基于像散与理想光源成像原理的高亮度半导体激光器光纤耦合设计方法

运用像散原理和理想光源成像原理,讨论了半导体激光器消像散设计.提出了一种基于消像散的高亮度半导体激光器光纤耦合系统的设计方法.以波长为808 nm,输出功率为10 W的半导体激光器的光纤耦合为例,给出了详细的计算方法和设计步骤.结果表明:采用该方法将半导体激光器光束耦合入数值孔径为0.22,芯径为50 μm的光纤中,耦...     

二波混频高功率单频窄线宽光纤激光器

设计并制造了一种基于二波混频的高功率单频窄线宽光纤激光器.激光器采用长线形腔结构,以Er3+/Yb3+双包层光纤作为增益介质,利用输出信号光分束反馈注入,与腔内振荡激光混频干涉,形成分布的增益光栅与折射率光栅共同作用选模,获得稳定的1550.63 nm单频高功率激光输出.在975 nm多模激光二极管(LD)抽运下,激光...     

点可迁图的限制边连通性

3限制边割是连通图的一个边割, 它将此图分离成阶不小于3的连通分支. 图G的最小3限制边割所含的边数称为此图的3限制边连通度, 记作λ\-3(G). 它以图G的3阶连通点导出 子图的余边界的最小基数ξ_3(G)为上界. 如果λ_3(G)=ξ_3(G), 则称图G是极大3限制边连通的 . 已知在某种程度上,3限制边连通度较大的网络有较好的可靠性. 作者在文中证明: 如果k正则连通点可迁图的 围长至少是5, 那么它是是极大3限制边连通的.     

A HYDROGEN BONDING ASSISTED CATALYST SCREENED OUT VIA COMBINATORIAL CHEMISTRY STRATEGY

1. INTRODUCTIONReduction of organic compounds by NaBH, is often used in organic synthesis. The reactiollis only proceeded in the interface between the organic phase and water phase because of the lowsolubility of NaBH. in organic compounds, and this results in the slow reaction rate and lowyield. In order to increase the reaction rate and yield, NaBH, was converted totetraalkylammonium borohydrides II' 'l, and this made the operating process complex and greatamount of quaternary ammon…     

原子相干态中的压缩现象

计算表明,与场的相干态类似的原子相干态,具有不同于场的相干态的压缩行为;进一步证明:直接类比于(?)(ξ)不能得到“原子压缩算符”.     

用于非光滑优化的信赖域算法的一个实施方案

本给出了处理无约束非光滑优化的信赖域算法的一个实施方案。数值实验表明：这种方案是切实可行和可靠的。     

热核的热稳定曲线

从核极限温度的角度研究了热核的热稳定性.采用Skyrme相互作用力计算热核同位素的极限温度,得到的极限温度的同位素分布呈现出倒置抛物线的趋势,与中能重离子反应多重碎裂中同位素产额分布的实验结果具有一致的行为表现.系统地计算了从轻到重的一系列元素极限温度的同位素分布,并从中抽取出热核的热稳定曲线.与β稳定线相比,热核的热稳定线更加偏丰中子.     

Isolation and Crystal Structure of Ent-kaurane Diterpenes from Rubus corchorifolius L. f.

In this study, ent-Kaurane-3β,16β,17-triol(1) and ent-kaurane-2α,16β,17-triol(2), were isolated from the leaves of Rubus corchorifolius L. f. Their structures were elucidated based on extensive spectroscopic analysis. NMR experiments identified the two compounds and X-ray crystallographic analysis confirmed their crystal structures. The crystal of 1 belongs to monoclinic with space group P21 and a = 10.7641(3), b = 7.2789(3), c = 11.7862(4) , β = 95.275(3)°, V = 919.55(6) 3, Z = 2, C20H34O4, Mr = 322.49 g/mol, Dc = 1.230 g/m3, F(000) = 376, λ = 1.54178 , μ = 0.661 mm-1, R = 0.0319, and wR = 0.0811 for 10889 observed reflections(Ⅰ 2σ(Ⅰ)). The crystal of 2 is classified as orthorhombic with space group P212121 and a = 10.7641(3), b = 12.72224(19), c = 21.3929(3) , V = 1748.94(4) 3, Z = 4, C20H34O4, Mr = 322.47, Dc = 1.225 Mg/m3 F(000) = 712, λ = 1.54184 , μ = 0.625 mm-1, R = 0.0303 and w R = 0.0759 for 10470 observed reflections(Ⅰ 2σ(Ⅰ)). Meanwhile, the compound revealed low inhibitory activities toward Hep G2, MCF-7, and SCG-7901 cells.     

Syntheses and Structures of Two Macrocyclic Nickel(Ⅱ) Complexes Bridging Benzene Polycarboxylic Acid

Two complexes with formulas [Ni L][(Ni L)(IPA)2]·8H2O(1) and [(Ni L)(H2O)2] [(Ni L)(PMA)]·4H2O(2)(L = 5,5,7,12,12,14-hexamethyl-1,4,8,11-tetraazacyclotetradecane,IPA2– = isophthalic anion,PMA4– = 1,2,4,5-benzenetetracarboxylic anion) were synthesized and characterized by elemental analyses and IR spectra.The crystal structures were determined by X-ray diffraction.In complex 1,the [Ni L]2+ bridged IPA2– to give [(Ni L)(IPA)2]2– monomer,and the [Ni L]2+ bridged PMA4– to form a one-dimensional chain [(Ni L)(PMA)]n2n– in complex 2.The [Ni L]2+ and [(Ni L)(IPA)2]2–/[(Ni L)(PMA)]2– are connected through intermolecular hydrogen bonding to generate three-dimensional supramolecular structures.     

Li3V2（PO4）3/C正极材料在不同电压区间的电化学行为及容量衰减原因

采用溶胶-凝胶法制备锂离子电池正极材料Li3V2(PO4)3/C.通过恒电流充放电测试、循环伏安(CV)、电化学阻抗谱(EIS)等方法,研究了Li3V2(PO4)3/C在不同电压区间的电化学行为(3.0-4.5 V和3.0-4.8 V).结果表明,3.0-4.8 V电压区间的循环性能和倍率性能均不及3.0-4.5 V电压区间的.3.0-4.5 V区间0.1C (1C=150 mA?g-1)倍率首次放电比容量为127.0 mAh?g-1,循环50次后容量保持率为99.5%,而3.0-4.8 V区间的分别为168.2 mAh?g-1和78.5%.经过高倍率测试后再回到0.1C倍率充放电,3.0-4.5 V和3.0-4.8 V的放电比容量分别为初始0.1C倍率的99.0%和80.7%.经过3.0-4.8 V电压区间测试后,少部分第三个锂离子能够在低于4.5 V的电压脱出,使3.0-4.5 V电压区间的放电比容量提升了7.4%. CV结果表明3.0-4.8 V区间的容量损失主要表现为第一个锂离子的不可逆损失.极片的X射线衍射(XRD)和X射线光电子能谱(XPS)分析测试结果表明经过3.0-4.8 V测试后, Li3V2(PO4)3的结构发生了轻微的改变.电感耦合等离子体(ICP)测试结果表明循环后的电解液中含有少量的V.结构变形和V溶解可能是Li3V2(PO4)3在3.0-4.8 V区间容量衰减的主要原因.