Water transport in a polyketone terpolymer

Water transport in a polyketone terpolymer was analyzed performing both sorption and permeation experiments. Water vapor sorption tests were conducted at four temperatures (35, 45, 55, and 65°C) and at several activities. The analysis of sorption isotherms revealed the occurrence of water clustering. A reduction of the endothermicity of mixing as the amount of sorbed water increased was observed which is consistent with significant association of penetrant molecules in the polymer. Permeation experiments performed at 35°C at upstream pressures ranging from 4 to 25 Torr showed evidence of a reduction in water diffusivity as function of sorbed water concentration which is a typical indication of penetrant aggregation. © 1995 John Wiley & Sons, Inc.     

Synthesis of poly(biphenylene ketone)s via palladium catalyzed cross-coupling reactions with ketone diacetals

Dibromobenzophenone diacetals (BrC₆H₄)₂C(OR)₂ undergo cross-coupling reactions with (Bu₃SnC₆H₄)₂O in the presence of palladium catalysts to give poly (diacetal ether)s whose molecular weights reflect the solubility changes of the growing polymer chains as a function of the diacetal precursors, R = Me < 1/2 CH₂CH₂ < 1/2 CH₂CHMe and are significantly higher than those of polymers derived from dibromobenzophenone. New di-zinc reagents based on diacetal derivatives were synthesized and used as organometallic coupling reagents with a range of dibromoarenes, resulting in a series of previously inaccessible poly (biphenylene ketone)s and poly (biphenylene ketone sulfone)s. While poly (biphenylene ether ketone)s are insoluble, poly (biphenylene ketone)s readily dissolve in concentrated sulfuric acid. The effects of reaction parameters on the molecular weight of poly (biphenylene ketone) were determined. © 1994 John Wiley & Sons, Inc.     

Pd(Oac)2/(S)-P-PHOS催化的丙烯与CO交替共聚合成手性功能高分子

以丙烯和CO为原料,Pd(OAc)2/(S)-P-PHOS为手性催化剂,在有机溶剂中,经不对称交替共聚反应合成了手性功能高分子聚酮.当过量的还原剂LiAlH4和NaBH4分别还原聚酮时,手性聚醇产率达90%;当NaBH4/羰基摩尔比分别为0.5,1和2,紫外光谱(200～400am)检测证明,手性聚酮中羰基的29%,7...     

Copolymerization of carbon monoxide and norbornadiene with a palladium catalyst

Carbon monoxide (CO) and norbornadiene (NBD) with Pd(CH₃CN)₄(BF₄)₂ were copolymerized under various conditions at 50°C. Elemental analysis, infrared spectra, UV, Raman, and NMR spectra showed that the copolymers contained both ketone and unsaturated ring structures. Bidentate nitrogen ligands and phosphorus ligands proved to be more effective at stabilizing catalytic activity than monodentate arsenic ligands or phosphorus ligands. Methanol, protic acid, and an oxidant served as the coinitiator and chain transfer agent, respectively. X-ray diffraction analysis showed the copolymer to be partially crystalline. Thermogravimetric analysis showed that the TG curve for the NBD/CO copolymer has two stages with two maxima peaks at 251 and 470°C. This phenomenon was probably due to increased instability of the copolymers as CO content is increased. Hydrogenation of norbornadiene/CO copolymer with LiAlH₄ and Pd/C in THF yields a hydroxyl-containing polymer and norbornene/CO copolymer, respectively. © 1997 John Wiley & Sons, Inc. J Polym Sci A: Polym Chem 35: 1157–1166, 1997     

Catalytic carbonylation of ethylene in the presence of the Pd(acac)2-m-Ph2PC6H4SO3Na(H)-AcOH system

Catalytic systems based on phosphine complexes of palladium have been developed for synthesizing propionic acid (monocarbonylation) and alternating (11) ethylene-carbon monoxide copolymers,i.e., polyketones (polycarbonylation).m-(Diphenylphosphino)benzenesulfonic acid or its sodium salt were used as ligands. Monocarbonylation proceeds at atmospheric pressure in dioxane or acetic acid solvents. Under high pressure, the reaction pathway can change from monocarbonylation, which occurs in the presense of the sodium salt of the ligand, to polycarbonylation when the sodium ion at the sulfo group is completely replaced by a proton. This change in reaction selectivity is observed when the process is performed in acetic acid. When the ligand is present both in the acid and the neutral form, products of di- and oligocarbonylation are formed along with propionic acid and the polyketone. These products were characterized by¹H and¹³C NMR spectra as alternating keto acids C₂H₅(COCH₂CH₂) _n COOH, wheren=1÷3. Kinetic equations were derived for the selective synthesis of propionic acid and polyketones.Translated fromIzvestiya Akademii Nauk. Seriya Khimicheskaya, No. 3, pp. 401–404, March, 1994.The authors are grateful to V. A. Zavel'skii who recorded the 1H NMR spectra on a Bruker CXP-200 spectrometer.     

