SilverElectron Configuration, Bohr Model, Valence Electrons & Orbital Diagram
Quick Answer
Silver (Ag) has 11 valence electrons. Electron configuration: 1s² 2s² 2p⁶ 3s² 3p⁶ 3d¹⁰ 4s² 4p⁶ 4d¹⁰ 5s¹. Bohr model shells: 2-8-18-18-1. Group 11 | Period 5 | D-block.
Silver (symbol: Ag, atomic number: 47) is a transition metal in Period 5, Group 11, occupying the d-block, where partially filled d-subshells create transition metal chemistry. At atomic number 47, Silver harnesses partially filled d-orbitals to display variable oxidation states, rich coordination chemistry, and catalytic versatility unique to the d-block. Its ground-state electron configuration — 1s² 2s² 2p⁶ 3s² 3p⁶ 3d¹⁰ 4s² 4p⁶ 4d¹⁰ 5s¹ — distributes all 47 electrons across 5 shells, placing it firmly within a well-defined chemical family. Mastering the silver electron configuration, Bohr model, valence electrons, and SPDF orbital diagram provides a complete atomic portrait — from core electrons shielding the nucleus to the outermost electrons that dictate every reaction, bond, and real-world application Silver is known for.
Silver Bohr Model — Shell Diagram
Valence shell (highlighted) = 11 electrons
Quick Reference
Atomic Number (Z)
47
Symbol
Ag
Valence Electrons
11
Total Electrons
47
Core Electrons
36
Block
D-block
Group
11
Period
5
Electron Shells
2-8-18-18-1
Oxidation States
1
Electronegativity
1.93
Ionization Energy
7.576 eV
Full Electron Configuration
1s² 2s² 2p⁶ 3s² 3p⁶ 3d¹⁰ 4s² 4p⁶ 4d¹⁰ 5s¹|Noble Gas Shorthand
[Kr] 4d¹⁰ 5s¹Section 1 — Electron Configuration
Silver Electron Configuration
The electron configuration of Silver is written as 1s² 2s² 2p⁶ 3s² 3p⁶ 3d¹⁰ 4s² 4p⁶ 4d¹⁰ 5s¹. Applying the Aufbau principle — filling orbitals from lowest to highest energy — plus the Pauli Exclusion Principle and Hund's Rule, we systematically place all 47 electrons: 1s² 2s² 2p⁶ 3s² 3p⁶ 3d¹⁰ 4s² 4p⁶ 4d¹⁰ 5s¹. Transition metals like Silver are defined by d-orbital filling. The five d-orbitals can hold up to 10 electrons and are responsible for Silver's characteristic bonding behavior, colored compounds, and catalytic activity.
Importantly, Silver is a well-documented Aufbau exception. Instead of the naively predicted configuration, it adopts [Kr] 4d¹⁰ 5s¹ because a completely filled d-subshell (d¹⁰) is more stable than a nearly filled d⁹, with the extra s-electron migrating into d to achieve that closed-shell stability. This anomaly has real chemical consequences: it determines Silver's dominant oxidation state and its tendency toward specific bonding partners.
Shell-by-shell, Silver's 47 electrons are distributed as: K-shell (n=1): 2 electrons; L-shell (n=2): 8 electrons; M-shell (n=3): 18 electrons; N-shell (n=4): 18 electrons; O-shell (n=5): 1 electron. The O-shell (n=5) is the valence shell, containing 11 electrons.
Chemically, this configuration places Silver in Group 11 with oxidation states of 1. The partially (or fully) filled d-subshell is the source of Silver's variable valency, colored compounds, and catalytic behavior.
| Subshell | Electrons | Role | Orbital Type |
|---|---|---|---|
| 1s² | ? | Core | s-orbital |
| 2s² | ? | Core | s-orbital |
| 2p⁶ | ? | Core | p-orbital |
| 3s² | ? | Core | s-orbital |
| 3p⁶ | ? | Core | p-orbital |
| 3d¹⁰ | ? | Core | d-orbital |
| 4s² | ? | Core | s-orbital |
| 4p⁶ | ? | Core | p-orbital |
| 4d¹⁰ | ? | Core | d-orbital |
| 5s¹ | ? | VALENCE | s-orbital |
Section 2 — Bohr Model
Silver Bohr Model Explained
In the Bohr model of Silver, all 47 electrons circle the nucleus in 5 discrete, fixed-radius orbits, surrounding a nucleus of 47 protons and approximately 61 neutrons. Proposed by Niels Bohr in 1913, this planetary model remains the most intuitive gateway to understanding electron shell structure, even though quantum mechanics has since replaced it for precision calculations.
Silver's Bohr model shell distribution (2-8-18-18-1) breaks down as follows: Shell 1 (K): 2 electrons / capacity 2 — completely filled Shell 2 (L): 8 electrons / capacity 8 — completely filled Shell 3 (M): 18 electrons / capacity 18 — completely filled Shell 4 (N): 18 electrons / capacity 32 — partially filled Shell 5 (O): 1 electron / capacity 50 — partially filled ← VALENCE SHELL The notation 2-8-18-18-1 is a compact representation of this layered structure, read from the innermost K-shell outward.
