6-三氟甲基嘧啶-2,4(1H,3H)-二酮类化合物的合成及其除草活性

以三氟乙酰乙酸乙酯和单取代脲为原料,设计并合成了10个6-三氟甲基嘧啶-2,4(1H,3H)-二酮类化合物,其结构经1H NMR和元素分析确证。初步生物活性测试表明,部分化合物具有较好的除草活性。在用药量为100μg.mL-1时,3-(4-氟苄基)-6-三氟甲基嘧啶-2,4(1H,3H)-二酮对油菜根长生长抑制率为98%。     

N-杂环甲基2-(4-杂芳氧基苯氧基)丙酰胺的合成及除草活性

以2-(4-羟基苯氧)丙酸为原料,设计合成了16个新的手性N-杂环甲基2-(4-杂芳氧基苯氧基)丙酰胺化合物,其化学结构经核磁共振、色谱-质谱、红外光谱及元素分析确证.初步生物活性测定结果表明,合成的化合物在2.25×103g/ha剂量时对单子叶杂草马唐(Digitaria sanguinalis)、稗草(Echinochloa crus-galli)及狗尾草(Setaria viridis)等均具有90%以上的活性;进一步活性及作物安全性测试表明,化合物(R)-(+)-N-[(6-氯吡啶-3-基)甲基]-2-[4-(3-氯-5-三氟甲基吡啶-2-基氧基)苯氧基]丙酰胺(2b)的除草活性高于噁唑酰草胺,且对水稻茎叶处理安全,同时对水稻田主要杂草千金子的活性远高于氰氟草酯;化合物的除草活性与立体构型有关,R构型为活性构型.     

1-(三氟甲基)-1,2-苯碘酰-3(1H)-酮在芳杂环上三氟甲基化的应用研究

以1-(三氟甲基)-1,2-苯碘酰-3(1H)-酮为三氟甲基源,并以2-氨基-5-溴吡啶为三氟甲基化底物,采用响应面分析法对合成工艺进行了分析优化,确定了最佳反应条件为:反应时间4 h,催化剂用量0.16 eq,反应温度50℃.经过3次验证实验,其平均收率为87％.最后继续合成了多个三氟甲基杂环芳香胺,且化合物结构经1...     

3-(2-氯-4-三氟甲基苯氧基)苯甲酸酯的合成、晶体结构及生物活性

以3-(2-氯-4-三氟甲基苯氧基)苯甲酸为起始原料,经氯化亚砜氯化后得中间体3-(2-氯-4-三氟甲基苯氧基)苯甲酰氯(1),再与不同取代的苯酚反应,合成了13个未见文献报道的3-(2-氯-4-三氟甲基苯氧基)苯甲酸酯(2).通过1H NMR,IR,EI-MS和元素分析对所合成的化合物进行了结构表征,3-甲基苯基3-(2-氯-4-三氟甲基苯氧)苯甲酸酯(2f)通过单晶X射线衍射进一步确证结构.初步的除草活性测试结果表明:大多数目标化合物在1.5 kg/ha剂量下对双子叶植物油菜和苋菜具有较高的抑制活性.     

2-氰基-3-(2-氟吡啶-5-基)甲氨基-3-甲硫基氰基丙烯酸酯类化合物的合成及除草活性

设计合成了系列光系统II (PS-II)电子传递抑制剂2-氰基-3-(2-氟吡啶-5-基)甲氨基-3-甲硫基氰基丙烯酸酯类化合物. 其结构经¹H NMR、元素分析确证. 生物活性测定表明: 部分化合物显示出很好的除草活性. 其中活性最好的化合物在150 g/ha, 对阔叶杂草的防效在90%以上. 构效关系研究表明: 氰基丙烯酸酯的3位取代基对它们的活性影响较大. 3位由(2-氟吡啶-5-基)甲氨基取代的氰基丙烯酸酯和相应的氯取代的氰基丙烯酸酯的除草活性相当或稍高.     

N-(4-甲基苯甲酰氨基) N’-[5-(2-三氟甲基苯基)-2-呋喃甲酰硫脲的合成、晶体结构测定与生物活性测定

本文首次合成标题化合物N-(4-甲基苯甲酰氨基)-N’-[5-(2-三氟甲基苯基)-2-呋喃甲酰硫脲。化合物(C21H16F3N3O3S, Mr = 447.43)单晶经测定为单斜晶体,空间群为P -1。在晶体中,存在一些分子内和分子间的相互作用,分子间还有C—H···π 的相互作用,这可能导致晶体更稳定的原因。目标产物的结构经IR, H NMR和元素分析测定确证。初步生物活性测试表明,部分化合物对棉花枯萎病、黄瓜灰霉病、苹果轮纹病和棉花炭疽病有较好的选择性杀菌活性;部分目标化合物有较好的除草活性。     

新型N-[cis-3-(2-氯-3,3,3-三氟丙烯基)-2,2-二甲基环丙烷基羰基]-N'-芳氧乙酰肼的合成与生物活性

为了寻找高效、低毒的农药先导化合物,利用cis-3-(2-氯-3,3,3-三氟丙烯基)-2,2-二甲基环丙烷酰氯(1)与芳氧乙酰肼的缩合反应,合成了12种未见文献报道的目标化合物,其结构经IR,1H NMR,MS和元素分析测试技术确证.初步的生物活性测定结果表明,部分目标化合物在100 mg/L浓度下对双子叶植物(油菜)显示出良好的除草活性;同时,部分化合物在200 mg/L浓度下对蚕豆蚜虫(Aphis fabas)显示出较好的杀虫活性.     

