Fact-checked by Grok 2 weeks ago

Isotopes of neon

Neon (atomic number 10) has three stable isotopes—^{20}Ne, ^{21}Ne, and ^{22}Ne—which together make up natural neon with relative abundances of 90.48(3)%, 0.27(1)%, and 9.25(3)%, respectively, yielding a standard atomic weight of 20.1797(6). In addition to these stable nuclides, 16 radioactive isotopes of neon have been identified, spanning mass numbers from 15 to 34, all characterized by very short half-lives ranging from nanoseconds to minutes. The longest-lived among the radioactive isotopes is ^{24}Ne, with a half-life of 3.38(2) minutes, decaying primarily via β⁻ emission to ^{24}Na. The stable isotopes of neon are primordial in origin for ^{20}Ne, the most abundant, while ^{21}Ne and ^{22}Ne include contributions from nucleogenic production in and through nuclear reactions such as α,n reactions on ^{18}O and ^{19}F, respectively. Variations in their isotopic ratios in natural samples, particularly elevated ^{21}Ne/^{20}Ne, serve as tracers in for processes like exposure dating of rocks and meteorites, as ^{21}Ne is produced by reactions in the atmosphere and surface materials. Radioactive neon isotopes, produced artificially in accelerators or reactors, have limited practical applications due to their instability, though ^{20}Ne is bombarded with deuterons via the ^{20}Ne(d,α)^{18}F reaction to generate ^{18}F for (PET) imaging, and ^{22}Ne serves as a precursor for the medical radioisotope ^{22}Na via proton bombardment such as ^{22}Ne(p,n)^{22}Na. Nuclear properties of neon isotopes reveal insights into shell structure and decay mechanisms; for instance, lighter isotopes like ^{15}Ne and ^{16}Ne undergo two-proton emission, while heavier ones beyond ^{22}Ne predominantly β⁻ decay, often with delayed neutron emission in neutron-rich cases. Studies of charge radii across the neon chain, including unstable neutron-rich isotopes, highlight anomalies near the N=20 shell closure, indicating deformation in nuclei like ^{30}Ne. These isotopes are crucial for probing nuclear forces and astrophysical processes, such as nucleosynthesis in stars where neon isotopes participate in alpha-capture reactions.

Introduction

Discovery and basic properties

Neon was discovered in 1898 by chemists Sir William Ramsay and Morris William Travers at . They isolated the element through of liquefied air, capturing the gases that boiled off at specific temperatures after had been removed. The new gas exhibited a brilliant red glow when an electric current was passed through it in a discharge tube, leading to its name derived from word neos, meaning "new." This discovery expanded the known , confirming their group in the periodic table. The existence of isotopes was first experimentally confirmed through studies on by J.J. Thomson in 1913. Using his positive ray analysis apparatus, a precursor to the mass spectrometer, Thomson observed two distinct parabolas corresponding to neon atoms of mass 20 and 22 atomic mass units in a sample of the element. This demonstration that comprised a of atoms with the same chemical properties but different masses provided key evidence for the concept of isotopes, challenging the prevailing view of elements as uniform. Thomson's work on thus marked a pivotal moment in , highlighting atomic weight discrepancies as isotopic mixtures. Neon has atomic number 10 and an electron configuration of [He] $2s^2 2p^6, resulting in a completely filled outer shell that renders the element chemically inert as a . Nuclearly, neon possesses three stable isotopes—^{20}Ne, ^{21}Ne, and ^{22}Ne—arising from even-even and even-odd combinations of protons and neutrons that contribute to their binding stability, with even-even configurations generally more robust due to pairing effects. The neon nucleus exhibits general stability, particularly in ^{20}Ne, owing to its proximity to filled shell structures in light nuclei near the magic neutron number 28, though neon isotopes span a range approaching this subshell closure. In total, 19 neon isotopes are known, ranging from the proton-rich ^{15}Ne to the neutron-rich ^{34}Ne.

