methene
Chlorine molecules will break down when exposed to UV light and create CL free radicals. CL molecules will freely colide with other molecules and create free radicals. I cannot find a specific reason for why CL doesn't decompose.
Tetramethyl-lead IV acts as a catalyst in the free radical substitution reaction between methane and chlorine by generating methyl radicals through homolytic cleavage. These methyl radicals then react with chlorine to form methyl chloride and regenerate the lead catalyst, thus increasing the rate of the overall reaction.
Chloromethane is the product that is formed when methane and chlorine react with each other. Dichloromethane is another product that can also be formed when methane and chlorine react.
Natural spring water typically does not contain chlorine because it comes from underground sources, such as aquifers or springs, where chlorine is not typically found. Chlorine is a chemical that is added to municipal drinking water supplies to kill bacteria and other contaminants.
Theotically, methane can't react with Cl2 in shade as UV light is required to initiate the substitution reaction. Only when there is Cl2 can the C-H bond be broken. However, alkene can react directly with Cl2 due to hydrohalogenation.
The main sources of chlorine radicals in the atmosphere are man-made chlorofluorocarbons (CFCs) and other halocarbons. These compounds are released into the atmosphere from activities such as refrigeration, air conditioning, and aerosol propellant use. Once in the atmosphere, sunlight breaks down these compounds, releasing chlorine radicals that can contribute to ozone depletion.
In the upper atmosphere, ultraviolet (UV) radiation breaks apart chlorine-containing compounds like chlorofluorocarbons (CFCs). This process releases chlorine free radicals, which then participate in ozone-depleting reactions. The resulting chlorine free radicals can catalytically destroy ozone molecules in the stratosphere.
When chlorine water is exposed to direct sunlight, it undergoes a photochemical reaction that produces free radicals like chlorine atoms. These radicals react with water to form hydrochloric acid and hypochlorous acid. The hydrochloric acid is produced as a result of the chlorine radicals combining with water molecules.
Chlorine released from natural sources like volcanic eruptions does not significantly contribute to ozone depletion. The main concern is human-made chlorine compounds like chlorofluorocarbons (CFCs) used in refrigerants and aerosols, which can break down ozone in the stratosphere. These compounds release chlorine atoms that can catalyze the destruction of ozone molecules.
Chlorine can enter fresh water sources through the process of chlorination, where chlorine is added to the water as a disinfectant to kill harmful bacteria and pathogens. It can also enter fresh water sources through industrial discharges and runoff from areas where chlorine-based products are used or produced.
Chlorine molecules will break down when exposed to UV light and create CL free radicals. CL molecules will freely colide with other molecules and create free radicals. I cannot find a specific reason for why CL doesn't decompose.
Chlorine can enter fresh water sources through discharges from industrial activities, wastewater treatment plants, and agricultural runoff. It can also enter water sources through the use of chlorine-based disinfectants in water treatment processes.
No. Chlorine is a main group element, but is a nonmetal in the halogen family (group 17).
1. The most important part of the sodium and chlorine are dissolved from the earth salts and transported by rivers in seas/oceans.2. A small part of chlorine is originated from the eruptions of submarine volcanoes
It is a photochemical reaction; the diatomic molecule of chlorine is photochemically (under the action of photons) dissociated in chlorine radicals. Chlorine radicals react with the diatomic molecule of hydrogen to form hydrogen chloride (HCl). A radical chain reaction was initiated and is continued. For details you can read a very interesting article at the link below.
The biggest and the most deadly by far is when chlorine radicals destroy ozone since the reduction in use of chlorofluorocarbons the amount of chlorine radicals being pumped into the atmosphere has decreased, but chlorine radicals cannot be destroyed by reactions unless they are with each other.cl and o3 (chlorine and ozone)become clo and O2 (chlorineoxide and oxygen)clo and 03become cl and 202 (chlorine radical and 2 oxygen)so ozone gets destroyed a lot and the cl is free againMy friend got all his chemistry assignment answer help from examville.com and if he needs any specific question to be answered that he just can't find on any site, he posts it on examville and gets the answer...cool site.
chlorine water + sunlight gives chlorine and oxygen in normal STP conditions .