A hydrocarbon such as an alkane, alkene, or alkyne will NOT react with a hydroxide ion. Simply put, the base is not strong enough to deprotonate these molecules. The resulting anion would Not form,,,,,since a stronger base would be generated. For example, if methane was deprotonated,,,,,we would get the methide anion......This is MUCH MUCH stronger than the OH- ion........a reaction is not favorable when a stronger base is generated. The same logic applies to generation of a base from the alkene or alkyne.
Hydrocarbons do not react with sodium hydroxide under normal conditions. However, in the presence of certain catalysts or under specific reaction conditions, hydrocarbons can undergo a reaction called saponification with sodium hydroxide to form soaps and glycerol.
The reaction between glucose solution and sodium hydroxide is a chemical reaction that involves the hydrolysis of glucose molecules by the strong base (sodium hydroxide). This reaction results in the formation of sodium gluconate and water. The hydroxide ions from the sodium hydroxide cleave the glycosidic bonds in glucose molecules, leading to the breakdown of glucose into simpler compounds.
One possible product of the reaction between chloromethane and sodium hydroxide solution is methanol and sodium chloride. Methanol is formed by the substitution of the chlorine in chloromethane with the hydroxide ion from sodium hydroxide, while sodium chloride is a byproduct of the reaction.
The reaction between sodium hydroxide and sulfuric acid is called a neutralization reaction. In this reaction, sodium hydroxide (a base) reacts with sulfuric acid (an acid) to form water and sodium sulfate salt.
There is no reaction , because of the Common Ion Effect. The Common Ion is the Hydroxide.
Water is produced in the neutralization reaction between hydrochloric acid and sodium hydroxide.
A chemical reaction occurs between sodium hydroxide and hydrogen chloride. Adding more sodium hydroxide to the reaction causes it to speed up. If you add more of a reactant, such as sodium hydroxide, can it be considered a catalyst? Why or why not?
The reaction between glucose solution and sodium hydroxide is a chemical reaction that involves the hydrolysis of glucose molecules by the strong base (sodium hydroxide). This reaction results in the formation of sodium gluconate and water. The hydroxide ions from the sodium hydroxide cleave the glycosidic bonds in glucose molecules, leading to the breakdown of glucose into simpler compounds.
One possible product of the reaction between chloromethane and sodium hydroxide solution is methanol and sodium chloride. Methanol is formed by the substitution of the chlorine in chloromethane with the hydroxide ion from sodium hydroxide, while sodium chloride is a byproduct of the reaction.
Any reaction between sodium chloride and sodium hydroxide.
There is no reaction , because of the Common Ion Effect. The Common Ion is the Hydroxide.
Water is produced in the neutralization reaction between hydrochloric acid and sodium hydroxide.
Any reaction between sodium chloride and sodium hydroxide.
Any reaction between sodium chloride and hydrochloric acid.
There is no reaction, therefore no equation!!
When sodium hydroxide reacts with methanol, a neutralization reaction occurs, forming sodium methoxide and water. The balanced chemical equation for this reaction is: CH3OH + NaOH → CH3ONa + H2O
The reaction between sulfur dichloride (SCl2) and sodium hydroxide (NaOH) will produce sodium chloride (NaCl), water (H2O), and hydrogen sulfide gas (H2S) as products.
The reaction between acetic acid (CH3COOH) and sodium hydroxide (NaOH) produces sodium acetate (CH3COONa) and water (H2O).