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Interactive Shell Diagram

Samarium Bohr Model, Electron Shell Diagram

Visualize the exact electron shell distribution of Samarium (Sm). Its 62 total electrons orbit the microscopic nucleus across 6 quantum energy shells in the specific mathematical pattern 2 – 8 – 18 – 24 – 8 – 2.

Atomic Number: Z = 62Symbol: SmShells: 6Shell Pattern: 2-8-18-24-8-2Valence e⁻: 3

Live Bohr Shell Diagram

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Shell Distribution:2 – 8 – 18 – 24 – 8 – 2

Samarium Nuclear Composition

Protons, neutrons, and electrons at a glance

Protons

62

Positive charge carriers in the nucleus

Neutrons

88

Neutral mass carriers in the nucleus

Electrons

62

Across 6 shells: 2-8-18-24-8-2

Detailed Bohr Model Analysis

Samarium's traditional Bohr model diagram provides a spectacular two-dimensional blueprint of its subatomic structure. By plotting its 62 negatively charged electrons rotating around a positively charged nucleus (containing 62 protons and approximately 88 neutrons), we can visually decrypt its chemical properties.

Across its 6 electron shells, Samarium distributes its electrons in the following exact hierarchical sequence, from the innermost ring outward: 2 – 8 – 18 – 24 – 8 – 2.

Applying the Bohr Rules to Samarium

The Bohr model, introduced by Niels Bohr in 1913, radically changed our understanding of atomic structure by proposing that electrons orbit the nucleus in strictly quantized circular energy levels (or 'shells'). For Samarium, we apply the 2n² rule, which states that the maximum electron capacity of any given shell is determined by two times the shell number (n) squared.

In the case of Samarium, its 62 total electrons stack outward from the nucleus. The innermost K-shell (n=1) holds 2 electrons. The L-shell (n=2) holds 8. This stacking continues geometrically until we map the entire 2 – 8 – 18 – 24 – 8 – 2 sequence. Because Samarium is a high-mass transuranic or deep-period element, its inner shells are packed with immense density—holding up to 32 electrons in a single shell. This massive inner core creates a powerful electrostatic shield, severely shielding the outermost electrons from the nucleus and introducing complex relativistic contraction.

The Role of Samarium's Valence Electrons

When analyzing the Bohr model of Samarium, the absolute most critical ring is the outermost shell. This layer holds exactly 3 valence electrons.

In chemistry, the core electrons (the inner rings) are chemically inert. They do not participate in bonding. All chemical reactivity, covalent sharing, and ionic transfers are conducted exclusively by the valence electrons. Because Samarium has 3 valence electrons, it inherently seeks to achieve a stable "octet" (a full outer shell of 8 electrons, or 2 for lightweight elements). Because it has fewer than 4 valence electrons, Samarium generally behaves as an electron donor. It prefers to shed its outer electrons completely, dropping down to the beautifully stable full shell beneath it, typically forming an electropositive cation.

Bohr Shell Rules (Quick Reference)

  • 2n² Rule: Shell n holds a maximum of 2n² electrons.
  • Octet Rule: The outermost (valence) shell holds a max of 8 electrons for chemical stability.
  • Aufbau Order: Electrons fill from innermost shell outward.
  • Valence = Reactivity: The electrons in the last shell dictate how the element bonds.

Chemical & Physical Overview

The element Samarium, represented universally by the chemical symbol Sm, holds the atomic number 62. This means that a standard neutral atom of Samarium possesses exactly 62 protons within its dense nucleus, orbited precisely by 62 electrons. With a standard atomic weight of approximately 150.360 atomic mass units (u), Samarium is classified fundamentally as a lanthanide.

From a periodic standpoint, Samarium resides in Period 6 and Group 3 of the periodic table, placing it firmly within the f-block. The overarching category of an element—whether it behaves as an alkali metal, a halogen, a noble gas, or a transition metal—is determined exclusively by how these electrons fill the available quantum shells.

Diving deeper into its physical footprint, Samarium exhibits a calculated atomic radius of 229 picometers (pm). When attempting to physically remove an electron from its outermost shell, it requires a primary ionization energy of 5.644 eV. Furthermore, its tendency to attract shared electrons in a covalent chemical bond—known as its electronegativity—measures at 1.17 on the Pauling scale. These specific subatomic metrics (radius, ionization, and electron affinity) combine to define exactly how Samarium interacts, bonds, and reacts with every other chemical element in the observable universe.

Atomic Properties — Samarium

Atomic Mass

150.36 u

Electronegativity

1.17 (Pauling)

Block / Group

F-block, Group 3

Period

Period 6

Atomic Radius

229 pm

Ionization Energy

5.644 eV

Electron Affinity

0.5 eV

Category

Lanthanide

Oxidation States

+3+2

Real-World Applications

SmCo Permanent Magnets (High-Temp)Neutron Absorber (Nuclear)Cancer Treatment (Sm-153 EDTMP)Laser (Nd:YAG dopant)Headphones & Guitar Pickups

Real-World Applications & Industrial Uses

The distinct electronic structure of Samarium directly empowers its functionality in the physical world. Its specific combination of atomic radius, electron affinity, and valence shell configuration makes it absolutely indispensable across modern industry, biological systems, and advanced technology.

