Question

how does ionization energy change across a period? 1. label your x-axis as atomic number and the y-axis as ionization energy 2. fill in the table below 3. use this link: http://bit.ly/462joem 3. plot on your graphs
element name
lithium
boron
oxygen
fluorine
atomic number
ionization energy

Explanation:

To solve this problem, we first need to find the atomic number and ionization energy for each element:

Step 1: Determine Atomic Numbers

• Lithium (Li): Atomic number = 3
• Boron (B): Atomic number = 5
• Oxygen (O): Atomic number = 8
• Fluorine (F): Atomic number = 9

Step 2: Find Ionization Energies (using the provided link or reference data)

• Lithium (Li): First ionization energy ≈ 520 kJ/mol
• Boron (B): First ionization energy ≈ 801 kJ/mol
• Oxygen (O): First ionization energy ≈ 1314 kJ/mol
• Fluorine (F): First ionization energy ≈ 1681 kJ/mol

Step 3: Fill the Table

Element Name	Atomic Number	Ionization Energy (kJ/mol)
Boron	5	801
Oxygen	8	1314
Fluorine	9	1681

Step 4: Plot the Graph

• X - axis: Atomic number (3, 5, 8, 9)
• Y - axis: Ionization energy (520, 801, 1314, 1681)
• Plot points: (3, 520), (5, 801), (8, 1314), (9, 1681)
• Connect the points to observe the trend (ionization energy generally increases across a period due to increasing effective nuclear charge, pulling electrons closer to the nucleus, making them harder to remove).

Final Table (Filled)

Element Name	Atomic Number	Ionization Energy (kJ/mol)
Boron	5	801
Oxygen	8	1314
Fluorine	9	1681

Trend Observation

Across a period (from left to right), ionization energy increases because:

• The number of protons (atomic number) increases, so the nucleus pulls electrons more strongly (higher effective nuclear charge).
• Electrons are added to the same energy level, so shielding from inner electrons remains constant. This makes it harder to remove the outermost electron, increasing ionization energy.

Answer:

To solve this problem, we first need to find the atomic number and ionization energy for each element:

Step 1: Determine Atomic Numbers

• Lithium (Li): Atomic number = 3
• Boron (B): Atomic number = 5
• Oxygen (O): Atomic number = 8
• Fluorine (F): Atomic number = 9

Step 2: Find Ionization Energies (using the provided link or reference data)

• Lithium (Li): First ionization energy ≈ 520 kJ/mol
• Boron (B): First ionization energy ≈ 801 kJ/mol
• Oxygen (O): First ionization energy ≈ 1314 kJ/mol
• Fluorine (F): First ionization energy ≈ 1681 kJ/mol

Step 3: Fill the Table

Element Name	Atomic Number	Ionization Energy (kJ/mol)
Boron	5	801
Oxygen	8	1314
Fluorine	9	1681

Step 4: Plot the Graph

• X - axis: Atomic number (3, 5, 8, 9)
• Y - axis: Ionization energy (520, 801, 1314, 1681)
• Plot points: (3, 520), (5, 801), (8, 1314), (9, 1681)
• Connect the points to observe the trend (ionization energy generally increases across a period due to increasing effective nuclear charge, pulling electrons closer to the nucleus, making them harder to remove).

Final Table (Filled)

Element Name	Atomic Number	Ionization Energy (kJ/mol)
Boron	5	801
Oxygen	8	1314
Fluorine	9	1681

Trend Observation

Across a period (from left to right), ionization energy increases because:

• The number of protons (atomic number) increases, so the nucleus pulls electrons more strongly (higher effective nuclear charge).
• Electrons are added to the same energy level, so shielding from inner electrons remains constant. This makes it harder to remove the outermost electron, increasing ionization energy.