2-氰基-3-取代氨基-3-(2-甲基苯基)丙烯酸乙酯的合成和杀菌活性

2-甲基苯甲酰氯与氰乙酸乙酯反应得到2-氰基-3-羟基-3-(2-甲基苯基)丙烯酸乙酯, 经氯化得到2-氰基-3-氯-3-(2-甲基苯基)丙烯酸乙酯, 再用三乙胺处理合成了11个2-氰基-3-取代氨基-3-(2-甲基苯基)丙烯酸乙酯类目标化合物. 生物活性研究表明这类新化合物具有良好的杀菌活性.     

3-(2-苯并呋喃甲酰甲基)喹唑啉酮的合成及抗球虫活性研究

为寻求具有抗球虫活性的新化合物,本文设计并合成了4个含卤素的3-(2-苯并呋喃甲酰甲基)喹唑啉酮。所有化合物的结构经1H NMR,HRMS和IR所证实。抗球虫活性实验的结果表明,在18 mg/kg的浓度下,化合物8-氯-3-(2-苯并呋喃甲酰甲基)喹唑啉酮具有抗球虫活性效果。     

3-(2-氯-4-三氟甲基)苯氧基取代苯甲酰腙衍生物的合成与生物活性

选择3-(2-氯-4-三氟甲基苯氧基)苯甲酸为起始原料,经酰氯化,再与乙醇反应成酯,然后和水合肼反应,最后与芳香醛缩合,合成了10个未见文献报道的3-(2-氯-4-三氟甲基苯氧基)苯甲酰腙4.通过IR,1H NMR,EI-MS,元素分析等方法对所合成的化合物进行了结构表征.代表化合物4-氯苯亚甲基-3-(2-氯-4-三氟甲基苯氧基)苯甲酰腙(4f)经单晶X衍射证实了结构.并初步测定了所合成化合物的杀菌和除草活性.结果表明:部分测试化合物在50 mg/L浓度下对水稻纹枯菌和黄瓜灰霉菌具有优良的抑制效果,在100 mg/L浓度下对油菜和稗草的根显示一定的抑制效果.     

LiMn3(SeO3)2(HSeO3)6

The title compound, lithium trimanganese bis­[trioxo­selenate(IV)] hexa­kis[hydrogentrioxoselenate(IV)], is built up from a vertex‐sharing network of distorted Mn^IIIO₆ octa­hedra, SeO₃ and HSeO₃ pyramids and unusual Li(OH)₆ octa­hedra, resulting in a dense three‐dimensional structure. Mn, Li and one Se atom have site symmetries of , , and 3, respectively. An O—H⋯O hydrogen bond helps to establish the crystal packing.     

Tris(tris(trimethylsilyl)silyl)gallium,Ga{Si(Si(CH3)3)3}3

The title compound has been prepared in good yield by the reaction of gallium trichloride with base‐free hypersilyl lithium (Li–Si(SiMe₃)₃, Me = CH₃) in a 1 : 3 molar ratio. Ga(Si(SiMe₃)₃)₃ is monomeric in solution and in the solid state. The compound has been characterized with NMR, IR and Raman techniques as well as by an X‐ray structure determination (planar GaSi₃‐skeleton, monoclinic space group P2₁/c, Z = 4, d(Ga–Si) = 249,8 ± 0,2 pm).     

Spectroscopic properties of Er(3+)/Yb(3+) co-doped Bi(2)O(3)-B(2)O(3)-GeO(2) glasses

Er(3+)/Yb(3+) co-doped 60Bi(2)O(3)-(40 - x)B(2)O(3)-xGeO(2) (BBG; x=0, 5, 10, 15 mol%) glasses that are suitable for fiber lasers, amplifiers have been fabricated and characterized. The absorption spectra, emission spectra, and lifetime of the (4)I(13/2) level and quantum efficiency of Er(3+):(4)I(13/2) --> (4)I(15/2) transition were measured and calculated. With the substitution of GeO(2) for B(2)O(3), both Delta lambda(eff) and sigma(e) decrease from 75 to 71 nm and 9.88 to 8.12 x 10(-21) cm(2), respectively. The measured lifetime of the (4)I(13/2) level and quantum efficiency of Er(3+):(4)I(13/2) --> (4)I(15/2) transition increase from 1.18 to 1.5 ms and 36.2% to 43.2%, respectively. The emission spectra of Er(3+):(4)I(13/2) --> (4)I(15/2) transition was also analyzed using a peak-fit routine, and an equivalent four-level system was proposed to estimate the stark splitting for the (4)I(15/2) and (4)I(13/2) levels of Er(3+) in the BBG glasses. The results indicate that the (4)I(13/2) --> (4)I(15/2) emission of Er(3+) can be exhibit a considerable broadening due to a significant enhance the peak A, and D emission.     

