桂醛转化率和对肉桂醇的选择性可分别达96.5%和86.2%。Pt/MIL-101(Cr)催化剂具有良好的稳定性。Pt/MIL-101(Cr)所表现出的优良的催化性能同MIL-101(Cr)载体的孔道结构及其表面性质密切相关。     

五乙烯六胺改性金属有机骨架材料MIL-101(Cr)对CO_2的吸附性能

采用溶剂热法合成金属有机骨架材料MIL-101(Cr),用回流法将五乙烯六胺(PEHA)负载到MIL-101(Cr)孔道中的不饱和金属位点上,使用扫描电镜、粉末X射线衍射、氮气物理吸附、元素分析和傅里叶变换红外光谱等表征手段考察材料的结构和形貌,测试氨基改性前后的MIL-101(Cr)在25℃、不同压力下对CO_2的吸附效果。结果表明,负载0.24 m L五乙烯六胺后的MIL-101(Cr)对CO_2的吸附效果最好,在25℃、常压下对CO_2的饱和吸附量可达58.944 mg/g,相比未负载五乙烯六胺的MIL-101(Cr)吸附量(CO_2饱和吸附量为44.208 mg/g)增加了33%。随着吸附压力的增加,MIL-101(Cr)和0.24PEHAM IL-101(Cr)对CO_2的饱和吸附量逐渐增加,当吸附压力为1.1 MPa时,两者的吸附量分别为1 147.59和1 256.74 mg/g,表明该类材料在高压下对CO_2有着良好的吸附效果。     

Ag-Y/MIL-101吸附剂的制备及其吸附脱硫性能

通过银、钇双金属改性制备了Ag-Y/MIL-101吸附剂,并对Ag-Y/MIL-101进行了X射线衍射(XRD)、电镜(SEMEDS)、比表面积(BET)和热重(TG-DTG)表征。考察了Ag-Y/M IL-101金属负载顺序、金属负载浓度、金属溶液用量、负载时间对脱硫性能的影响,优化了吸附脱硫条件。结果表明,金属改性得到的Ag-Y/MIL-101保持了MIL-101的晶格结构。与M IL-101相比,Ag-Y/MIL-101的比表面积和孔容均有所下降。适宜Ag-Y/MIL-101的制备条件为:先负载银后负载钇,银离子和钇离子的负载浓度均为30 mmol/L,金属溶液用量均为1 mL,负载时间为8 h。适宜Ag-Y/MIL-101的吸附脱硫条件为:吸附剂用量0.05 g,模拟油为10 mL,吸附温度为60℃,吸附时间为8 h。在此条件下,Ag-Y/MIL-101对噻吩的吸附量达到21.7 mg/g。Ag能显著提高MIL-101的吸附硫容,Y能显著提高MIL-101的吸附选择性,因此,Ag-Y/MIL-101吸附剂中Ag和Y的协同作用使其拥有比MIL-101更高的硫容和噻吩脱硫选择性。     

季铵功能化的金属有机骨架对水中双氯芬酸钠的高效吸附与去除

通过两步合成法制备了季铵功能化的金属有机骨架MIL-101（Cr）即MIL-101（Cr）-NMe₃,并考察了该材料对双氯芬酸钠（DCF）的吸附行为。通过不同浓度的DCF在MIL-101（Cr）-NMe₃吸附剂上的动力学数据,以及在不同温度下的吸附平衡等温线和MIL-101（Cr）-NMe₃吸附剂的重复使用性能考察,发现该材料对DCF的吸附过程符合准二级动力学方程,吸附平衡等温线符合Langmuir等温吸附模型,在20℃下的最大吸附量为310.6 mg/g,5次循环使用后吸附量未明显减少。MIL-101（Cr）-NMe₃对DCF的吸附作用机理可归结为静电相互作用和π-π相互作用,吸附效果远大于未修饰氨基的MIL-101（Cr）。可以预见该材料对水中DCF的去除具有良好的应用前景。     

A method for increasing permeability in O2/N2 separation with mixed-matrix membranes made of water-stable MIL-101 and polysulfone

Water-stable MIL-101 microcrystals adhere well to polysulfone (PSF) and yield a very robust mixed-matrix MIL-101-PSF membrane for the O(2)/N(2) separation with a selectivity of 5-6 and an unsurpassed O(2) permeability increase by a factor of four to above 6 barrer for MIL-101 loadings of 24%.     

