SiO_2负载的磺化三苯膦铑配合物催化高碳烯氢甲酰化及反应中的氘逆同位素效应

水溶性磺化三苯膦铑配合物担载在SiO_2表面制得的负载化水溶性Wilkinson催化剂具较大的比表面积,当1-己烯、1-辛烯、1-庚烯和十一烯酸甲酯等液态高碳烯烃在这种催化剂上于固定床加压流动态反应器中连续进行氢甲酰化催化反应时,产物醛的选择性98～100%,并可在适当过量配体存在下保持较高的催化活性.在这种催化剂上分别于CO用/H_2和CO/D_2气氛下进行烯烃氢甲酰化反应,可观察到显著的氘逆同位素效应.根据分析,初步认为酰基物中间体氢解反应可能是SiO_2负载的磺化三苯膦铑配合物催化剂上高碳烯氢甲酰化的速控步骤.     

铑/双膦配体催化均相内烯烃氢甲酰化反应的研究进展

烯烃氢甲酰化反应是工业上合成醛的重要方法.由于双膦配体良好的配位能力,形成的铑配合物有很好的催化活性,在内烯烃氢甲酰化反应中,可以有效地提高直链醛选择性.本文系统地综述了近年来双膦配体铑配合物催化均相内烯烃氢甲酰化反应的研究进展,讨论了双膦配体结构对催化剂活性和生成直链醛选择性的影响.     

两相催化体系中双子表面活性剂对1-十二烯氢甲酰化反应的促进作用

报道了水溶性铑膦配合物组成的复合催化体系催化1-十二烯氢甲酰化反应中,双子表面活性剂[二溴化-(N,N,N′,N′-四甲基)-N,N′-二(十六烷基)-乙二铵]形成胶束的助催化作用.结果表明,在水/有机两相中,双子表面活性剂比单链表面活性剂CTAB具有更好加速催化反应的作用,并使烯烃氢甲酰化的区域选择性显著提高.这归因于双子表面活性剂有较低的cmc,可形成更加紧密规整的胶束结构,有利于增溶在胶束中的烯烃与铑催化剂配位和生成正构醛.     

SiO2负载的磺化三苯膦铑配合物催化高碳烯氢甲酰化

本文将水溶性磺化三苯基膦铑配合物催化剂负载在SiO_2表面使其复相化,考察不同制备方法制得催化剂的性能及对反应活性和选择性的影响。这种负载化水溶性Wilkinson催化剂比表面积较大,可在适当过量配体存在下保持较高的催化活性;当液态高碳烯烃十一烯酸甲酯和1-己烯在固定床加压流动态反应器中连续进行氢甲酰化催化反应时,产物醛的选择性大于95%;正异醛比(n/i值)随P/Rh摩尔比的提高而提高P/Rh=15,产物中正构醛大于或接近80%(n/i为4)。P/Rh>15后,配体增多几乎不再提高产物n/i值,而影响反应速度。     

金属离子对RhCl（CO）（TPPTS）2催化1—己烯氢甲酰化反应的影响

在以水溶性铑－膦配合物为催化剂的烯烃氢甲酰化反应中,铑的存在形态及配位结构对烯烃氢甲酰化反应的转化率及选择性起着决定性的作用．在反应过程中,特别是工业生产过程中,会由于各种原因导致一些杂质进入反应体系,这些杂质可能会影响铑－膦配合物催化剂的性质,改变...     

水溶性铑膦配合物催化烯烃氢甲酰化反应研究进展

 水/有机两相体系中水溶性铑膦配合物催化的烯烃氢甲酰化反应由于具有环境友好和催化剂容易分离等优点而受到广泛关注. 其中水溶性催化剂体系已经用于丙烯氢甲酰化反应制备丁醛的工业化生产. 然而, 长链烯烃在含有催化剂的水相中溶解性较差, 反应速率较慢. 综述了有关加速水/有机两相体系中长链烯烃氢甲酰化反应的方法和进展, 包括使用具有表面活性的膦配体, 以及在催化体系中添加环糊精和表面活性剂等促进剂. 另外, 还讨论了有关内烯烃氢甲酰化反应和提高直链醛选择性的方法.     

