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Flame

Flame, also known as Flamer, sKyWIper, and Skywiper, is a modular computer discovered in 2012 that attacks computers running the Windows operating system for purposes. The malware is notable for its massive size and complexity, with a main body exceeding 20 megabytes and numerous add-on modules enabling capabilities such as , capture, audio recording via activation, and network . Primarily deployed in the , Flame infected thousands of machines in and other countries like , , and , collecting sensitive information for intelligence gathering. Researchers at , in collaboration with the CrySyS Lab at University of Technology and Economics and Iran's , identified Flame on May 28, 2012, revealing it as one of the most advanced cyber threats at the time. Flame shares cryptographic algorithms and development patterns with and , leading experts to believe it was developed by the same or closely related state-sponsored groups, possibly the and , though no official attribution has been confirmed. Its propagation methods included exploiting Windows vulnerabilities and using command-and-control servers disguised as legitimate updates, allowing it to remain undetected for up to five years prior to discovery. Unlike destructive like , Flame focused on rather than , marking a significant in nation-state operations.

Definition and Classification

Definition

A flame is the visible, luminous region within a process, characterized by hot, glowing gases undergoing rapid exothermic chemical reactions, often resulting in a partially ionized state known as a weakly ionized . This plasma-like behavior arises from the high temperatures that partially dissociate gas molecules, allowing electrons to become mobile, though typical flames from everyday fuels do not reach the full levels of true plasmas. The stems from the of reacting species and chemiluminescent emissions, distinguishing flames as dynamic zones of energy release during oxidation. The core prerequisites for flame formation involve the interaction of , oxidizer, and , forming the foundational "" that sustains the process. Fuel provides the combustible material, typically hydrocarbons or other organics, while the oxidizer—most commonly atmospheric oxygen—facilitates the ; serves as the ignition source to initiate the self-propagating exothermic chain. This combination creates a gaseous reaction zone where occurs, releasing energy that maintains the flame without external input. Unlike the broader concept of , which includes the entire burning phenomenon including solid or liquid phases, a flame specifically refers to this confined, visible gaseous interface of ongoing reactions. Flame initiation requires specific conditions, including reaching the ignition —the minimum at which the fuel-oxidizer autoignites—and maintaining concentrations within flammable s to support . Below the lower flammable limit, the is too lean to sustain , while above the upper limit, it becomes too rich; for example, in air ignites between 5% and 15% by volume, with an ignition of 537°C. These limits ensure the reaction zone remains viable, preventing or outside the optimal range. The term "flame" originates from the Latin flamma, denoting a blaze or , entering English via in the . Historical recognition of flames dates to ancient texts, such as 's Meteorology, where he described flame as "burning smoke or dry exhalation," classifying as one of the four —hot and dry—and observing its natural tendency to rise due to its lightness relative to air.

Types of Flames

Flames are classified primarily by the manner in which fuel and oxidizer mix prior to or during , as well as by the and propagation mode, which influence their behavior and stability. Premixed flames occur when fuel and oxidizer are thoroughly mixed before ignition, resulting in uniform across the reaction zone. A classic example is the flame, where a homogeneous propagates steadily. In these flames, propagation is governed by the laminar S_L, which the Zeldovich-Frank-Kamenetskii theory derives through , with S_L scaling as the square root of times a characteristic rate. In contrast, diffusion flames form when and oxidizer are initially separate and mix primarily through molecular and turbulent during the process, leading to a reaction zone at the . Common in everyday fires, such as the candle flame, these flames burn more slowly than premixed ones because the rate is limited by mixing rather than intrinsic . Incomplete mixing often results in higher production, as fuel-rich pockets undergo before full oxidation, contributing to luminous yellow regions in the flame. Partially premixed flames represent a , where and oxidizer are introduced separately but achieve partial mixing upstream of the reaction zone due to or , combining elements of both premixed and diffusion behaviors. These flames are prevalent in practical devices like combustors, where scalar gradients lead to varying local ratios and enhanced stabilization. Flames can further be categorized by flow regime into laminar and turbulent types, determined by the Reynolds number (Re), which compares inertial to viscous forces in the unburned mixture. Laminar flames maintain smooth, steady fronts at low Re (typically below 100–10,000, depending on geometry), while turbulent flames emerge at higher Re > 2000, exhibiting wrinkled fronts, increased surface area, and enhanced burning rates due to chaotic mixing. Regarding propagation modes, most flames operate as deflagrations, with flame speeds (typically < 100 m/s) driven by heat and mass diffusion ahead of the front. Detonations, however, involve supersonic propagation (> in the mixture), where a compresses the reactants, leading to rapid energy release and peak pressures up to 20 atm in confined systems like power applications.

