The main uses of 1-alkane, 2-ene, and 3- (trienomethyl) benzene vary.
Among alkanes, methane is an example, which is the main component of natural gas and is often used as a fuel. For civilian use, it can be used for cooking and heating; in industry, it is also an important energy source, providing energy for various production activities. And because of its relatively stable chemical properties, it can be used as an inert medium in some specific chemical processes to ensure the smooth progress of the reaction.
Enes, such as ethylene, are the cornerstones of the chemical industry. They are widely used in the production of plastics, such as polyethylene, which is widely used in packaging, building materials, and other fields; they are also used in synthetic fibers, such as polyester fibers, which are commonly found in textiles and clothing. In addition, ethylene hydration can produce ethanol, which is an important organic solvent and chemical raw material, and is widely used in medicine, food and other industries.
(trienomethyl) benzene has a significant position in the field of organic synthesis. It can be used as a key intermediate for the preparation of various complex organic compounds. Because of its unique structure, it can participate in a variety of chemical reactions, such as electrophilic substitution reactions, etc., to construct organic molecules with special functions, which can be used in pharmaceutical research and development to prepare drugs with specific pharmacological activities. In materials science, new polymer materials can be synthesized to endow materials with special properties, such as high strength and corrosion resistance.
In summary, 1-alkane, 2-ene, and 3- (trienomethyl) benzene have indispensable and important uses in energy, chemical industry, materials, medicine, and many other fields, promoting the progress and development of human society.

1-Alkane, a genus of hydrocarbon synthesis, containing only carbon and hydrogen diphenols, connected by a single bond, and its properties are peaceful. At room temperature, small molecules of methane and ethane are gas, and those above pentane are mostly liquid, and those with macromolecules are often solid. Alkane is insoluble in water, has a density less than water, is flammable, and burns to form carbon dioxide and water. This is its remarkable property.
2-ene, an unsaturated hydrocarbon containing carbon-carbon double bonds. Because of its double bond, its activity is higher than that of alkane. At room temperature, small molecules such as ethylene and propylene are gas, and those slightly larger are liquid or solid. Alene can undergo addition reaction, can be added with hydrogen, halogen, hydrogen halide, etc., and can be polymerized due to double bonds, which is an important chemical property. And alkene is insoluble in water, and its density is slightly lower than that of water.
3 - (trifluoromethyl) benzene, which has special physical properties. In terms of phase state, it is a liquid at room temperature and has certain volatility. Because of its fluoromethyl content, the intermolecular force is different, resulting in its boiling point, melting point and other physical parameters different from common benzene series. In terms of solubility, it is insoluble in water, but soluble in common organic solvents such as ethanol, ether, chloroform, etc. From the density point of view, it is larger than water. And because of its fluorine-containing structure, its chemical stability is enhanced, and some reactivity is different from that of ordinary benzene derivatives.

1% deuterium-2% tritium-3 (trideuteromethyl) boron are all special chemical substances with different properties and are related to many fields.
Deuterium, the isotope of hydrogen, also has more neutrons in its nucleus than ordinary hydrogen. Due to its special nuclear structure, its physical and chemical properties are different from hydrogen. In chemical reactions, deuterium participates in a reaction rate that is often different from hydrogen. This phenomenon is called the isotope effect. Taking heavy water (deuterium-substituted water) as an example, its physical properties such as melting point and boiling point are slightly higher than ordinary water, because its intermolecular force is slightly stronger. And deuterium is also important in the field of nuclear physics and is a key raw material for nuclear fusion reactions.
Tritium is also an isotope of hydrogen and is radioactive. Its nucleus contains one proton and two neutrons. The radioactivity of tritium originates from its unstable nuclear structure, which will spontaneously decay and release beta particles. Its chemical properties are similar to those of hydrogen and deuterium, but its application is strictly controlled due to radioactivity. In the military, tritium is an important material for the manufacture of hydrogen bombs; in scientific research, it can be used as a tracer to track the chemical reaction process and the metabolic path of substances in living organisms.
(trideuteromethyl) Boron is a compound containing boron and has a special substituent. Boron is electron-deficient and often presents a unique chemical behavior. ( In trideuteromethyl) boron, the introduction of deuterated methyl not only affects the spatial structure of the molecule, but also changes its electron cloud distribution. This may cause the compound to exhibit special reactivity and selectivity in organic synthesis reactions, or be used as a special reagent to prepare organic materials with specific structures and properties.
All three exhibit chemical properties different from common compounds due to their unique nuclear structure or atomic composition, and play an indispensable role in energy, scientific research, materials and other fields.