Schwingungsspektren und Kraftkonstanten der Übergangsreihen OP(N(CH3)2)3 – OP(CH3)3 und SP(N(CH3)2)3 – SP(CH3)3

Vibrational Spectra and Force Constants of the Series OP(N(CH₃)₂)₃ – OP(CH₃)₃ and SP(N(CH₃)₂)₃ – SP(CH₃)₃ The vibrational spectra (IR and Raman) of the compounds of the title series are recorded and assigned to the normal vibrations. By a simplified force field the valence force constants are calculated and discussed. The results are compared with those of the NMR spectroscopy.     

Hyperfine structures of the 2 (3)Sigma(g) (+), 3 (3)Sigma(g) (+), and 4 (3)Sigma(g) (+) states of Na(2)

The hyperfine structures of the 2 (3)Sigma(g) (+), 3 (3)Sigma(g) (+), and 4 (3)Sigma(g) (+) states of Na(2) have been resolved with sub-Doppler continuous wave perturbation facilitated optical-optical double resonance spectroscopy via A (1)Sigma(u) (+) approximately b (3)Pi(u) mixed intermediate levels. The hyperfine patterns of these three states are similar. The hyperfine splittings of the low rotational levels are all very close to the case b(betaS) limit. As the rotational quantum number increases, the hyperfine splittings become more complicated and the coupling cases become intermediate between cases b(betaS) and b(beta J) due to spin-rotation interaction. We present a detailed analysis of the hyperfine structures of these three (3)Sigma(g) (+) states, employing both case b(betaS) and b(beta J) coupling basis sets. The results show that the hyperfine splittings of the (3)Sigma(g) (+) states are mainly due to the Fermi-contact interaction. The Fermi contact constants for the two d sigma Rydberg states, the 2 (3)Sigma(g) (+) and 4 (3)Sigma(g) (+), are 245+/-5 MHz and 225+/-5 MHz, respectively, while the Fermi contact constant of the s sigma 3 (3)Sigma(g) (+) Rydberg state is 210+/-5 MHz. The diagonal spin-spin and spin-rotation constants, and nuclear spin-electronic spin dipolar interaction parameters of the 3 (3)Sigma(g) (+) and 4 (3)Sigma(g) (+) states are also obtained.     

Interactions in the Quinary System H2O-Y(NO3)3-La(NO3)3-Pr(NO3)3-Nd(NO3)3 to Very High Concentrations

Isopiestic measurements have been carried out for the quinary system H₂O-Y(NO₃)₃-La(NO₃)₃-Pr(NO₃)₃-Nd(NO₃)₃ at 298.15 K to near saturation. The measurements can be represented within experimental uncertainty over the full concentration range by a modified Pitzer ion-interaction model extending to the C ⁽³⁾ term. In addition, the system obeys the Zdanovskii–Stokes–Robinson model or partial ideal solution model within the accuracy of the isopiestic measurements, indicating zero interchange energy between the unlike salts, which is consistent with the nature of trivalent rare-earth elements.     

Li(VO2)3(TeO3)2

The title compound, lithium tris[dioxidovanadium(V)] bis[trioxidotellurium(IV)], contains chains of edge‐sharing distorted VO₆ octahedra. The pyramidal TeO₃ groups crosslink the chains into sheets. Finally, an Li⁺ cation adopting an unusual capped trigonal–bipyramidal LiO₆ geometry bridges the layers to complete a three‐dimensional structure.     

Bis(trifluoroacetyl) peroxide, CF(3)C(O)OOC(O)CF(3)

Pure, highly explosive CF(3)C(O)OOC(O)CF(3) is prepared for the first time by low-temperature reaction between CF(3)C(O)Cl and Na(2)O(2). At room temperature CF(3)C(O)OOC(O)CF(3) is stable for days in the liquid or gaseous state. The melting point is -37.5 degrees C, and the boiling point is extrapolated to 44 degrees C from the vapor pressure curve log p = -1875/T + 8.92 (p/mbar, T/K). Above room temperature the first-order unimolecular decay into C(2)F(6) + CO(2) occurs with an activation energy of 129 kJ mol(-1). CF(3)C(O)OOC(O)CF(3) is a clean source for CF(3) radicals as demonstrated by matrix-isolation experiments. The pure compound is characterized by NMR, vibrational, and UV spectroscopy. The geometric structure is determined by gas electron diffraction and quantum chemical calculations (HF, B3PW91, B3LYP, and MP2 with 6-31G basis sets). The molecule possesses syn-syn conformation (both C=O bonds synperiplanar to the O-O bond) with O-O = 1.426(10) A and dihedral angle phi(C-O-O-C) = 86.5(32) degrees. The density functional calculations reproduce the experimental structure very well.