Combustion Mechanism

Chemical Reactions

The combustion of flames primarily involves the oxidation of hydrocarbon fuels by oxygen, represented by the general stoichiometric equation for complete combustion: \mathrm{C}_n\mathrm{H}_m + \left(n + \frac{m}{4}\right)\mathrm{O}_2 \rightarrow n\mathrm{CO}_2 + \frac{m}{2}\mathrm{H}_2\mathrm{O} This reaction releases heat and sustains the flame through exothermic processes. For example, the combustion of methane (\mathrm{CH_4}) follows \mathrm{CH_4 + 2O_2 \rightarrow CO_2 + 2H_2O}, with a standard heat of combustion of approximately 890 kJ/mol, which provides the thermal energy for self-propagating reactions. This exothermicity enables the flame to maintain temperatures sufficient for continuous reaction without external heating. At the molecular level, flame combustion proceeds via free-radical chain reactions, categorized into , , branching, and termination steps. typically begins with the () of the , generating initial s such as \mathrm{H \cdot} or \mathrm{OH \cdot}, often requiring energies around 150 kJ/mol for hydrocarbons like . involves s reacting with molecules to form products and new s, for instance, \mathrm{H \cdot + O_2 \rightarrow OH \cdot + O \cdot}, sustaining the chain without net radical consumption. Branching amplifies the radical pool, as seen in \mathrm{OH \cdot + H_2 \rightarrow H_2O + H \cdot}, which produces more radicals than it consumes, accelerating the . Termination occurs through radical recombination, such as $2\mathrm{H \cdot + M \rightarrow H_2 + M}, where M is a third body, limiting chain length and preventing explosion under certain conditions. Intermediates play a critical role in flame chemistry, particularly in non-stoichiometric conditions. In fuel-lean mixtures, the primary products are \mathrm{CO_2} and \mathrm{H_2O}, but carbon monoxide (CO) forms as an intermediate via partial oxidation, such as \mathrm{CO_2 + \mathrm{C \cdot} \leftrightarrow 2\mathrm{CO}. Under fuel-rich conditions, incomplete combustion leads to soot precursors like polycyclic aromatic hydrocarbons (PAHs) and acetylene (\mathrm{C_2H_2}), which nucleate into particulate soot through polymerization and growth mechanisms. These intermediates influence flame efficiency and emissions. Additionally, in high-temperature flames, nitrogen oxides (NOx) form via the Zeldovich mechanism, initiated by \mathrm{N_2 + O \cdot \rightarrow NO + N \cdot}, followed by \mathrm{N \cdot + O_2 \rightarrow NO + O \cdot}, contributing to atmospheric pollutants when flames exceed about 1800 K.

