SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2034785410> ?p ?o ?g. }

Showing items 1 to 100 of ±110 with 100 items per page.

W2034785410 endingPage "283" @default.
W2034785410 startingPage "259" @default.
W2034785410 abstract "Heat of dissociation from band spectra data.---The limiting amount of vibrational energy which a diatomic molecule can possess is given by ${E}_{n}=hensuremath{int}{o}^{{n}_{o}}{ensuremath{omega}}^{n}mathrm{dn},$ where ${ensuremath{omega}}^{n}$ is the frequency of vibration, as a function of the vibrational quantum number $n$, and ${n}_{o}$ is the value of $n$ for ${ensuremath{omega}}^{n}=0$. For non-polar molecules ${n}_{o}$ is finite, for polar molecules it is infinite. The ${ensuremath{omega}}^{n}:n$ curve for the normal state of each of the molecules here discussed is strictly linear, over the known range, and its linear extrapolation to ${ensuremath{omega}}^{n}=0$, for essentially non-polar molecules, seems to give the true value of ${E}_{n}$ to within half a volt. Since increasing the vibrational energy until the two nuclei dissociate, results in the formation of two normal atoms, ${E}_{n}=D$, the heat of dissociation. When a molecule dissociates, while excited by ${E}_{e}$ units of electronic energy, the products of dissociation seem in some cases to include at least one excited atom. The total energy required for the dissociation thus exceeds the true heat of dissociation by the amount of the resulting atomic excitation. The ${ensuremath{omega}}^{n}:n$ curves, and the correlated sets of energy levels are shown for all known band systems of ${mathrm{O}}_{2}$, ${mathrm{O}}_{2}^{+}$, ${mathrm{N}}_{2}$, ${mathrm{N}}_{2}^{+}$, CO, C${mathrm{O}}^{+}$, and NO.Oxygen. The ${ensuremath{omega}}^{n}:n$ curve of one excited state can be followed almost to ${ensuremath{omega}}^{n}=0$, and the resulting limiting energy is 7.05ifmmodepmelsetextpmfi{}0.01 volts. The situation is similar to that found in iodine. From the known structure of the oxygen atom, the products of dissociation are either two normal atoms, or one or two atoms excited with 0.02 or 0.03 volts energy. Hence $D=7.02ifmmodepmelsetextpmfi{}0.05$ volts. The linear ${ensuremath{omega}}^{n}:n$ curve of the normal state gives 6.65 volts. For ${mathrm{O}}_{2}^{+}$ the normal state curve gives 6.46 volts, and the only known excited state curve, 6.49 volts. Knowing the heat of dissociation of an ionized molecule (${D}^{ensuremath{'}}$) and of a neutral molecule ($D$), and the ionization potential of the constituent atom (${I}_{a}$), one can calculate the ionization potential of the molecule (${I}_{m}$), since from conservation of energy, ${I}_{m}+{D}^{ensuremath{'}}=D+I$. For oxygen this gives ${I}_{m}=14.1$ volts. ${D}^{ensuremath{'}}=6.5$ volts is however probably too low, and ${I}_{m}=14.1$ volts too high, according to recent work on the spectrum of ${mathrm{O}}_{2}^{+}$.Nitrogen. From the energy of active nitrogen, $D$ for ${mathrm{N}}_{2}$ is 11.4 volts. This value can be checked approximately, but not accurately, from band spectra data. The normal state of the nitrogen molecule is not known. ${D}^{ensuremath{'}}$ is found to be about 9.1 volts, and ${I}_{m}$ is 16.5 volts, giving ${I}_{a}=14.2$ volts, compared to Hopfield's observed value of 14.5 volts. These results for oxygen and nitrogen are in satisfactory agreement with the positive ray work of Hogness and Lunn.Carbon monoxide. $D=11.2$ volts, from the ${ensuremath{omega}}^{n}:n$ curve of the normal state. Assuming our value of $D$ for ${mathrm{O}}_{2}$ and certain chemical data, $D$ for CO can be calculated as 10.8 volts. ${D}^{ensuremath{'}}=9.8$ volts, from the spectral data. ${I}_{m}$ is known to be closely 14.2 volts, and if C${mathrm{O}}^{+}$ dissociates into C+${mathrm{O}}^{+}$, ${I}_{a}=13.56$ volts. The equation ${I}_{m}+{D}^{ensuremath{'}}=D+{I}_{a}$ checks to 0.3 volts.Nitric oxide. $D=7.9$ volts, from the normal state curve. Assuming our value of $D$ for ${mathrm{O}}_{2}$ and for ${mathrm{N}}_{2}$, and certain chemical data, $D$ for NO is 8.3 volts. From one of the excited state curves, the total limiting energy is 17.2 volts, indicating dissociation into one normal nitrogen atom and one 9.1 volt (resoanance state) excited oxygen atom.General considerations. The possibility of the dissociation of a molecule adiabatically, by means of light absorption, is discussed and a tentative explanation given of the difference in behavior found in the positive ray analysis for oxygen and nitrogen. The various possible processes resulting in dissociation from excited molecular states are considered in the light of the evidence presented by the known sets of vibrational energy levels." @default.
