Bye My Love- FLAME - You. Tube. Subscribe. Subscribed. Unsubscribe. 20. 62. Add to. Want to watch this again later? Please try again later. An urgent plea for our time: The Flame of Love of the Immaculate Heart of Mary Movement. Flame Quotes from BrainyQuote, an extensive collection of quotations by famous authors, celebrities, and newsmakers. Paroles : Paroles - FLAME : Bye My Love. Iikagen na mono NE unmei-tte yatsu wa Uragiru koto ga daisuki de Anna ni mo sou mitsumeatta jik. Lyrics to 'My Flame' song by BOBBY CALDWELL: How long How long have you been away Oh how long I can't find the words to say I've kept your pictur. DL:http:// tell me if it is the right one Jalina! My Love's Flame A Ranma 1/2 & Sailor Moon Fanfiction by Ryan Erik. With his shoulders slumped and his eyes downcast, the teenager followed his father's lead. His brow was covered with sweat on that. Flame of my love pattern by Olga Milukova. Credit must be given to Olga Milukova & xelda45. Commercial use is not allowed. Derivative works are allowed, but must be shared with this license. The messages given to Elizabeth Kindelmann are urgent and emphasize the “same” message as most of the other approved ones from Akita, Betania and elsewhere. The Lord states: “The Grace from the Flame of Love of My Mother. Lyrics to song 'My Love, My Life, My Flame' by Michael Sweet: It's hard to breath, so hard to move, I can't believe what we've been through. Our world came down so suddenly, Without a. Lyrics to 'My Flame' by Caldwell Bobby: Long How long have you been away Oh how long. Flame - Wikipedia. Laminar flame of a burning candle. A flame (from Latin flamma) is the visible, gaseous part of a fire. It is caused by a highly exothermicreaction taking place in a thin zone. The applied heat causes the fuel molecules in the candle wax to vaporize. In this state they can then readily react with oxygen in the air, which gives off enough heat in the subsequent exothermic reaction to vaporize yet more fuel, thus sustaining a consistent flame. The high temperature of the flame causes the vaporized fuel molecules to decompose, forming various incomplete combustion products and free radicals, and these products then react with each other and with the oxidizer involved in the reaction. Sufficient energy in the flame will excite the electrons in some of the transient reaction intermediates such as the Methylidyne radical (CH) and Diatomic carbon (C2), which results in the emission of visible light as these substances release their excess energy (see spectrum below for an explanation of which specific radical species produce which specific colors). As the combustion temperature of a flame increases (if the flame contains small particles of unburnt carbon or other material), so does the average energy of the electromagnetic radiation given off by the flame (see Black body). Other oxidizers besides oxygen can be used to produce a flame. Hydrogen burning in chlorine produces a flame and in the process emits gaseous hydrogen chloride (HCl) as the combustion product. Fluoropolymers can be used to supply fluorine as an oxidizer of metallic fuels, e. For instance, a well- known chemical kinetics scheme, GRI- Mech. In a diffusion flame, oxygen and fuel diffuse into each other; the flame occurs where they meet. In a premixed flame, the oxygen and fuel are premixed beforehand, which results in a different type of flame. Candle flames (a diffusion flame) operate through evaporation of the fuel which rises in a laminar flow of hot gas which then mixes with surrounding oxygen and combusts. Flame color. Note that virtually all the light produced is in the blue to green region of the spectrum below about 5. On the left a rich fuel with no premixed oxygen produces a yellow sooty diffusion flame; on the right a lean fully oxygen premixed flame produces no soot and the flame color is produced by molecular radicals, especially CH and C2 band emission. Flame color depends on several factors, the most important typically being black- body radiation and spectral band emission, with both spectral line emission and spectral line absorption playing smaller roles. In the most common type of flame, hydrocarbon flames, the most important factor determining color is oxygen supply and the extent of fuel- oxygen pre- mixing, which determines the rate of combustion and thus the temperature and reaction paths, thereby producing different color hues. In a laboratory under normal gravity conditions and with a closed oxygen valve, a Bunsen burner burns with yellow flame (also called a safety flame) at around 1,0. This