Overview of isotopes

Neon (Z=10) has 19 known isotopes, with mass numbers ranging from ^{15}Ne to ^{34}Ne. These isotopes are classified into three stable nuclides—^{20}Ne, ^{21}Ne, and ^{22}Ne—and 16 radioactive ones. The stable isotopes dominate natural neon, while the radioactive variants are short-lived, typically decaying via beta emission or particle ejection. As a light element in the second period of the periodic table, neon exhibits isotope stability primarily around neutron numbers N=10 to 12, with no long-lived radioactive isotopes beyond the stable trio. This reflects the general trend for light nuclei, where binding energies favor stability in a narrow mass range without extended radioactive decay chains. Key nuclear properties, including atomic masses and ground-state spins, for these isotopes are compiled in the NUBASE 2020 evaluation and the Atomic Mass Evaluation (AME) 2020. For instance, ^{20}Ne has a spin of 0^+ and a mass excess of -7041.9322(15) keV, serving as a reference for precision measurements. These evaluations provide the foundational data for understanding neon's nuclear structure and applications.

Natural occurrence and abundances

Stable isotopes

Neon has three stable isotopes: neon-20 (²⁰Ne), neon-21 (²¹Ne), and neon-22 (²²Ne). These isotopes constitute the entire natural abundance of neon on Earth and are primordial in origin, formed primarily through stellar nucleosynthesis processes rather than Big Bang nucleosynthesis, which does not produce neon in significant quantities. Their nuclear structures consist of 10 protons and varying numbers of neutrons: 10 neutrons for ²⁰Ne, 11 for ²¹Ne, and 12 for ²²Ne. None undergo radioactive decay and are thus classified as stable, with half-lives exceeding the age of the universe. Nucleogenic and cosmogenic contributions are minor (<1%) to the atmospheric abundances of ²¹Ne and ²²Ne but can be significant in crustal and surface samples. The natural abundances and atomic masses of these isotopes, as measured in Earth's atmosphere, reflect their primordial stellar production with minor modifications for ²¹Ne and ²²Ne due to in situ nucleogenic processes. The isotopic ratio ²⁰Ne/²²Ne is approximately 9.8 in the atmosphere, providing a baseline for distinguishing primordial from secondary neon components.
IsotopeAtomic Mass (u)Natural Abundance (%)
²⁰Ne19.9924401762(17)90.48(3)
²¹Ne20.993846685(41)0.27(1)
²²Ne21.991385114(18)9.25(3)
²⁰Ne is the most abundant stable isotope of and arises predominantly from helium burning in , where alpha capture on ¹⁶O produces ²⁰Ne via the ¹⁶O(α,γ)²⁰Ne during the hydrostatic of massive . This occurs in the cores of more massive than about 8 masses after the completion of carbon burning. contributes negligibly to ²⁰Ne, as fusion halts before reaching . ²¹Ne, the rarest stable isotope, has a primarily stellar origin through the neon-sodium () cycle in hydrogen-burning shells of massive and asymptotic giant branch (AGB) , involving proton capture on ²⁰Ne to form ²¹Na, which beta decays to ²¹Ne: ²⁰Ne(p,γ)²¹Na(β⁺ν)²¹Ne. On , its abundance includes a minor nucleogenic component produced in the crust via reactions such as ¹⁸O(α,n)²¹Ne and ²⁴Mg(n,α)²¹Ne, where alpha particles and neutrons originate from the decay chains of and . ²²Ne forms mainly through alpha capture on ¹⁸O during helium burning in red giants and AGB stars: ¹⁸O(α,γ)²²Ne, with ¹⁸O itself derived from primary ¹⁴N (a product) via ¹⁴N(α,γ)¹⁸F(β⁺ν)¹⁸O. This isotope is dominated by helium-shell burning in low- to intermediate-mass stars.

