氢倡议:氢储存挑战The Hydrogen Initiative: The Hydrogen Storage Challenge |
|
课程网址: | http://videolectures.net/mitworld_dresselhaus_thi/ |
主讲教师: | Mildred Dresselhaus |
开课单位: | 麻省理工学院 |
开课时间: | 2013-04-19 |
课程语种: | 英语 |
中文简介: | 在布什总统呼吁科学家们追求“氢能经济”之后,米尔德里德·德雷塞尔豪斯(Mildred Dresselhaus)跳上了氢气潮流。她领导能源部研究,为氢生产,储存和使用提供必要的研究途径。她将氢描述为“一种有趣的媒介”,它将提供可再生能源组合的一部分。但Dresselhaus也承认“这是一个非常困难的问题。”氢气倡议背后的前提看似简单:氢气作为水的一部分几乎无处不在,因此与化石燃料不同,它提供了几乎无穷无尽的能源供应。氢基燃料电池的效率可以是内燃机的两倍以上,使用氢作为能源的副产品是良性的。但是存在重大问题。首先,我们不能开采氢气,我们必须制造氢气,而今天的产量平均每年仅为900万吨。扩大规模还不能大规模地进行。车辆的任何实际应用必须包括与当前燃气技术竞争的存储解决方案,每个“填充”大约300英里.Dresselhaus看到解决方案,尽管是长期的,这些问题。 “氢气图片的每个方面都涉及催化剂,无论是生产,储存还是最终用途,”她说。她的纳米技术研究专长似乎特别重要。因为纳米尺寸的颗粒具有全新的工作参数,例如更大的表面积,所以它们作为催化剂非常好地起作用,特别是当涉及氢反应时。纳米结构可以允许这些过程在室温下进行,并且可以帮助更紧密地结合氢原子,从而氢燃料可以以更小和更易管理的体积储存。碳纳米管泡沫可能用于帮助将氢气加载到车辆中,因此驾驶员不必等待两个小时来填充这种高挥发性元素。成熟的氢气经济的理想,“水和阳光不知何故Dresselhaus表示,制造氢能为燃料电池提供动力为世界提供能源“并非不可能”。为实现这一目标,研究必须全力以赴解决热管理和氢动力学问题。 “我们只是认为它非常困难,”她说,“时间视野为30至50年。” |
课程简介: | Mildred Dresselhaus jumped on the hydrogen bandwagon following President Bush’s call for scientists to pursue a “Hydrogen Economy.” She led the Department of Energy study laying out essential research avenues in hydrogen production, storage and use. She describes hydrogen as “an interesting medium” that will provide one part of the renewable energy mix. But Dresselhaus also acknowledges “it is a really hard problem.” The premise behind the hydrogen initiative is deceptively simple: hydrogen, as part of water, is pretty much everywhere, so it presents a nearly endless energy supply, unlike fossil fuels. Hydrogen-based fuel cells could be more than twice as efficient as the internal combustion engine, and the byproducts of using hydrogen for energy are benign. But there are major problems. For one thing, we can’t mine for hydrogen, we have to make it, and production today averages a measly 9 million tons per year. Scaling up can’t yet be done cheaply in large quantities. Any practical application for vehicles must include a storage solution competitive with current gas technology -- approximately 300 miles per “fill up.” Dresselhaus sees solutions, albeit long-term, to these problems. “Every aspect of the hydrogen picture involves catalyses, whether in production, storage or end use,” she says. Her research specialty of nanotechnology seems to be particularly relevant. Because nano-sized particles present completely new parameters to work with, such as greater surface area, they function extremely well as catalysts, especially when it comes to hydrogen reactions. Nanostructures could permit these processes to take place at room temperature, and could help bind hydrogen atoms more tightly, so that hydrogen fuel could be stored in smaller and more manageable volumes. A carbon nanotube foam might be used to help load hydrogen into a vehicle, so drivers don’t have to wait two hours to fill up with this otherwise highly volatile element. The ideal of a mature hydrogen economy, where “water and sunlight are somehow making hydrogen to power fuel cells to supply energy for the world” is not impossible, says Dresselhaus. To get there, research must proceed at full steam to solve issues of thermal management and hydrogen kinetics. “We concluded only that it’s very difficult,” she says, with “time horizons 30 to 50 years out.” |
关 键 词: | 氢能经济; 纳米技术; 碳纳米管泡沫 |
课程来源: | 视频讲座网 |
最后编审: | 2019-05-29:lxf |
阅读次数: | 144 |