Difference between revisions of "Base"
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− | A base is a type of chemical, one that can be said to receive a [[proton]], or make a -OH ion in water. By the Lewis theory, a base is an electron-pair donor. | + | A '''base''' is a type of chemical, one that can be said to receive a [[proton]], or make a -OH ion in water. By the Lewis theory, a base is an electron-pair donor. |
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==Strong vs. weak== | ==Strong vs. weak== | ||
A strong base is one that disassociates completely in the solvent. A weak base is one that does not associate completely, but achieves an equilibrium between conjugate acids and bases. | A strong base is one that disassociates completely in the solvent. A weak base is one that does not associate completely, but achieves an equilibrium between conjugate acids and bases. | ||
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===Arrhenius base=== | ===Arrhenius base=== | ||
Arrhenius bases produce a hydroxide ion when dissolved in water. These are often hydroxide salts of metal ions, most notably [[sodium hydroxide]] and [[potassium hydroxide]]. | Arrhenius bases produce a hydroxide ion when dissolved in water. These are often hydroxide salts of metal ions, most notably [[sodium hydroxide]] and [[potassium hydroxide]]. | ||
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===Brønsted-Lowry base=== | ===Brønsted-Lowry base=== | ||
Arrhenius ran into problems when trying to describe the basic nature of [[ammonia]], because ammonia does not contain a hydroxide group. Instead, Brønsted and Lowry independently described bases as being ''proton acceptors'' rather than hydroxide donors. This allowed them to describe the action of ammonia as creating hydroxide ions by removing a [[proton]] from the solvent (in most cases, water), forming the conjugate acid, and leaving hydroxide as the base: | Arrhenius ran into problems when trying to describe the basic nature of [[ammonia]], because ammonia does not contain a hydroxide group. Instead, Brønsted and Lowry independently described bases as being ''proton acceptors'' rather than hydroxide donors. This allowed them to describe the action of ammonia as creating hydroxide ions by removing a [[proton]] from the solvent (in most cases, water), forming the conjugate acid, and leaving hydroxide as the base: | ||
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By this definition, sodium hydroxide is not a base in itself, but it is a source of a base, hydroxide. The hydroxide ion can accept a proton to become water. | By this definition, sodium hydroxide is not a base in itself, but it is a source of a base, hydroxide. The hydroxide ion can accept a proton to become water. | ||
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===Lewis base=== | ===Lewis base=== | ||
Lewis bases extend the theory of proton acceptance to exactly what does the accepting: electron pairs. Lewis bases donate free electron pairs to species which lack them. All Brønsted-Lowry bases are Lewis bases because they donate electron pairs to at least one species (in this case, a proton). However, they can react with any sort of Lewis acid, one common example being metal ions. When a base such as ammonia or ethylenediamine interacts with a sufficiently acidic metal ion such as [[nickel]], a [[coordination complex|complex ion]] forms that is an adduct between the metal ion and the base. | Lewis bases extend the theory of proton acceptance to exactly what does the accepting: electron pairs. Lewis bases donate free electron pairs to species which lack them. All Brønsted-Lowry bases are Lewis bases because they donate electron pairs to at least one species (in this case, a proton). However, they can react with any sort of Lewis acid, one common example being metal ions. When a base such as ammonia or ethylenediamine interacts with a sufficiently acidic metal ion such as [[nickel]], a [[coordination complex|complex ion]] forms that is an adduct between the metal ion and the base. | ||
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Complexation reactions are in equilibrium, but the equilibrium normally shifts so far to the right that it is convenient to say that it goes to completion. | Complexation reactions are in equilibrium, but the equilibrium normally shifts so far to the right that it is convenient to say that it goes to completion. | ||
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===Usanovich definition=== | ===Usanovich definition=== | ||
A Usanovich base is any donor of a positive species or an acceptor of a negative one. These species can be individual [[electron|electrons]], thus allowing [[redox]] reactions to be described as a reaction between an acid (the oxidizer) and a base (the reducer). | A Usanovich base is any donor of a positive species or an acceptor of a negative one. These species can be individual [[electron|electrons]], thus allowing [[redox]] reactions to be described as a reaction between an acid (the oxidizer) and a base (the reducer). | ||
