缓倾外层状结构边坡变形破坏模式及支护对策研究

高速公路开挖形成越来越多的工程边坡。缓倾外层状结构边坡作为一种典型的岩质边坡,一般情况下整体稳定性较好,但在特定的结构面组合状况下,开挖后也可能产生整体变形破坏。本文以软弱结构面和长大裂隙发育的公路工程边坡为例,通过岩体结构及边坡一定范围内已有边坡破坏现象的调查研究,采用工程地质类比和三维离散元法综合分析边坡变形破坏模式,并针对变形破坏模式的特点,提出支护对策。研究结果表明,结构面贯通坡体形成切割块体的后缘和侧缘边界时,缓倾外层状结构边坡可沿层面产生滑移-拉裂变形,若滑面与临空面具有一定夹角,边坡的变形可表现为旋转式滑移-拉裂;结构面组合控制的缓倾外层状结构岩质边坡稳定性受坡体中下部的关键块体控制,一旦关键块体失稳,将引起上部块体的连锁失稳,此类边坡变形控制的重点是对关键块体分布区域进行强支护;支护工程实施后的变形监测结果表明,基于变形破坏模式分析的边坡支护方案保证了边坡施工和运营过程中的安全。     

Fabrication of superconducting Nb N meander nanowires by nano-imprint lithography

Superconducting nanowire single photon detector(SNSPD), as a new type of superconducting single photon detector(SPD), has a broad application prospect in quantum communication and other fields. In order to prepare SNSPD with high performance, it is necessary to fabricate a large area of uniform meander nanowires, which is the core of the SNSPD. In this paper, we demonstrate a process of patterning ultra-thin Nb N films into meander-type nanowires by using the nanoimprint technology. In this process, a combination of hot embossing nano-imprint lithography(HE-NIL) and ultraviolet nano-imprint lithography(UV-NIL) is used to transfer the meander nanowire structure from the NIL Si hard mold to the Nb N film. We have successfully obtained a Nb N nanowire device with uniform line width. The critical temperature(Tc) of the superconducting Nb N meander nanowires is about 5 K and the critical current(Ic) is about 3.5 μA at 2.5 K.     

Design of a gap tunable flux qubit with FastHenry

In the preparations of superconducting qubits, circuit design is a vital process because the parameters and layout of the circuit not only determine the way we address the qubits, but also strongly affect the qubit coherence properties. One of the most important circuit parameters, which needs to be carefully designed, is the mutual inductance among different parts of a superconducting circuit. In this paper we demonstrate how to design a gap-tunable flux qubit by layout design and inductance extraction using a fast field solver Fast Henry. The energy spectrum of the gap-tunable flux qubit shows that the measured parameters are close to the design values.     

Superconducting phase qubits with shadow-evaporated Josephson junctions

We develop a fabrication process for the superconducting phase qubits in which Josephson junctions for both the qubit and superconducting quantum interference device(SQUID) detector are prepared by shadow evaporation with a suspended bridge. Al junctions with areas as small as 0.05 μm~2 are fabricated for the qubit, in which the number of the decoherencecausing two-level systems(TLS) residing in the tunnel barrier and proportional to the junction area are greatly reduced. The measured energy spectrum shows no avoided crossing arising from coherent TLS in the experimentally reachable flux bias range of the phase qubit, which demonstrates the energy relaxation time T_1 and dephasing time T_φ on the order of 100 ns and 50 ns, respectively. We discuss several possible origins of decoherence from incoherent or weakly-coupled coherent TLS and further improvements of the qubit performance.     

Modification of short-range repulsive interactions in ReaxFF reactive force field for Fe-Ni-Al alloy

The short-range repulsive interactions of any force field must be modified to be applicable for high energy atomic collisions because of extremely far from equilibrium state when used in molecular dynamics (MD) simulations. In this work, the short-range repulsive interaction of a reactive force field (ReaxFF), describing Fe-Ni-Al alloy system, is well modified by adding a tabulated function form based on Ziegler-Biersack-Littmark (ZBL) potential. The modified interaction covers three ranges, including short range, smooth range, and primordial range. The short range is totally predominated by ZBL potential. The primordial range means the interactions in this range is the as-is ReaxFF with no changes. The smooth range links the short-range ZBL and primordial-range ReaxFF potentials with a taper function. Both energies and forces are guaranteed to be continuous, and qualified to the consistent requirement in LAMMPS. This modified force field is applicable for simulations of energetic particle bombardments and reproducing point defects' booming and recombination effectively.     

