Question

review: ionic compounds & lewis diagrams
for each of the element pairs, write the formula, draw the lewis dot diagram, and name the compound.

element pair	formula	lewis dot diagram	name
boron & iodine
francium & oxygen

transition metals review
for each of the following, write either the chemical formula or the name of the compound.

formula	name
pdo₂
	platinum (iv) sulfide
	mercury (i) fluoride

Answer:

Part 1: Ionic Compounds & Lewis Diagrams (Element Pairs)

1. Beryllium & Bromine

Step 1: Determine oxidation states
Beryllium (Be) is in Group 2, so it has a +2 oxidation state. Bromine (Br) is in Group 17, so it has a -1 oxidation state.

Step 2: Balance charges for the formula
To balance the charges, we need 2 Br⁻ ions for every 1 Be²⁺ ion. Thus, the formula is $\boldsymbol{BeBr_2}$.

Step 3: Lewis Dot Diagram

• Be: 2 valence electrons (dots: $\cdot \cdot$)
• Br: 7 valence electrons (dots: $\cdot \cdot \cdot \cdot \cdot \cdot \cdot$)
• In $BeBr_2$, Be donates 2 electrons (one to each Br), so each Br gains 1 electron (becomes Br⁻ with 8 valence electrons). The Lewis structure shows Be in the center with two Br atoms, each with 8 electrons (3 lone pairs + 1 bond pair from Be).

Step 4: Name the compound
Beryllium bromide (since Be is a metal, use the metal name + nonmetal name with -ide suffix).

2. Boron & Iodine

Step 1: Determine oxidation states
Boron (B) is in Group 13, so it has a +3 oxidation state. Iodine (I) is in Group 17, so it has a -1 oxidation state.

Step 2: Balance charges for the formula
To balance +3 (B) and -1 (I), we need 3 I⁻ ions. Thus, the formula is $\boldsymbol{BI_3}$.

Step 3: Lewis Dot Diagram

• B: 3 valence electrons (dots: $\cdot \cdot \cdot$)
• I: 7 valence electrons (dots: $\cdot \cdot \cdot \cdot \cdot \cdot \cdot$)
• In $BI_3$, B donates 3 electrons (one to each I), so each I gains 1 electron (becomes I⁻ with 8 valence electrons). The Lewis structure shows B in the center with three I atoms, each with 8 electrons (3 lone pairs + 1 bond pair from B).

Step 4: Name the compound
Boron iodide (B is a metalloid, but for ionic naming, use metal/metalloid name + nonmetal name with -ide suffix).

3. Francium & Oxygen

Step 1: Determine oxidation states
Francium (Fr) is in Group 1, so it has a +1 oxidation state. Oxygen (O) is in Group 16, so it has a -2 oxidation state.

Step 2: Balance charges for the formula
To balance +1 (Fr) and -2 (O), we need 2 Fr⁺ ions for every 1 O²⁻ ion. Thus, the formula is $\boldsymbol{Fr_2O}$.

Step 3: Lewis Dot Diagram

• Fr: 1 valence electron (dot: $\cdot$)
• O: 6 valence electrons (dots: $\cdot \cdot \cdot \cdot \cdot \cdot$)
• In $Fr_2O$, each Fr donates 1 electron (total 2 electrons) to O, so O gains 2 electrons (becomes O²⁻ with 8 valence electrons). The Lewis structure shows O in the center with two Fr atoms, each with 0 valence electrons (donated), and O with 8 electrons (4 lone pairs).

Step 4: Name the compound
Francium oxide (Fr is a metal, so metal name + nonmetal name with -ide suffix).

Part 2: Transition Metals Review

1. $\boldsymbol{Cr_2O_3}$ (Chromium(III) oxide)

Step 1: Determine chromium’s oxidation state
Let Cr’s oxidation state be $x$. Oxygen (O) is -2.
For $Cr_2O_3$: $2x + 3(-2) = 0 \implies 2x - 6 = 0 \implies x = +3$.

Step 2: Name the compound
Chromium(III) oxide (use Roman numerals for the transition metal’s oxidation state, then nonmetal with -ide).

2. $\boldsymbol{PdO_2}$ (Palladium(IV) oxide)

Step 1: Determine palladium’s oxidation state
Let Pd’s oxidation state be $x$. Oxygen (O) is -2.
For $PdO_2$: $x + 2(-2) = 0 \implies x - 4 = 0 \implies x = +4$.

Step 2: Name the compound
Palladium(IV) oxide (Roman numeral for Pd’s +4 state, then nonmetal with -ide).

3. Platinum(IV) sulfide

Step 1: Determine the formula
Platinum (Pt) has a +4 oxidation state. Sulfide (S) has a -2 oxidation state.

Step 2: Balance charges
To balance +4 (Pt) and -2 (S), we need 1 Pt⁴⁺ and 2 S²⁻ ions. Thus, the formula is $\boldsymbol{PtS_2}$.

4. Mercury(I) fluoride

Step 1: Determine the formula
Mercury(I) is $Hg_2^{2+}$ (a polyatomic ion with a +2 overall charge, so each Hg is +1). Fluoride (F) has a -1 oxidation state.

Step 2: Balance charges
To balance $Hg_2^{2+}$ (+2) and F⁻ (-1), we need 2 F⁻ ions. Thus, the formula is $\boldsymbol{Hg_2F_2}$ (simplified to $\boldsymbol{Hg_2F_2}$, but often written as $Hg_2F_2$ or $HgF$ if considering average charge, but strictly $Hg_2F_2$ for the dimeric ion).

Final Table (Ionic Compounds & Lewis Diagrams)

Element Pair	Formula	Lewis Dot Diagram (Brief)	Name
Boron & iodine	$BI_3$	B: $\cdot \cdot \cdot$; I: $\cdot \cdot \cdot \cdot \cdot \cdot \cdot$ (3 I, each with 8 e⁻)	Boron iodide
Francium & oxygen	$Fr_2O$	Fr: $\cdot$ (2 Fr, no e⁻); O: $\cdot \cdot \cdot \cdot \cdot \cdot \cdot \cdot$ (8 e⁻)	Francium oxide

Final Table (Transition Metals Review)

Formula	Name
$PdO_2$	Palladium(IV) oxide
$PtS_2$	Platinum(IV) sulfide
$Hg_2F_2$	Mercury(I) fluoride

(Note: Lewis dot diagrams are best drawn with proper electron dot notation, but the brief description above outlines the valence electrons and bonding.)