超细SiO2负载型水溶性铑膦配合物催化剂研究

用超细SiO2负载水溶性铑膦配合物,并研究其对1-已烯氢甲酰化的催化性能。结果表明,粒径为10-20nm的超细SiO2负载水溶性铑膦配合物所表现的催化活性比颗粒SiO2负载型催化剂高3倍多,且可在较宽的含水量范围内保持高反应活性。当膦铑摩尔比为50,超细SiO2负载型催化剂含水量为25%-55%（质量分数）、烯铑摩尔比为2500、反应温度373K和CO/H2（1/1,体积比）压力4.0MPa的反应条件下,其1-已烯氢甲酰化的反应转化数为450h^-1,产物醛的选择性为100%,醛的n/i比值达3.2。     

聚乙二醇-水反应介质中长链烯烃的氢甲酰化反应

以聚乙二醇(PEG)为反应介质,考察了水溶性铑膦络合物RhCl(CO)(TPPTS)2 (TPPTS为间-三苯基膦三磺酸钠)对长链烯烃氢甲酰化反应的催化性能. 结果表明,添加适量的水于PEG中对催化剂活性有重要影响. 以PEG-400-H2O为溶剂的催化体系对 1-十二烯氢甲酰化反应的催化活性较高,在100 ℃, 5 0 MPa的优化条件下, 1-十二烯的转化率可达到92 6%, 生成醛的选择性为95 8%. 反应完成后,含水溶性铑膦络合物的PEG-水溶液与含产物的有机相分离方便,易于实现催化剂的循环使用,催化剂重复使用8次,未观察到活性和选择性下降.     

长链烷基二苯基膦—铑配合物催化烯烃氢甲酰化反应研究

研究了烷基二苯基膦-铑配合物RhCl(CO0(n-C8H17PPh2)2(1)和RhCl(Co)(n-C12H25PPh2)2（2）对1-辛烯氢甲酰化反应的催化性能。结果表明,配合物1比2具有更高的催化活性,而配合物2对生成正构醛的选择性更好;当催化剂浓度或膦/铑比增加时,配合物2催化成正构醛的选择性呈下降趋势,显示出与以PPh3为配体时的不同的性能。     

室温离子液体中水溶性铑膦配合物催化1-己烯氢甲酰化反应的研究

研究了水溶性膦配体铑配合物在若干离子液体中的1-己烯氢甲酰化反应性能．通过改变离子液体的阴阳离子结构，可使水溶性TPPTS-铑配合物在离子液体中表现出较高的卜己烯氢甲酰化反应活性和选择性；在[BMI]BF4离子液体中加入适量的水，可提高TPPTS-铑配合物的催化活性；在[BMI]BF4离子液体中，水／有机两亲性膦配体与铑形成的配合物，反应后催化剂与产物自动分层，实现催化剂的循环使用．本文结果表明，水溶性膦配体铑配合物的催化活性与其在离子液体中的溶解度密切相关．     

负载水溶性铑－膦配合物催化1－己烯氢甲酰化反应的研究

将水溶性铑－膦配合物Ｒｈｃｉ（ＣＯ）（ＴＰＰＴＳ）＿２（ＴＰＰＴＳ：Ｐ－（ｍ－Ｃ＿６Ｈ＿４ＳＯ＿３Ｎａ）＿３）负载于扩孔硅胶上，制成负载水相催化剂（ＳＡＰＣ），在高压反应釜中研究其催化１－己烯氢甲酰化的性能。结果表明，催化剂的水含量对其活性影响很大，在一较窄的水含量范围内（２５—３５ｗｔ％），催化剂活性急剧增大，且存在一极大值，表现出水膜催化剂的特性。反应温度、总压和ＣＯ／Ｈ＿２分压、Ｒｈ／Ｐ比的影响，与使用烃溶性能。三苯膦络合催化剂时有类似规律，溶剂的影响不明显，实验证明，ＳＡＰＣ具有良好催化活性，ＳｉＯ＿２上负载的铑配合物不会被原料和产物洗提而造成流失，有利于催化剂的稳定和重复使用。     