Fabrication and properties of the meander nanowires based on ultra-thin Nb films

We report the fabrication and the study of superconducting properties of ultra-thin Nb superconducting meander nanowires, which can be used as superconducting nanowire single-photon detectors （SNSPDs）. The ultra-thin （about 7- nm thick） Nb films are patterned into micro-bridges, and 100-nm wide meander nanowires by using e-beam lithography （EBL）. The average transition temperature （Tc） of the nanowires is about 4.8 K and the critical current density jc is about 2.8 × 10^6 A/cm2. Superconducting characteristics of the specimens at different applied magnetic fields up to 8 T （parallel or perpendicular to the specimen） are systematically investigated. The normalized temperature t （= T/Tc） dependences of the parallel critical field （HcⅡ） for both the micro-bridge and the meander nanowire are almost the same, following the Ginzburg and Landau （GL） formalism for ultra-thin films. However, in perpendicular field and in the vicinity of Tc （〉 0.95Tc）, the critical field Hc⊥ of the nanowire exhibits a down-turn curvature nonlinear temperature dependence while the micro-bridge displays a linear temperature dependence. The nonlinear behavior of Hc⊥ in the nanowire is believed to be due to the fact that in the vicinity of Tc the coherence length becomes larger than the line width. Additionally, the localization of carriers in the nanowire could also contribute to the nonlinear behavior. The resistive transitions could be described by the phase-slip model for quasi-one-dimensional system. Moreover, the hysteresis in I-V curve of the meander nanowires can be illustrated by a simple model of localized normal hotspot maintained by Joule heating.     

面向实战化需求的流体力学教学改革与实践

流体力学课程理论性强、内容抽象、枯燥难懂,传统教学内容缺乏与实战化内容的联系,学员学习目标不明确,理论性与实战性分离,因而学员的主体性和教学内容的高阶性不足。为了解决学员学习兴趣不高、动力不足的问题,面向实战化教学需求,在教学内容上发展了“四个引入”理念,即引入流动现象、军事应用、科研成果、思想方法,在教学模式上提出了具体实施的“六个环节”,即设疑、分析、释疑、拓展、应用、创新,通过理论与实际相结合,搭建起了课堂与战场之间的桥梁。提升了学员学习动力和兴趣,改善了教学效果。     

181Hf(n,γ)182Hf反应截面测量

在中国原子能科学研究院重水研究堆上用活化法对反应堆中子引起的181Hf (n,γ)182Hf反应截面进行了测量. 反应堆中样品照射位置的热中子与超热中子的通量比值约为10. 照射后样品中的182Hf/180Hf和 181Hf/180Hf的原子数比值是用热电离质谱测量的. 本工作以180Hf (n,γ)181Hf反应截面(14.80±0.60 b)为标准，测得的反应堆中子引起的181Hf (n,γ)182Hf反应截面值为80.0±5.6 b.     

液态锂在铜的微通道中的流动行为

本文采用分子动力学方法模拟了液态锂在铜的微通道内的流动行为. 通过构建铜(111), (100)和(110)晶面的微通道内壁, 研究了液态锂在流固界面上的微观结构以及在铜微通道中的流动速度分布情况, 并探讨了微通道尺寸对液态锂流动行为的影响. 研究结果表明铜微通道内的液态锂在靠近铜固体壁附近区域呈有序的层状结构分布, 并受铜内壁晶面微观结构的影响. 铜(111)和(100)面内壁附近的液态锂有序层分布结构更明显. 外驱力作用下的液态锂在微通道内的流动速度呈抛物线分布, 流固界面和流动方向对液态锂的流动速度都会产生影响. 液态锂在铜(111)面内壁上流动的速度最大, 且出现了速度滑移; 在铜(110)面内壁上流动速度最小. 通过对不同尺寸的微通道内液态锂流动行为的研究, 发现流动速度的大小随着微通道尺寸的增加而增大, 且最大速度与微通道尺寸呈二次函数关系, 与有关理论计算结果符合得很好.     

一种新尾式卟啉吡啶季铵盐对锌离子显色反应的研究

本文研究了一种新型尾式卟啉吡啶季铵盐５－［４－（４－吡啶丁氧基）苯基］－１０,１５,２０－三（４－氯苯基）卟啉溴化物与锌的反应条件。ｐＨ＝１０．０,在吡啶存在下,于沸水浴中加热１５ｍｉｎ,其与Ｚｎ２＋形成１∶１配合物,其最大吸收波长位于４２８．６ｎｍ,在此条件下试剂的最大吸收波长在４１８．２ｎｍ,相差１０ｎｍ,配合物摩尔吸光系数４．６４×１０５Ｌ·ｍｏｌ－１·ｃｍ－１,锌在０—１．２μｇ／１０ｍＬ范围内符合比耳定律,相关系数ｒ＝０．９８８８,本法是目前报道的分光光度法测定锌的最灵敏方法之一。