Nh 113

Nihonium (Nh)

post-transition-metal

Period: 7 Group: 13 Block: p

Expected to be a Solid

Standard Atomic Weight

Electron configuration

[Rn] 5f¹⁴ 6d¹⁰ 7s² 7p¹(predicted)

Melting point

426.85 °C (700 K)

Boiling point

1156.85 °C (1430 K)

Density

1.600000e+4 kg/m³

Oxidation states

N/A

Electronegativity (Pauling)

N/A

Ionization energy (1st)

Discovery year

2004

Atomic radius

170 pm

Details

Name origin Named after the country of Japan.

Discovery country Japan

Discoverers RIKEN

Nihonium is a synthetic transactinide element in group 13, below thallium. It has been identified only as individual atoms produced in heavy-ion nuclear reactions, chiefly through decay chains from heavier nuclei and by direct fusion experiments. Its chemistry has not been characterized experimentally in bulk. Relativistic calculations predict that nihonium may differ markedly from lighter group 13 elements, with a particularly stable +1 oxidation state and a less accessible +3 state.

Nihonium does not occur naturally in the Earth’s crust. The name nihonium and the symbol Nh are the accepted ones for element 113. Nihon is one of the two ways to say “Japan” in Japanese and means “the land of the Rising Sun.” It is the first element to have been discovered in an Asian country [665], [666], [667].

The synthesis of nihonium was first announced in 2004. The Joint Institute for Nuclear Research (JINR) and the Lawrence Livermore National Laboratory were able to produce two super-heavy elements by bombarding a rotating 243Am disc with an ion beam of 48Ca in a U-400 cyclotron. During the reaction, isotopes of moscovium, previously known as ununpentium, were synthesized and decayed in a tenth of a second to nihonium, which then decayed to roentgenium. Because the atoms of moscovium only existed for a tenth of a second, radiochemical proof was needed to support its syntheses. A Swiss scientist at the Paul Scherrer Institute (PSI) performed the radiochemical experiment by analyzing a copper plate that had been placed behind the 243Am disc in the cyclotron. This copper plate collected all moscovium atoms that were synthesized and was processed through liquid chromatography techniques that yielded five times more moscovium atoms than produced by fusion alone. The direct synthesis of nihonium was announced later that year by a team of Japanese scientists from the Cyclotron Center of the RIKEN Research Institute. These scientists bombarded atoms of 209Bi with a beam of 70Zn in a RIKEN heavy-ion linear accelerator (RILAC), shown in Fig. IUPAC.113.1, and gas-filled recoil ion separator (GARIS), shown in Fig. IUPAC.113.2. Nihonium has no known isotopic applications aside from scientific research.

On July 23, 2004, scientists working at the RIKEN Nishina Center for Accelerator-based Science in Wako, Japan, created the first two atoms of the element nihonium by accelerating zinc ions to 10 percent the speed of light and then impacting them onto a thin bismuth target. Both atoms quickly underwent a series of four alpha decays, forming dubnium-262, which then decayed by spontaneous fission. Nihonium's most stable isotope, nihonium-286, has a half-life of about 20 seconds. It decays into roentgenium-282 through alpha decay.

On November 28th, 2016 element 113 was named “nihonium” with the symbol Nh. The name was proposed by the discoverers at RIKEN Nishina Center for Accelerator-Based Science in Japan. The name means mean “the Land of Rising Sun” and comes from the word “Nihon,” which means “Japan” in Japanese.

Read about Nihonium on Wikipedia

Images

Properties

Physical

Atomic radius (empirical) 170 pm

Density

Phase at STP solid

Melting point 426.85 °C

Boiling point 1156.85 °C

Chemical

Electron affinity

Valence electrons 3

Electron configuration

Electron configuration (semantic)

Thermodynamic

N/A

Nuclear

Stable isotopes 0

Mass number (most stable) 286

Discovery year 2004

Abundance

N/A

Reactivity

N/A

Crystal Structure

N/A

Electronic Structure

Electrons per shell 14, 10, 3

Identifiers

CAS number 54084-70-7

InChI InChI=1S/Nh

InChI Key KUGNSLWRKGRKGS-UHFFFAOYSA-N

Electron Configuration Predicted

Ion charge

Protons 113

Electrons 0

Charge Neutral

Configuration —

—

Electron configuration data not available for this ion.

Atomic model

Protons 113

Neutrons 170

Electrons 113

Mass number 283

Stability Radioactive

Isotopes change neutron count, mass, and stability — not the electron configuration of a neutral atom.

N/A

Schematic atomic model, not to scale.

Atomic Fingerprint

Emission / Absorption Spectrum

Emission Visible: 380–750 nm

Isotope Distribution

No stable isotopes.

