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10.1: Introduction to Acids and Bases

  • Page ID
    3487
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    Learning Objectives

    Make sure you thoroughly understand the following essential ideas which have been presented above.

    • Suggest simple tests you could carry out to determine if an unknown substance is an acid or a base.
    • State the chemical definitions of an acid and a base in terms of their behavior in water.
    • Write the formula of the salt formed when a given acid and base are combined.

    The concepts of an acid, a base, and a salt are very old ones that have undergone several major refinements as chemical science has evolved. Our treatment of the subject at this stage will be mainly conceptual and qualitative, emphasizing the definitions and fundamental ideas associated with acids and bases. We will not cover calculations involving acid-base equilibria in these lessons.

    1 Acids

    The term acid was first used in the seventeenth century; it comes from the Latin root ac-, meaning “sharp”, as in acetum, vinegar. Some early writers suggested that acidic molecules might have sharp corners or spine-like projections that irritate the tongue or skin. Acids have long been recognized as a distinctive class of compounds whose aqueous solutions exhibit the following properties:

    • A characteristic sour taste (think of lemon juice!);
    • ability to change the color of litmus from blue to red;
    • react with certain metals to produce gaseous H2;
    • react with bases to form a salt and water.

    Note: Litmas

    Litmus is a natural dye found in certain lichens. The name is of Scandinavian origin, e.g. lit (color) + mosi (moss) in Icelandic. "Litmus test" has acquired a meaning that transcends both Chemistry and science to denote any kind of test giving a yes/no answer.

    How oxygen got mis-named

    The first chemistry-based definition of an acid turned out to be wrong: in 1787, Antoine Lavoisier, as part of his masterful classification of substances, identified the known acids as a separate group of the “complex substances” (compounds). Their special nature, he postulated, derived from the presence of some common element that embodies the “acidity” principle, which he named oxygen, derived from the Greek for “acid former”.

    Note

    Lavoisier had recently assigned this name to the new gaseous element that Joseph Priestly had discovered a few years earlier as the essential substance that supports combustion. Many combustion products (oxides) do give acidic solutions, and oxygen is in fact present in most acids, so Lavoisier’s mistake is understandable. In 1811 Humphrey Davy showed that muriatic (hydrochloric) acid (which Lavoisier had regarded as an element) does not contain oxygen, but this merely convinced some that chlorine was not an element but an oxygen-containing compound. Although a dozen oxygen-free acids had been discovered by 1830, it was not until about 1840 that the hydrogen theory of acids became generally accepted. By this time, the misnomer oxygen was too well established a name to be changed. The root oxy comes from the Greek word οξνς, which means "sour".

    2 Acids and the hydrogen ion

    The key to understanding acids (as well as bases and salts) had to await Michael Faraday's mid-nineteenth century discovery that solutions of salts (known as electrolytes) conduct electricity. This implies the existence of charged particles that can migrate under the influence of an electric field. Faraday named these particles ions (“wanderers”). Later studies on electrolytic solutions suggested that the properties we associate with acids are due to the presence of an excess of hydrogen ions in the solution. By 1890 the Swedish chemist Svante Arrhenius (1859-1927) was able to formulate the first useful theory of acids:

    Arrhenius Definition

    "an acidic substance is one whose molecular unit contains at least one hydrogen atom that can dissociate, or ionize, when dissolved in water, producing a hydrated hydrogen ion and an anion."

    hydrochloric acid HCl → H+(aq) + Cl(aq)
    sulfuric acid H2SO4→ H+(aq) + HSO4(aq)
    hydrogen sulfite ion HSO3(aq) → H+(aq) + SO32–(aq)
    acetic acid H3CCOOH → H+(aq) + H3CCOO(aq)

    Strictly speaking, an “Arrhenius acid” must contain hydrogen. However, there are substances that do not themselves contain hydrogen, but still yield hydrogen ions when dissolved in water; the hydrogen ions come from the water itself, by reaction with the substance.

    Definition of an acid

    An acid is a substance that yields an excess of hydrogen ions when dissolved in water.

