Atom and ion sizes

Some metals do not adopt a close-packed structure but have a slightly less efficient packing method this is the body-centred cubic structure (bcc), shown in Figure 1.8. (Unlike the previous diagrams, the positions of the atoms are now represented here—and in subsequent diagrams—by small spheres which do not touch this is merely a device to open up the structure and allow it to be seen more clearly—the whole question of atom and ion size is discussed in Section 1.6.4.) In this structure an atom in the middle of a cube is surrounded by eight identical and equidistant atoms at the corners of the cube—... 

Atom and ion sizes and the lanthanoid contraction Spectroscopic and magnetic properties Sources of the lanthanoids and actinoids... 

Another property that is closely related to electronegativity and position in the periodic table is polarizability. Polarizability is related to the size of atoms and ions and the... 

The electron configuration or orbital diagram of an atom of an element can be deduced from its position in the periodic table. Beyond that, position in the table can be used to predict (Section 6.8) the relative sizes of atoms and ions (atomic radius, ionic radius) and the relative tendencies of atoms to give up or acquire electrons (ionization energy, electronegativity). 

Using only the periodic table, arrange each of the following sets of atoms and ions in order of increasing size. 

A similar model for many-electron atoms has been developed,6 by considering each electron to be hydrogen-like, but under the influence of an effective nuclear charge (Z — Ss)e, in which Ss is called the size-screening constant. It is found that atoms and ions containing only 5 electrons (with the quantum number l equal to zero) and completed sub-groups of... 

VI.—The Electron Distribution in Atoms and Ions. Atomic Sizes. 

Much of what has been said so far in this chapter applies equally well to complexes of second- and third-row transition metals. However, there are some general differences that result from the fact that atoms and ions of the second- and third-row metals are larger in size than those of first-row metals. For example, because of their larger size (when in the same oxidation state as a first-row ion), ions of metals in the second and third rows form many more complexes in which they have a coordination number greater than 6. Whereas chromium usually has a coordination number of 6, molybdenum forms [Mo(CN)8]4 and other complexes in which the coordination number is 8. Other complexes of second- and third-row metals exhibit coordination numbers of 7 and 9. 

The ICP torch provides a rich source of free atoms and ions from the elements comprising the sample. In ICP-MS, part of the sample stream from a point close to the centre of the fireball is directed to a mass spectrometer. The resulting mass spectrum can be used to identify elements from the mass numbers of the ion peaks and the peak size for quantitative analysis. Moreover, the whole spectrum can be displayed at the same time providing qualitative analysis for a wide range of elements from one display... 

Materials and substances are composed of particles such as molecules, atoms and ions, which in turn consist of much smaller particles of electrons, positrons and neutrons. In electrochemistry, we deal primarily with charged particles of ions and electrons in addition to neutral particles. The sizes and masses of ions are the same as those of atoms for relatively light lithiiun ions the radius is 6 x 10 m and the mass is 1.1 x 10" kg. In contrast, electrons are much smaller and much lighter them ions, being 1/1,000 to 1/10,000 times smaller (classical electron radius=2.8 x 10 m, electron mass = 9.1 x 10" kg). Due to the extremely small size and mass of electrons, the quantization of electrons is more pronoimced than that of ions. Note that the electric charge carried by an electron (e = -1.602 X 10 C) is conventionally used to define the elemental unit of electric charge. 

Polarisability follows roughly the order of the size of atoms, which is also consistent with lower ionization potentials of larger atoms and ions (e.g., Se>S>0, Se2 >S2 >02 ). 

Porstendorfer, J. Mercer, T.T. (1978) Adsorption probability of atoms and ions on particulate surfaces in submicrometer size range. Journal of Aerosol Science, 9, 469-74. 

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