The number of water molecules is maximum in

This problem has been solved! You'll get a detailed solution from a subject matter expert that helps you learn core concepts. See Answer See Answer See Answer done loading Question:the molecular formula of a carbohydrate molecule is c24h42o21. The maximum number of glucose and water molecules that will be consumed by complete hydrolysis of the carbohydrate is a. 4 molecules of glucose and 3 molecules of water b. 6 molecules of glucose and 5 molecules of water c. 6 molecules of glucose and 3 molecules of water d. 4 molecules of glucose the molecular formula of a carbohydrate molecule is c24h42o21. The maximum number of glucose and water molecules that will be consumed by complete hydrolysis of the carbohydrate is a. 4 molecules of glucose and 3 molecules of water b. 6 molecules of glucose and 5 molecules of water c. 6 molecules of glucose and 3 molecules of water d. 4 molecules of glucose and 4 molecules of water

This problem has been solved! You'll get a detailed solution from a subject matter expert that helps you learn core concepts. See Answer See Answer See Answer done loading Question:H :0: H-N-C -С Asparagine is a polar amino acid, shown at pH 7. What is the maximum number of water molecules that, in theory, one asparagine molecule at pH 7 can hydrogen bond with? Consider any intermolecular attractions between the asparagine molecule and water to be hydrogen bonds. H CH2 0: :0: :N-H number of water molecules: H H :0: H-N-C -С Asparagine is a polar amino acid, shown at pH 7. What is the maximum number of water molecules that, in theory, one asparagine molecule at pH 7 can hydrogen bond with? Consider any intermolecular attractions between the asparagine molecule and water to be hydrogen bonds. H CH2 0: :0: :N-H number of water molecules: H Previous question Next question

You are a talking, tool-making, learning bag of water. Okay, that’s not completely fair, but it's close since the human body is 60 to 70% water. And it's not just humans—most animals and even tiny bacteria are made up mostly of water 1 ^1 1 start superscript, 1, end superscript . Water is key to the existence of life as we know it. That may sound dramatic, but it’s true—and dramatic things that are true are what make life interesting! Most of an organism’s cellular chemistry and metabolism occur in the water-based “goo” inside its cells, called cytosol. Water is not only very common in the bodies of organisms, but it also has some unusual chemical properties that make it very good at supporting life. These properties are important to biology on many different levels, from cells to organisms to ecosystems. You can learn more about the life-sustaining properties of water in the following articles: The key to understanding water’s chemical behavior is its molecular structure. A water molecule consists of two hydrogen atoms bonded to an oxygen atom, and its overall structure is bent. This is because the oxygen atom, in addition to forming bonds with the hydrogen atoms, also carries two pairs of unshared electrons. All of the electron pairs—shared and unshared—repel each other. The most stable arrangement is the one that puts them farthest apart from each other: a tetrahedron, with the O − H \text O − H start text, O, end text, minus, start text, H, end text bonds is slightly l...

https://chem.libretexts.org/@app/auth/3/login?returnto=https%3A%2F%2Fchem.libretexts.org%2FBookshelves%2FPhysical_and_Theoretical_Chemistry_Textbook_Maps%2FSupplemental_Modules_(Physical_and_Theoretical_Chemistry)%2FChemical_Bonding%2FFundamentals_of_Chemical_Bonding%2FCoordinate_(Dative_Covalent)_Bonding \( \newcommand\) • • • • • • • • A coordinate bond (also called a dative covalent bond) is a covalent bond (a shared pair of electrons) in which both electrons come from the same atom. A covalent bond is formed by two atoms sharing a pair of electrons. The atoms are held together because the electron pair is attracted by both of the nuclei. In the formation of a simple covalent bond, each atom supplies one electron to the bond - but that does not have to be the case. Figure \(\PageIndex \nonumber \] Ammonium ions, NH 4 +, are formed by the transfer of a hydrogen ion (a proton) from the hydrogen chloride molecule to the lone pair of electrons on the ammonia molecule. When the ammonium ion, NH 4 +, is formed, the fourth hydrogen is attached by a dative covalent bond, because only the hydrogen's nucleus is transferred from the chlorine to the nitrogen. The hydrogen's electron is left behind on the chlorine to form a negative chloride ion. Once the ammonium ion has been formed it is impossible to tell any difference between the dative covalent and the ordinary covalent bonds. Although the electrons are shown differently in the diagram, there is no difference between them in r...