Electronegativity: An Insight in Terms of Atomic Number Approached Via Isoelectronic Series

Abstract

In this communication, an insight intoelectronegativityin terms of fundamental property, the atomic number (Z) is approached via isoelectronic series, using the electronegativity measure, (I+A)/2 (isoelectronic values) vs. atomic number plots. On the basis of these excellent smooth quadratic curves (r2≈1), we have inferred that the neutral atom electronegativity, (I+A)/2 is proportional to Z2. Our view justifies the suggestion made by Islam et al.

Keywords

Insight, Atomic number, Isoelectronic series, Electronegativity.

Introduction

Electronegativity [1,2] has become an indispensible tool for chemist, to understand physico-cs properties. This theoretical construct of chemistry finds multifarious applications in biology, physics and geology [3,4], nanochemistry, hightemperature superconductors [5,6], spectroscopy [7,8], qualitative understanding of quark atoms [9] and several others.

Pauling [1,2] defined electronegativity, “as the power of an atom in a molecule to attract electrons to itself.” Pauling [1], Mulliken [10], Gordy [11], Allred and Rochow [12] are some of the pioneering measures of electronegativity. Besides these, there are other scales as well [3,4]。In density functional theory (DFT) [13,14], the electronegativity (χ) is defined [15,16] as follows

Where, ν is external nuclear potential and E, is the total energy of an N-electron system. The approximate expression for electronegativity in terms of ionization potential, I, and electron affinity, A provides a reliable electronegativity measure. It is also the Mulliken electronegativity measure [10]。

The privilege of correlations that electronegativity enjoys with large number of atomic and molecular properties such as atomic radius [17], ionization potential [18], polarizability [19] etc. click and reflect something. In atomic species, most of the properties are governed by the electron distribution around the nucleus. So, they have common origin: the atomic nucleus or the atomic number, and the surrounding electrons. It is the binding of the surrounding electrons by the nucleus that is an important controlling factor for most of the properties. Therefore, an insight of electronegativity in terms of atomic number is required and in this communication, this has been done via isoelectronic series.

Isoelectronic series are fundamental periodic properties [20]。等电子物种拥有相同数量的electrons. Therefore, the change in any property will be mainly due to atomic number. Recently, we have reported the variation of Mulliken’s electronegativity measure, (I+A)/2 isoelectronic values with atomic number [21]。然而,没有specifically approaching the electronegativity of neutral atomic species has been pointed out. In the present work, we identify interrelation between electronegativity of neutral atoms and their atomic number, using isoelectronic series as a tool. This has been achieved through an analysis of the variation of isoelectronic values of (I+A)/2 with atomic number, Z. In the present study, we have analysed the first ten isoelectronic series (H-Ne).

Methodology

The methodology that we here use is very simple. It is based on the fact that every neutral atomic species is also a part of some isoelectronic series (series, hereafter). Therefore, from the (I+A)/2 (isoelectronic values) vs. atomic number plots, we can infer about the interrelation between the two i.e electronegativity and atomic number, as for neutral atomic species, (I+A)/2 is the electronegativity. A strict adherence of I and A as the first ionization potential and electron affinity is not required. We just need consecutive ionization potentials that can be depicted as I and A.

Results

The electronegativity measure, (I+A)/2 (isoelectronic values) vs. atomic number (up to Z= 20) plots, for the first ten isoelectronic series, are presented inFigures 1-2. These plots [21] can be represented by (2)

InTable 1the determination coefficients, r²and correlation coefficients a, b, and c, of theFigures 1-2plots, obtained from least square fitting, are listed.

All the ionization potentials that we have used, for (I+A)/2 computation, are from reference [22]。

Discussion

For the first time an insight into electronegativity in terms of atomic number is approached via isoelectronic series. It can be seen fromFigure 1-2that the plots are apparently smooth curves and strikingly, the data are not scattered. Equation (2) points towards a quadratic relationship. It reveals from the determination coefficients (r²=1), listed inTable 1, that there is high degree of correlation between the electronegativity measure, (I+A)/2 (isoelectronic values) and atomic number, Z. The exact depiction of variation ofFigure 1-2is Eq. (2) expressed throughTable 1. On this basis, we infer (as the neutral atomic species are also part of some isoelectronic series) and suggest that the electronegativity is proportional to Z², provided (I+A)/2 is the measure.

Our present inference and methodology justify the suggested proportionality between electronegativity and square of the effective nuclear charge (Z_eff) [23]。

Conclusion

An insight of electronegativity in terms of atomic number, approached via isoelectronic series, reveals that if (I+A)/2 is the measure, the electronegativity is proportional to square of the atomic number. The present work justifies the suggested proportionality between electronegativity and square of the effective nuclear charge.

Acknowledgement

One of the authors (DPU) is grateful to university grants commission (UGC) for a fellowship.

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