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Alkali

In , an alkali is defined as a , ionic of an or , or more commonly as a that dissolves in to produce ions (OH⁻). These substances neutralize acids by combining with them to form salts and , exhibit a greater than 7 in , have a bitter , feel slippery due to their reaction with skin oils, and turn litmus paper . Common examples include (NaOH), also known as caustic soda, and (KOH), which are strong alkalis that fully dissociate in . Unlike general bases, which may be insoluble in water, alkalis are specifically water-soluble and often derived from the hydroxides of (alkali metals) or Group 2 (alkaline earth metals) elements in the periodic table. The term "alkali" originates from the Arabic word al-qaly, referring to the calcined ashes of plants ( species) from which () was historically extracted, a process dating back to ancient times for producing basic substances used in glassmaking and production. In modern chemistry, alkalis play a crucial role in neutralization reactions and are distinguished from weaker bases by their strong reactivity and corrosiveness. Their solutions conduct electricity due to the presence of free ions and are essential in maintaining acid-base balance in various natural and industrial processes. Alkalis have extensive industrial applications, including the production of soaps, detergents, and through and pulping processes, as well as in to adjust and remove impurities. , for instance, is a key output of the chlor-alkali process, where it is electrolytically produced alongside and from , and is widely used in chemical manufacturing and other processes. Other uses encompass , such as curing olives, and pharmaceuticals, where they aid in pH control and synthesis. Due to their caustic nature, handling alkalis requires safety precautions to prevent burns and environmental harm.

Etymology and History

Etymology

The term "alkali" originates from the word al-qaliy (القلي), meaning "the calcined or burnt ashes," specifically referring to the ashes obtained from burning plants ( species) to extract soda ash, a soluble alkaline substance used in early chemical processes. This term emerged during the , when scholars documented the preparation of such ashes for applications in , , and glassmaking, drawing on practical knowledge from ancient traditions. The word was adopted into as alkali around the by European alchemists, who encountered it through translations of scientific texts that preserved and advanced classical knowledge. This linguistic borrowing occurred amid the broader transmission of chemical terminology from the to , influencing alchemical practices in regions like and . In English, alkali first appeared in the late , initially denoting soda ash derived from plants, before expanding to encompass other alkaline materials by the . Earlier references to similar substances appear in ancient texts, such as Pliny the Elder's (1st century AD), where he describes nitrum—a natural soda deposit used in —as a key flux material, preferably sourced from . This prefigures the Arabic development of the term, highlighting a continuum in the recognition of alkaline extracts from natural sources. The for alkali metals later echoed this etymological root, denoting elements that yield alkaline solutions in water.

Historical Development

The use of alkali substances dates back to ancient civilizations, where extracted —a naturally occurring deposit—from sites like Natrun for essential applications. Around 3000 BC, they employed in mummification processes to dehydrate bodies by absorbing moisture as part of the overall 70-day procedure, with the body packed in for about 40 days to preserve tissues for the . Additionally, served as a flux in early glassmaking, combining with sand and to lower melting points and produce glazes and vessels during the predynastic and periods. In , contemporaneous alkali extraction involved burning halophytic plants to obtain soda-rich ashes, which were used similarly in glazing ceramics and early by the late third millennium BC. During the medieval period, Islamic scholars advanced the manipulation of alkali compounds through systematic experimentation. In the , , often regarded as a foundational figure in , developed techniques to isolate and purify alkalis from various s, including methods for deriving from common via and . His works, such as the Kitab al-Kimya (Book of ), emphasized empirical classification of substances into spirits, metals, and non-malleable bodies, with alkalis categorized for their properties, influencing European for centuries. The marked a shift toward isolating pure alkali compounds in European chemistry. In 1774, English chemist first isolated gas—recognizing it as a volatile alkali—by reacting with quicklime and collecting the gas over mercury, a discovery that expanded understanding of alkaline airs beyond fixed and . This work laid groundwork for distinguishing properties, such as its solubility in water to form an alkaline solution. Building on such insights, British chemist advanced the field in 1807 by electrolyzing molten and using a large , yielding the elemental forms of and sodium, which he named "alkali metals" to reflect their origins in alkaline earths. Industrial production of alkali scaled dramatically in the early , driven by demand for in manufacturing. In 1791, French chemist Nicolas Leblanc patented a process converting (common salt), , and into () through sequential and steps, enabling economical synthetic production. This revolutionized industries by supplying for , , and , with factories proliferating in despite environmental drawbacks, until superseded by more efficient methods later in the century.