MIL-101 (Fe) @Ag Rapid Synergistic Antimicrobial and Biosafety Evaluation of Nanomaterials

Metal-organic frameworks (MOFs), which have become popular in recent years as excellent carriers of drugs and biomimetic materials, have provided new research ideas for fighting pathogenic bacterial infections. Although various antimicrobial metal ions can be added to MOFs with physical methods, such as impregnation, to inhibit bacterial multiplication, this is inefficient and has many problems, such as an uneven distribution of antimicrobial ions in the MOF and the need for the simultaneous addition of large doses of metal ions. Here, we report on the use of MIL-101(Fe)@Ag with efficient metal-ion release and strong antimicrobial efficiency for co-sterilization. Fe-based MIL-101(Fe) was synthesized, and then Ag⁺ was uniformly introduced into the MOF by the substitution of Ag⁺ for Fe³⁺. Scanning electron microscopy, powder X-ray diffraction (PXRD) Fourier transform infrared spectroscopy, and thermogravimetric analysis were used to investigate the synthesized MIL-101(Fe)@Ag. The characteristic peaks of MIL-101(Fe) and silver ions could be clearly seen in the PXRD pattern. Comparing the diffraction peaks of the simulated PXRD patterns clearly showed that MIL-101(Fe) was successfully constructed and silver ions were successfully loaded into MIL-101(Fe) to synthesize an MOF with a bimetallic structure, that is, the target product MIL-101(Fe)@Ag. The antibacterial mechanism of the MOF material was also investigated. MIL-101(Fe)@Ag exhibited low cytotoxicity, so it has potential applications in the biological field. Overall, MIL-101(Fe)@Ag is an easily fabricated structurally engineered nanocomposite with broad-spectrum bactericidal activity.     

以醋酸盐为矿化剂合成金属有机骨架MIL-101

以醋酸钠为矿化剂, 通过水热合成法直接获得了较纯净的Material Institut Lavoisier-101(MIL-101). 样品经粉末X射线衍射、比表面积及孔径分布和热重分析表征, 并与以氢氟酸为矿化剂合成的MIL-101进行了比较. 结果表明, 以醋酸钠为矿化剂合成的MIL-101的性能优于以氢氟酸作为矿化剂合成的MIL-101, 并且样品经后续纯化处理后能进一步提高比表面积和孔容; 用非定域密度泛函法(NLDFT)分析计算得到了MIL-101的孔结构信息. 合成的MIL-101骨架能稳定至300 ℃以上, 其热稳定性略低于以氢氟酸作为矿化剂合成的MIL-101.     

Synergistic catalysis of metal-organic framework-immobilized Au-Pd nanoparticles in dehydrogenation of formic acid for chemical hydrogen storage

Bimetallic Au-Pd nanoparticles (NPs) were successfully immobilized in the metal-organic frameworks (MOFs) MIL-101 and ethylenediamine (ED)-grafted MIL-101 (ED-MIL-101) using a simple liquid impregnation method. The resulting composites, Au-Pd/MIL-101 and Au-Pd/ED-MIL-101, represent the first highly active MOF-immobilized metal catalysts for the complete conversion of formic acid to high-quality hydrogen at a convenient temperature for chemical hydrogen storage. Au-Pd NPs with strong bimetallic synergistic effects have a much higher catalytic activity and a higher tolerance with respect to CO poisoning than monometallic Au and Pd counterparts.     

A new Brønsted acid MIL-101(Cr) catalyst by tandem post-functionalization; synthesis and its catalytic application