1-Alkane, there is a group of compounds. Its molecules are all composed of carbon and carbon elements, and the carbon and carbon atoms are made of carbon. If you want to make an alkane, there is a common method.
2-Alkene, there is also a group of compounds, and there are carbon and carbon atoms in its molecules. The method of making alkenes also has many ways.
The method of making 3 - (trienomethyl) benzene, which is not known in ancient books, can be as follows:
-Raw materials: If you want to make (trienomethyl) benzene, you need to first obtain the starting material of the phase. For example, you can take benzene-containing substances, and you can introduce alkenyl methyl. In the past and present, it can be improved and improved, but it can be approximated in natural materials. Such as some lipids, balms, etc., or benzene-containing compounds; and some plant extracts, or containing alkenyl-methyl-based compounds.
- Reverse methods: First, it can be used to add and catalyze. Take the amount of benzene-containing raw materials, place them in crucibles and other containers, and add them with charcoal fire. In the same way, add suitable catalysts, or use powder, grass ash, etc. The catalyzed substances can promote the reaction, so that the atoms on the benzene are replaced by alkenyl-methyl groups. The reaction needs to pay attention to the heat, the heat is large, the raw materials may decompose, and the heat is small, and the reaction is slow or even difficult. Second, the method of dissolving can be used. Take a suitable solution, and dissolve the raw materials and the materials that can be introduced into the alkenyl methyl group. The solution can help all the substances to mix evenly, and it is beneficial to reverse. Place it in the first pass, and wait for the reverse. During the period, it may be necessary to mix, so as to promote its full reaction. Anti-waste, use steaming methods such as steaming, steaming, etc. Ancient steaming or using a ceramic steamer, add to separate the substances of different boils; use cloth,. In this way, (triene methyl) benzene may be obtained. However, the precision and efficiency of the ancient method are not as good as today's chemical methods.

When storing and transporting 1-alkane, 2-ene, 3-triene methyl benzene, pay attention to many matters.
When storing, choose the first environment. It should be placed in a cool and ventilated place, away from fire and heat sources, to prevent danger caused by excessive temperature. Because of its flammability, it is easy to burn and explode in case of open flames and hot topics, so fireworks are strictly prohibited in the storage area, and complete fire protection facilities, such as fire extinguishers, fire sand, etc. should be equipped for emergencies.
Furthermore, the choice of storage container is also crucial. A specially adapted container must be used to ensure good sealing and prevent leakage. Alkane, alkene and other substances are volatile. If the container is not well sealed, the escaped gas will not only pollute the environment, but also form explosive mixed gases, which will endanger safety. The storage container should be carefully inspected regularly to check for damage, corrosion and other conditions. Once found, it should be replaced or repaired in time.
During transportation, the transportation vehicle must meet safety standards. Equipped with corresponding safety equipment, such as arrestors, electrostatic grounding devices, etc., to avoid accidents caused by static electricity or sparks during transportation. Transportation personnel also need to undergo professional training to be familiar with the characteristics of the transported goods and emergency treatment methods.
In addition, reasonable arrangements should be paid attention to when loading to avoid mixing of conflicting substances. Mixing alkane and alkene with certain oxidants may cause severe chemical reactions, resulting in serious consequences. The transportation process should be kept smooth, avoid bumps and excessive vibration, and prevent material leakage due to damage to the container.
In short, when storing and transporting 1-alkane, 2-ene, 3-triene methyl benzene, regardless of environmental selection, container use, or transportation operation, it is necessary to strictly follow safety regulations and treat every link carefully to ensure safety.