Physical Structure

A flame's physical structure is organized into distinct internal zones that reflect the of , , and reaction rates. The preheat zone, located ahead of the primary reaction region, is where heat conduction from the flame front raises the of the unburned , facilitating ignition without significant chemical activity. This zone transitions into the reaction zone, a thin layer typically 0.1 to 1 mm thick, where the majority of exothermic reactions occur, consuming fuel and oxidizer at rapid rates. Beyond this lies the oxidation zone, in which residual intermediate undergo further oxidation to complete the combustion process, leading to the fully burned products. Transport phenomena govern the dynamics across these zones, enabling the movement of heat, mass, and momentum. Species diffusion follows Fick's law, expressed as \mathbf{J} = -D \nabla c, where \mathbf{J} is the diffusive flux, D the diffusion coefficient, and \nabla c the concentration gradient, which supplies reactants to the reaction zone. Convection, often buoyancy-driven due to density differences between hot products and cooler reactants, is quantified by the Grashof number Gr = \frac{g \beta \Delta T L^3}{\nu^2}, where g is gravity, \beta the thermal expansion coefficient, \Delta T the temperature difference, L a characteristic length, and \nu kinematic viscosity; high Gr values indicate dominant natural convection flows. Thermal conduction complements these by transferring heat upstream into the preheat zone, balancing the energy required for sustained propagation. The flame front's propagation is characterized by its laminar thickness \delta = \frac{\alpha}{S_L}, where \alpha is the of the unburned mixture and S_L the , providing a measure of the over which the transition from unburned to burned gas occurs. This thickness typically ranges from 0.1 to 1 mm for common hydrocarbon-air mixtures, influencing overall and speed. In premixed flames, the Darrieus-Landau hydrodynamic instability arises from the acceleration of flow through the density discontinuity at the flame front, promoting perturbations that evolve into cellular structures and enhanced surface area. In confined environments, flame quenching becomes prominent when the gap distance falls below a critical quenching distance, approximately 2 mm for methane-air mixtures at standard conditions, beyond which heat losses to walls extinguish the flame. Wall effects in such setups introduce additional complexities, including altered velocity profiles and enhanced conductive , which can stretch and weaken the flame front, potentially leading to incomplete propagation or .

Optical and Thermal Properties

Flame Color

The color of a flame arises from the emission of light due to thermal excitation, combining continuum radiation from hot gases and particles with discrete line spectra from electronically excited atoms and molecules. In the continuum component, follows , where the peaks at wavelengths determined by the of the emitting species, such as particles or gas volumes. Superimposed on this are sharp emission lines and bands from atomic transitions (e.g., metal ions) and molecular radicals in excited states, which dominate the and produce characteristic hues./University_Physics_III_-Optics_and_Modern_Physics(OpenStax)/06%3A_Photons_and_Matter_Waves/6.02%3A_Blackbody_Radiation) Specific colors depend on the chemical species involved in the combustion. Blue flames typically result from emissions of CH* and C₂* radicals, with the latter producing prominent Swan bands around 473 nm and 516 nm in hydrocarbon flames. In contrast, yellow or orange hues often stem from the sodium D-line at 589 nm, emitted by trace sodium impurities in fuels, or from the incandescence of carbon soot particles under oxygen-limited conditions. These spectral features allow flames to serve as visual indicators of composition, with cleaner, radical-dominated burns appearing bluish and sooty ones shifting toward warmer tones. Flame color correlates with through the shift in peak emission , as described by : \lambda_{\max} T = 2898 \, \mu\mathrm{m \cdot K}, where hotter flames (e.g., above 2000 K) emit more due to shorter \lambda_{\max}, while cooler ones peak in the yellow-red range. The , influenced by fuel-oxidizer mixtures, thus modulates this shift, though line emissions can overlay and alter the perceived color. For instance, high-temperature premixed flames often appear blue from bands, whereas lower-temperature flames may glow yellow from . Several factors beyond temperature affect flame color, primarily tied to fuel chemistry and combustion environment. Fuel type plays a key role; for example, alcohol flames like those from methanol burn pale blue due to minimal soot and dominant CH* emissions in oxygen-rich conditions. Additives introduce atomic lines, such as copper salts yielding green hues (around 500-570 nm) in pyrotechnic applications like fireworks. Oxygen availability is critical: in diffusion flames with limited mixing, incomplete combustion produces soot, leading to yellow incandescence, whereas premixed flames remain blue. In modern flame diagnostics, color analysis enables non-intrusive temperature measurement through ratio pyrometry, where the intensity ratio of two spectral bands (e.g., red-to-blue channels) correlates with temperature, compensating for emissivity variations in sooting flames without physical probes. This technique, applied in combustion research and industrial monitoring, leverages digital imaging to map two-dimensional temperature fields with errors under 100 K.

