ZJR型涂料的制备及特性研究

利用溶胶凝胶法制备TiO2光催化剂,使用磷酸氢二钠、十水合四硼酸钠和氢氧化镁等制备了阻燃体系料,复合后制成ZJR涂料。利用热分析仪分析纳米TiO2和阻燃体系复合的防火涂料的温度与热失率关系,并得到热重与微商热重曲线。550~650℃之间,失重率约为11%,ZJR涂料在400~600℃有较好的阻燃效果。该涂料对污染气体的光催化降解研究结果表明:光照60 m in后,对二氧化硫的降解率为90.40%,紫外光照40 m in后,甲醛气体降解率为68.98%。进一步添加聚乙二醇和银离子使涂料改性,使涂料光催化甲醛的活性分别提高了11%和14%,效果显著。     

Recycling of high purity selenium from CIGS solar cell waste materials

Copper indium gallium diselenide (CIGS) is a promising material in thin film solar cell production. To make CIGS solar cells more competitive, both economically and environmentally, in comparison to other energy sources, methods for recycling are needed. In addition to the generally high price of the material, significant amounts of the metals are lost in the manufacturing process. The feasibility of recycling selenium from CIGS through oxidation at elevated temperatures was therefore examined. During oxidation gaseous selenium dioxide was formed and could be separated from the other elements, which remained in solid state. Upon cooling, the selenium dioxide sublimes and can be collected as crystals. After oxidation for 1 h at 800 °C all of the selenium was separated from the CIGS material. Two different reduction methods for reduction of the selenium dioxide to selenium were tested. In the first reduction method an organic molecule was used as the reducing agent in a Riley reaction. In the second reduction method sulphur dioxide gas was used. Both methods resulted in high purity selenium. This proves that the studied selenium separation method could be the first step in a recycling process aimed at the complete separation and recovery of high purity elements from CIGS.     

Quantifying the rebound effects of residential solar panel adoption

Customers who adopt solar panels can reduce their energy bills and lower the effective average electricity prices they pay. When the price falls, a solar consumer might consume more electricity than before – a solar rebound effect. We provide the first empirical evidence of residential solar rebound effects in the U.S. We use household level hourly and daily electricity meter data as well as hourly solar panel electricity generation data from 277 solar homes and about 4000 non-solar homes from 2013 to 2017 in Phoenix Arizona. Using matching methods and a fixed effects panel regression approach, we find that when solar electricity generation increases by 1 kWh, solar homes increase their total electricity consumption by 0.18 kWh. This indicates that solar rebound effects are estimated at 18%. Building upon our theoretical framework, the increase in consumer surplus from solar panel adoption is estimated at $972/yr.     

La3+掺杂对吸附相反应制备TiO2复合催化剂的结晶过程及弱紫外光下活性的影响

利用吸附相反应技术制备弱紫外光响应的高效催化剂,并通过XRD、XPS以及HRTEM探索了不同焙烧温度下La3+掺杂量对TiO2结晶过程的影响.结合弱紫外光下甲基橙的降解反应,深入研究催化剂结晶过程的变化对弱紫外光下催化剂活性的影响.结果表明,La3+掺杂会抑制TiO2的结晶过程.当焙烧温度或者掺杂量较低时,La3+不能进入TiO2的晶格结构但会轻微地抑制TiO2的结晶过程;未进入晶格结构的La3+存在会引入光生载流子的浅能级捕获中心,在弱光体系中极大提升了催化剂的活性.当La3+的掺杂量为0.05%(原子分数)时,经过900℃焙烧后催化剂降解能力最高,其活性超过商用P25的2倍多.在较高La3+掺杂量(超过0.20%)时,900℃焙烧后一定量La3+进入TiO2的晶格结构而大大抑制了TiO2结晶;这种强烈的抑制作用使得催化剂中存在大量无定形结构TiO2,无定形TiO2甚至多于700℃焙烧后的催化剂,反而大大抑制了弱光体系中催化剂活性.     

Effect of transition metal doping under reducing calcination atmosphere on photocatalytic property of TiO2 immobilized on SiO2 beads

TiO₂ immobilized on SiO₂ (TiO₂/SiO₂) have been prepared by sol-gel method and various ions of transition metals (Cr³⁺, Co²⁺, Ni²⁺, Cu²⁺, and Zn²⁺) were doped on the photocatalyst using wet impregnation method under reducing calcination atmosphere. The photocatalytic activity of metal doped TiO₂/SiO₂ towards phenol degradation under black light irradiation were investigated and compared with undoped TiO₂/SiO₂. The results showed that the photoresponse of Cu²⁺ and Zn²⁺ doped TiO₂/SiO₂ were larger than undoped TiO₂/SiO₂, indicating that the photogenerated carriers were separated more efficiently in Cu²⁺ and Zn²⁺ doped TiO₂/SiO₂. The reactivity was in the order of Cu²⁺ > Zn²⁺ > Ni²⁺ > Cr³⁺ > Co²⁺. The different photoreactivity was ascribed to combine effect of the different ionic radii and photocorrison tendency of the dopants. The sample was also characterized by surface analytical methods such as X-ray diffraction, scanning electron micrograph/electron dispersive X-ray analyzer and UV-Vis absorption spectrum.     

