USING MEASURING METHOD TO FIND AREA OF ENCLOSED PLANE REGION AND VOLUME OF ENCLOSED SPACE REGION

Two simple methods to calculate the area and volume called improved square gridmethod and cube cutting method are proposed in this paper. For any plane curve orspace surface satisfying certain conditions, by our method, the error of measurement isof the second infinitive order of measuring unit (the side length of the square grid or theside length of the little cube) when the unit is small enough. And when some properties ofthe curve or the surface can be found or its varying bounds can be evaluated, it is pointedout, in order to make the error smaller than any given value, how small the length of themeasuring unit should be.     

Y2O3:Eu3+纳米线阵列的制备与表征

Y2O3:Eu3+红色荧光粉由于色纯度高、化学性质稳定和量子效率接近100%而广泛用于荧光灯和投影电视等方面.近年来,Y2O3:Eu3+的大量研究工作主要集中于纳米粉末的制备方法及其与体相材料不同的发光特性[1～3].最近,有关Y2O3:Eu3+及其稀土化合物的纳米管、纳米线和纳米带一维材料的制备成为研究热点.Wu Changfeng等[4,5]利用表面活性剂合成了Y2O3 : Eu3+纳米管.激光格位选择激发测试结果表明,Eu3+在纳米管中占据3个不同的格位,其611 nm处的红色发光峰出现了宽化.He Yu等[6]采用水热法及退火处理制备出了Y2O3:Eu3+纳米带,发现Eu3+的发射峰不仅宽化,而且出现了625 nm的新峰.Li Yadong等[7～9]采用水热法制备了稀土氧化物、硫氧化物和氢氧化物等的纳米线和纳米管,并探索了其形成机理,同时发现Y2O3S : yb3+,Er3+具有上转换的性质.     

多壁碳纳米管对沙林的敏感性研究

自碳纳米管被发现以来,由于其具有许多独特的电学、磁学、力学和气敏特性而引起了人们广泛的关注,在结构增强、纳米电子器件、场发射、储氢、传感器等众多领域具有非常广阔的应用前景,成为当前研究的热点之一[1,2].近年来,随着碳纳米管在传感器特别是气体检测领域研究的不断深入,碳纳米管为敏感材料的传感器已成功应用于对O2、NO2、NH3、H2等气体的检测研究[3],其中对NO2的检测可达到10×10-9(φ),但尚未见碳纳米管用于毒剂检测的报道.本文以碳纳米管作为石英晶体微天平膜材料,研究了碳纳米管的化学修饰方法及其对检测沙林的影响,结果表明经强酸加热氧化的碳纳米管对沙林响应大、解吸快、重复性好,可以作为传感器检测沙林的膜材料.该研究为碳纳米管在化学毒剂中的应用奠定了基础.     

CH2(COO)2Cu·2H2O热分解的非等温动力学研究

The thermal dehydration and decomposition kinetics of CH₂(COO)₂Cu·2H₂O were investigated using the non-isothermal method by thermogravimetry (TG) technique in N₂. The iterative iso-conversional methods were applied to calculate the activation energy E_a of dehydration and decomposition， and the most probable mechanism function G(α) was determined by means of the master plots method. The pre-exponential factor A was obtained on the basis of E_a and G(α). Kinetic parameters (E_a and lnA) of dehydration were given as: E_a=139.79 kJ·mol^-1， ln(A/s^-1)=47.38. The mechanism function of the dehydration was G(α)=[-ln(1-α)]^2/3， and the decomposition of CH₂(COO)₂Cu proceeds to completion by two distinct reactions. These two reactions overlap in the transition process (0.45<α<0.65). Kinetic parameters (E_a and lnA )of the first reaction of decomposition were: E_a=201.15 kJ·mol^-1， ln(A/s^-1)=52.29， and the mechanism function was G(α)=[1-α]^-0.37. And in the second reaction G(α)=α+(1-α)ln(1-α)， E_a=156.74 kJ·mol^-1， ln(A/s^-1)=39.58.     