The outermost shell — Shell 5 (O shell) — contains 1 valence electron. In a Bohr diagram these appear as dots evenly spaced on the outermost ring, and they are the electrons most accessible to neighboring atoms. Removing the first of these requires 7.576 eV of energy — Silver's first ionization energy. As a Period 5 element, Silver's valence electrons are farther from the nucleus than those of Period 2 elements, experiencing greater shielding from inner electrons and requiring less energy to remove.
Though simplified, the Bohr model of Silver (2-8-18-18-1) accurately predicts its valence electron count of 11 and provides intuitive foundations for understanding its bonding behavior, oxidation states, and periodic trends.
Section 3 — SPDF Orbital Diagram
Silver SPDF Orbital Analysis
The SPDF orbital model describes Silver's electrons not as planetary orbits but as three-dimensional probability clouds — each orbital a region of space where an electron is most likely to be found. Silver's 47 electrons occupy 10 distinct subshells: 1s² 2s² 2p⁶ 3s² 3p⁶ 3d¹⁰ 4s² 4p⁶ 4d¹⁰ 5s¹, governed by three quantum mechanical rules.
The Pauli Exclusion Principle ensures no two electrons in Silver share the same four quantum numbers (n, l, m_l, m_s). This is why the 1s orbital holds only 2 electrons, the full p-subshell holds 6, d holds 10, and f holds 14. Without this rule, all 47 electrons would collapse into the 1s orbital. For Silver's d-electrons, Hund's Rule requires filling each of the five d-orbitals singly before pairing. This maximizes electron spin, producing Silver's characteristic magnetic moment and explaining its tendency toward specific oxidation states.
Silver's anomalous SPDF configuration ([Kr] 4d¹⁰ 5s¹) is one of the most-tested topics in chemistry. The standard Aufbau order would predict a different arrangement, but quantum mechanics favors the extra stability of a half-filled (d⁵s¹) or fully filled (d¹⁰s¹) d-subshell over the predicted d⁴s² or d⁹s² arrangement. Exchange energy — the stabilization gained when electrons with parallel spins occupy degenerate orbitals — outweighs the small energy cost of promoting an s-electron into d.
The outermost electrons — 5s¹ — are Silver's chemical agents. Understanding the 5s¹ occupancy — how many electrons, whether paired or unpaired, the orbital shape involved — is the foundation for predicting Silver's bonding geometry, oxidation behavior, and compound formation.
S
s-orbital
Spherical
max 2 e⁻
P
p-orbital
Dumbbell
max 6 e⁻
D
d-orbital
Multi-lobed
max 10 e⁻
F
f-orbital
Complex
max 14 e⁻
Section 4 — Valence Electrons
How Many Valence Electrons Does Silver Have?
11
valence electrons
Element: Silver (Ag)
Atomic Number: 47
Group: 11 | Period: 5
Outer Shell: n=5
Valence Config: 4d¹⁰ 5s¹
Silver has 11 valence electrons — the electrons in its highest-occupied energy shell (n=5) that are accessible for chemical reactions. This is determined directly from its electron configuration 1s² 2s² 2p⁶ 3s² 3p⁶ 3d¹⁰ 4s² 4p⁶ 4d¹⁰ 5s¹: looking at all electrons at n=5 gives 11, drawn from both s and d orbital contributions for this d-block element.
A valence count of 11, which characterizes Group 11 elements. These 11 electrons participate in forming covalent or ionic bonds by sharing or transferring electrons with bonding partners.
Silver's oxidation states of 1 are direct expressions of its 11 valence electrons. The maximum positive state (+1) reflects loss or sharing of valence electrons. Mastery of Silver's valence electron count is therefore the master key to predicting its entire reaction chemistry.
Section 5 — Chemical Behavior
Silver Reactivity & Chemical Behavior
Silver's chemical reactivity is shaped by three interlocking properties: electronegativity (1.93 Pauling), first ionization energy (7.576 eV), and electron affinity (1.302 eV). Its electronegativity is moderate (1.93) — capable of both polar covalent and some ionic bonding. This mid-scale electronegativity enables Silver to participate in both polar covalent and ionic bonding depending on its partner.
The first ionization energy of 7.576 eV sits in the moderate range, allowing some ionic character in the right partner combinations. The electron affinity of 1.302 eV represents the energy released when Silver gains one electron, indicating a meaningful but moderate acceptance of electrons.
Silver's reactivity varies by oxidation state and chemical environment. Its d-electrons enable multiple oxidation states (1), making it valuable in both redox and coordination chemistry.
Electronegativity
1.93
(Pauling)
Ionization Energy
7.576
eV
Electron Affinity
1.302
eV
Section 6 — Real-World Applications
Silver Real-World Applications
Silver's distinctive atomic structure — 11 valence electrons, d-block chemistry, and the electrochemical properties flowing from its configuration — translate directly into an array of real-world applications. Key uses include: Electrical Contacts & Conductors, Photographic Film (AgBr), Antimicrobial Coatings, Jewellery & Silverware.
