与高层大气臭氧层不同的是,地面的臭氧是光化学烟雾的一个主要组成部分。
Ozone at ground level - not to be confused with the ozone layer in the upper atmosphere - is one of the major constituents of photochemical smog.
目前,对PCP的主要处理方法是:生物方法、芬顿试剂法、光化学、电化学、臭氧处理、超声波及金属催化氧化等处理方法。
Currently, the main treatment of PCP includes: biological method, fenton reaction photochemical method, electrodeposition, ozone treatment, ultrasonic, metallocene catalysts.
在各类环境影响类型中,光化学臭氧合成是两种方案的最主要影响类型。
Photochemical Ozone synthesis is the most important environmental impact category in both methods.
无论是从光化学角度还是从动力学角度,给出臭氧变化的机制都是初步的,但这是认识这种现象的第一步。
The mechanisms raising both in view of photochemistry and in dynamics are as yet in their infancy, but they are the first step of the whole process of understanding the phenomenon.
光化学烟雾的臭氧和氮氧化物和碳氢化合物在阳光下产生的反应。
Photochemical ozone and smog are created as nitrogen oxides and hydrocarbons react to sunlight.
这些污染物常常与其他有害物质,如铅、锌和地面臭氧一起出现。地面臭氧是汽车排气与太阳光一起发生光化学反应形成的一种烟雾成分。
The pollutants often occur with high levels of other toxins such as lead, zinc, and ground-level ozone, a component of smog formed by chemical reactions between car exhausts and sunlight.
光化学烟雾和大气臭氧形成的重要前体物之一——非甲烷烃(NMHC)的排放受到研究者的热切关注。
As one important predecessor of photo-chemical smog and ozone, non-methane hydrocarbon's (NMHC) emission is paid great attention.
研究表明,颗粒物对光化学过程的抑制造成了大气氧化能力的降低,是近地面臭氧浓度减少的可能原因。
The results indicate that impacts of atmospheric particles on photochemistry and oxidation ability of atmosphere are responsible for the reduction of the observed surface ozone concentration.
研究表明,颗粒物对光化学过程的抑制造成了大气氧化能力的降低,是近地面臭氧浓度减少的可能原因。
The results indicate that impacts of atmospheric particles on photochemistry and oxidation ability of atmosphere are responsible for the reduction of the observed surface ozone concentration.
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