Flame Temperature

The adiabatic flame temperature represents the maximum theoretical temperature achievable in a combustion process under constant pressure with no heat loss to the surroundings, serving as a key benchmark for flame energetics. It is calculated using the energy balance equation T_{af} = T_0 + \frac{\Delta H_c}{n C_p}, where T_0 is the initial temperature of the reactants, \Delta H_c is the heat of combustion per mole of fuel, n is the number of moles of products, and C_p is the average specific heat capacity of the products. This formulation assumes complete combustion and neglects dissociation effects initially. For a stoichiometric methane-air mixture at standard conditions, the adiabatic flame temperature is approximately 2226 K. In practical flames, actual temperatures are lower due to heat losses and incomplete combustion but still reach significant levels depending on the fuel and oxidizer. A typical candle flame operates at around 1400 K in its hottest region, while a Bunsen burner with a natural gas-air mixture achieves about 1900 K in the inner cone. The oxy-acetylene flame represents one of the highest practical temperatures at approximately 3300 K, enabling applications like metal cutting due to its intense heat. Flame temperatures are measured using various techniques, each with trade-offs in accuracy and intrusiveness. Thermocouples, often made of platinum-rhodium, provide direct readings but introduce errors of about 100 K or more due to radiative heat loss from the probe, requiring corrections for conduction and radiation. Optical pyrometry estimates temperature non-intrusively by analyzing the flame's thermal radiation spectrum, applying Wien's displacement law to relate peak wavelength to temperature for blackbody approximations. Coherent anti-Stokes Raman spectroscopy (CARS) offers high-precision, non-intrusive measurements by probing molecular vibrations in the flame gases, achieving accuracies within 50 K without physical probes. Several factors influence flame temperature, primarily the equivalence ratio, pressure, and dissociation at elevated temperatures. The equivalence ratio, defined as the actual fuel-to-oxidizer ratio divided by the stoichiometric ratio, yields the peak temperature at unity (stoichiometric conditions), with lean or rich mixtures reducing it due to excess inert diluents absorbing heat. Increasing pressure raises the adiabatic flame temperature by roughly 10% per atmosphere, as higher densities enhance reaction rates and limit dissociation, though the effect diminishes at extreme pressures. At temperatures above 2000 K, dissociation of products like O₂ into 2O consumes energy, effectively lowering the observed temperature by 200–500 K compared to undissociated predictions. In laboratory settings, specialized flames produced by electric arcs or laser ignition can exceed 5000 K transiently, far surpassing conventional combustion limits and enabling studies of plasma-like behaviors. For instance, arc-heated flames in controlled environments reach up to 6000 K, while laser-induced breakdown in gaseous fuels can produce localized hotspots over 10,000 K for microseconds.