Getting ready for the manned mission to Mars: the astronauts’ risk from space radiation

Space programmes are shifting towards planetary exploration and, in particular, towards missions by human beings to the Moon and to Mars. Radiation is considered to be one of the major hazards for personnel in space and has emerged as the most critical issue to be resolved for long-term missions both orbital and interplanetary. The two cosmic sources of radiation that could impact a mission outside the Earth’s magnetic field are solar particle events (SPE) and galactic cosmic rays (GCR). Exposure to the types of ionizing radiation encountered during space travel may cause a number of health-related problems, but the primary concern is related to the increased risk of cancer induction in astronauts. Predictions of cancer risk and acceptable radiation exposure in space are extrapolated from minimal data and are subject to many uncertainties. The paper describes present-day estimates of equivalent doses from GCR and solar cosmic radiation behind various shields and radiation risks for astronauts on a mission to Mars.     

An environmental impact assessment of quantum dot photovoltaics (QDPV) from raw material acquisition through use

Some emerging technologies are expected to be pivotal for solving many of the environmental challenges faced today, especially those related to energy. However, many of these technologies may incur significant environmental impacts over their life cycle, while having environmental benefits during their use. This paper presents results of a Life Cycle Assessment (LCA) of a proposed type of nanophotovoltaic, quantum dot photovoltaic (QDPV) module. The LCA is confined to the stages of raw materials acquisition, manufacturing, and use. The impacts of QDPV are compared with other types of PV modules and energy sources - both renewable and nonrenewable. To provide a comprehensive comparative assessment, QDPV modules were compared with mature as well as emerging PV types for which data are available. Comparative assessment with other types of energy sources includes coal, oil, lignite, natural gas, diesel, nuclear, wind, and hydropower.QDPV modules may have the potential to overcome two current barriers of solar technology: low efficiencies and high manufacturing costs. If higher efficiencies are realized, QDPV modules could pave the way to large scale implementation of solar energy, helping nations move toward greater energy independence. On the other hand, candidate materials as quantum dots for solar cell applications are mostly compound semiconductors such as cadmium selenide, cadmium telluride, and lead sulfide which may be toxic and for which renewable options are limited. Toxic effects of these materials may be exacerbated by their nanoscale features.The LCA was carried out using the software SimaPro, and the Ecoinvent Life Cycle Inventory (LCI) database supplemented with available literature and patent information. Our results indicate that while QDPV modules have shorter Energy PayBack Time (EPBT), lower Global Warming Potential (GWP), SO_x and NO_x emissions than other types of PV modules, they have higher heavy metal emissions, underscoring the need for investigation of emerging technologies, especially nano-based ones, from a life cycle perspective. QDPV modules are better in all impact categories assessed than carbon-based energy sources but they have longer EPBT than wind and hydropower and higher GWP.     

Ash deposition impact on the energy performance of photovoltaic generators

A little known side effect of the atmospheric air pollution is the degradation of photovoltaic (PV) cells’ performance due to the deposition of solid particles varying in composition, size and origin. In this context, an experimental-based investigation is conducted in order to compare the energy performance of two identical pairs of PV-panels; the first being clean and the second being artificially polluted with ash, i.e. a by-product of incomplete hydrocarbons’ combustion mainly originating from thermal power stations and vehicular exhausts. A series of systematic measurements of current intensity, voltage output and solar radiation are executed simultaneously for the clean and the polluted PV-panel, so that the effect of several mass depositions on the PVs’ power output, energy yield and conversion efficiency may be determined. According to the results, a considerable deterioration of the PV-panels’ performance is obtained, i.e. almost 30% energy reduction per hour or 1.5% efficiency decrease (in absolute terms) for ash accumulation on the panels’ surface reaching up to 0.4 mg/cm².     

TiO2/粉煤灰光催化降解双氯芬酸钠研究

以燃煤电厂外排的废弃物粉煤灰(CFA)为载体,采用混合泥浆法将TiO2负载在CFA的表面,得到一种新型的复合光催化剂TiO2/CFA.对TiO2/CFA进行了扫描电镜分析、X射线衍射分析和氮吸附测试,并以双氯芬酸钠的光催化降解为评价手段,研究了TiO2负载量对TiO2/CFA光催化性能及重复使用性能的影响.结果表明,TiO2负载量的增加有助于提高TiO2/CFA的光催化性能,但当TiO2负载量过高时,CFA上的TiO2在水处理过程中容易脱落,对TiO2/CFA光催化剂的重复使用性能不利.本研究中,最佳的TiO2负载量约为50%,循环使用6次,其光催化降解效率没有明显降低,双氯芬酸钠的降解率均可达70%以上.     

BiOCl/ZnMgAl-HTLCs复合材料光催化去除水中的甲基橙

以Mg(NO3)2·6H2O、Al(NO3)3·9H2O、Zn(NO3)2·6H2O、Bi(NO3)3·5H2O为主要原料,采用水热合成法,制备了Bi OCl/Zn Mg Al-HTLCs光催化剂,对其进行XRD、EDS、SEM、FT-IR、UV-Vis、TGA表征,并通过降解甲基橙(MO)实验,探究催化剂水热合成的p H、溶剂、温度对其光催化性能的影响.结果表明:Zn Mg Al-HTLCs改善了Bi OCl的分散性,Bi OCl/Zn Mg Al-HTLCs能够有效地催化去除水中的甲基橙,在p H=7.5、溶剂为水、T=140℃条件下,可见光催化活性最佳,光照60 min后对10 mg·L-1的甲基橙溶液(MO)的降解率均达到85%以上.综合表明,Bi OCl/Zn Mg Al-HTLCs是一种具有潜在应用前景的光催化剂.