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+ | ===Hard-soft acid-base theory=== | ||
== Common bases == | == Common bases == | ||
The most common strong base in the lab is sodium hydroxide]]. [[Potassium hydroxide]], [[rubidium hydroxide]], and [[cesium hydroxide]] are all useful as well, but are harder to find and are generally more expensive. [[Lithium hydroxide]], [[calcium hydroxide]], [[strontium hydroxide]], and [[barium hydroxide]] are not very soluble in water, but count as strong bases. Of these, Calcium hydroxide is used most, and the least expensive of all hydroxides. Potassium hydroxide is most useful for energetic materials, as the potassium emission lines are weak and do not interfere with any desired colors. | The most common strong base in the lab is sodium hydroxide]]. [[Potassium hydroxide]], [[rubidium hydroxide]], and [[cesium hydroxide]] are all useful as well, but are harder to find and are generally more expensive. [[Lithium hydroxide]], [[calcium hydroxide]], [[strontium hydroxide]], and [[barium hydroxide]] are not very soluble in water, but count as strong bases. Of these, Calcium hydroxide is used most, and the least expensive of all hydroxides. Potassium hydroxide is most useful for energetic materials, as the potassium emission lines are weak and do not interfere with any desired colors. | ||
[[Ammonia]] is the most common weak base in the lab. | [[Ammonia]] is the most common weak base in the lab. | ||
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+ | ==References== | ||
+ | <references/> | ||
+ | ===Relevant Sciencemadness threads=== | ||
+ | *[http://www.sciencemadness.org/talk/viewthread.php?tid=65082 Acids and Bases: Brønsted–Lowry Theory (an interactive educational thread)] | ||
[[Category:Chemical compounds]] | [[Category:Chemical compounds]] |
Revision as of 16:13, 1 September 2016
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A base is a type of chemical, one that can be said to receive a proton, or make a -OH ion in water. By the Lewis theory, a base is an electron-pair donor.
Contents
Strong vs. weak
A strong base is one that disassociates completely in the solvent. A weak base is one that does not associate completely, but achieves an equilibrium between conjugate acids and bases.
Superbases are very strong bases which react with water, like if it was an acid, to completion. Some examples of superbases are alkoxides and alkyl compounds of alkali metals.
Types
Arrhenius base
Arrhenius bases produce a hydroxide ion when dissolved in water. These are often hydroxide salts of metal ions, most notably sodium hydroxide and potassium hydroxide.
Brønsted-Lowry base
Arrhenius ran into problems when trying to describe the basic nature of ammonia, because ammonia does not contain a hydroxide group. Instead, Brønsted and Lowry independently described bases as being proton acceptors rather than hydroxide donors. This allowed them to describe the action of ammonia as creating hydroxide ions by removing a proton from the solvent (in most cases, water), forming the conjugate acid, and leaving hydroxide as the base:
NH3 + H2O ⇌ NH4+ + OH-
Ammonia is a weak base, so the reaction does not go to completion.
By this definition, sodium hydroxide is not a base in itself, but it is a source of a base, hydroxide. The hydroxide ion can accept a proton to become water.
Lewis base
Lewis bases extend the theory of proton acceptance to exactly what does the accepting: electron pairs. Lewis bases donate free electron pairs to species which lack them. All Brønsted-Lowry bases are Lewis bases because they donate electron pairs to at least one species (in this case, a proton). However, they can react with any sort of Lewis acid, one common example being metal ions. When a base such as ammonia or ethylenediamine interacts with a sufficiently acidic metal ion such as nickel, a complex ion forms that is an adduct between the metal ion and the base.
[Ni(H2O)6]2+ + 3C2H4(NH2)2 → [Ni(C2H4(NH2)2)3]2+ + 6H2O
Complexation reactions are in equilibrium, but the equilibrium normally shifts so far to the right that it is convenient to say that it goes to completion.
Usanovich definition
A Usanovich base is any donor of a positive species or an acceptor of a negative one. These species can be individual electrons, thus allowing redox reactions to be described as a reaction between an acid (the oxidizer) and a base (the reducer).
Hard-soft acid-base theory
Common bases
The most common strong base in the lab is sodium hydroxide]]. Potassium hydroxide, rubidium hydroxide, and cesium hydroxide are all useful as well, but are harder to find and are generally more expensive. Lithium hydroxide, calcium hydroxide, strontium hydroxide, and barium hydroxide are not very soluble in water, but count as strong bases. Of these, Calcium hydroxide is used most, and the least expensive of all hydroxides. Potassium hydroxide is most useful for energetic materials, as the potassium emission lines are weak and do not interfere with any desired colors.
Ammonia is the most common weak base in the lab.