Elements inner-transition

Reference has been made already to the existence of a set of inner transition elements, following lanthanum, in which the quantum level being filled is neither the outer quantum level nor the penultimate level, but the next inner. These elements, together with yttrium (a transition metal), were called the rare earths , since they occurred in uncommon mixtures of what were believed to be earths or oxides. With the recognition of their special structure, the elements from lanthanum to lutetium were re-named the lanthanons or lanthanides. They resemble one another very closely, so much so that their separation presented a major problem, since all their compounds are very much alike. They exhibit oxidation state -i-3 and show in this state predominantly ionic characteristics—the ions. 

The three series of elements arising from the filling of the 3d, 4d and 5d shells, and situated in the periodic table following the alkaline earth metals, are commonly described as transition elements , though this term is sometimes also extended to include the lanthanide and actinide (or inner transition) elements. They exhibit a number of characteristic properties which together distinguish them from other groups of elements ... 

Thus far, we have focused exclusively upon the block metals. For some, the term transition elements defines just these J-block species for others, it includes the rare earth or lanthanoid elements, sometimes called the inner transition elements . In this chapter, we compare the elements with respect to their valence shells. In doing so, we shall underscore concepts which we have already detailed as well as identifying both differences and similarities between certain aspects of main and inner transition-metal chemistry. We make no attempt to review lanthanoid chemistry at large. Instead our point of departure is the most characteristic feature of lanthanoid chemistry the +3 oxidation state. 

The solubility of transition elements in o-rh boron is low. The purity of a-rh boron prepared by thermal decomposition of BI3 is high, although that of -rh prepared from the same reactants is low. Crystallization of a-rh boron from a Pt melt requires pure chemicals. The solubility of transition and inner transition elements in -tetragonal boron is not known, but that in j8-rh boron is deseribed in 6.7.2.5.2 and 6.7.2.5.3. 

Only covalent bonds between Li and Na and transition metals are known, there being none with the lower group-IA metals or with inner transition elements. Bonding is inferred from metal-metal distances as well as calculations. ... 

Fidelis IK, Mioduski T (1981) Double-Double Effect in the Inner Transition Elements. 47 27-51... 

The rules above gave maximum and minimum oxidation numbers, but those might not be the only oxidation numbers or even the most important oxidation numbers for an element. Elements of the last six groups of the periodic table for example may have several oxidation numbers in their compounds, most of which vary from each other in steps of 2. For example, the major oxidation states of chlorine in its compounds are -1, +1, +3, +5, and +7. The transition metals have oxidation numbers that may vary from each other in steps of 1. The inner transition elements mostly form oxidation states of + 3, but the first part of the actinoid series acts more like transition elements and the elements have... 

Groups or families are the vertical rows on the periodic table. They may be labeled in two ways. The older way involves a Roman numeral and a letter, either A or B. We call the groups labeled with an A the main-group elements, while the B groups are the transition elements. Two horizontal groups, the inner transition elements, belonging to periods 6 and 7 are normally pulled out of the main body of the periodic table and are placed at the bottom of the table. 

Elements that appear in the d block are called the transition elements. They mark the transition from the p orbital filling order to the d orbital filling order. By the same reasoning, the /block elements are called the inner transition elements, because they mark a transition from the d orbital filling order to the / orbital filling order. 

The /block includes all the inner transition elements. Atoms of /block elements have filled s orbitals in the outer energy levels, as well as filled or partially filled 4/and 5/orbitals. In general, the notation for the orbital filling sequence is ns, followed by (n - 2)/, followed by (n - l]d, followed by (for period 6 elements) np. However, there are many exceptions that make it difficult to predict electron configurations. Because there are seven/orbitals, with a maximum of fourteen electrons, the /block spans fourteen groups. 

Symbol La atomic number 57 atomic weight 138.91 a rare-earth transition metal, precursor to a series of 14 inner-transition elements known as the lanthanide series electron configuration [XejSdiGs oxidation state -i-3 atomic radius 1.879A ionic radius (LaS+) 1.061A electronegativity 1.17 two natural isotopes are La-139 (99.911%) and La-138 (0.089%). 

Symbol Md atomic number 101 atomic weight (most stable isotope) 257 a man-made radioactive transuranium element an inner-transition element of actinide series electron configuration [Rn]5/i37s2 valence +2, -i-3. Isotopes, half-lives and their decay modes are ... 

Moving across each period the f orbital is progressively filled the 4f orbital is filled for the lanthanides, and the 5f orbital is filled for the actinides. These elements are sometimes referred to as the rare earths, because it was originally difficult to separate and identify these elements. Rare earths are actually not scarce, but the term rare earths is still used for the lanthanides and actinides. A more accurate modern term for these two periods are the inner transition elements. 

FIGURE 20.1 Thetransi- tion elements (d-block elements, shown in yellow) are located in the central region of the periodic table between the s-block and p-block main-group elements. The two series of inner transition elements (/-block elements, shown in green) follow lanthanum and actinium. 

Tucked into the periodic table between lanthanum (atomic number 57) and hafnium (atomic number 72) are the lanthanides. In this series of 14 metallic elements, the seven 4/orbitals are progressively filled, as shown in Figure 5.17 (page 185). Following actinium (atomic number 89) is a second series of 14 elements, the actinides, in which the 5f subshell is progressively filled. The lanthanides and actinides together comprise thef-block elements, or inner transition elements. 

Where are the transition and inner transition elements in the periodic table The inner transition elements (lanthanides and actinides) are placed in a special region in the periodic table. Explain the reason for this. 

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