Definition and Properties

Definition

In chemistry, an alkali is a water-soluble , typically the of an from of the periodic table, that neutralizes acids and turns paper from red to blue. These substances exhibit basic properties due to their ability to accept protons or donate ions in aqueous solutions. Alkalis form a specific of bases, distinguished by their high in , which allows them to and release ions (OH⁻). This increases the concentration of OH⁻ in , resulting in a greater than 7. For example, undergoes the following in : \ce{NaOH (s) -> Na+ (aq) + OH- (aq)} Historically, the term "alkali" referred broadly to any alkaline substance obtained from calcined plant ashes, which contained soluble salts like carbonates of or . In modern chemical usage, however, it is more precisely restricted to the hydroxides of the alkali metals (, , , , cesium, and ). Representative examples include (commonly called ) and (known as caustic potash), both of which are strong alkalis widely used in industrial applications.

Chemical Properties

Alkali hydroxides, such as (NaOH) and (KOH), are typically white crystalline solids at , exhibiting a hygroscopic nature that causes them to absorb moisture from the air. For instance, NaOH has a of 2.13 g/cm³ and a of 318.4°C, while KOH melts at approximately 360°C. These compounds demonstrate high in , often exceeding 100 g/100 mL at , and possess a corrosive character that can severely irritate , eyes, and mucous membranes upon contact. As strong bases, alkali hydroxides exhibit pronounced chemical reactivity, particularly in neutralization reactions with acids to produce salts and water, as represented by the general equation: \text{Alkali hydroxide} + \text{Acid} \rightarrow \text{Salt} + \text{H}_2\text{O} These reactions are exothermic, releasing significant heat. Additionally, their dissolution in water is highly exothermic, generating heat that can lead to boiling or splattering if not handled carefully. In aqueous solutions, alkali hydroxides undergo complete , dissociating fully into their respective metal cations and s; for example, \text{NaOH} \rightarrow \text{Na}^+ + \text{OH}^- \text{KOH} \rightarrow \text{K}^+ + \text{OH}^- This full results in high values, typically ranging from 12 to 14 depending on concentration, due to the elevated hydroxide levels. Regarding stability, alkali hydroxides are prone to reaction with atmospheric , forming carbonates; a representative reaction for NaOH is $2\text{NaOH} + \text{CO}_2 \rightarrow \text{Na}_2\text{CO}_3 + \text{H}_2\text{O} This process, combined with their hygroscopicity, can lead to gradual degradation when exposed to air.

Distinction from Bases

In , bases are substances capable of accepting protons according to the Brønsted-Lowry definition, which describes a base as a proton acceptor in an acid-base reaction. Under the definition, bases are donors that form coordinate bonds with electron-deficient . The Arrhenius definition specifies bases as compounds that increase the (⁻) concentration in aqueous solutions. A key characteristic is that bases are not required to be soluble in water; for example, (Ca(OH)₂) qualifies as a despite its low of approximately 0.173 g/100 mL at 20°C. Alkalis represent a specific category of bases defined by their solubility in water, generally referring to the hydroxides of alkali metals (Group 1 elements) such as sodium hydroxide (NaOH) and potassium hydroxide (KOH), which dissolve readily to form alkaline solutions. This solubility requirement means that all alkalis are bases, but the reverse is not true, as many bases lack sufficient water solubility to be classified as alkalis. For instance, ammonia (NH₃) acts as a base by accepting a proton to form the ammonium ion (NH₄⁺), yet it is not considered an alkali because it is not a metal hydroxide and its basicity arises from partial ionization rather than complete dissociation like metal hydroxides. Within the Arrhenius framework, bases produce OH⁻ ions in , but alkalis achieve this more efficiently due to their high and tendency to fully ionize, resulting in strongly basic solutions with values typically above 11. This full enables alkalis to exhibit strong characteristics in quantitative analyses, such as acid-base titrations, where their predictable OH⁻ release facilitates accurate determination of endpoints using indicators like . Conversely, insoluble bases like metal oxides (e.g., , MgO) react more slowly or partially with or acids, limiting their use in titrations but making them suitable for applications requiring controlled reactivity, such as in antacids or materials.