Here are the primary real-world applications of Samarium:

  • SmCo Permanent Magnets (High-Temp): Its baseline chemical reactivity makes it specifically suited for this primary role.
  • Neutron Absorber (Nuclear): Used heavily in advanced manufacturing and chemical processing.
  • Cancer Treatment (Sm-153 EDTMP)
  • Laser (Nd:YAG dopant)
  • Headphones & Guitar Pickups

    Without the specific quantum mechanics occurring microscopically within Samarium's electron cloud, these macroscopic technologies and biological processes would fundamentally fail to operate.

    • Did You Know?

    Samarium-cobalt (SmCo) magnets were the first rare-earth magnets, predating NdFeB. They outperform NdFeB at high temperatures (>300°C), making them critical for jet engine actuators. ¹⁴⁹Sm is the largest known neutron absorber (poison) in nuclear reactors.

    Shell-by-Shell Capacity Table

    How each of Samarium's 6 shells compare to their theoretical maximum

    ShellSymbolElectrons (This Element)Max Capacity (2n²)Fill %
    1K (n=1)22
    100%
    2L (n=2)88
    100%
    3M (n=3)1818
    100%
    4N (n=4)2432
    75%
    5O (n=5)850
    16%
    6P (n=6)272
    3%

    Shell Comparison: Samarium vs Neighbors

    ← Previous Element

    Pm

    Promethium

    Z=61

    2-8-18-23-8-2 shells

    View Bohr Model

    ⬤ Current

    Sm

    Samarium

    Z=62

    2-8-18-24-8-2 shells

    Next Element →

    Eu

    Europium

    Z=63

    2-8-18-25-8-2 shells

    View Bohr Model

    Explore Other Atomic Models of Samarium

    Full Analysis

    Samarium Electron Configuration

    Complete config (1s² 2s² 2p⁶ 3s² 3p⁶ 3d¹⁰ 4s² 4p⁶ 4d¹⁰ 5s² 5p⁶ 4f⁶ 6s²), quizzes, trends & comparisons

    Quantum Orbitals

    Samarium SPDF Orbital Diagram

    Subshell breakdown, Aufbau principle & 3D orbital shapes

    Frequently Asked Questions — Samarium Bohr Model

    Authoritative References

    The atomic and structural data for Samarium provided on this page has been cross-referenced with primary chemical databases. For further primary-source research, consult the following global authorities:

    PubChem Database

    National Institutes of Health

    NIST Atomic Spectra

    National Institute of Standards & Tech.

    Bohr Models for All 118 Elements

    HHydrogen1HeHelium2LiLithium3BeBeryllium4BBoron5CCarbon6NNitrogen7OOxygen8FFluorine9NeNeon10NaSodium11MgMagnesium12AlAluminum13SiSilicon14PPhosphorus15SSulfur16ClChlorine17ArArgon18KPotassium19CaCalcium20ScScandium21TiTitanium22VVanadium23CrChromium24MnManganese25FeIron26CoCobalt27NiNickel28CuCopper29ZnZinc30GaGallium31GeGermanium32AsArsenic33SeSelenium34BrBromine35KrKrypton36RbRubidium37SrStrontium38YYttrium39ZrZirconium40NbNiobium41MoMolybdenum42TcTechnetium43RuRuthenium44RhRhodium45PdPalladium46AgSilver47CdCadmium48InIndium49SnTin50SbAntimony51TeTellurium52IIodine53XeXenon54CsCesium55BaBarium56LaLanthanum57CeCerium58PrPraseodymium59NdNeodymium60PmPromethium61SmSamarium62EuEuropium63GdGadolinium64TbTerbium65DyDysprosium66HoHolmium67ErErbium68TmThulium69YbYtterbium70LuLutetium71HfHafnium72TaTantalum73WTungsten74ReRhenium75OsOsmium76IrIridium77PtPlatinum78AuGold79HgMercury80TlThallium81PbLead82BiBismuth83PoPolonium84AtAstatine85RnRadon86FrFrancium87RaRadium88AcActinium89ThThorium90PaProtactinium91UUranium92NpNeptunium93PuPlutonium94AmAmericium95CmCurium96BkBerkelium97CfCalifornium98EsEinsteinium99FmFermium100MdMendelevium101NoNobelium102LrLawrencium103RfRutherfordium104DbDubnium105SgSeaborgium106BhBohrium107HsHassium108MtMeitnerium109DsDarmstadtium110RgRoentgenium111CnCopernicium112NhNihonium113FlFlerovium114McMoscovium115LvLivermorium116TsTennessine117OgOganesson118
    Toni Tuyishimire — Principal Software Engineer, Toni Tech Solution
    Technical AuthorFact CheckedLast Reviewed: April 2026

    Toni Tuyishimire

    Principal Software EngineerScience & EdTech Systems

    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.