Atomic radius decreases across a period (left to right) because the nucleus gains more protons while electrons are added to the same outer shell , so the nucleus pulls the electrons closer without adding new shielding layers.

Quick scoop

  • Across a period, atomic number increases , so the nuclear charge becomes more positive.
  • Electrons go into the same principal energy level , so shielding by inner electrons barely changes.
  • The effective nuclear charge on the outer electrons rises, pulling them closer to the nucleus and shrinking the atom.

Why the nucleus “wins”

  • Each step to the right adds one proton and one electron ; the electron goes into the same shell , not a new one.
  • More protons mean a stronger electrostatic pull on the same‑shell electrons, overcoming the slight extra electron–electron repulsion.
  • Because no new inner shells appear , the inner‑electron “shield” stays roughly constant, so the outer electrons feel a net stronger inward pull.

Effective nuclear charge in a nutshell

  • Effective nuclear charge ( ZeffZ_{\text{eff}}Zeff​) is the net positive charge felt by valence electrons after accounting for shielding.
  • Across a period, ZeffZ_{\text{eff}}Zeff​ increases steadily , which compresses the electron cloud and reduces atomic radius.

Trend snapshot (example: Period 2)

Element (Period 2)| Trend in atomic radius
---|---
Li → Be → B → C → N → O → F → Ne| Radius decreases left to right 910

  • Lithium (Li) is largest in the period; neon (Ne) is smallest because of the increasing nuclear pull on the same‑shell electrons.

In simple terms

Think of the nucleus as a magnet and electrons as metal filings. As you move right across a period, the magnet gets stronger (more protons) but the filings stay in the same layer , so they get pulled in tighter and the whole “cloud” shrinks.

Information gathered from public forums or data available on the internet and portrayed here.