Mass number	Atomic mass (u)	Natural abundance	Half-life
282 Radioactive	282.17567 ± 0.00039	N/A	140 ms
283 Radioactive	283.17657 ± 0.00052	N/A	140 ms
281 Radioactive	281.17348 ± 0.00075	N/A	100 ms
289 Radioactive	289.188461 ± 0.000537	N/A	30 seconds
287 Radioactive	287.18339 ± 0.00081	N/A	20 seconds

Measured

Phase / State

Predicted

Solid 25 °C (298.15 K)

Reason: 401.9 °C below melting point (426.85 °C)

Melting point 426.85 °C

Boiling point 1156.85 °C

Below melting by 401.9 °C

0 K Current temperature: 25 °C 6000 K

Phase timeline

Schematic, not to scale

Solid

Liquid

Gas

Melting

Boiling

25°C

Solid

Liquid

Gas

Current

Phase transition points

Melting point Predicted

426.85 °C

Boiling point Predicted

1156.85 °C

Current phase Predicted
Solid

Density

Reference density Predicted

1.600000e+4 kg/m³

At standard conditions

Current density Predicted

1.600000e+4 kg/m³

At standard conditions

113 Nh 286

Nihonium — Atomic Orbital Visualizer

[Rn] 5f14 6d10 7s2 7p1(predicted)

Energy levels 2 8 18 32 32 18 3

Oxidation states N/A

HOMO 7p n=7 · l=1 · m=-1

Nihonium — Atomic Orbital Visualizer Preview

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113 Nh 286

Nihonium — Crystal Structure Visualizer

Crystal structure data not available

Isotopes (5)

Mass number	Atomic mass (u)	Natural abundance	Half-life	Decay mode
282 Radioactive	282.17567 ± 0.00039	N/A	140 ms	α =100%
283 Radioactive	283.17657 ± 0.00052	N/A	140 ms	α =100%
281 Radioactive	281.17348 ± 0.00075	N/A	100 ms	α ?SF ?
289 Radioactive	289.188461 ± 0.000537	N/A	30 seconds	α ?SF ?
287 Radioactive	287.18339 ± 0.00081	N/A	20 seconds	α ?SF ?

282 Radioactive

Atomic mass (u) 282.17567 ± 0.00039

Natural abundance N/A

Half-life 140 ms

Decay mode

α =100%

283 Radioactive

Atomic mass (u) 283.17657 ± 0.00052

Natural abundance N/A

Half-life 140 ms

Decay mode

α =100%

281 Radioactive

Atomic mass (u) 281.17348 ± 0.00075

Natural abundance N/A

Half-life 100 ms

Decay mode

α ?SF ?

289 Radioactive

Atomic mass (u) 289.188461 ± 0.000537

Natural abundance N/A

Half-life 30 seconds

Decay mode

α ?SF ?

287 Radioactive

Atomic mass (u) 287.18339 ± 0.00081

Natural abundance N/A

Half-life 20 seconds

Decay mode

α ?SF ?

Extended Properties

Covalent Radii (Extended)

Covalent radius (Pyykkö)

Numbering Scales

Mendeleev

Polarizability & Dispersion

Dipole polarizability

Dipole polarizability (unc.)

Advanced Reference Data

Isotope Decay Modes (20)

Isotope	Mode	Intensity
278	A	100%
279	A	—
279	SF	—
280	A	—
280	SF	—
281	A	—
281	SF	—
282	A	100%
283	A	100%
284	A	100%

Additional Data

Estimated Crustal Abundance

The estimated element abundance in the earth's crust.

Not Applicable

References (1)

[5] Nihonium https://education.jlab.org/itselemental/ele113.html

Estimated Oceanic Abundance

The estimated element abundance in the earth's oceans.

Not Applicable

References (1)

[5] Nihonium https://education.jlab.org/itselemental/ele113.html

References

(8)

1 PubChem

Data deposited in or computed by PubChem

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2 Atomic Mass Data Center (AMDC), International Atomic Energy Agency (IAEA)

The half-life and atomic mass data was provided by the Atomic Mass Data Center at the International Atomic Energy Agency.

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3 IUPAC Commission on Isotopic Abundances and Atomic Weights (CIAAW)

Nihonium

Element data are cited from the Atomic weights of the elements (an IUPAC Technical Report). The IUPAC periodic table of elements can be found at https://iupac.org/what-we-do/periodic-table-of-elements/. Additional information can be found within IUPAC publication doi:10.1515/pac-2015-0703 Copyright © 2020 International Union of Pure and Applied Chemistry.

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4 IUPAC Periodic Table of the Elements and Isotopes (IPTEI)

The information are cited from Pure Appl. Chem. 2018; 90(12): 1833-2092, https://doi.org/10.1515/pac-2015-0703.

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License note: Copyright (c) 2020 International Union of Pure and Applied Chemistry. The International Union of Pure and Applied Chemistry (IUPAC) contribution within Pubchem is provided under a CC-BY-NC-ND 4.0 license, unless otherwise stated.

5 Jefferson Lab, U.S. Department of Energy

Nihonium

Thomas Jefferson National Accelerator Facility (Jefferson Lab) is one of 17 national laboratories funded by the U.S. Department of Energy. The lab's primary mission is to conduct basic research of the atom's nucleus using the lab's unique particle accelerator, known as the Continuous Electron Beam Accelerator Facility (CEBAF). For more information visit https://www.jlab.org/

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License note: Please see citation and linking information: https://education.jlab.org/faq/index.html

6 Los Alamos National Laboratory, U.S. Department of Energy

Nihonium

The periodic table at the LANL (Los Alamos National Laboratory) contains basic element information together with the history, source, properties, use, handling and more. The provenance data may be found from the link under the source name.

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7 NIST Physical Measurement Laboratory

Nihonium

The periodic table contains NIST's critically-evaluated data on atomic properties of the elements.

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8 PubChem Elements

Nihonium

This section provides all form of data related to element Nihonium.

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Last updated: May 1, 2026

Data verified: May 12, 2026

Content is reviewed against latest scientific data.