What is the diagonal relationship in the periodic table?

The diagonal relationship will hold for those elements that are diagonally placed in the periodic table because they will exhibit similar properties between the second and third periods. For example, beryllium will have some similar chemical properties to aluminium. They both have close values of electronegativity, ionization energy, and atomic radius.

What is the diagonal relationship in the periodic table?

The diagonal relationship refers to similarities in properties between certain elements that are diagonally adjacent to each other in the periodic table. This occurs due to a balance between atomic size and nuclear charge, resulting in comparable chemical behaviors.

Why do beryllium and aluminium form compounds with similar properties?

The reason why beryllium and aluminium behave almost alike results from a balance between an enhanced nuclear charge traversed across the period and that of atomic size by going down each group. The same sets of electronegativities and ionization energies are thereby obtained, hence similar chemical behaviour.

How do beryllium and aluminium resemble each other?

Some of the common properties between beryllium and aluminium are their amphoteric nature, the formation of covalent compounds, and their non-corrosive nature due to the formation of a protective oxide layer. Beryllium and aluminium also readily react with acids like base metals and metals (alkalis) with bases. The reason for this is the covalent compound formation of beryllium chloride (BeCl2) and aluminium chloride (AlCl2).

Industrial application of beryllium to aluminium based on their diagonal relationship?

However, the industry exploits this diagonal relationship for its various applications. On account of its high strength-to-weight ratio, beryllium finds its way into aerospace and military uses, while aluminium does so due to its unique properties in construction, packaging, and transport. These members further find applications in chemical processes via corrosion resistance and covalent compounds.

What is the importance of knowing the diagonal relationship in academics?

The study of the diagonal relationship is very important since it helps in understanding and predicting properties for elements moving forward and across a periodic table. This allows for advanced qualitative and separation techniques and fully appreciating periodic trends through an enriched study of chemistry.

Why do Beryllium and Aluminum exhibit a diagonal relationship?

Beryllium and Aluminum exhibit a diagonal relationship because they have similar charge-to-size ratios. This similarity arises from Be's small size and low charge, which is comparable to Al's larger size but higher charge, leading to analogous chemical properties.

How does the atomic size of Beryllium compare to Aluminum?

Beryllium has a smaller atomic size compared to Aluminum. However, the difference in their sizes is less pronounced than between Beryllium and its group members, contributing to their diagonal relationship.

What role does electronegativity play in the Be-Al diagonal relationship?

Electronegativity values for Beryllium and Aluminum are similar, which contributes to their diagonal relationship. This similarity results in comparable tendencies to attract electrons in chemical bonds, leading to analogous chemical behaviors.

How do the melting points of Beryllium and Aluminum compare?

Beryllium and Aluminum have relatively high and similar melting points compared to other elements in their respective groups. This similarity is a characteristic of their diagonal relationship and is due to strong metallic bonding in both elements.

How does the ionization energy of Beryllium compare to Aluminum?

Beryllium has a higher ionization energy than Aluminum, but both have relatively high values compared to other elements in their respective groups. This similarity contributes to their diagonal relationship.

Why do both Beryllium and Aluminum form amphoteric oxides?

Both Beryllium and Aluminum form amphoteric oxides because they can react with both acids and bases. This behavior is due to their similar charge-to-size ratios, which allow their oxides to act as both proton donors and acceptors.

How does the reactivity of Beryllium compare to that of Aluminum?

Beryllium and Aluminum have similar reactivity, which is lower than other elements in their respective groups. This comparable reactivity is a result of their diagonal relationship and is due to similar effective nuclear charges.

What is the significance of the Be-Al diagonal relationship in complex formation?

Both Beryllium and Aluminum tend to form strong complexes, particularly with oxygen and fluorine. This similarity in complex formation is a result of their diagonal relationship and is due to their comparable charge densities.

How does the hydrolysis of Be2+ and Al3+ ions compare?

Both Be2+ and Al3+ ions undergo significant hydrolysis in aqueous solutions, forming acidic solutions. This similar behavior is due to their high charge densities, which is a characteristic of their diagonal relationship.

Why do Beryllium and Aluminum both form covalent compounds?

Beryllium and Aluminum both tend to form covalent compounds due to their relatively high electronegativity values compared to other metals. This tendency is a result of their diagonal relationship and similar effective nuclear charges.

How does the electrical conductivity of Beryllium compare to Aluminum?

Beryllium and Aluminum both have good electrical conductivity, though Aluminum is a better conductor. Their similar conductive properties are related to their diagonal relationship and comparable electronic structures.

How do the atomic radii of Beryllium and Aluminum compare to their group members?

Beryllium has a smaller atomic radius than expected for Group 2, while Aluminum has a larger radius than expected for Group 13. This anomaly contributes to their diagonal relationship and similar chemical properties.

Why do both Beryllium and Aluminum form polymeric structures?

Both elements tend to form polymeric structures due to their small size and high charge density. This similarity is a characteristic of their diagonal relationship and results in comparable bonding behaviors.