A new heterogeneous Brønsted solid acid catalyst was prepared by tandem post-functionalization of MIL-101(Cr) and utilized for acetic acid esterification and alcoholysis of epoxides under solvent-free conditions. First, MIL-101(Cr) was functionalized with pyrazine to achieve MIL-101(Cr)-Pyz. Afterwards, the nucleophilic reaction of MIL-101(Cr)-Pyz with 1,3-propane sultone and next acidification with diluted sulfuric acid gave MIL-101(Cr)-Pyz-RSO₃H Brønsted solid acid catalyst. Various characterization methods such as Fourier transformation infrared (FT-IR) spectroscopy, X-ray diffraction (XRD), elemental analysis (CHNS), X-ray photoelectron spectroscopy (XPS), scanning electron microscopy (SEM), energy-dispersiveX-ray(EDX) spectroscopy, thermal analysis (TGA/DTA), acid–base titration, and N₂ adsorption/desorption analysis were employed to fully characterize the prepared catalyst. The catalyst showed high activity compared to unmodified MIL-101(Cr) in both catalytic acetic acid esterification and alcoholysis of epoxides. It can also be readily isolated from the reaction mixture and reused three times without major decrease in its activity.     

Preparation of (Fe)MIL-101 on short carbon fibers to improve the flame retardancy,smoke suppression,and mechanical of epoxy resin

Nano (Fe)MIL-101 particles were grafted on the short carbon fibers (SCFs) by in situ growth method to prepare (Fe)MIL-101@SCFs. The flame-retarded composites of epoxy resin (EP) were fabricated with combination of (Fe)MIL-101@SCFs and ammonium polyphosphate (APP). The composites showed good flame retardancy, smoke suppression, and mechanical properties simultaneously. The main heat release rate peak of the flame-retarded composites was reduced and delayed evidently in comparison with pristine EP. The high amount of residual char with coherent and dense structure was formed owing to the catalytic char formation of (Fe)MIL-101 as well as the strengthening action of SCF. The improvement in mechanical properties of the flame-retarded composite was due to the reinforcement effects of (Fe)MIL-101@SCFs and its action of interfacial adjustment. This research solved the contradiction between the flame retardancy and mechanical properties of EP, and proposed a new method to prepare the mechanically reinforced and flame retardant EP.     

Enhancement of CO2 adsorption on nanoporous chromium terephthalate（MIL-101） by amine modification

Carbon dioxide(CO 2) adsorption on a standard metal-organic framework MIL-101 and a pentaethylenehexamine modified MIL-101(PEHAMIL-101) are investigated and compared in this study.The adsorbent samples were characterized by XRD,FT-IR and nitrogen adsorptiondesorption isotherms analysis.CO 2 adsorption capacity was measured by a volumetric method.MIL-101 and PEHA-MIL-101 exhibited CO 2 adsorption capacities of 0.85 and 1.3 mmol CO 2 /g adsorbent at 10 bar and 298 K,respectively.It is observed that CO 2 adsorption capacity was fairly improved about 50% after amine modification.     

In situ conversion builds MIL-101@NiFe-LDH heterojunction structures to enhance the oxygen evolution reaction

The construction of rich phase interfaces to increase active reaction area in hybrid materials is an excellent strategy to improve electrochemical performance. Under this guideline, MIL-101@OX-metal organic framework (MOF) is constructed by the "MOF on MOF" method, then converts to MIL-101@NiFe-layered double hydroxides (LDH) by in situ transformation in alkaline solution. MIL-101@NiFe-LDH shows excellent electrochemical water oxidation performance. It needs only an overpotential of 215 mV to drive 10 mA/cm² of oxygen evolution reaction (OER), which is less than that of NiFe-LDH, MIL-101. In addition, MIL-101@NiFe-LDH has the smallest Tafel slope (55.1 mV/dec) compared with NiFe-LDH (61.1 mV/dec), MIL-101 (150.8 mV/dec). The excellent water oxidation activity is due to the high phase interfaces derived from high specific surface area of MOF. This work offers an alternative method for making MOF/LDH heterostructures with an optimized phase interfaces and provides new insights for OER.     

Construction of Hyaluronic Acid-Covered Hierarchically Porous MIL-nanoMOF for Loading and Controlled Release of Doxorubicin