Compounds and Reactions

Alkali Salts

Alkali salts are formed through the neutralization reaction between an and an acid, resulting in the production of a and . For instance, reacts with to yield and , as shown in the equation: \text{NaOH} + \text{HCl} \rightarrow \text{NaCl} + \text{H}_2\text{O} Key types of alkali salts include neutral salts, such as sodium chloride (NaCl), which is the product of complete neutralization; carbonates, exemplified by sodium carbonate (Na₂CO₃, commonly known as soda ash); and bicarbonates, like sodium bicarbonate (NaHCO₃, or baking soda). Sodium chloride serves as a fundamental electrolyte and seasoning agent, while sodium carbonate and bicarbonate exhibit mildly basic properties due to their derivation from carbonic acid. These salts are typically highly soluble in water, forming alkaline solutions that enable diverse applications. In industry, is particularly valued for , where it facilitates by precipitating calcium ions as insoluble : \text{Na}_2\text{CO}_3 + \text{Ca}^{2+} \rightarrow \text{CaCO}_3 + 2\text{Na}^{+} This process removes hardness-causing ions, improving for detergents and boilers./Descriptive_Chemistry/Main_Group_Reactions/Reactions_of_Main_Group_Elements_with_Carbonates) Historically, soda ash holds significant importance as a key industrial chemical, primarily extracted from trona ore, a naturally occurring mineral with the composition Na₂CO₃·NaHCO₃·2H₂O. Trona mining, especially in regions like Wyoming, has supplanted earlier plant-ash methods, enabling large-scale production since the mid-20th century for uses in glassmaking and chemicals.

Alkali Metal Hydroxides

Alkali metal hydroxides are the hydroxides of the Group 1 elements: lithium hydroxide (LiOH), sodium hydroxide (NaOH), potassium hydroxide (KOH), rubidium hydroxide (RbOH), and cesium hydroxide (CsOH). These compounds are strong bases, typically prepared through distinct industrial or laboratory methods tailored to the availability of the respective metal salts. LiOH is commonly produced by the reaction of lithium carbonate with calcium hydroxide, yielding LiOH and precipitating calcium carbonate as a byproduct. NaOH is manufactured on a large scale via the chloralkali process, which involves the electrolysis of aqueous sodium chloride (brine) solution, producing NaOH at the cathode alongside chlorine gas and hydrogen. KOH is similarly obtained through the electrolysis of potassium chloride brine, analogous to the chloralkali method but using KCl as the feedstock. RbOH and CsOH, being less commercially significant, are primarily synthesized in laboratories by electrolyzing aqueous solutions of their respective chlorides (RbCl and CsCl) using specialized cells to isolate the hydroxides. A key trend in these hydroxides is their increasing in down , attributed to decreasing lattice energies as the metal ions grow larger, which outweighs the corresponding changes in energies. LiOH exhibits the lowest among them, with a solubility of approximately 12.8 g/100 mL at 20°C, while CsOH is highly soluble at over 300 g/100 mL under similar conditions, reflecting enhanced ionic dissociation and basicity. Reactivity also escalates down the group; for instance, the hydroxides become more hygroscopic and deliquescent, readily absorbing atmospheric moisture to form concentrated solutions. This progression underscores their utility in applications requiring varying degrees of . NaOH plays a pivotal role in soapmaking through , where it reacts with fats or oils (triglycerides) to produce (sodium carboxylates) and , a process essential for converting natural into cleansing agents. KOH finds application as the in alkaline batteries, such as nickel-metal hydride and zinc-manganese dioxide cells, where its high ionic facilitates efficient transport between electrodes, enhancing performance and longevity. These uses highlight the hydroxides' versatility in industrial chemistry. Due to their strong basicity, alkali metal hydroxides are highly corrosive, capable of causing severe chemical burns to , eyes, and mucous membranes upon contact, necessitating immediate rinsing with and medical attention. They are hygroscopic and must be stored in moisture-free, airtight containers to prevent unintended reactions with atmospheric or , which could form carbonates.