How does the Be-Al diagonal relationship affect their reaction with water?

Both Beryllium and Aluminum react slowly with water at room temperature, forming a protective oxide layer. This similar behavior is due to their diagonal relationship and comparable reactivity.

What role does electron configuration play in the Be-Al diagonal relationship?

The electron configurations of Beryllium (1s² 2s²) and Aluminum (1s² 2s² 2p⁶ 3s² 3p¹) result in similar valence electron behavior. This contributes to their diagonal relationship and analogous chemical properties.

How does the polarizing power of Be2+ compare to Al3+?

Both Be2+ and Al3+ ions have high polarizing power due to their small size and relatively high charge. This similarity is a characteristic of their diagonal relationship and influences their chemical behavior.

Why do Beryllium and Aluminum both form strong bonds with oxygen?

Both elements form strong bonds with oxygen due to their high charge densities and similar electronegativity values. This is a result of their diagonal relationship and leads to the formation of stable oxides.

How does the crystal structure of Beryllium compare to that of Aluminum?

Both Beryllium and Aluminum crystallize in close-packed structures, though Be has a hexagonal close-packed (hcp) structure while Al has a face-centered cubic (fcc) structure. This similarity in close-packing is related to their diagonal relationship.

Why do both Beryllium and Aluminum form strong intermetallic compounds?

Both elements can form strong intermetallic compounds due to their similar atomic sizes and electronic structures. This is a characteristic of their diagonal relationship and results in comparable alloying behaviors.

How does the Be-Al diagonal relationship affect their behavior in coordination compounds?

Both Beryllium and Aluminum form tetrahedral complexes in many coordination compounds. This similarity is due to their diagonal relationship and comparable charge-to-size ratios.

Why do both Beryllium and Aluminum have low electrical resistivity?

Both elements have low electrical resistivity due to their similar electronic structures and the ease with which their valence electrons can move. This is a characteristic of their diagonal relationship.

How does the hardness of Beryllium compare to Aluminum?

Beryllium is significantly harder than Aluminum, but both are harder than other elements in their respective groups. This relative hardness is related to their diagonal relationship and strong metallic bonding.

Why do both Beryllium and Aluminum have high specific heat capacities?

Both elements have high specific heat capacities compared to other metals. This similarity is due to their diagonal relationship and comparable electronic structures and bonding.

Diagonal relationship between Beryllium and Aluminium

Chemistry
The S-Block Elements
Diagonal Relationship Between Beryllium and Aluminium

Diagonal relationship between Beryllium and Aluminium

Shivani PooniaUpdated on 02 Jul 2025, 06:04 PM IST

Consider a class of students wherein two kids, apparently not related to each other through bloodlines, share strikingly similar characteristics, which stand as a class apart. The best way to explain the diagonal relationship is by using this analogy between beryllium and aluminium in the periodic table. Although beryllium, marked by the symbol Be, and aluminium, marked by the symbol Al, come from Group 2 and Group 13, respectively, they share some similarities in their chemical properties that are deviations from what would be expected in their respective groups.

General Concepts and Definitions

The diagonal relationship is the relationship between pairs of elements that are diagonal across each other in the table of elements. It goes from the second period to the third period. This phenomenon could easily be best described by the conduct of beryllium and aluminium, as they are of approximately the same electronegativities and have values for ionization energy that are nearly the same, while the atomic radii are also the same. These two elements combined are in separate groups but possess a very similar chemical behaviour. Beryllium has the atomic number 4 and is one of the light metals, also placing it in Group 2: alkaline earth metals. Due to the balancing ability of elements, while they move diagonally across the periodic table, aluminium bears an atomic number of 13 and appears just below boron in Group 13 of the periodic table.

Various Aspects and Examples

Several aspects of beryllium and aluminium are the same, such as being amphoteric, the formation of covalent compounds, and resistance to acid attacks. The two elements form an oxide layer on their surface that offers them protection from corrosion. As such, beryllium hydroxide, Be(OH)2, and aluminium hydroxide, Al(OH)₂, form amphoteric oxides; thus, they react with both acids and bases. The property is very crucial for various industrial uses of the two elements. Also, beryllium and aluminium combine to form some covalent compounds with certain elements. For instance, beryllium chloride, BeCl₂, and aluminium chloride, AlCl₂, are formed, which presents yet another piece of evidence of the chemical similarity between these elements.

The ionic radius of Be²⁺ is estimated to be 31 pm; the charge/radius ratio is nearly the same as that of the Al³⁺ ion. Hence beryllium resembles aluminium in some ways. Some of the similarities are:

Like aluminium, beryllium is not readily attacked by acids because of the presence of an oxide film on the surface of the metal.
Beryllium hydroxide dissolves in excess of alkali to give a beryllate ion, [Be(OH)₄]^2-just as aluminium hydroxide gives aluminate ion, [Al(OH)₄]^2-
The chlorides of both beryllium and aluminium have a Cl^– bridged chloride structure in a vapour phase. Both the chlorides are soluble in organic solvents and are strong Lewis acids. They are used as Friedel Craft catalysts.
Beryllium and aluminium ions have a strong tendency to form complexes, BeF₄^2–, AlF₆^3–.

