hydrogen bond

Chemistry

(noun)

An intermolecular attraction between a partially positively charged hydrogen in one molecule and a partially negatively charged oxygen, nitrogen, or fluorine in a nearby molecule.

Related Terms

(noun)

The attraction between a partially positively charged hydrogen atom attached to a highly electronegative atom (such as nitrogen, oxygen, or fluorine) and another nearby electronegative atom.

Related Terms

(noun)

A strong intermolecular bond in which a hydrogen atom in one molecule is attracted to a highly electronegative atom (usually nitrogen or oxygen) in a different molecule.

Related Terms

Physics

(noun)

A weak bond in which a hydrogen atom in one molecule is attracted to an electronegative atom (usually nitrogen or oxygen) in the same or different molecule.

Biology

(noun)

A weak bond in which a hydrogen atom already covalently bonded to a oxygen or nitrogen atom in one molecule is attracted to an electronegative atom (usually nitrogen or oxygen) in the same or different molecule.

Related Terms

Examples of hydrogen bond in the following topics:

  • Hydrogen Bonding

    • A hydrogen bond is a type of dipole-dipole interaction; it is not a true chemical bond.
    • This hydrogen atom is a hydrogen bond donor.
    • Greater electronegativity of the hydrogen bond acceptor will create a stronger hydrogen bond.
    • Hydrogen bonds are shown with dotted lines.
    • Where do hydrogen bonds form?

  • Hydrogen Bonding and Van der Waals Forces

    • Hydrogen bonds and van der Waals interactions are two types of weak bonds that are necessary to the basic building blocks of life.
    • Two weak bonds that occur frequently are hydrogen bonds and van der Waals interactions.
    • When polar covalent bonds containing hydrogen form, the hydrogen in that bond has a slightly positive charge because hydrogen’s one electron is pulled more strongly toward the other element and away from the hydrogen.
    • This interaction is called a hydrogen bond.
    • Hydrogen bonds are also responsible for zipping together the DNA double helix.

  • Hydrogen Bonding

    • The most powerful intermolecular force influencing neutral (uncharged) molecules is the hydrogen bond.
    • Hydrogen forms polar covalent bonds to more electronegative atoms such as oxygen, and because a hydrogen atom is quite small, the positive end of the bond dipole (the hydrogen) can approach neighboring nucleophilic or basic sites more closely than can other polar bonds.
    • In the following diagram the hydrogen bonds are depicted as magenta dashed lines.
    • The molecule providing a polar hydrogen for a hydrogen bond is called a donor.
    • Also, O–H---O hydrogen bonds are clearly stronger than N–H---N hydrogen bonds, as we see by comparing propanol with the amines.

  • Biology: DNA Structure and Replication

    • Hydrogen bonding, brought on by electrostatic interactions, is critical to holding together strands of DNA.
    • Electrostatic interactions, in this case otherwise known as hydrogen bonds, are what hold these bonds together.
    • For adenine and thymine, there are two such hydrogen bonds.
    • These enzymes break the electrostatic hydrogen bonds between the two strands.
    • Describe effect of the DNA replication process on the hydrogen bonds

  • Background and Properties

    • The important classes of organic compounds known as alcohols, phenols, ethers, amines and halides consist of alkyl and/or aryl groups bonded to hydroxyl, alkoxyl, amino and halo substituents respectively.
    • As noted earlier, the relatively high boiling point of carboxylic acids is due to extensive hydrogen bonded dimerization.
    • Similar hydrogen bonding occurs between molecules of 1º and 2º-amides (amides having at least one N–H bond), and the first three compounds in the table serve as hydrogen bonding examples.
    • The last nine entries in the above table cannot function as hydrogen bond donors, so hydrogen bonded dimers and aggregates are not possible.
    • Indeed, if hydrogen bonding is not present, the boiling points of comparable sized compounds correlate reasonably well with their dipole moments.

  • Covalent Bonds and Other Bonds and Interactions

    • Two types of weak bonds that frequently occur are hydrogen bonds and van der Waals interactions.
    • When polar covalent bonds containing hydrogen are formed, the hydrogen atom in that bond has a slightly positive charge (δ+) because the shared electrons are pulled more strongly toward the other element and away from the hydrogen atom.
    • The weak interaction between the δ+ charge of a hydrogen atom from one molecule and the δ- charge of a more electronegative atom is called a hydrogen bond.
    • For example, hydrogen bonds are responsible for zipping together the DNA double helix.
    • Like hydrogen bonds, van der Waals interactions are weak interactions between molecules.

  • Analysis of Molecular Formulas

    • The number of hydrogen atoms that can be bonded to a given number of carbon atoms is limited by the valence of carbon.
    • For compounds of carbon and hydrogen (hydrocarbons) the maximum number of hydrogen atoms that can be bonded to n carbons is 2n + 2 (n is an integer).
    • The number of hydrogen atoms in stable compounds of carbon, hydrogen & oxygen reflects the number of double bonds and rings in their structural formulas.
    • The molecular formula is C4H10 (the maximum number of bonded hydrogens by the 2n + 2 rule).
    • Similarly, the introduction of a double bond entails the loss of two hydrogens, and a triple bond the loss of four hydrogens.

  • Bond Energy

    • Bond energies are commonly given in units of kcal/mol or kJ/mol, and are generally called bond dissociation energies when given for specific bonds, or average bond energies when summarized for a given type of bond over many kinds of compounds.
    • First, a single bond between two given atoms is weaker than a double bond, which in turn is weaker than a triple bond.
    • Second, hydrogen forms relatively strong bonds (90 to 110 kcal) to the common elements found in organic compounds (C, N & O).
    • Third, with the exception of carbon and hydrogen, single bonds between atoms of the same element are relatively weak (35 to 64 kcal).
    • Indeed, the fact that carbon forms relatively strong bonds to itself as well as to nitrogen, oxygen and hydrogen is a primary factor accounting for the very large number of stable organic compounds.

  • Hydrogenation

    • Addition of hydrogen to a carbon-carbon double bond is called hydrogenation.
    • The overall effect of such an addition is the reductive removal of the double bond functional group.
    • Regioselectivity is not an issue, since the same group (a hydrogen atom) is bonded to each of the double bond carbons.
    • Next, two hydrogens shift from the metal surface to the carbons of the double bond, and the resulting saturated hydrocarbon, which is more weakly adsorbed, leaves the catalyst surface.
    • This is often true, but the hydrogenation catalysts may also cause isomerization of the double bond prior to hydrogen addition, in which case stereoselectivity may be uncertain.

  • Hydrogenation

    • First, the unsaturated bond binds to the catalyst, followed by H2 dissociation into atomic hydrogen onto the catalyst.
    • Partial hydrogenation reduces most, but not all, of the carbon-carbon double bonds, making them better for sale and consumption.
    • Incomplete hydrogenation of the double bonds has health implications; some double bonds can isomerize from the cis to the trans state.
    • The process of partial hydrogenation adds hydrogen atoms and reduces the double bonds in the fatty acids, creating a semi-solid vegetable oil at room temperature.
    • Hydrogen can be added across a double bond—such as the olefin in maleic acid shown—by utilizing a catalyst, such as palladium.