Recycle and recovery of rhodium complexes with water-soluble and amphiphilic phosphines in ionic liquids for hydroformylation of 1-hexene

A biphasic catalysis system composed of ionic liquid and rhodium complexes with water-soluble or amphiphilic phosphine ligands bearing water-soluble groups of sodium sulfonate have been employed for hydroformylation of 1-hexene. The experimental results show that the activity is almost independent of the hydrotropicity of the phosphine ligands in BMI·BF₄. In this system, the extraction of phosphine species by the organics from the IL phase was quite low but larger than that of rhodium species and showed rather good stability of catalytic activity. A slight decrease in the aldehyde n/i ratio during the catalyst reuse could be recovered, in part, by replenishing certain amount of ligand into the used catalyst system.     

硅胶键合膦的制备及其对铑络合物催化1-辛烯氢甲酰化反应的影响

以硅胶为载体, 采用键合接枝法将2-(二苯膦基)乙基三乙氧基硅烷(DPPES)共价键合于硅胶表面, 制备了性能优良的硅胶键合型膦配体(以SiO₂(PPh₂)表示). 以SiO₂(PPh₂)为配体, Rh(acac)(CO)₂ (acac:乙酰丙酮)为催化前体, 负载铑膦络合物催化剂(SiO₂(PPh₂)/Rh)在1-辛烯氢甲酰化反应中原位生成. 对生成的负载型催化剂和硅胶键合型膦配体进行了傅里叶变换红外(FTIR)光谱表征, 考察了膦/铑摩尔浓度比([P]/[Rh])、温度等因素对铑催化的长链1-辛烯氢甲酰化反应的影响. 结果表明, 膦/铑摩尔浓度比的增加能显著提高反应的成醛选择性, 降低铑的流失. 在[P]/[Rh]=12、363 K、2.0 MPa、1.5 h 的温和反应条件下, 1-辛烯转化率和成醛选择性分别可达98.4%和95.3%, 其催化活性与DPPES或三苯基膦(TPP)作配体时的均相铑催化相近. 催化剂循环4 次后, 反应活性无明显下降, 1-辛烯转化率均在97.0%左右, 经电感耦合等离子体原子发射光谱(ICP-AES)检测,有机相中铑流失低于0.1%.     

Studies on the Recycling Efficiency of Thermoregulated Phase-separable Rh/PETPP Complex Catalyst

Effects on the recycling efficiency of thermoregulated phase-separable Rh/PETPP(P-[p-C6H4O(CH2CH2O)nH]3,N=3n) complex catalyst involved in hydroformylation of 1-decene are for the first time presented.It was found that the loss of Rh is dependent greatly on the composition of phosphine ligand PETPP and the organic solvent employed in the reaction.     

Importance of interfacial adsorption in the biphasic hydroformylation of higher olefins promoted by cyclodextrins: a molecular dynamics study at the decene/water interface

