![]() ![]() Rad-energy is also a force that radiates. The term radiation implies a force that radiates. If the atom was very dense as in uranium or other radio-active substances, then this effect is very noticeable. We may (with tongue-in-cheek) associate Keely's Thermism with the modern term of "latent heat." The other force, Rad-energy, we may conceptualize as that force or energy that radiates from given atom and causes the effects an atom has on its neighbors. Thermism as we have already seen, is or can be associated with heat. The unique idea here is the separate distinction between creative force (Thermism) and the Transmissive force ((Rad-energy). This is a simple statement and one that is easily verifiable by consulting any good reference work on atomic resonances. Keely indicates that atoms oscillate within and just around the visible light frequencies depending on the weight of the atoms. The Law of Harmonic Attraction & Repulsion was discussed in issue #8. Scholium: Dark radiant heat begins at absolute zero temperature, and extends through light, chemical rays, actinic rays, and infra-violet rays, up to the dissociation of all molecules to the 63rd octave." "All atoms when in a state of tension are capable of oscillating at a pitch inversely as the cube of their atomic weights, and directly as their tension from 42 to 63 octaves per second, producing the creative force (Thermism), whose transmissive force (Rad-energy) propagated in solid, liquid, and gaseous ether, produces the static effects (Cohesion and Chemism) on other atoms of association, or dissociation, according to the Law of Harmonic Attraction and Repulsion. A., Levitskii, Computational Methods in Chemical Kinetics, Nauka, Moscow (1984).In court? Need assistance? Jurisdictionary Problems in Combustion and Explosion, Chernogolovka (1989), pp. Ryabinin, “Modeling oscillatory combustion of hydrogen in a well-stirred reactor at low pressures,” in: Chemical Physics of the Processes of Combustion and Explosion. Khaken, Synergetics, Mir, Moscow, (1985). Babkin, “The structure of the chain-heat self-ignition limit”, Kinet. Koslyuk, “Heterogeneous recombination of atoms of hydrogen, oxygen, and nitrogen at metal surfaces,” Khim. Zhdanov, Elementary Physicochemical Processes at the Surface, Nauka, Novosibirsk (1988). Shavard, “Quantitative relationships governing the liberation of energy in branch-chain processes”, Kinet. Neigauz, et al., “The role of self-heating in the combustion of hydrogen near the first ignition limit”, Kinet. Ryabinin, “An investigation into the quantitative relationships governing the oxidation of hydrogen in a well-stirred reactor”, Fiz. Babkin, et al., “Chain explosion in the oxidation of hydrogen at high levels of depletion burnout”, Fiz. The Kinetics of Chemical Reactions, Chernogolovka (1977), pp. Dimitrov, et al., “The maximum kinetic mechanism and special models of ignition in the (H 2−O 2) system,” in: Chemical Physics of Processes of Combustion and Explosion. Merzhanov, et al., “The mechanism and kinetics of hydrogen oxidation as functions of temperature and pressure in the mixture”, Kinet. Semenov, “The mechanism of burning hydrogen at low pressures”, Kinet. Nikitin, The Kinetics and Mechanism of Gas-Phase Reactions, Nauka, Moscow (1974). Semenov, Certain Problems in Chemical Kinetics and Reaction Capabilities, Izd. Elbe, Combustion, Flames, and Explosions in Gases, IL, Moscow (1948). Slin'ko, “Self-oscillations and rates of heterogeneous catalytic reactions”, Usp. Azatyan, “Valuable processes and nonsteadiness in the state of the surface,” Usp. Pappin, et al., “Third-body interactions in the oscillatory oxidation of hydrogen in a well-stirred flow reactor”, J. Pappin, et al., “Stationary-state and oscillatory combustion of hydrogen in a well-stirred flow reactor”, Combust. Griffiths, et al., “Isothermal interpretations of oscillatory ignition during hydrogen oxidation in an open system,” Proc. Scott, “Branched-chain reactions in open systems: theory of the oscillatory ignition limit for the hydrogen + oxygen reaction in a continuous-flow stirred tank reactor,” Proc. Scott, “Isothermic isolations and relaxation flares in gas-phase reactions: Oxidation of the monoxide of carbon and hydrogen”, in: Oscillations and Traveling Waves in Chemical Systems, Mir, Moscow (1988), pp. Nekrasov, “Ignition and spontaneous combustion of ammonia and a nitrogen-air mixture,” ZhFKh, 8, No. The thermokinetic self-oscillatory model,” ZhFKh, 23, No. Sal'nikov, “The theory of periodic homogeneous chemical reactions. ![]()
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