    There are three important points to understand about hydrogen in acids:

    • Although all Arrhenius acids contain hydrogen, not all hydrogen atoms in a substance are capable of dissociating; thus the –CH3hydrogens of acetic acid are “non-acidic”. An important part of knowing chemistry is being able to predict which hydrogen atoms in a substance will be able to dissociate into hydrogen ions.
    • Those hydrogens that do dissociate can do so to different degrees. The strong acids such as HCl and HNO3 are effectively 100% dissociated in solution. Most organic acids, such as acetic acid, are weak; only a small fraction of the acid is dissociated in most solutions. HF and HCN are examples of weak inorganic acids.
    • Acids that possess more than one dissociable hydrogen atom are known as polyprotic acids; H2SO4 and H3PO4 are well-known examples. Intermediate forms such as HPO42–, being capable of both accepting and losing protons, are called ampholytes.
    H2SO4
    sulfuric acid
    HSO4 hydrogen sulfate ("bisulfate") ion SO42–
    sulfate ion
    H2S
    hydrosulfuric acid
    HS
    hydrosulfide ion

    S2–
    sulfide ion

    H3PO4
    phosphoric acid
    H2PO4
    dihydrogen phosphate ion
    HPO42–
    hydrogen phosphate ion
    PO43–
    phosphate ion
    HOOC-COOH
    oxalic acid
    HOOC-COO
    hydrogen oxalate ion
    OOC-COO
    oxalate ion

    You will find out in a later section of this lesson that hydrogen ions cannot exist as such in water, but don't panic! It turns out that chemists still find it convenient to pretend as if they are present, and to write reactions that include them.

    3 Bases

    The name base has long been associated with a class of compounds whose aqueous solutions are characterized by:

    • a bitter taste;
    • a “soapy” feeling when applied to the skin
    • ability to restore the original blue color of litmus that has been turned red by acids
    • ability to react with acids to form salts.
    • react with certain metals to produce gaseous H2

    Note

    The word “alkali” is often applied to strong inorganic bases. It is of Arabic origin, from al-kali ("the ashes") which refers to the calcined wood ashes that were boiled with water to obtain potash which contains the strong base KOH, used in soap making. The element name potassium and its symbol K (from the Latin kalium) derive from these sources.

    Just as an acid is a substance that liberates hydrogen ions into solution, a baseyields hydroxide ions when dissolved in water:

    NaOH(s) → Na+(aq) + OH(aq)

    Sodium hydroxide is an Arrhenius base because it contains hydroxide ions. However, other substances which do not contain hydroxide ions can nevertheless produce them by reaction with water, and are therefore also classified as bases. Two classes of such substances are the metal oxides and the hydrogen compounds of certain nonmetals:

    Na2O(s) + H2O → [2 NaOH] → 2 Na+(aq) + 2 OH(aq)

    NH3 + H2O → NH4+(aq) + OH(aq)

    Defination of a base

    A base is a substance that yields an excess of hydroxide ions when dissolved in water.

    4 Neutralization

    Acids and bases react with one another to yield two products: water, and an ionic compound known as a salt. This kind of reaction is called a neutralization reaction.

    HCl_NaOH.png

    This "molecular" equation is convenient to write, but we need to re-cast it as a net ionic equation to reveal what is really going on here when the reaction takes place in water, as is almost always the case.

    H+ + Cl + Na+ + OH Na+ + Cl + H2O

    If we cancel out the ions that appear on both sides (and therefore don't really participate in the reaction), we are left with the net equation

    H+(aq) + OH(aq) → H2O (1)

    which is the fundamental process that occurs in all neutralization reactions.

    Note

    Confirmation that this equation describes all neutralization reactions that take place in water is provided by experiments indicating that no matter what acid and base are combined, all liberate the same amount of heat (57.7 kJ) per mole of H+neutralized.

    In the case of a weak acid, or a base that is not very soluble in water, more than one step might be required. For example, a similar reaction can occur between acetic acid and calcium hydroxide to produce calcium acetate:

    2 CH3COOH + Ca(OH)2 → CH3COOCa + 2 H2O

    If this takes place in aqueous solution, the reaction is really between the very small quantities of H+ and OH resulting from the dissociation of the acid and the dissolution of the base, so the reaction is identical with Equation 1:

    H+(aq) + OH(aq) → H2O

    If, on the other hand, we add solid calcium hydroxide to pure liquid acetic acid, the net reaction would include both reactants in their "molecular" forms:

    2 CH3COOH(l) + Ca(OH)2 (s) → 2 CH3COO + Ca2+ + 2 H2O

    The “salt” that is produced in a neutralization reaction consists simply of the anion and cation that were already present. The salt can be recovered as a solid by evaporating the water.


    This page titled 10.1: Introduction to Acids and Bases is shared under a CC BY 3.0 license and was authored, remixed, and/or curated by Stephen Lower via source content that was edited to the style and standards of the LibreTexts platform.