is due to incandescence of very fine soot particles that are produced in the flame. With increasing oxygen supply, less black body- radiating soot is produced due to a more complete combustion and the reaction creates enough energy to excite and ionize gas molecules in the flame, leading to a blue appearance. The spectrum of a premixed (complete combustion) butane flame on the right shows that the blue color arises specifically due to emission of excited molecularradicals in the flame, which emit most of their light well below ~5. The colder part of a diffusion (incomplete combustion) flame will be red, transitioning to orange, yellow, and white as the temperature increases as evidenced by changes in the black- body radiation spectrum. For a given flame's region, the closer to white on this scale, the hotter that section of the flame is. The transitions are often apparent in fires, in which the color emitted closest to the fuel is white, with an orange section above it, and reddish flames the highest of all. In analytical chemistry, this effect is used in flame tests to determine presence of some metal ions. In pyrotechnics, the pyrotechnic colorants are used to produce brightly colored fireworks. Flame temperature. Note that the yellow color in this gas flame does not arise from the black- body emission of soot particles (as the flame is clearly a blue premixed complete combustion flame) but instead comes from the spectral line emission of sodium atoms, specifically the very intense sodium D lines. When looking at a flame's temperature there are many factors which can change or apply. An important one is that a flame's color does not necessarily determine a temperature comparison because black- body radiation is not the only thing that produces or determines the color seen; therefore it is only an estimation of temperature. Here are other factors that determine its temperature: Adiabatic flame; i. Atmospheric pressure. Percentage oxygen content of the atmosphere. The fuel being burned (i. Any oxidation of the fuel. Temperature of atmosphere links to adiabatic flame temperature (i. How stoichiometric the combustion process is (a 1: 1 stoichiometricity) assuming no dissociation will have the highest flame temperature.. Here the red color compared to typical yellow color of the flames suggests that the temperature is lower. This is because there is a lack of oxygen in the room and therefore there is incomplete combustion and the flame temperature is low, often just 6. This means that a lot of carbon monoxide is formed (which is a flammable gas) which is when in fire and arson investigation there is greatest risk of backdraft. When this occurs combustible gasses, already at or above flash point of spontaneous combustion, are exposed to oxygen, carbon monoxide and superheated hydrocarbons combust and temporary temperatures of up to 2,0. The phenomenon was discovered by Humphry Davy in 1. The process depends on a fine balance of temperature and concentration of the reacting mixture, and if conditions are right it can initiate without any external ignition source. Cyclical variations in the balance of chemicals, particularly of intermediate products in the reaction, give oscillations in the flame, with a typical temperature variation of about 1. K (. Sometimes the variation can lead to explosion. In microgravity or zero gravity environment, such as in orbit, natural convection no longer occurs and the flame becomes spherical, with a tendency to become bluer and more efficient. There are several possible explanations for this difference, of which the most likely is the hypothesis that the temperature is sufficiently evenly distributed that soot is not formed and complete combustion occurs. Cambridge, England: Cambridge University Press. Archived from the original on 2. Golden; Michael Frenklach; Nigel W. Moriarty; Boris Eiteneer; Mikhail Goldenberg; C. Thomas Bowman; Ronald K. Hanson; Soonho Song; William C. Gardiner, Jr.; Vitali V. Lissianski; Zhiwei Qin. The analysis of burned human remains. Combustion Phenomena: Selected Mechanisms of Flame Formation, Propagation and Extinction. Retrieved on 2. 01. Kirshenbaum, A. Journal of the American Chemical Society. The Journal of Chemical Physics. Bibcode: 1. 95. 2JCh. Ph. 2. 0. 3. 69. T. Journal of the American Chemical Society. Retrieved 1. 3 May 2. Hydrocarbon process safety: a text for students and professionals. ISBN 9. 78- 1- 5. Kim et al. Laminar Soot Processes Experiment Shedding Light on Flame Radiation. NASA, HTMLExternal links.
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