资料摘要
资料下载The storage of H2 in a safe and compact form represents a significant current challenge,[1] and there is wide-ranging interest in materials that can store and release H2 with fast kinetics and high reversibility over multiple cycles.[2] Porous coordination frameworks have become competitors to other porous materials, such as zeolites[3] and carbon materials (for example, activated carbon or nanotubes),[4] with recent studies confirming that these frameworks can store considerable quantities of H2 at 78 K.[5–11] Most studies of H2 adsorption in coordination frameworks focus on the lowpressure region (0–1 bar) and, therefore, do not fully address the relationship between porosity and storage capacity. Although recent high-pressure volumetric measurements on some coordination frameworks revealed a correlation between maximum uptake and surface area,[9] the study involved several coordination frameworks with different structure types, and the influence of pore size and shape on guest adsorption was not investigated systematically. Herein, we report the structures of three close structural analogues, along with studies of high-pressure H2 adsorption by these materials, to establish a route to higher H2 storage capacity.
The Method, Hardware and Performance of the PTR3
简介:The PTR3 is a specialized system dedicated to the highly sensitive detection of ultra low traces of volatile organic compounds and their oxidation products that enables monitoring reactions from the first oxidation steps up to highly-oxygenated organic molecules (HOMs) down to ppqV levels (Breitenlechner et al., 2017). The inlet system and the ionization chamber are especially designed to reduce surface interactions. This concept of contact free sampling allows for detecting organics of virtually all volatility classes ranging from volatile (VOC) to extremely low volatile (ELVOC). Recent results from the well-known CLOUD experiment very well illustrate the advantages of the PTR3 over a commonly used nitrate (NO3-) Chemical Ionization Mass Spectrometer (CIMS). Both instruments show a similar detection efficiency towards ELVOCs, but the PTR3 clearly excels the CIMS when it comes to the detection of less oxidized VOCs. https://www.ionicon.com/technologies/details/ptr3
Trident在散热器上的应用
简介:散热器是被动式热交换器,用于将设备产生的热量传递到流动介质中,例如液体冷却剂或空气。 • 散热器是电子和机械设备中热管理的关键
Trident在热界面材料上的应用
简介:导热硅脂、垫片、凝胶等 很多为高分子聚合物基,添加导热填料增加导热系数(石墨烯、氮化硼、陶瓷粉末等) 液体金属导热膏
Trident在导热灌封料上的应用
简介:填充型聚合物通常作为电子产品中的灌封胶,以降低接触热阻并固定电子元器件。灌封胶设计为体或胶状材料,可为电子组件提供结构支撑和物理保护,同时还可置换热量和气体以防止诸如电晕放电之类的现象。 为了提高性能电子设备的散热效果,人们越来需要导热系数更高的灌封料。
Trident在动力电池热管理上的应用
简介:Trident在动力电池热管理上的应用 电子设备和组件的热管理不当通常会导致产品性能下降、产品生命周期缩短以及给用户带来负面的使用体验。 电池的不良热管理会加速电池材料的老化,导致使用寿命缩短、循环效率降低以及存储容量降低,甚至有可能引起热失控,导致燃烧和爆炸。
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