二硝基苯乙基氟代膦酸二乙酯的制备

在室温下,二氟溴甲基膦酸二乙酯与锌粉反应生成锌试剂;2,4-二硝基氯化苄与合成的锌试剂在溴化亚铜催化作用下即可反应生成二硝基苯乙基(氟代)磷酸二乙酯化合物。两步反应都可在室温下进行,操作简单易行。     

2-二氟溴甲基-1,3-苯并噻唑的简便合成

本文应用二氟溴乙酸作为二氟溴甲基的合成子,实现了2 巯基芳胺与二氟溴乙酸的缩合反应合成2-二氟溴甲基-1,3-苯并噻唑。该反应以5当量二氟溴乙酸,氯苯为溶剂,于100 ℃下与2-巯基芳胺反应18~40 h,产率高达88%。目标产物通过核磁共振和高分辨质谱表征。该反应条件温和,是对现有合成2-二氟溴甲基-1,3-苯并噻唑的良好补充。     

2-溴-4,4'-二硝基-3'-二甲基锍-2'-联苯酚内盐的合成、结构及性质的研究

在胺存在下,3,7-二硝基二苯并溴五环硫酸氢盐与二甲基亚砜反应生成2-溴-4,4'-二硝基-3'-二甲基锍-2'-联苯酚内盐(3).3的X射线晶体结构分析数据表明其分子具有内盐结构但酚氧负离子的负电荷是部分离域的,分子内两苯环所成的两面角为117.3°.3在熔解时发生重排及热分解分别生成2-溴-2'-甲氧基-3'-甲硫基-4,4'-二硝基联苯(6)及3,7-二硝基-4-甲硫基-二苯并呋喃(7).3与盐酸反应生成相应的锍盐(8).     

2,5-二溴-4-硝基咪唑的合成

以咪唑为原料,经硝化和溴化反应合成了抗炎药物中间体——2,5-二溴-4-硝基咪唑,总收率80.3%,其结构经1H NMR和IR确认。     

N,N-二(2-羟乙基)氨甲基膦酸二乙酯的合成

改进了非卤反应型阻燃剂N,N-二(2-羟基乙基)氨甲基膦酸二乙酯(BHAPE)的合成方法.在35℃左右将二乙醇胺滴入37%~40%的甲醛水溶液中,加毕,于40~45℃继续保温反应2 h,然后于80~82℃,小于0.094 MPa,减压蒸馏直到没有馏分为止,得到中间体3-(2-羟基乙基)-1,3-氧氮杂环戊烷(HENH).向HENH中加入阳离子交换树脂催化剂,于55~62℃滴入亚磷酸二乙酯,加毕,于60~62℃保温反应2 h,降到室温,过滤回收催化剂,得黄色透明液体产品,收率98.5%.用元素分析、红外光谱和核磁共振谱表征了中间体和标题化合物.     

2-溴甲基-3-(二溴甲基)喹喔啉的合成研究

以2，3－二（溴甲基）喹喔啉为原料，以N－溴琥珀酰亚胺为溴化试剂合成了2－溴甲基－3－（二溴甲基）喹喔啉（1），1是Diels-Alder环加成反应中形成含杂原子环的C60衍生物的一种重要中间体。通过IR，^1H NMR,^13C NMR,DEPT谱和MS对其进行了结构表征。     

2α-甲基-2β-溴甲基青霉烷酸二苯甲酯的合成

以6,6-二氢青霉烷酸二苯甲酯-1-氧化物(Ⅰ)和2-巯基苯并噻唑为原料,通过热裂解开环反应和溴代环合反应,制备得到了β-内酰胺酶抑制剂他唑巴坦关键中间体2α-甲基-2β-溴甲基青霉烷酸二苯甲酯(Ⅲ)。考察了反应温度、反应时间、物料比、催化剂用量对目标产物的影响。结果表明,在n(Ⅱ)∶n(HBr)∶n(Na NO_2)=1∶3∶6,催化剂质量分数为4%,-5℃反应2. 5h的条件下,收率为85. 4%。产物结构经1HNMR、FTIR、MS等技术手段得到验证。     

二(2,4,4-三甲基戊基)膦酸萃取分离稀土元素(Ⅲ)的研究

本文研究了二(2,4,4-三甲基戊基)磷酸(Cyanex 272)的煤油溶液在不同介质(HCI,HNO_3)中对三价混合稀土的萃取分离性能.观测了平衡水相酸度对萃取平衡的影响,由酸度曲线求出相邻元素的平均分离系数,并考察了酸度对反萃取平衡的影响.比较了HCI和HNO_3介质中,Cyanex 272对混合稀土(Ⅲ)的萃取性能.     