Specialized Phenomena

Cool Flames

Cool flames represent a distinct low-temperature combustion phenomenon involving self-sustaining oxidation reactions at temperatures typically ranging from 150 to 400 °C, below the threshold for conventional ignition and full exothermic combustion. Unlike hot flames, these processes release minimal heat and generate weak chemiluminescence, often manifesting as pale blue or nearly invisible emissions primarily from excited formaldehyde (CH₂O*) and other intermediates. The underlying mechanism centers on two-stage ignition chemistry prevalent in hydrocarbons, where initial oxidation forms alkyl peroxy radicals (RO₂•) that drive chain branching. In the cool flame stage, these RO₂• radicals isomerize to hydroperoxyalkyl radicals (QOOH), which decompose via pathways such as RO₂• → carbonyl compounds + OH•, amplifying radical production and sustaining the reaction without rapid heat buildup. This branching occurs prominently in the negative temperature coefficient (NTC) regime, approximately 250–400 °C, where rising temperature paradoxically slows reactivity as peroxy-dominated pathways yield to less efficient high-temperature chains, leading to delayed full ignition. In practical examples, cool flames frequently precede autoignition in internal combustion engines, acting as precursors to knock when unburned end-gas oxidizes prematurely, as seen in fuels like n-heptane under compression. Their subtle pale blue or invisible nature heightens risks in fuel handling, as they can propagate undetected before escalating to hot ignition. Pioneered in the 1920s by D.T.A. Townend through flow reactor studies of hydrocarbons and ethers, cool flame research has evolved to address autoignition control for improved engine timing and efficiency. Today, they inform designs for low-emission combustors by leveraging NTC behavior to extend lean-burn limits and minimize NOx formation. In the 2020s, microgravity investigations on the International Space Station, including the Flame Extinguishment Experiment (FLEX) and Cool Flames Investigation (CFI-G), have demonstrated self-sustaining cool flames lasting hours without buoyancy-driven convection, revealing enhanced stability and novel diffusion-dominated structures for advanced combustion modeling.

Edge Flames

Edge flames represent the dynamic structures that form at the boundaries or edges of flame sheets in non-premixed combustion, where fuel and oxidizer streams meet at an interface, facilitating the transition between burning and non-burning regions. These flames are prevalent in diffusion flame configurations and lifted jet flames, where the flame base detaches from the fuel source and propagates upstream against the flow. The concept was formalized in theoretical analyses emphasizing their role in flame initiation and stabilization, distinguishing them from bulk premixed or diffusion flames by their localized, edge-dominated propagation. The internal dynamics of edge flames typically feature a tribrachial structure, comprising two premixed flame branches—a lean premixed wing extending toward the oxidizer side and a rich premixed wing toward the fuel side—joined by a central non-premixed diffusion flame branch. This configuration arises due to the scalar gradients at the interface, enabling enhanced propagation compared to isolated premixed flames. The propagation speed of the edge is modulated by hydrodynamic stretch and curvature effects, quantified through the Markstein number, which describes how local flame speed varies with these perturbations; positive Markstein numbers indicate stabilization under convex curvature, while negative values promote instability. Seminal studies, such as those by Chung, established the tribrachial model's predictive power for lifted flame bases in jets. Stability of edge flames depends on balancing convective and reactive timescales, often anchored by radiative heat loss to unburned reactants or aerodynamic focusing from the flow field, which maintains the tribrachial tip against . Extinction limits are governed by the , defined as the ratio of flow residence time to chemical reaction time: Da = \frac{\tau_{\text{flow}}}{\tau_{\text{chem}}} where stability persists for Da > 1, allowing the edge to resist blow-off; below this threshold, the flame retracts or extinguishes due to insufficient reaction rates relative to straining. Theoretical frameworks by Buckmaster highlighted these wave-like behaviors, with positive, negative, or zero propagation speeds tunable via . In practical applications, edge flame dynamics inform modeling of flame anchoring in gas turbine combustors, where lifted diffusion flames enhance mixing and reduce NOx emissions through controlled stabilization at the jet periphery. Similarly, in wildfire propagation, the leading edge of flames spreading over heterogeneous fuel beds exhibits edge flame characteristics, influencing headfire rates under wind-driven conditions. Experimental investigations employ schlieren imaging to visualize density gradients, revealing the tribrachial contours and propagation velocities in controlled jet setups. Post-2010 numerical advancements, particularly large eddy simulations (LES), have advanced understanding of turbulent edge flames by resolving unsteady evolution in spark-ignited jets, demonstrating how turbulence modulates lift-off heights and partial premixing at the base—for instance, in methane-air systems where edge contributions dominate stabilization. These LES approaches integrate subgrid models for scalar dissipation, outperforming Reynolds-averaged methods for capturing intermittent edge behaviors.