We report herein a molecular dynamics study of the main species involved in the hydroformylation of higher olefins promoted by cyclodextrins in 1-decene/water biphasic systems at a temperature of 350 K. The two liquids form a well-defined sharp interface of approximately 7 A width in the absence of solute; the decene molecules are generally oriented "parallel" to the interface where they display transient contacts with water. We first focused on rhodium complexes bearing water-soluble TPPTS(3-) ligands (where TPPTS(3-) represents tris(m-sulfonatophenyl)phosphine) involved in the early steps of the reaction. The most important finding concerned the surface activity of the "active" form of the catalyst [RhH(CO)(TPPTS)(2)](6-), the [RhH(CO)(2)(TPPTS)(2)](6-) complex, and the key reaction intermediate [RhH(CO)(TPPTS)(2)(decene)](6-) (with the olefin pi-coordinated to the metal center) which are adsorbed at the water side of the interface in spite of their -6 charge. The free TPPTS(3-) ligands themselves are also surface-active, whereas the -9 charged catalyst precursor [RhH(CO)(TPPTS)(3)](9-) prefers to be solubilized in water. The role of cyclodextrins was then investigated by performing simulations on 2,6-dimethyl-beta-cyclodextrin ("CD") and its inclusion complexes with the reactant (1-decene), a reaction product (undecanal), and the corresponding key reaction intermediate [RhH(CO)(TPPTS)(2)(decene)](6-) as guests; they were all shown to be surface-active and prefer the interface over the bulk aqueous phase. These results suggest that the biphasic hydroformylation of higher olefins takes place "right" at the interface and that the CDs promote the "meeting" of the olefin and the catalyst in this peculiar region of the solution by forming inclusion complexes "preorganized" for the reaction. Our results thus point to the importance of adsorption at the liquid/liquid interface in this important phase-transfer-catalyzed reaction.     

担载型水溶性膦铑配合物催化剂研究

烯类氢甲酰化反应包括了均相催化的某些重要应用。含贵金属和贵重配体的均相催化剂与产物的分离及制备高活性、高选择性、高稳定性催化剂,是均相催化及其多相化最活跃的研究领域之一。对于氢甲酰化催化剂多相化,在基础研究和技术上都仍存在如何解决好催化活性、反应选择性变化或金属流失等问题。将HRh(CO)[P(m-C_6H_4SO_33Na)_3]_3担载在亲水性     

聚-4-氧杂-6,7-双二苯膦基庚基硅氧烷铑配合物的合成及其催化硅氢化性能

4-氧杂-6,7-二氯庚基三甲氧基硅烷依次与二苯膦钾、气相法二氧化硅、三氯化铑作用,合成了聚-4-氧杂-6,7-双二苯膦基庚基硅氧烷铑配合物。它对烯烃与取代烯烃的硅氢化反应具有良好的催化活性。     

Micellar effect in hydroformylation of high olefin catalysed by water-soluble rhodium complexes associated with sulfonated diphosphines

High linear alkenes (1-octene and 1-decene) have been hydroformylated using water-soluble rhodium complexes associated with sulfonated diphosphines in the presence of ionic surfactants or methanol. In all cases, the hydroformylation activities were higher than in experiments without additives. The selectivity in aldehydes was higher when we used cetyltrimethylammonium hydrogensulfate (CTAHSO₄) as the surfactant or methanol as the co-solvent.     

水/有机两相体系中单萜烯烃的氢甲酰化反应

考察了水溶性铑膦络合物RhCl(CO)(TPPTS)2(TPPTS为间-三苯基膦三磺酸钠)在水/有机两相体系中对不同单萜烯的氢甲酰化反应的催化性能.结果表明,添加表面活性剂对催化活性影响很大.在8.0 MPa,100℃的条件下,该催化体系对萜烯氢甲酰化反应具有较好的催化活性,月桂烯、莰烯和艹宁烯的转化率可分别达到92%,72%和86%.反应完成后,含水溶性铑膦络合物的水溶液与含产物的有机相分离方便,催化剂重复使用8次,其活性和选择性均未明显下降,易于实现催化剂的循环使用.     

MCM‐41‐Supported Bidentate Phosphine Rhodium Complex: An Efficient and Recyclable Heterogeneous Catalyst for the Hydrosilylation of Olefins

MCM‐41‐supported bidentate phosphine rhodium complex (MCM‐41‐2P‐RhCl₃) was conveniently synthesized from commercially available and cheapγ‐aminopropyltriethoxysilane via immobilization on MCM‐41, followed by reacting with diphenylphosphinomethanol and rhodium chloride. It was found that the title complex is a highly efficient catalyst for the hydrosilylation of olefins with triethoxysilane and can be recovered and recycled by a simple filtration of the reaction solution and used for at least 10 consecutive trials without any decreases in activity.