W2034785410 created "2016-06-24" @default.
W2034785410 creator A5009828238 @default.
W2034785410 creator A5026261644 @default.
W2034785410 date "1926-08-01" @default.
W2034785410 modified "2023-09-27" @default.
W2034785410 title "The Heat of Dissociation of Non-Polar Molecules" @default.
W2034785410 cites W1965631511 @default.
W2034785410 cites W1967140097 @default.
W2034785410 cites W1973911974 @default.
W2034785410 cites W1979364293 @default.
W2034785410 cites W1983383078 @default.
W2034785410 cites W1990281795 @default.
W2034785410 cites W1991016793 @default.
W2034785410 cites W1994832546 @default.
W2034785410 cites W1997562135 @default.
W2034785410 cites W2001866955 @default.
W2034785410 cites W2004690470 @default.
W2034785410 cites W2004989445 @default.
W2034785410 cites W2017257230 @default.
W2034785410 cites W2027305589 @default.
W2034785410 cites W2028107598 @default.
W2034785410 cites W2048954637 @default.
W2034785410 cites W2054308314 @default.
W2034785410 cites W2056366098 @default.
W2034785410 cites W2061825702 @default.
W2034785410 cites W2067324858 @default.
W2034785410 cites W2073291340 @default.
W2034785410 cites W2075635827 @default.
W2034785410 cites W2079157982 @default.
W2034785410 cites W2079894825 @default.
W2034785410 cites W2082548347 @default.
W2034785410 cites W2087783405 @default.
W2034785410 cites W2091307064 @default.
W2034785410 cites W2094770898 @default.
W2034785410 cites W2106590561 @default.
W2034785410 cites W2108913979 @default.
W2034785410 cites W2242694920 @default.
W2034785410 cites W2985424420 @default.
W2034785410 cites W4232211611 @default.
W2034785410 cites W4234678185 @default.
W2034785410 cites W4248764499 @default.
W2034785410 cites W4299088690 @default.
W2034785410 doi "https://doi.org/10.1103/physrev.28.259" @default.
W2034785410 hasPublicationYear "1926" @default.
W2034785410 type Work @default.
W2034785410 sameAs 2034785410 @default.
W2034785410 citedByCount "226" @default.
W2034785410 countsByYear W20347854102012 @default.
W2034785410 countsByYear W20347854102014 @default.
W2034785410 countsByYear W20347854102015 @default.
W2034785410 countsByYear W20347854102018 @default.
W2034785410 countsByYear W20347854102019 @default.
W2034785410 countsByYear W20347854102020 @default.
W2034785410 countsByYear W20347854102021 @default.
W2034785410 countsByYear W20347854102023 @default.
W2034785410 crossrefType "journal-article" @default.
W2034785410 hasAuthorship W2034785410A5009828238 @default.
W2034785410 hasAuthorship W2034785410A5026261644 @default.
W2034785410 hasConcept C102931765 @default.
W2034785410 hasConcept C111806078 @default.
W2034785410 hasConcept C121332964 @default.
W2034785410 hasConcept C132459708 @default.
W2034785410 hasConcept C134306372 @default.
W2034785410 hasConcept C147789679 @default.
W2034785410 hasConcept C181500209 @default.
W2034785410 hasConcept C184779094 @default.
W2034785410 hasConcept C185592680 @default.
W2034785410 hasConcept C2779557605 @default.
W2034785410 hasConcept C29705727 @default.
W2034785410 hasConcept C32909587 @default.
W2034785410 hasConcept C33923547 @default.
W2034785410 hasConcept C62396407 @default.
W2034785410 hasConcept C62520636 @default.
W2034785410 hasConceptScore W2034785410C102931765 @default.
W2034785410 hasConceptScore W2034785410C111806078 @default.
W2034785410 hasConceptScore W2034785410C121332964 @default.
W2034785410 hasConceptScore W2034785410C132459708 @default.
W2034785410 hasConceptScore W2034785410C134306372 @default.
W2034785410 hasConceptScore W2034785410C147789679 @default.
W2034785410 hasConceptScore W2034785410C181500209 @default.
W2034785410 hasConceptScore W2034785410C184779094 @default.
W2034785410 hasConceptScore W2034785410C185592680 @default.
W2034785410 hasConceptScore W2034785410C2779557605 @default.
W2034785410 hasConceptScore W2034785410C29705727 @default.
W2034785410 hasConceptScore W2034785410C32909587 @default.
W2034785410 hasConceptScore W2034785410C33923547 @default.
W2034785410 hasConceptScore W2034785410C62396407 @default.
W2034785410 hasConceptScore W2034785410C62520636 @default.
W2034785410 hasIssue "2" @default.
W2034785410 hasLocation W20347854101 @default.
W2034785410 hasOpenAccess W2034785410 @default.
W2034785410 hasPrimaryLocation W20347854101 @default.
W2034785410 hasRelatedWork W114530401 @default.
W2034785410 hasRelatedWork W1974435925 @default.
W2034785410 hasRelatedWork W1998971618 @default.
W2034785410 hasRelatedWork W2033817753 @default.
W2034785410 hasRelatedWork W2086436431 @default.