Flames in Microgravity

In microgravity environments, the absence of buoyancy-driven convection fundamentally alters flame behavior, leading to spherical symmetry in diffusion flames as fuel and oxidizer mix primarily through diffusion rather than convective flows. This results in slower mixing rates compared to Earth conditions, where buoyancy induces rapid upward flow of hot gases and entrainment of ambient air, causing flames to elongate vertically. Consequently, microgravity diffusion flames tend to grow larger in diameter—often several centimeters—while exhibiting lower peak temperatures due to reduced oxygen supply rates and increased radiative heat losses. These characteristics have been observed in burner-stabilized experiments aboard spacecraft, where flames maintain a near-perfect spherical shape around the fuel source until extinction. Key experiments have illuminated these dynamics, including the 1997 Space Shuttle mission, which featured the Laminar Soot Processes (LSP) experiment to study non-buoyant laminar jet diffusion over extended microgravity periods of up to 16 days. This work revealed detailed soot volume fraction profiles and flame structures unattainable on , confirming the spherical enclosure of within the flame zone. More recently, the Flame Extinguishment Experiment-2 (FLEX-2), conducted on the with results analyzed in 2022 publications, investigated propagation around fuel droplets in microgravity, demonstrating sustained low-temperature modes that persist longer than in normal gravity. These ISS-based droplet studies highlighted oscillatory behaviors and transitions to , providing on ignition and under diffusion-dominated conditions. Extinction limits for microgravity flames are notably lower than on Earth, with flames sustaining combustion at oxygen concentrations around 17%—compared to approximately 18% in normal gravity—due to diminished aerodynamic strain rates that allow slower, more stable diffusion processes. This reduced threshold has been documented in NASA's Zero Gravity Research Facility drop tower tests, where materials like PMMA cylinders exhibited persistent flame spread in oxygen-lean environments that would quench flames under 1g conditions. Post-2020 simulations of partial gravity environments, such as lunar conditions (1/6g), have further explored hybrid flame regimes blending microgravity diffusion with weak buoyancy effects, revealing expanded flammability windows and heightened spread risks near lunar gravity levels. These findings carry critical implications for spacecraft fire safety, as microgravity flames pose unique hazards like slower but more persistent burning in low-oxygen atmospheres, potentially leading to undetected flare-ups in enclosed habitats. Spherical flame geometries also show reduced visible soot emission near extinction limits, attributed to enhanced oxidation within the enclosed structure and diffusion-dominated quenching mechanisms that limit soot escape. Such insights inform the design of fire suppression systems and material selection for future missions, emphasizing the need for elevated oxygen monitoring to mitigate risks in reduced-gravity settings.

Thermonuclear Flames

Thermonuclear flames describe turbulent, propagating fronts of reactions within dense plasmas, most prominently in astrophysical environments such as Type supernovae explosions of carbon-oxygen dwarfs. These structures analogously to chemical flames by advancing through the medium via and instabilities, but they involve thermonuclear rather than oxidation, and they do not visible . In Type events, ignition occurs near the Chandrasekhar mass limit (~1.4 solar masses), where accreted material triggers runaway carbon in the degenerate . The underlying mechanism centers on the rapid of carbon and oxygen nuclei at temperatures exceeding 10^9 , converting them into intermediate-mass and iron-group elements through successive alpha-capture reactions. This process liberates approximately 6-8 MeV of energy per nucleon, corresponding to an release on the order of 10^{13} J/—orders of magnitude greater than chemical flames—driving expansion and further ignition. Flame speeds in the initial subsonic phase typically reach ~100 km/s, sustained by and turbulent mixing in the . As burning progresses, the flame structure evolves into a complex, wrinkled conglomerate with distinct zones of carbon, oxygen, and combustion, depending on local density gradients. Propagation begins as a laminar but accelerates due to hydrodynamic instabilities, notably Rayleigh-Taylor effects at the , where denser falls into unburned , enhancing wrinkling and . This leads to a (), where the surges supersonically to thousands of km/s, generating a shock wave that completes the white dwarf's disruption and ejects ~10^{51} erg of kinetic energy. The DDT mechanism is pivotal for matching observed Type Ia supernova spectra, nucleosynthetic yields, and light curves, as pure deflagrations underproduce iron-group elements while pure detonations overproduce them. Laboratory analogs of thermonuclear flames are realized in (ICF) experiments, where laser-driven implosions compress deuterium-tritium fuel to densities and temperatures mimicking stellar cores, igniting a propagating burn wave. At the (NIF), a was achieved on , 2022, with scientific : 3.15 MJ of output from 2.05 MJ of delivered to the , demonstrating self-sustaining thermonuclear propagation beyond ignition. These experiments validate models of flame-like burn in dense plasmas and inform astrophysical simulations. Observations from the (JWST) in the 2020s have bolstered these models by revealing spectral and morphological details in Type Ia supernovae and remnants. For instance, JWST mid-infrared of events like SN 2022aaiq and SN 2024gy shows enhanced central nickel abundances consistent with scenarios, while imaging of young remnants like displays clumpy distributions aligning with turbulent flame predictions from hydrodynamical simulations. These findings refine our understanding of flame dynamics and systems.