Transport properties of uniaxially oriented aliphatic polyketone

The oxygen, carbon dioxide, and water‐transport properties of a uniaxially oriented aliphatic polyketone were determined. The polyketone was drawn to 5–10 times its original length. The transport properties were related to changes in crystallinity estimated by differential scanning calorimetry and density measurements and by changes in the molecular and crystal orientation assessed by, respectively, infrared and X‐ray spectroscopy. The film structures were characterized by confocal scanning laser microscopy and scanning electron microscopy. Stress‐strain tests on the drawn specimens enabled the impacts of orientation on the transport and mechanical properties to be compared. A draw‐induced increase in crystallinity and molecular orientation yielded permeabilities at a draw ratio of 10 that were 30–40% of the original value, and the percentage decrease was basically independent of the type of gas/vapor molecule. Also, the diffusivities of oxygen and carbon dioxide decreased by an order of magnitude. The fact that the amorphous permeability was peaking at a draw ratio of about 5 was a consequence of a peak in amorphous solubility, which was very high for oxygen and absent for water. It was suggested that the peak in solubility was mainly caused by the destruction of the polymer hydrogen‐bond network during drawing and crystal reorientation. The impact of structural reorganization within the polymer and presence of surface valleys seemed to have less impact on the mechanical properties than on the transport properties. This suggested that transport data are more sensitive than mechanical data in probing material defects and changes in molecular packing and morphology. © 2004 Wiley Periodicals, Inc. J Polym Sci Part B: Polym Phys 42: 947–955, 2004     

Copolymerization of carbon monoxide with 1,3-cyclopentadiene by palladium complexes

Copolymerization of carbon monoxide with 1,3-cyclopentadiene (CPD) by palladium complexes, [Pd(CH₃CN)_4?n (PPh₃)n] (BF₄)₂, n = 1–3 (especially n = 1), was studied at 60°C. Results of elementary analysis, infrared spectra, and NMR spectra showed that copolymers containing ketone and ring structures were produced. Phosphorus compounds such as PPh₃ were found to be more effective stabilizing ligands for the catalytic activity compared to arsenic or nitric ligands. A higher activity of the catalyst for the copolymerization of CPD with carbon monoxide was observed in noncoordinating solvents such as CHCl₃ even at a pressure as low as 300 psi. The amount of 1,2 structure for the CPD-CO copolymer increased as the polarity of solvent increased. The copolymer was confirmed to be partially crystalline by the x-ray diffraction. TGA shows that weight loss of copolymer starts at 120°C and the maximum peak of decomposition occurs at 469°C. © 1993 John Wiley & Sons, Inc.     

Copolymerization of carbon monoxide and 4-vinylcyclohexene with a palladium catalyst

In this work, carbon monoxide (CO) and 4-vinylcyclohexene (VCH) with [Pd(CH₃CN)₄](BF₄)₂ were copolymerized under various conditions at 60°C. Elemental analysis and infrared, UV, and NMR spectra indicated that copolymers containing a ketone and a cyclic structure of cyclohexyl and norbornane groups are produced. Bidentate nitrogen ligands proved to be more effective at stabilizing catalytic activity than monodentate phosphorus or nitrogen ligands. Also, the bulk substituent on the bidentate ligand led to inactive catalysts. Methanol served as the coinitiator and chain transfer agent. Increasing the concentration of 4-vinylcyclohexene caused the copolymer's CO content to be enhanced. TGA revealed that the copolymer's mass loss starts at 120°C and the maximum peak of decomposition occurs at 450°C. Moreover, X-ray diffraction analysis demonstrated the copolymer to be partially crystalline. Furthermore, reduction of 4-vinylcyclohexene/CO copolymer with LiAlH₄ in THF yields a hydroxyl-containing polymer. © 1997 John Wiley & Sons, Inc. J Polym Sci A: Polym Chem 35 : 2759–2768, 1997     

手性钯(Ⅱ)配合物及BF3·Et2O助剂催化的丙烯与一氧化碳立体选择性交替共聚反应研究

BF3·Et2O助催化剂加速了[L2]Pd (OAC)2(L:手性双瞵配体)催化的丙烯与一氧化碳立体选择性交替共聚反应,在相对较短的时间里合成了手性聚酮高分子,13C NMR和1H NMR,及摩尔旋光度证实产物具有较高的区域规整度和立构规整度,红外光谱指出产物同时具有螺旋缩酮和交替聚酮结构,凝胶渗透色谱法测定产物具有较低的分子量和宽的聚合度。     

Exploitation of a promising flame‐retardant engineering plastics by molten composited polyketone and diethyl zinc phosphinate

Aliphatic polyketone (POK) is a new engineering plastic owning outstanding mechanics, chemical resistance, and gas/liquid barrier properties. However, analogous to other polymers, the nature of combustion severely restricts the widespread application of POK. Herein, the diethyl zinc phosphinate (ZnPi) was compounded with three grades of POKs, which were different among each other in viscosity as low (L), medium (M), and high (H) levels, by melt mixing. It is intriguing to suggest that increasing the viscosity of POK could remarkably improve the dispersion homogeneity of ZnPi, which was beneficial to superior flame retardancy, simultaneously with comprehensive mechanical properties. For the H‐POK matrix, only 10% well‐dispersed ZnPi resulted in a V0 ranking with a good maintenance of its notched impact strength, whereas the load of ZnPi for reaching V0 rank increased to 14% in L‐POKs and M‐POKs and the mechanical performances decreased mildly. By a combination of scanning electron microscopy (SEM), Fourier‐transform infrared (FTIR), thermogravimetric analysis (TGA), and cone calorimetry, it is well revealed that the flame retardancy induced by adding ZnPi could mainly ascribe to the formation of various zinc phosphate species. This work exploits a facile and feasible method for fabrication of antiflame engineering plastics, which will be promising for large‐scale applicability of high‐performance POK materials.