Trace and cosmogenic isotopes

A trace cosmogenic , ²¹Ne, is generated through reactions where high-energy s collide with heavier target nuclei such as calcium () and iron () in minerals like and silicates. These reactions primarily involve neutrons produced by cosmic ray interactions with the atmosphere, leading to the fragmentation of atomic nuclei and the release of ²¹Ne. At , the production rate of cosmogenic ²¹Ne in quartz is approximately 17 atoms per gram per year under standard high-latitude conditions. In contrast, a nucleogenic component of neon-22 (²²Ne) is formed through (α,n) initiated by alpha particles from the of and in rocks. These alpha particles interact with nuclei like fluorine-19 (¹⁹F), producing ²²Ne via direct such as ¹⁹F(α,n)²²Ne, particularly in - and -rich crustal materials. This process results in elevated ²²Ne concentrations in the continental crust compared to atmospheric levels. Isotopic ratios of neon exhibit notable variations between atmospheric, crustal, and reservoirs due to these production mechanisms. Atmospheric has a baseline ²¹Ne/²⁰Ne ratio of approximately 0.0029, but crustal influences introduce excesses, such as elevated ²¹Ne/²⁰Ne in from cosmogenic accumulation in aquifers. In deep brines, the ²¹Ne component can derive up to 42% from non-atmospheric (crustal) sources, reflecting mixing between air-saturated and in-situ . Extraterrestrial environments reveal additional neon isotope signatures shaped by implantation and fractionation. Lunar regolith samples show implanted neon, with ²⁰Ne/²²Ne ratios around 12-13, higher than terrestrial air, due to direct bombardment and trapping in soil grains over billions of years. In meteorites, mass-dependent processes, such as differential escape or variability, lead to depleted ²⁰Ne relative to ²²Ne in certain components, with ²⁰Ne/²²Ne ratios as low as 9-10 in fractionated solar-derived gases. preserves primordial neon signatures, characterized by elevated ²¹Ne/²²Ne ratios (up to 0.06) along a mixing line with solar-like ²⁰Ne/²²Ne (∼12.5-13.8), indicating inheritance from early nebula sources with minimal post-accretionary processing.

Artificial isotopes

Production and synthesis

Artificial neon isotopes are primarily synthesized in settings using particle accelerators and reactors, as they do not occur naturally in significant quantities. Charged-particle accelerators, such as cyclotrons and linear accelerators, enable the production of neutron-deficient isotopes through reactions involving proton or deuteron bombardment of lighter s. For instance, the neutron-deficient isotope ^{18} is generated via the reaction ^{19}F(p,2n)^{18}, where a proton beam irradiates a , often in facilities like the ISOLDE at or similar setups with proton energies around 30 MeV. Similarly, lighter neutron-deficient isotopes such as ^{15}, ^{16}, and ^{17} are produced using high-energy heavy-ion beams in projectile fragmentation or knockout reactions, typically at relativistic energies (e.g., 100-200 MeV/) on light s like or , resulting in very low yields due to their extreme instability and rapid decay. Heavier, neutron-rich neon isotopes are synthesized either through neutron-induced reactions in reactors or via fragmentation in accelerators. In reactor environments, neutron irradiation of sodium targets produces ^{23}Ne through the (n,p) reaction ^{23}Na(n,p)^{23}Ne, utilizing thermal or fast neutrons from sources like fission reactors or neutron generators. For more neutron-rich species like ^{24}Ne, production often involves projectile fragmentation of heavier projectiles (e.g., argon or calcium beams) at intermediate energies (around 1 GeV/nucleon) on production targets, followed by in-flight separation. These accelerator-based methods for neutron-rich isotopes leverage facilities like those at GSI or NSCL, where spallation or fragmentation yields a range of exotic nuclei including ^{24}Ne to ^{30}Ne. To prepare enriched targets for these syntheses, stable neon isotopes (^{20}Ne, ^{21}Ne, ^{22}Ne) are separated from natural mixtures using techniques such as low-temperature in cascades or thermal diffusion columns, achieving high purity for use in gaseous targets. isotope separation methods, involving selective photoexcitation of specific isotopic transitions, are also employed for enhancing target purity, particularly for astrophysical reaction studies. Challenges in production include the inherently low cross-sections and yields for the most exotic neutron-deficient isotopes like ^{15}Ne–^{17}Ne, where detection often requires advanced tracking detectors due to their fleeting existence, limiting practical quantities to those observable in beam experiments rather than isolated samples.

