As monomers are added, water is being taken out.
Water molecule is removed during dehydration synthesis.
The nucleotide that supplies energy for dehydration synthesis is adenosine triphosphate (ATP). ATP releases energy when its terminal phosphate group is cleaved in a hydrolysis reaction, providing energy for bond formation during dehydration synthesis.
Dehydration synthesis cannot be reversed directly. To break down the molecules formed during dehydration synthesis, a hydrolysis reaction is required. This involves adding water to break the bonds between the molecules and return them to their original components.
A disaccharide forms when two monosaccharide molecules undergo a dehydration synthesis reaction, in which a water molecule is removed, leaving a covalent bond between the two monosaccharides. This process typically occurs during carbohydrate digestion and synthesis.
As monomers are added, water is being taken out.
A covalent bond is formed during dehydration synthesis, also known as a condensation reaction. This type of bond involves sharing of electrons between atoms, resulting in the formation of larger molecules such as carbohydrates, proteins, and lipids.
Water is removed during dehydration synthesis. A covalent bond is produced by dehydration synthesis. Hydrolysis, the addition of water, can break apart this bond.
When glucose is polymerized to form glycogen or starch, a water molecule is removed during each condensation reaction between glucose molecules. This process is known as dehydration synthesis.
Cyclohexene can be formed as a byproduct in the synthesis of cyclohexanone through dehydration of cyclohexanol. During the oxidation of cyclohexanol to cyclohexanone, some cyclohexanol may lose a water molecule, undergo dehydration, and form cyclohexene as a byproduct. This side reaction can occur when the temperature and reaction conditions favor dehydration over oxidation.
i have no idea because im haveing the same problem
H2O. That's why its called dehydration reaction
Water