Natural and Environmental Contexts

Alkaline Soils

Alkaline soils, also known as sodic soils, develop primarily through the accumulation of soluble salts such as (Na₂CO₃) and (NaHCO₃) in the profile. This process is driven by environmental factors in arid and semi-arid regions, including poor drainage that prevents salt leaching, high rates that concentrate salts at the surface, and with water containing elevated levels of sodium and . Over time, these conditions lead to a exceeding 8.5, creating an alkaline that distinguishes these soils from neutral or acidic types. A defining characteristic of alkaline soils is a high exchangeable sodium (ESP > 15%), where sodium ions dominate the cation exchange sites on particles, while electrical (EC) remains relatively low (typically < 4 dS/m). This sodium dominance causes clay particles to disperse rather than flocculate, resulting in a degraded structure with reduced permeability, poor water infiltration, and a crusty, impermeable surface layer that hinders root penetration and aeration. Agriculturally, these properties lead to significant challenges, including stunted plant growth, nutrient imbalances (such as deficiencies in iron and zinc due to high pH), waterlogging in wet periods, and overall reduced crop yields, particularly for sensitive crops like beans or rice. These soils are prevalent in arid and semi-arid landscapes worldwide, with notable occurrences in the Indo-Gangetic Plain of India and Pakistan, where alluvial deposits and monsoon-influenced irrigation exacerbate salt buildup, and in the US Great Plains, including areas of South Dakota and the Southwest like New Mexico. Identification involves measuring soil pH in a 1:1 soil-to-water suspension, which confirms alkalinity above 8.5, alongside EC assessment using a saturated paste extract to evaluate soluble salt levels, and laboratory determination of ESP through analysis of exchangeable sodium relative to total cation exchange capacity. Effective management of alkaline soils centers on chemical amendments to counteract sodium effects, primarily through the application of gypsum (CaSO₄·2H₂O) at rates calculated based on ESP and soil depth, typically 1–5 tons per hectare depending on severity. Gypsum dissolves to release calcium ions (Ca²⁺), which compete with and displace sodium ions (Na⁺) from exchange sites via cation exchange, allowing the sodium to become soluble and be leached away with low-salinity irrigation water. This reclamation improves soil aggregation, enhances permeability, and restores agricultural productivity, often enabling successful cultivation within 1–3 years when combined with drainage improvements and tolerant crop selection.