The porous nano-sized metal–organic framework (nanoMOF) and its proper surface modification could greatly promote the drug loading capability and introduce biocompatibility, biodegradability, and targeting functions into nano-drug delivery systems. Herein, the HACD@ADA-PA/MIL-101_NH₂ (Fe)-P nanoparticle was successfully fabricated through supramolecular and coordination interactions from three building blocks, including hierarchically porous MIL-101_NH₂ (Fe)-P nanoMOF, phosphite-modified adamantane (ADA-PA), and β-cyclodextrin (β-CD)-modified hyaluronic acid (HACD). The obtained HACD@ADA-PA/MIL-101_NH₂ (Fe)-P nanoparticle was nano-sized and highly stable in physiological fluids. The porous structure of HACD@ADA-PA/MIL-101_NH₂ (Fe)-P nanoparticle could effectively load the commercial chemotherapeutic drug doxorubicin (DOX) with an encapsulation rate of 41.20 % and a loading rate of 48.84 %. The obtained drug-loaded HACD@ADA-PA/MIL-101_NH₂ (Fe)-P@DOX nanoparticle was pH-sensitive and relatively stable at neutral condition (pH 7.2) but could release DOX in a controlled way in subacid solution at pH 5.7. The simulated in vitro DOX release experiment signified that the HACD@ADA-PA/MIL-101_NH₂ (Fe)-P@DOX nanoparticle could realize the controlled release of DOX in tumor issues.     

A surface architectured metal–organic framework for targeting delivery: Suppresses cancer growth and metastasis

Porous nanosized metal–organic frameworks (MOFs) are becoming possible candidates as drug-delivery nanocarriers for their versatile porous structures and large loadings of drugs. However, controlling synthesis of MOFs with uniform morphology, good biocompatibility and targeting drug delivery is still a challenge, which greatly limits their clinical applications. Herein, a multifunctional nano-sized drug-delivery material MIL-101(Fe)@FU@FA with a uniform particle size about 500 nm was successfully synthesized for targeting therapeutic purposes. The targeting reagent folic acid (FA) molecules are connected on the surface of 5-FU-loaded nanoparticle MIL-101(Fe)-NH₂ by a covalent conjugation. Cytotoxicity tests showed that the synthesized nanoparticles are biocompatible and can significantly inhibit cell proliferation on SMMC-7721 cells compared with MIL-101(Fe)@FU and free 5-FU. The cell metastasis and invasion experiments proved that the nanoparticles had a good anti-metastasis ability to tumor cells. Mechanistically, MIL-101(Fe)@FU@FA induces apoptosis of SMMC-7721 cells and block cell cycle progression in the G2/M phase. Taken together, the drug-loaded nanoparticles MIL-101(Fe)@FU@FA have the effect of targeting and sustained release to achieve the therapeutic effect.     

金属有机框架MIL-101(Fe)对水中微囊藻毒素-LR的吸附

通过溶剂热法制备了性质稳定的金属有机框架材料MIL-101(Fe),并用于吸附去除水中的微囊藻毒素-LR。采用电子显微镜、傅立叶变换红外光谱(FT-IR)、Zeta电位和N_2吸附-脱附等方法对制备的纳米材料进行了表征。MIL-101(Fe)具有多孔结构和较高的比表面积(375.2 m~2/g),尺寸约为500 nm。考察了pH值、离子强度、温度、吸附时间、浓度等参数对吸附剂吸附能力的影响。结果表明,静电作用和配位作用是主要的作用机理。MIL-101(Fe)对微囊藻毒素-LR的吸附速度很快(20 min内达到吸附平衡),吸附过程符合准二级动力学模型;MIL-101(Fe)对微囊藻毒素-LR表现出良好的吸附性能,其最大吸附量为256.4 mg/g。溶液中存在的腐植酸对MIL-101(Fe)的吸附性能产生一定的影响。受腐殖酸、盐类的影响,相同条件下MIL-101(Fe)对江水中微囊藻毒素-LR的吸附性能有所下降,但仍可达到68.1 mg/g。因此,该方法简便、高效,适用于快速除去污染水体中的微囊藻毒素-LR。     

A 3D MIL-101@rGO composite as catalyst for efficient conversion of straw cellulose into valuable organic acid

Efficient conversion of straw cellulose to chemicals or fuels is an attracting topic today for the utilization of biomass to substitute for fossil resources. The development of catalysts is of vital importance.In this work, a composite catalyst metal-organic frameworks(MOFs) immobilized on three-dimensional reduced graphene oxide(3D-r GO) were synthesized by in situ growth of the MIL-101(Cr) within the 3Dr GO matrix. The supporting of 3D-r GO guaranteed the dispersion and acid site density of MI...