Stereoselective Synthesis of Piperamide Alkaloids by Modified Ramberg-Bcklund Reaction

A convenient and rapid approach for the synthesis of piperamide alkaloids la ~ h by the recently developed one-flask Ramberg-Backlund reaction was described. The synthesis of 1e was reported for the first time.     

导电氧化物电极上丁酸丁酯电化学合成的研究

本文研究了某些氧化物电极在不同条件下对丁醇电解直接合成丁酸丁酯的影响，并测定了这些氧化物电极上的丁醇氧化极化曲线，结果表明Ｔｉ／ＰｂＯ２电极在加入ＳｎＯ２，Ｓｂ２Ｏ３，ＰｄＯｘ中间层后，不仅电极的ＰｂＯ２层不易脱落，而且使电极的电催化性能有较大的提高。     

1,3,3a,5-四苯基-3a,4,5,11-四氢-3H,6H-1,2,4-三唑并[4,3-d][1,5]苯并二氮杂(艹卓)的合成及晶体结构

通过2,4-二苯基-2,3-二氢-1H-1,5-苯并二氮杂(艹卓)与苯甲酰氯苯腙的[2+3]环加成反应制备了标题化合物,用X射线单晶衍射仪测定了其晶体结构.晶体属正交晶系,空间群为Fdd2.晶胞参数:a=1.762 8(4)nm,b=5.751 2(12)nm,c=1.022 7 nm,V=10.368(5)nm3,Z=16,Dc=1.262 g·cm-3,μ=0.075 mm-1,F(000)=4 160,1 139个可观测衍射点,R-0.046 1,Rw=0.056 0.     

一种含氟丙烯酸树脂的制备及其表面疏水性

在聚合反应的后期阶段,向体系中引入含氟丙烯酸酯单体全氟辛基-(N-乙基-N-丙烯酸乙酯基)磺酰胺(QG-F814)共聚改性的方法制备了一种含氟丙烯酸树脂.接触角测定表明,该树脂具有良好的疏水性能.热重分析表明,该树脂在改性前后的耐热稳定性差别不大.     

羧甲基壳聚糖/明胶共混膜的结构表征与吸湿保湿性

壳聚糖通过羧甲基化得到水溶性N，O-羧甲基壳聚糖，并将其配制成4Wt％水溶液，与4Wt％明胶水溶液共混，成功制得了羧甲基壳聚糖／明胶共混膜。采用红外光谱、x射线衍射、扫描电镜对共混膜进行结构表征，结果表明，共混膜中羧甲基壳聚糖和明胶分子间存在着较强的相互作用及良好的相容性。通过共混膜的力学性能测试，发现当羧甲基壳聚糖含量为20％时，共混膜的抗张强度达到最大值(75MPa)，分别比单独的羧甲基壳聚糖(45MPa)和明胶(43MPa)提高了66．7％和74％。经过吸湿和保湿性能测试，发现当羧甲基壳聚糖含量为80％时，吸湿率和保湿率分别为33．4％和69．2％，比单独的明胶膜分别提高了1．8倍和2．1倍。     

Synthesis and Crystal Structure of 9-（ 4-M e tho xylphen yl ）-1,8-dioxo-3,4,5,6,7,9hexahydroxanthene under Microwave Irradiation

1INTRODUCTIONInthepastfewyears,potassiumchannelacti-vatorshavegainedincreasingattentionbecauseoftheirclinicalpotentialapplicationsinvariousdiseases.Oneofthemostpotentcompoundsamongthisnewclassofdrugsisthebenzopyranderivativecroma-kalim[1～4].Benzopyranaswellasitsderivativesex-hibitsextensivepharmacologicalandbiologicalacti-vities[5],suchasantibacterialactivities[6,,antitumor7]activity[8],hypotensiveeffect[9],antiproliferationef-fect[10],etc.Thetitlecompoundbearingabenzo-pyranstructuraluni…