History and Uses

Historical Context

The understanding of flames dates back to , where they were conceptualized both philosophically and harnessed practically. In the 5th century BCE, Greek philosopher proposed a foundational theory positing fire as one of four eternal "roots" or elements—alongside earth, air, and water—that constituted all matter, with cosmic forces of love and strife governing their mixtures and separations. This elemental view of fire as a fundamental substance influenced Western thought for millennia, framing flames not merely as a phenomenon but as a building block of reality. Concurrently, by around 2000 BCE, flames were essential in early during the , where controlled fires in furnaces enabled the of ores into alloys like , marking a pivotal advancement in human technology across regions such as the and . The scientific study of flames accelerated in the with the chemical revolution. In the 1770s, demonstrated the critical role of oxygen in , overturning the by showing that burning substances combined with oxygen from the air, leading to the formation of acidic products like from flames. This quantitative approach, supported by precise measurements of gas volumes, established as an oxidative process and laid the groundwork for modern chemistry. In the early , practical innovations addressed flame hazards in industrial settings. In 1815, invented the for coal mines, featuring a flame enclosed by fine that dissipated heat to prevent ignition of explosive () while allowing light to pass through. This device, tested in British collieries, reduced mine explosions by quenching potential flames through across the gauze. The mid-19th century saw advancements in flame control for use. In 1855, , in collaboration with Peter Desaga, developed the , which premixed fuel gas and air before ignition to produce a hot, non-luminous flame reaching temperatures over 1,500°C, ideal for spectroscopic analysis and chemical reactions. Toward the end of the century, in the 1880s, French scientists Émile Mallard and Henry Le Chatelier pioneered the thermal theory of flame propagation, proposing that arises from heat conduction ahead of the reaction zone, with their 1883 work in the Annales des Mines correlating burning velocities to in gaseous mixtures. The 20th century brought deeper insights into flame mechanisms, including overlooked contributions from women scientists. In the 1910s, amid , Martha Whiteley led research at Imperial College on chemical warfare agents and explosives, testing samples such as . In the 1920s, Nikolai Semenov developed the chain reaction theory for combustion, explaining how branching radicals sustain explosive propagation and detonation, a framework that earned him the 1956 for elucidating chemical transformation kinetics. By the 1970s, computational tools revolutionized flame modeling; the CHEMKIN software, initiated at , enabled detailed simulations of gas-phase kinetics, integrating reaction mechanisms to predict flame behaviors under varying conditions.