2-溴-4-甲基苯酚的合成

2-溴-4-甲基苯酚是合成许多药物及广谱型香料香兰素的重要中间体。常温下,以对甲基苯酚为原料加溴易生成2,6-二溴-4-甲基苯酚,本文在原来工作的基础上,在低温下,通过溴化氧化一步直接合成了2-溴-4-甲基苯酚,产率可达93％并通过红外光谱和核磁共振谱对产物结构进行确证。反应的最佳条件是：反应温度为-5～-10℃,反应时间为4h,搅拌速度为1000r／min,对甲基苯酚与双氧水物质的量比为1：0．85。反应方程式如下：     

Nucleophilic activity of peroxyhydrocarbonate and peroxocarbonate ions relative to 4-nitrophenyl diethyl phosphonate

Peroxocarbonate ions HCO ₄ ^? and CO ₄ ^2? , which are formed in the H₂O₂/NH₄HCO₃/HO^? system, react with 4-nitrophenyl diethyl phosphonate (I) through a nucleophilic mechanism with rate constants \(k_{HCO_4^ - } = 0.008\) and \(k_{CO_4^{2 - } } = 0.13 L/mol \cdot s\). Comparison of these constants with the corresponding constants of other inorganic anions in their reaction with I in the framework of the Brönsted equation indicates that HCO ₄ ^? and CO ₄ ^2? are typical α-nucleophiles.     

Synthesis and Crystal Structure of Diethyl (4,6-diamino-1,3,5-triazine-2-yl) phosphonate

1　INTRODUCTIONSomeoforganophosphoruscompounds,includingmanyheterocycliccompoundscontainingphosphonogroup,havegoodbioactivityinorganism[1].Duetotheirrela-tionwithbiochemical/biological,pharmacologicalandpesticidalresearch,hetero-cycliccompoundscontainingphosphonogrouphavebeensynthesizedbysomeofnewsyntheticmethods,inwhichseveralnewbuildingblockwereused,suchasβ-phos-phonicenemines,[2,3]isocyanomethylphosphonate,[4]β-functionalγ-oxo-alkylphos-phonates,[5]andacetylenicphosphonate.[6]Inourpr…     

Synthesis and characterization of poly (styrene-co-vinyl phosphonate) ionomers

Poly(styrene-co-diethyl vinylphosphonate) copolymers were synthesized by free radical copolymerization. The ester groups of the copolymers were hydrolyzed to phosphonic acid groups, and the sodium and zinc salts ionomers were obtained by neutralization. The structure and the thermal and viscoelastic properties of the copolymers and ionomers were characterized by nuclear magnetic resonance, Fourier transform infrared spectroscopy, differential scanning calorimetry, dynamic mechanical analysis, and small-angle X-ray scattering. The phosphonate ester lowered the glass transition temperature (T_g) of polystyrene. The free acid derivatives and metal phosphonates increased T_g and produced a rubbery plateau region in the viscoelastic properties due to the formation of a physical network. The acid and salt ionomers exhibited microphase-separated morphologies and were thermorheologically complex. The phosphonic acid derivatives absorbed relatively little water, even for materials with ion-exchange capacities greater than 1.0 mEq/g, and were not conductive, which made them unsuitable for application as proton exchange membranes. © 2004 Wiley Periodicals, Inc. J Polym Sci Part B: Polym Phys 42: 3628–3641, 2004     

十二水合硫酸铁铵催化合成己二酸二乙酯的研究

以十二水合硫酸铁胺为催化剂合成了己二酸二乙酯,确定了酯化优化条件。实验结果表明,催化剂的催化活性高,反应条件温和,方法简便,酯化率优良。     

Thermal degradation and flame retardance in copolymers of methyl methacrylate with diethyl(methacryloyloxymethyl)phosphonate

Methyl methacrylate (MMA) has been free radically copolymerized, both in bulk and in solution, with diethyl(methacryloyloxymethyl)phosphonate (DEMMP), to give polymers which are significantly flame retarded when compared with PMMA, as indicated by the results of limiting oxygen index (LOI) measurements, UL 94 tests, and the results of cone calorimetric experiments. The physical and mechanical properties of the copolymers are similar to those of PMMA, except that the bulk copolymers are slightly crosslinked, and are better than those of PMMA flame retarded to a similar extent by some phosphate and phosphonate additives. Examination of the some of the gaseous products of pyrolysis and combustion, and of chars produced on burning, show that flame retardation occurs in the copolymers by both a condensed-phase and a vapour-phase mechanism. The condensed-phase mechanism is shown to involve generation of phosphorus acid species followed by reaction of these with MMA units giving rise to methacrylic acid units. The methacrylic acid units subsequently form anhydride links, which probably impede depolymerization of the remaining MMA sequences, resulting in evolution of less MMA (the major fuel when MMA-based polymers burn). By undergoing decarboxylation, leading to interchain cyclisation and, eventually, to aromaticisation, the anhydride units are probably also the principal precursors to char.     

