剩余臭氧分解是影响臭氧技术应用的另一个难题。
Residual ozone disassociation is another problem that affects the application of ozone technology.
在研究中,科学家们发现含有鲨烯的皮肤碎屑覆盖在室内各种物体的表面,使得窗户、门及沙发和皮肤一样,都能分解臭氧。
In this study, the researchers determined that skin flakes on surfaces were covering those surfaces with squalene, thus making those Windows, doors or couches break up ozone as well as skin does.
但是,三氧化二氮分子的大小与电特性使它很容易被光线分解成氮和臭氧。
The size and electrical properties of nitrogen trioxide, though, are such that it is easily broken up by light into nitrogen and ozone.
一氧化二氮在地平面时是稳定的,但在高层大气中则分解而形成某种化合物,从而引发化学反应而破坏臭氧层。
Nitrous oxide is stable at ground level but breaks down in the upper atmosphere to form compounds that trigger chemical reactions that destroy ozone.
首先从理论上推导了臭氧在碳酸盐水溶液中的分解动力学方程,然后通过实验予以论证。
In this article, the decomposition dynamics equation of ozone in carbonate solution is deducted and proved through experiment.
臭氧氧化的也允许的分解产物搬迁,畅通血管动脉斑块。
Ozone also oxidizes the plaque in arteries allowing the removal of the breakdown products, unclogging vessels.
本文介绍了催化分解臭氧过程中,臭氧在催化剂表面的吸附形态,及各种条件下的反应下臭氧催化分解的动力学和机理。
This review provides many kinds of adsorbed ozone forms on the catalyst surface and the kinetics and mechanism of ozone decomposition reaction.
科学家们认为人类造成臭氧层破坏的主要原因是一些化学物质,像氯氟碳,当它们到达平流层后会分解成氯和溴,然后和臭氧发生化学反应从而破坏臭氧层。
The problem with the ozone layer is that when certain chemicals, like chlorofluorocarbons, reach the stratosphere, they break down into chlorine and bromine, which react with the ozone and destroy it.
实现用电场强度、电子能量控制臭氧产生浓度和分解。
The ozone concentration and decomposition are controlled by the electric field intensity and electron energy.
根据模型可求得超声辐射条件下臭氧在水中的自分解反应速率常数和臭氧向水中的传质系数。
Mathematical model was proposed to determine rate constants of ozone self-decomposition in water and mass transfer coefficient of ozone.
UV辐射发射装置(24)分解气流中的臭氧,臭 氧通过臭氧催化装置(26)催化。
The UV radiation emitting device (24) breaks down ozone in the air stream, catalysed by the ozone catalysing device (26).
考察了水中本底成分对催化臭氧化分解水中微量硝基苯的影响规律。
Effect of background constituents on the catalytic ozonation of nitrobenzene was investigated.
在酸性废水中主要发生臭氧与4 -氯酚分子和4 -氯酚盐离子的反应,而臭氧在水溶液中分解形成的羟基自由基的氧化作用可以忽略。
The main reactions taking place in the acid aqueous solution were those between ozone and 4-chlorophenol and 4-chlorophenol salt ion.
臭氧应用于食品,因其分解速度快,所以在食品中无残留。
Treating fruits and vegetables with ozone has been found to increase shelf-life and degrade pesticide residues of the products.
一个氯分子可以分解十万多个臭氧分子。
Onechlorinemolecule can break apart more than one hundred thousandozonemolecules.
一个氯分子可以分解十万多个臭氧分子。
Onechlorinemolecule can break apart more than one hundred thousandozonemolecules.
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