Thermoelectric materials can convert waste heat directly into electricity. T

游客2024-03-07  21

问题     Thermoelectric materials can convert waste heat directly into electricity. Tommi Tynell, who is a doctoral candidate at the Aalto University School of Chemical Technology, has developed hybrid (混合的) thermoelectric materials which combine useful properties from different types of materials.
    He found that by adding organic layers between layers of zinc it is possible to improve the performance of thermoelectric materials. The organic layers are also believed to have a major effect in reducing thermal conductivity, which would be very useful in thermoelectric materials.
    Developing more efficient thermoelectric materials is a major challenge, because the physical properties that affect the performance of the materials are not independent of each other. The optimization of a material is very difficult, because as you improve one feature, other properties may deteriorate at the same time.
    The biggest obstacle to the broad utilization of thermoelectric generators is the low efficiency of currently known thermoelectric materials. In addition, the best existing compounds do not withstand the high temperatures required and often contain rare and harmful elements.
    In his research, Tynell added layer upon layer of nanoscale structures, examining their formation using X-ray and infrared (红外线的) devices. In the research, thin films of zinc oxide were used, because zinc oxide is one of the most promising thermoelectric oxide materials. Oxide materials are environmentally friendly and their availability is not a problem. It is believed that they will play an important role in the future development of sustainable energy technologies.
    Tynell combined atomic layer deposition and molecular layer deposition and thus succeeded in manufacturing a hybrid superlattice (超晶格) composed of organic and inorganic compounds. Atomic layer deposition is an extremely accurately controlled nanofabrication process. The process was used to produce layered nanostructures, with extremely thin organic layers alternating with thicker inorganic layers. Three different source materials were used for the organic substance: hydroquinone, 4-aminophenol and 4,4’-oxydianiline. All of the organic molecules tested were found to influence the thermoelectric properties of the thin zinc oxide film.
    Although the structures of the starting materials were quite similar, the size of the effect was quite variable depending on the source material. Hydroquinone (对苯二酚) was the most applicable of the three, because it formed the desired structures most easily.
    Tommi Tynell did his doctoral thesis in Academy Professor Maarit Karppinen’s research group. The research of the group is unique in that it is rare to use hybrid materials in thermoelectric research. Only a few research groups in the world are currently focused on investigating the properties of hybrid materials. By utilizing thermoelectric energy harvesting it will be possible to reduce our dependence on traditional energy sources. [br] What’s the weakness of the existing thermoelectric material compound?

选项 A、It can’t stand the temperatures required, containing rare and harmful elements.
B、It may lose large scale of energy while converting heat into electricity.
C、It can’t provide enough heat to produce electricity as people desired.
D、The cost to make the compound is too much for anyone to bear.

答案 A

解析 细节题。根据题干中的the existing thermoelectric material compound可定位到原文第四段第二句。该句提到,当前所存在的最佳混合物无法承受要求的高温,而且往往包含稀有及有害元素。由此可知,A选项符合,而B、C、D三项均未提到,故选A。
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