Hydrothermal synthesis,crystal structure and magnetic properties of a copper(II) phosphonate

The treatment of 3-ammonium-1-hydroxypropylidene-1,1′-bisphosphonate (H₇ahdp) and 4,4′-bipy with CuCl₂?·?2H₂O resulted in a metal phosphonate [Cu(H₅ahdp)?·?H₂O] _n . Its crystal structure has been characterized by single X-ray crystallography. Although there is no 4,4′-bipy in the lattice structure, it plays a very important role in forming the one-dimensional chain of the polymer. Hydrogen bonds link the chains into a 3D network. The dinuclear secondary building units are observed in the compound. The determination of variable-temperature magnetic susceptibilities (5?～?300?K) shows weak intrachain antiferromagnetic coupling between copper(II) centers. The magnetic data were fitted to the appropriate equations derived from the Hamiltonian H?=??2JS ₁ S ₂, giving the parameter J?=??25.78?cm^?1. Its thermal properties were also investigated.     

新型阻燃剂1 ,3 ,5-三(5 ,5-二甲基-1 ,3-二氧杂己内磷酸酯基)苯的合成及表征

以1,3,5-三羟基苯、新戊二醇、三氯氧磷等为原料,采用简洁、高效的合成路线,通过两步反应合成了新型阻燃剂1,3,5-三(5,5-二甲基-1,3-二氧杂己内磷酸酯基)苯.通过红外光谱、核磁共振氢谱、质谱、元素分析以及热失重分析等对产物结构和热性能进行了表征和研究.热失重分析表明:该阻燃剂起始分解温度为295.26℃ ,在295.26℃ ~343.38℃和350.40℃ ~578.04℃温区迅速炭化;当阻燃剂被加热到681.03℃时,炭残余量高达43.33 %.     

Graft copolymers of natural rubber and poly(dimethyl(acryloyloxymethyl)phosphonate) (NR-g-PDMAMP) or poly(dimethyl(methacryloyloxyethyl)phosphonate) (NR-g-PDMMEP) from photopolymerization in latex medium

Graft copolymers of natural rubber and poly(dimethyl(acryloyloxymethyl)phosphonate) (NR-g-PDMAMP), and natural rubber and poly(dimethyl(methacryloyloxyethyl)phosphonate) (NR-g-PDMMEP), were prepared in latex medium via a “grafting from” methodology based on the photopolymerization of dimethyl(acryloyloxymethyl)phosphonate (DMAMP) and dimethyl(methacryloyloxyethyl) phosphonate (DMMEP), respectively, used as phosphorus-containing monomers. The grafting polymerization was initiated from N,N-diethyldithiocarbamate groups previously bound in side position of the rubber chains. The effects of monomer concentration on monomer conversion and grafting rate were investigated, showing that conversion and grafting rate increased with increasing monomer concentration and reaction time. Highest conversions and grafting rates were obtained with a molar ratio [DMAMP]/[initiating units] = 7 for a reaction time of 180 min. Calculation of the graft average length () from ¹H NMR spectra of the synthesized graft copolymers showed values were in the range of 9-73. Visualizations of NR-g-PDMAMP and NR-g-PDMMEP latices by Transmission Electron Microscopy (TEM) showed that they exhibit core-shell morphologies. Degradation of NR-g-PDMAMP and NR-g-PDMMEP occurred in two steps: decomposition of dimethylphosphonate-functionalized grafts took place prior to the second step corresponding to the decomposition of NR backbone, but the degradation temperature of this last step was higher than that of pure NR.     

Study of intramolecular competition between carboxylate and phosphonate for Pt(II) with the aid of a novel tridentate carboxylato-thioether-phosphonato ligand

The tridentate dianionic ligand 2-[2'-(hydroxyisopropoxyphosphoryl)phenylsulfanyl]benzoate (L(2-)) reacts with cis-[Pt(NH(3))(2)(H(2)O)(2)](2+) to form an S,O-chelate in which the O-coordinated group is either carboxylate or phosphonate, depending on the degree of protonation of the complex. Carboxylate appears to be the stronger ligand, and the stoichiometric reaction between cis-[Pt(NH(3))(2)(H(2)O)(2)](2+) and L(2-) yields the neutral species [Pt(L)(NH(3))(2)], with L bound by sulfanyl and carboxylate groups, both in solution and in the solid state. Upon protonation of [Pt(L)(NH(3))(2)], the stronger basicity of the carboxylate causes the Pt coordination to switch from carboxylate to phosphonate, and the uncoordinated carboxylate group becomes protonated. In methanolic solution, the first-order kinetics of this rearrangement could be observed by (31)P NMR spectroscopy. Both complexes-the carboxylate-bound neutral complex [Pt(L)(NH(3))(2)].H(2)O (triclinic, P1 (no. 2), a=9.529(6), b=9.766(6), c=12.299(7) angstroms, alpha=106.91(2), beta=101.71(2), gamma=102.05(2) degrees, Z=2) and the perchlorate salt of the phosphonate-bound complex [Pt(LH)(NH(3))(2)]ClO(4).H(2)O (monoclinic, P2(1)/c (no. 14), a=12.095(2), b=14.046(2), c=14.448(2) angstroms, beta=95.55(2) degrees, Z=4)-were characterized by X-ray crystallography.