一种企业医疗保险接口解决方案及实现

针对当前各定点医院已有的医院管理系统与医疗保险系统之间存在着医疗信息传输数据格式和传输模式各不相同、不能通用等问题,提出在尽量减少修改原医疗管理系统软件设计和充分考虑统一联网后各定点医院管理数据信息安全性的基础上,利用嵌入连接与VPN技术来实现网络接口与布局,有效解决了医保系统与医院管理系统接口及其安全性问题,确保了医疗保险工作的顺利进行。     

基于嵌入式系统的应用功能重构

本文从软件平台和硬件平台两方面出发,详细的论述了一个基于uC/OS-II的嵌入式系统应用功能重构开发平台的设计思路和过程,设计了基于嵌入式系统的基本元功能模块,应用功能重构语言及其解释器。实现了一个基于嵌入式系统应用功能重构的系统原形。     

用正交实验法对碳还原氧化铜实验的研究

用正交实验法研究了木炭还原氧化铜实验的优化条件,深入探讨了采用酒精灯为热源能使实验获得满意效果的单质碳和氧化铜的类型,得出了保证该实验成功的优化方案。     

碳基片上沉积的金刚石涂层多孔电极的特性

采用化学气相沉积法（CVD）在多孔活性碳基体上制备掺硼金刚石涂层多孔电极。用扫描电子显微镜（SEM）法表征了金刚石膜的表面微观结构，采用循环伏安法和交流阻抗法研究了电极的电化学性质。结果表明，金刚石表面形态为球形，金刚石膜电极具有很宽的电势窗口，在酸性、中性和碱性3种介质中分别为4．4V、4．0V和3．0V。在铁氰化钾电解液中，金刚石膜电极表面在反应过程中始终保持良好的活性，在表面进行的电化学反应具有良好的准可逆性。     

江苏省里下河地区杨树人工林的碳储量及其动态

研究了江苏省里下河地区10年生I 69杨无性系(PopulusdeltoidesBartr.cv."Lux")人工林的碳储量及其动态。结果表明,林分总的碳储量为(136.2±15.9)(平均值±标准差)t/hm2,其中林木、林下植物、A0层以及土壤的碳储量分别为(74.1±8.3),(0.3±0.1),(1.9±0.2)和(59.9±14.2)t/hm2。10年生时林木碳的净生产力为(11.1±1.7)t/(hm2·a),凋落物归还量为(2.3±0.3)t/(hm2·a),土壤CO2释放量为(5.5±0.2)t/(hm2·a)。可见,I 69杨人工林具有较高的生物生产力和碳储量,发展杨树等速生丰产林能对大气碳循环起到积极的作用。     

巴基纸制备的研究进展

作为一种功能化的多孔宏观结构,巴基纸既保留了纳米材料的物理化学特性,又有效解决了碳纳米材料个体操作应用困难的缺点,适合在复合材料、电极、催化、过滤和提纯等领域的大规模工程应用.按照所用碳纳米材料的不同,巴基纸大致可分为四类:单壁碳纳米管巴基纸、多壁碳纳米管巴基纸、碳纳米纤维巴基纸、混合巴基纸.按照其材料的不同对巴基纸的制备进行综述,并对将来的研究进行了展望.     

碳纳米管金属复合材料的合成及其吸波性能

通过乙炔催化裂解制得碳纳米管,采用浓硫酸和双氧水的混合溶液对碳纳米管进行表面羟基化修饰,利用化学镀使Pd、Co以及FePt金属纳米粒子成功地吸附在碳管表面,结果发现碳纳米管及其复合物均为介电损耗型介质,Co-碳纳米管复合物相比纯碳纳米管在高频区域有较强的宽范围吸收.     

Mesoporous iron oxide-silica supported gold catalysts for low-temperature CO oxidation

Mesoporous iron oxide-silica composite with a high silica content was synthesized by hydrothermal method, and another composite material with a high iron content was obtained by etching part of silica in alkaline solution. Gold catalysts were loaded onto both composites by a deposition-precipitation method, and used for CO oxidation. The samples were characterized by Brumauer- Emmet-Teller （BET）, X-ray diffraction （XRD）, X-ray photoelectron spectra （XPS）, transmission electron micro- scope （TEM） and scanning electron microscope （SEM） techniques. Both composites had high specific surface areas and were amorphous. The Au nanoparticles dispersed on the surface of the composites existed in metallic state. Composite with high silica content was not suitable for Au loading, and its supported gold catalyst showed poor per- formance in catalytic reaction. In contrast, composite with high iron content allowed efficient Au loading, and CO could be oxidized completely at low temperature on its supported gold catalyst. The effects of deposition-precipi- tation pH values on Au loading and activity of the catalyst were investigated, and the results indicated that Au loading was the highest and the catalyst was the most active for CO oxidation when the synthesis pH was adjusted to 8.     

Gas sensors for CO_2 detection based on RGO–PEI films at room temperature

In this paper,polyethyleneimine(PEI)and reduced graphene oxide(RGO)were selected as sensing materials for carbon dioxide detection.Two kinds of sensors with different sensitive film structures,i.e.,RGO–PEI composite film and RGO–PEI bi-layer film were fabricated by airbrushing the sensitive films on interdigitated electrodes.Response performances of both sensors at room temperature were investigated.Results showed that sensors with bi-layer film exhibited smaller baseline drift and more stable sensing characteristics than the counterparts with composite film.Furthermore,bi-layer film sensors with different quantity of PEI solution deposited were studied.Performances of long-time stability,repeatability,low concentration of detection for carbon dioxide,and measurements of response time and recovery time were investigated.It was found that appropriate weight ratio of RGO and PEI was critical for sensing response.In addition,the sensor with bi-layer film exhibited a better repeatability but had longer response time and recovery time than RGO single-layer sensor,and both of them could detect as low as20 parts per million carbon dioxide gas.Sensing responses of the prepared sensors to carbon dioxide under dry air or nitrogen were compared.The relevant sensing mechanisms were studied as well.     

Impacts of climate change on ecosystem in Priority Areas of Biodiversity Conservation in China

Priority Areas of Biodiversity Conservation （PABCs） are the key areas for future biodiversity conservation in China. In this study, we used 5 dynamic global vegetation models （DGVMs） to simulate the ecosystem function changes under future climate change scenario in the 32 terrestrial PABCs. We selected vegetation coverage, vegetation productivity, and ecosystem carbon balance as the indicators to describe the ecosystem function changes. The results indicate that woody vegetation coverage will greatly increase in the Loess Plateau Region, the North China Plain, and the Lower Hilly Region of South China. The future climate change will have great impact on the original vegetation in alpine meadow and arid and semiarid regions. The vegetation productivity of most PABCs will enhance in the coming 100 years. The largest increment will take place in the southwestern regions with high elevation. The PABCs in the Desert Region of Inner Mongolia-Xinjiang Plateau are with fastest productivity climbing, and these areas are also with more carbon sink accumulation in the future. DGVM will be a new efficient tool for evaluating ecosystem function changes in future in large scale. This study is expected to provide technical support for the future ecosystem management and biodiversity conservation under climate change.