Applications

Controlled flames play a central role in various , providing precise heat for material manipulation and . In , oxy-fuel torches, which combine oxygen with fuels like , generate flames reaching approximately 3500 K, enabling the melting and joining of metals such as without electrical equipment. These torches are widely used in , automotive repair, and due to their portability and cost-effectiveness. For glassworking, oxy-hydrogen flames are employed to achieve high-purity melting and shaping of and , as the produces only , minimizing contamination in optical and laboratory components. utilizes controlled flames in furnaces operating at 870–1200°C to combust , reducing volume by up to 90% and destroying pathogens while recovering energy through heat capture. In energy production, flames drive in gas turbines, where fuel-air mixtures ignite to produce high-temperature gases that expand through blades, achieving efficiencies around 40% in simple-cycle configurations. This process powers and , with modern designs optimizing flame stability for reduced emissions. Rocket relies on intense flames from cryogenic propellants; for instance, SpaceX's engines use and in a full-flow , generating thrust via high-velocity exhaust flames for reusable launch vehicles like . Scientifically, flames enable analytical techniques such as (FAAS), where samples are aspirated into a flame to atomize elements, allowing measurement of trace metals like calcium and lead through light absorption at specific wavelengths. This method, with detection limits in the parts-per-billion range, supports and pharmaceutical quality control. In laboratories, Bunsen burners produce adjustable flames for heating, sterilization, and reactions, a staple since their introduction in the for education and research. Everyday applications harness flames for convenience and aesthetics. Gas stoves ignite or to create blue flames that heat cookware evenly, essential in over 40% of U.S. households for , , and . Candles and lighters provide portable flames for illumination and ignition, with or sustaining steady light in emergencies or rituals. Fireworks employ flames doped with metal salts—such as for red or for blue—to produce vibrant colors through atomic emission, entertaining millions during celebrations. Emerging uses include flame-assisted additive manufacturing (FLAMe), a post-2015 that integrates controlled flames with to fabricate high-melting-point metals like , overcoming limitations of laser-based methods by enabling solid-state deposition at elevated temperatures.

Safety and Environmental Impact

Flames pose significant safety hazards primarily through direct exposure and the inhalation of toxic byproducts from . burns from flames can result in third-degree injuries when skin temperatures exceed 70°C, leading to full-thickness damage that destroys all layers of the and underlying tissues. is another critical risk, where (CO) toxicity predominates; concentrations around 1000 ppm can cause unconsciousness and death within hours due to CO binding to , reducing oxygen delivery. In enclosed fire environments, represents a rapid escalation hazard, occurring when room temperatures reach approximately 500–600°C, igniting all combustible surfaces simultaneously and causing instantaneous fatalities from extreme heat and toxic gases. Mitigation strategies focus on preventing ignition and controlling fire spread through materials engineering and emergency response tools. Flame retardants, such as phosphorus-based compounds like ammonium polyphosphate, are incorporated into textiles, plastics, and building materials to inhibit combustion by promoting char formation and reducing heat release rates. Fire extinguishers classified as ABC types are versatile for common flame scenarios, using monoammonium phosphate powder to suppress ordinary combustibles (Class A), flammable liquids (Class B), and energized electrical equipment (Class C) without conducting electricity. Compliance with standards like NFPA 70, the , ensures safe installation of wiring and equipment to minimize ignition risks from electrical arcs or overloads in flame-prone settings. Environmentally, flames from contribute substantially to atmospheric pollutants that drive . Annual global CO₂ emissions from such reached approximately 37 Gt in 2023, accounting for over 75% of total anthropogenic and exacerbating . Incomplete produces , primarily , which exerts a positive of about 0.4–0.5 W/m² by absorbing solar and accelerating ice melt in polar regions. Regulatory frameworks address these impacts by limiting emissions and promoting sustainable alternatives. The Clean Air Act of 1970 empowers the EPA to establish for pollutants like and , generated from high-temperature flames in power plants and vehicles, with subsequent amendments mandating reductions through technologies like . Biofuel flames offer a mitigation pathway, achieving net-zero or reduced CO₂ emissions since the carbon released during is offset by uptake during growth, potentially lowering lifecycle emissions by up to 90% compared to fossil fuels. In the 2020s, research has highlighted emerging ecological risks from flame-related processes, particularly the combustion of microplastics in wildfires, which releases per- and polyfluoroalkyl substances (PFAS) into air, soil, and water, persisting as "forever chemicals" and contaminating ecosystems long-term.

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