Question

1. how many valence electrons does each of the following atoms have? a. rubidium, z = 37 b. arsenic, z = 33 c. aluminum, z = 13 d. nickel, z = 28 9. how many 3d electrons are found in each of the following elements? a. nickel, z = 28 b. vanadium, z = 23 c. manganese, z = 25 d. iron, z = 26 10. for each of the following elements, indicate which set of orbitals is filled last. a. radium, z = 88 b. iodine, z = 53 c. gold, z = 79 d. lead, z = 82 11. give some similarities that exist among the elements of group viia. 12. which elements on the periodic table lose electrons most easily (metals or nonmetals)? why? 13. in each of the following sets of atoms, which element would be expected to have the highest ionization energy? a. cs, k, li b. ba, sr, ca c. i, br, cl d. mg, si, s

Explanation:

8.

Step1: Determine electron - configurations

Use the periodic table and electron - filling rules to find the outermost electrons (valence electrons).

Step2: Identify valence electrons

• a. Rubidium ($Rb$, $Z = 37$) has an electron - configuration of $[Kr]5s^1$. The number of valence electrons is 1.
• b. Arsenic ($As$, $Z = 33$) has an electron - configuration of $[Ar]4s^23d^{10}4p^3$. The number of valence electrons is 5 ($2 + 3$ from the outermost $4s$ and $4p$ sub - shells).
• c. Aluminum ($Al$, $Z = 13$) has an electron - configuration of $[Ne]3s^23p^1$. The number of valence electrons is 3 ($2+1$ from the outermost $3s$ and $3p$ sub - shells).
• d. Nickel ($Ni$, $Z = 28$) has an electron - configuration of $[Ar]4s^23d^8$. The number of valence electrons is 2 (from the outermost $4s$ sub - shell).

Step1: Write electron - configurations

Use the Aufbau principle to write the electron - configurations of the elements.

Step2: Count 3d electrons

• a. Nickel ($Ni$, $Z = 28$) has an electron - configuration of $[Ar]4s^23d^8$. The number of 3d electrons is 8.
• b. Vanadium ($V$, $Z = 23$) has an electron - configuration of $[Ar]4s^23d^3$. The number of 3d electrons is 3.
• c. Manganese ($Mn$, $Z = 25$) has an electron - configuration of $[Ar]4s^23d^5$. The number of 3d electrons is 5.
• d. Iron ($Fe$, $Z = 26$) has an electron - configuration of $[Ar]4s^23d^6$. The number of 3d electrons is 6.

Step1: Write electron - configurations

Use the Aufbau principle to write the electron - configurations of the elements.

Step2: Identify the last - filled orbital

• a. Radium ($Ra$, $Z = 88$) has an electron - configuration of $[Rn]7s^2$. The last - filled orbital is the 7s orbital.
• b. Iodine ($I$, $Z = 53$) has an electron - configuration of $[Kr]5s^24d^{10}5p^5$. The last - filled orbital is the 5p orbital.
• c. Gold ($Au$, $Z = 79$) has an electron - configuration of $[Xe]4f^{14}5d^{10}6s^1$. The last - filled orbital is the 6s orbital.
• d. Lead ($Pb$, $Z = 82$) has an electron - configuration of $[Xe]4f^{14}5d^{10}6s^26p^2$. The last - filled orbital is the 6p orbital.

Answer:

a. 1
b. 5
c. 3
d. 2

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