Relevance and Applications

Some of the important implications of the diagonal relationship between beryllium and aluminium in theory and applications are that it helps students and researchers in academics identify and explain the diverse properties of these and other elements.

For example, the amphoteric nature of beryllium and aluminium compounds is applied to qualitative methods of analysis and separation techniques in analytical chemistry.
The uniqueness of beryllium is its application in both the aerospace and military industries for its high strength-to-weight ratio and good thermal stability in industrial applications.
Aluminium is a more abundant and hence reasonably priced metal, usage of which is in greater quantity in construction, packaging, and transport.
Aluminium has capability to form protective oxide films rendering both of these metals important materials where good resistance to corrosion is required.

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Some Solved Examples

Example 1

Question: Be and Al show a diagonal relationship, hence both have:

Amphoteric nature of oxides
Polarising nature
The same degree of electronegativity
All the above

Solution:

The oxides of both Be and Al are amphoteric in nature. The polarising power of Be²⁺ and Al³⁺ ions is high. Consequently, the compounds develop a covalent nature. The electronegativity values of both elements are the same.

Hence, the answer is option (4) - All the above.

Example 2

Question:

Be and Al exhibits many properties which are similar. But the two elements differ in:

Forming covalent compounds
Forming polymeric compounds
Exhibiting maximum covalency in compounds
Exhibiting amphoteric nature in their oxides

Solution:

Be shows a maximum covalency of four while Al shows a maximum covalency of six.

Hence, the answer is option (3) - Exhibiting maximum covalency in compounds.

Example 3

Question:

Beryllium shows a diagonal relationship with:

Solution:

Be shows a diagonal relationship with Al.

Hence, the answer is option (2) - Al.

Conclusion

The diagonal relationship between beryllium and aluminium has this exciting interplay with periodic trends that casts them into almost similar chemical properties despite being placed in different groups. How these elements can warrant such similarities through an analysis of their definitions, key properties, and examples drawn from applications in real-life scenarios will be discussed. This will not only enrich our knowledge of chemistry but also have practical implications for various industries. This periodic system is so great that, through diagonal relationships, it offers definite further study and probing of chemistry. Therefore, all rules of the periodic table are mutual and supported by other rules.

Frequently Asked Questions (FAQs)

Q: What is the significance of the Be-Al diagonal relationship in their reaction with organic compounds?

Both Beryllium and Aluminum can form organometallic compounds with similar structures and reactivities. This is due to their diagonal relationship and comparable tendencies to form covalent bonds with carbon.

Q: How does the Be-Al diagonal relationship affect their behavior in the formation of hydrides?

Both Beryllium and Aluminum can form complex hydrides like BeH2 and AlH3. This similar behavior is due to their diagonal relationship and comparable reactivity with hydrogen.

Q: Why do both Beryllium and Aluminum have high strength-to-weight ratios?

Both elements have high strength-to-weight ratios due to their strong metallic bonding and relatively low atomic masses. This is a characteristic of their diagonal relationship.

Q: How does the density of Beryllium compare to Aluminum?

Beryllium has a lower density than Aluminum, but both are relatively light metals. This similarity in being lightweight is related to their diagonal relationship and comparable atomic structures.

Q: What is the significance of the Be-Al diagonal relationship in their reaction with alkali metals?

Both Beryllium and Aluminum can form intermetallic compounds with alkali metals. This similar behavior is due to their diagonal relationship and comparable electronic structures.

Q: How does the Be-Al diagonal relationship affect their behavior in the formation of complex anions?

Both Beryllium and Aluminum can form complex anions like [Be(OH)4]2- and [Al(OH)4]-. This similar behavior is due to their diagonal relationship and comparable amphoteric nature.

Q: What is the significance of the Be-Al diagonal relationship in their reaction with acids?

Both Beryllium and Aluminum react with strong acids to produce hydrogen gas. This similar behavior is due to their diagonal relationship and comparable reactivity.

Q: What is the significance of the Be-Al diagonal relationship in their carbide formation?

Both Beryllium and Aluminum form covalent carbides (Be2C and Al4C3) with similar properties. This is a result of their diagonal relationship and comparable tendencies to form covalent bonds.

Q: How does the thermal conductivity of Beryllium compare to Aluminum?

Both Beryllium and Aluminum have high thermal conductivity, with Beryllium's being even higher than Aluminum's. This similarity is related to their diagonal relationship and comparable electronic structures.

Q: Why do both Beryllium and Aluminum form passivating oxide layers?

Both elements form thin, protective oxide layers when exposed to air, which prevent further oxidation. This similar behavior is due to their diagonal relationship and comparable reactivity with oxygen.

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