Difference between revisions of "?Algebraic Chemistry? Based on a ?PIRT?"
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The present paper continues on from my 2004 PIRT paper entitled ?Can Chemical Data Support a ?PIRT???. The present paper first provides more detail on the variation of ionization potentials within the periods of the Period-ic Table. The description developed refers to the standard quantum numbers n,l,s ( n=1 to infinity, l=0 to n−1, s=−1/2,+1/2) for single-electron states that are incorporated into successively larger atoms. The empiri-cal Madelung and Hund rules that are found in today?s chemistry textbooks provide the nominal filling order for sin-gle-electron states. Using this filling order, a simple empirical formula is developed for the local slopes on a log plot of the ionization potentials. The formula is quite accurate for first ionization potentials, but becomes less accurate for higher-order ionization potentials. This fact could well be related to the fact that the filling order that actually occurs in Nature departs from the standard one for about 20% of the known elements. Accordingly, the filling order for single-electron states is itself investigated next. A more efficacious empirical rule is developed. Like the stan-dard one, it involves sums of traditional quantum numbers, but unlike the standard one, judiciously chosen coeffi-cients that are powers of 2 provide the needed improvements. The resulting formulation automatically directs atten-tion to the elements for which the departures from the textbook rules actually do occur. The paper concludes with an indication of future work. | The present paper continues on from my 2004 PIRT paper entitled ?Can Chemical Data Support a ?PIRT???. The present paper first provides more detail on the variation of ionization potentials within the periods of the Period-ic Table. The description developed refers to the standard quantum numbers n,l,s ( n=1 to infinity, l=0 to n−1, s=−1/2,+1/2) for single-electron states that are incorporated into successively larger atoms. The empiri-cal Madelung and Hund rules that are found in today?s chemistry textbooks provide the nominal filling order for sin-gle-electron states. Using this filling order, a simple empirical formula is developed for the local slopes on a log plot of the ionization potentials. The formula is quite accurate for first ionization potentials, but becomes less accurate for higher-order ionization potentials. This fact could well be related to the fact that the filling order that actually occurs in Nature departs from the standard one for about 20% of the known elements. Accordingly, the filling order for single-electron states is itself investigated next. A more efficacious empirical rule is developed. Like the stan-dard one, it involves sums of traditional quantum numbers, but unlike the standard one, judiciously chosen coeffi-cients that are powers of 2 provide the needed improvements. The resulting formulation automatically directs atten-tion to the elements for which the departures from the textbook rules actually do occur. The paper concludes with an indication of future work. | ||
− | [[Category:Scientific Paper]] | + | [[Category:Scientific Paper|algebraic chemistry based pirt]] |
Latest revision as of 09:56, 1 January 2017
Scientific Paper | |
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Title | ?Algebraic Chemistry? Based on a ?PIRT? |
Author(s) | Cynthia Kolb Whitney |
Keywords | Algebraic Chemistry |
Published | 2006 |
Journal | None |
Abstract
The present paper continues on from my 2004 PIRT paper entitled ?Can Chemical Data Support a ?PIRT???. The present paper first provides more detail on the variation of ionization potentials within the periods of the Period-ic Table. The description developed refers to the standard quantum numbers n,l,s ( n=1 to infinity, l=0 to n−1, s=−1/2,+1/2) for single-electron states that are incorporated into successively larger atoms. The empiri-cal Madelung and Hund rules that are found in today?s chemistry textbooks provide the nominal filling order for sin-gle-electron states. Using this filling order, a simple empirical formula is developed for the local slopes on a log plot of the ionization potentials. The formula is quite accurate for first ionization potentials, but becomes less accurate for higher-order ionization potentials. This fact could well be related to the fact that the filling order that actually occurs in Nature departs from the standard one for about 20% of the known elements. Accordingly, the filling order for single-electron states is itself investigated next. A more efficacious empirical rule is developed. Like the stan-dard one, it involves sums of traditional quantum numbers, but unlike the standard one, judiciously chosen coeffi-cients that are powers of 2 provide the needed improvements. The resulting formulation automatically directs atten-tion to the elements for which the departures from the textbook rules actually do occur. The paper concludes with an indication of future work.