Alkali Lakes

Alkali lakes, also known as soda lakes, form in closed drainage basins under arid or semi-arid conditions where evaporation rates exceed precipitation and surface outflow, leading to the progressive concentration of dissolved ions from weathering of surrounding silicate rocks and volcanic materials. In these hydrologically restricted environments, sodium ions (Na⁺) become dominant as calcium and magnesium are preferentially removed through early precipitation of carbonates, resulting in brines enriched in (Na₂CO₃) and (NaHCO₃). This process is governed by the ionic composition of inflow waters and atmospheric interactions, often yielding perennial saline waters or ephemeral salt flats during dry periods. Prominent examples include Mono Lake in eastern California, USA, a terminal lake in a volcanic basin with no outlet, where continuous evaporation since the Pleistocene has accumulated salts from Sierra Nevada inflows, creating a hypersaline system. Similarly, Lake Magadi in the Kenyan Rift Valley exemplifies this formation, with sodium-rich brines derived from hot springs and volcanic weathering in a tectonically active closed basin, precipitating vast trona beds up to 30 meters thick. These lakes highlight how tectonic subsidence and climatic aridity sustain the evaporative concentration essential for alkali accumulation. Chemically, alkali lakes are characterized by elevated concentrations of Na₂CO₃ and NaHCO₃, often exceeding 10 g/L, which buffer the water to a high pH of 9 to 11 and create strongly alkaline conditions inhospitable to most aquatic life. For instance, Mono Lake maintains a pH of approximately 9.8 with carbonate alkalinity around 150 meq/L, supporting a unique food web. These hypersaline brines (salinity >50 g/L) foster adaptations in endemic species, such as (Artemia monica), which employ osmoregulatory mechanisms like ion-transporting gills to survive in salinities up to three times that of . Economically, alkali lakes serve as vital resources for (Na₂CO₃·NaHCO₃·2H₂O) extraction, the primary industrial source of soda ash (Na₂CO₃) used in glassmaking, detergents, and chemicals. The basin in , hosting Eocene-age trona deposits from ancient alkali lakes, accounts for about 90% of U.S. soda ash production, with annual output exceeding 10 million metric tons from solution and room-and-pillar operations. Ecologically, these lakes support specialized communities of alkaliphilic microbes, including and adapted to pH >9, which drive carbon and nitrogen cycling through processes like soda dissolution and under high alkalinity. However, anthropogenic water diversions for agriculture and urban supply reduce inflow volumes, causing lake levels to decline, to rise, and habitats to shrink, as evidenced by Mono Lake's 20-foot drop since the due to stream diversions, threatening populations and migratory bird foraging.

Industrial and Ecological Impacts

Alkali compounds, particularly (NaOH), play a central role in various due to their strong properties. In production, NaOH is extensively used in the pulping stage to break down in wood fibers, facilitating the separation of for high-quality manufacturing. This process, known as kraft pulping, accounts for a significant portion of global NaOH consumption, with approximately 25% of production directed toward the . Similarly, in aluminum extraction, the employs NaOH to digest ore, dissolving aluminum oxide into sodium aluminate solution via the reaction \ce{Al2O3 + 2NaOH -> 2NaAlO2 + H2O}, enabling efficient recovery of alumina for metal . In , alkalis like NaOH are applied for pH adjustment and precipitation of metals, neutralizing acidic effluents and aiding in the removal of contaminants to meet regulatory standards. Despite these benefits, industrial alkali use has notable ecological repercussions. Runoff from alkali-intensive operations, such as and in treated waters, contributes to soil salinization by elevating sodium levels, which disrupts , reduces permeability, and impairs plant growth, leading to in affected agro-ecosystems. The , historically used to produce NaOH and through of , released mercury from cells, causing widespread ; emissions peaked in the mid-20th century but were phased out in many regions starting in the 1970s due to toxicity concerns, with full conversion to mercury-free completed in by 2020. Efforts toward include the development of bio-based alternatives to caustic soda, such as plant-derived coagulants like those from seeds, which reduce sludge production by up to 50% in compared to traditional NaOH methods, lowering environmental footprints. Regulatory frameworks, such as the REACH regulation, mandate registration, evaluation, and restriction of NaOH handling to concentrations above 2% where it is classified as corrosive, ensuring safe , , and use to minimize risks. A prominent case illustrating ecological impacts is the 1986 in , , where firefighting water contaminated with approximately 30 tons of pesticides, solvents, and mercury from a entered the River, causing that killed millions of fish, including nearly all European eels in the affected stretch, and decimated benthic populations downstream. This incident prompted international cooperation under the Rhine Action Programme, accelerating controls and .