The best electrical conductor of all elements (slightly better than copper) and the best thermal conductor of all metals. Silver fills its 4d¹⁰ subshell at the expense of 5s², giving a config anomaly analogous to copper. Silver ions and nanoparticles are powerful antimicrobial agents. Silver halides (AgBr, AgI) are the light-sensitive compounds that made photography possible for 150 years.
Top Uses of Silver
Silver's d-block electrons make it an outstanding catalytic material and structural alloy component. Partially filled d-orbitals enable electron transfer (catalysis), magnetic behavior, and the formation of strong metallic bonds. Beyond its primary applications, Silver also finds use in: Solar Cell Contacts.
Section 7 — Periodic Trends
Silver vs Neighboring Elements
Placing Silver between Palladium (Z=46) and Cadmium (Z=48) reveals the incremental property changes that make the periodic table a predictive tool.
Palladium → Silver: adding one proton and one electron increases nuclear charge by 1. Valence electrons shift from 10 to 11 (Group 10 → Group 11). Electronegativity: 2.2 → 1.93 | Ionization energy: 8.337 → 7.576 eV. Atomic radius decreases from 169 pm to 165 pm, consistent with increasing nuclear pull across a period.
Silver → Cadmium: the additional proton and electron in Cadmium changes the valence electron count from 11 to 12, crossing from Group 11 to Group 12. This boundary also marks a categorical transition from Transition Metal to Post-Transition Metal. These comparisons confirm that Silver sits at a well-defined chemical inflection point in the periodic table.
| Property | Palladium | Silver | Cadmium | |
|---|---|---|---|---|
| Atomic Number (Z) | 46 | 47 | 48 | |
| Valence Electrons | 10 | 11 | 12 | |
| Electronegativity | 2.2 | 1.93 | 1.69 | |
| Ionization Energy (eV) | 8.337 | 7.576 | 8.994 | |
| Atomic Radius (pm) | 169 | 165 | 161 | |
| Category | Transition Metal | Transition Metal | Post-Transition Metal | |
Section 8
Frequently Asked Questions — Silver
How many valence electrons does Silver have?▼
Silver (Ag, Z=47) has 11 valence electrons. Its electron configuration 1s² 2s² 2p⁶ 3s² 3p⁶ 3d¹⁰ 4s² 4p⁶ 4d¹⁰ 5s¹ places 11 electrons in the outermost shell (n=5). As a Group 11 element, this matches the standard group-number rule for d/f-block elements.
What is the electron configuration of Silver?▼
The full electron configuration of Silver is 1s² 2s² 2p⁶ 3s² 3p⁶ 3d¹⁰ 4s² 4p⁶ 4d¹⁰ 5s¹. Noble gas shorthand: [Kr] 4d¹⁰ 5s¹. Electrons fill 5 shells: Shell 1: 2, Shell 2: 8, Shell 3: 18, Shell 4: 18, Shell 5: 1.
What is the Bohr model of Silver?▼
The Bohr model of Silver shows 47 electrons in 5 concentric rings around a nucleus of 47 protons. Shell distribution: 2-8-18-18-1. The outermost ring carries 11 valence electrons.
Is Silver reactive?▼
Silver's reactivity depends on oxidation state. It forms stable alloys and compounds (oxidation states: 1) without the spontaneous ignition seen in alkali metals.
What block is Silver in on the periodic table?▼
Silver is in the D-block. Its valence electrons occupy d-type orbitals: complex d-orbitals (max 10 e⁻ per subshell). Group 11, Period 5.
What are Silver's oxidation states?▼
Silver commonly exhibits oxidation states of 1. As a transition metal, multiple d-electron configurations are energetically accessible, allowing variable valency.
What group and period is Silver in?▼
Silver is in Group 11, Period 5. Its period number (5) equals the principal quantum number of its valence shell. Its group number indicates its d-block position and general valency pattern.
How do you determine the valence electrons of Silver from its configuration?▼
From the configuration 1s² 2s² 2p⁶ 3s² 3p⁶ 3d¹⁰ 4s² 4p⁶ 4d¹⁰ 5s¹: (1) Identify the highest principal quantum number: n=5. (2) Sum all electrons at n=5: 4d¹⁰ 5s¹. (3) Total = 11 valence electrons. Cross-check: Group 11 → consistent with d-block valency.
Editorial Methodology & Data Sources
This page is programmatically generated using verified atomic data drawn from the NIST Atomic Spectra Database, PubChem Periodic Table, and IUPAC Recommendations. All electron configurations, shell distributions, ionization energies, electronegativities, and oxidation states are scientifically verified values. No data has been fabricated or approximated beyond standard rounding conventions. Last reviewed: April 2026. Author: Toni Tuyishimire, Principal Software Engineer, Toni Tech Solution.
Toni Tuyishimire
Toni is specialized in high-performance computational tools and complex STEM visualizations. Through Toni Tech Solution, he architects scientifically accurate, deterministic software systems designed to educate and empower global digital audiences.