Decay modes and half-lives

The artificial neon isotopes exhibit a variety of decay modes, including proton emission, two-proton emission, beta-plus decay, electron capture, and beta-minus decay, with half-lives spanning from femtoseconds to minutes. These properties reflect the nuclear instability arising from imbalances in proton-neutron ratios, as determined from experimental measurements using accelerator-produced beams and decay spectroscopy techniques. The light, proton-rich isotopes (A = 15–19) are particularly unbound, leading to extremely rapid particle emission, while mid-mass (A = 23–26) and heavy (A = 27–34) isotopes favor beta decays with progressively varying lifetimes. Light neon isotopes (¹⁵Ne to ¹⁹Ne) are highly proton-rich and decay predominantly via proton emission or two-proton (2p) emission due to their location beyond the proton drip line, resulting in half-lives shorter than 1 μs. For instance, ¹⁶Ne undergoes true two-proton decay to ¹⁴O, with a measured half-life of (6.4 ± 1.6) × 10⁻²¹ s (0.64 fs), as observed in fragment separator experiments at relativistic energies. Similarly, ¹⁷Ne decays primarily by beta-plus emission to ¹⁷F, with a half-life of 109.2 ± 0.3 ms, and its ground state has spin-parity J^π = 1/2⁺, exhibiting a two-proton halo structure characterized by a low two-proton separation energy of 933 keV and extended proton density. This halo configuration arises from the weakly bound valence protons coupled to the ¹⁵O core, as confirmed through exclusive proton-knockout reactions and momentum distributions. Heavier in this group, ¹⁹Ne decays via beta-plus emission and electron capture to ¹⁹F, with a precisely measured half-life of 17.262 ± 0.007 s. In the mid-mass range (²³Ne to ²⁶Ne), the isotopes are less extreme in proton excess and primarily undergo beta-plus decay to fluorine isotopes or , with half-lives ranging from seconds to minutes. These decays populate excited states in the nuclei, often accompanied by . A representative example is ²⁴Ne, which decays by beta-minus to ²⁴Na with a of 3.38 ± 0.02 min, as established through high-resolution following its production in reactions like ²⁴Mg(p,n). The branching ratios favor ground-state and low-lying excited-state transitions, reflecting allowed Gamow-Teller strengths. Nearby, ²⁵Ne has a of 602 ± 8 ms for beta-minus decay to ²⁵Na. Heavy neon isotopes (²⁷Ne to ³⁴Ne) are neutron-rich and decay via beta-minus emission to sodium isotopes, with half-lives on the order of milliseconds or less. This mode compensates for neutron excess by converting a neutron to a proton. For example, ²⁹Ne undergoes beta-minus decay to ²⁹Na with a half-life of 14.7 ± 0.4 ms, including a neutron emission probability of 17 ± 5%, as measured in projectile fragmentation experiments at relativistic velocities. The ground-state spin-parity for several in this range, such as ²⁷Ne (J^π = 5/2⁺), indicates sd-shell configurations influencing the decay rates. Isotopes like ³⁰Ne and ³¹Ne show similar beta-minus pathways, with half-lives of 7.22 ± 0.18 ms and 3.4 ± 0.8 ms, respectively, and potential for delayed neutron emission due to high Q-values. These properties have been evaluated using shell-model calculations benchmarked against experimental data from facilities like GSI and NSCL.

Scientific applications

In nuclear medicine and isotope production

Neon-20 serves as a material in the production of , a key radioisotope for () imaging, particularly in cancer diagnostics. The reaction involves deuteron irradiation of neon-20 gas via the ^{20}Ne(d,\alpha)^{18}F process, where deuterons from a bombard the enriched neon gas , yielding with a of 109.8 minutes. This method allows for on-site production at medical facilities equipped with cyclotrons, enabling the synthesis of ^{18}F-labeled tracers like fluorodeoxyglucose (FDG) for detecting metabolic activity in tumors. The gas-phase approach facilitates efficient recovery of the volatile , which adheres to the walls post-irradiation. Similarly, neon-22 is utilized as a target for producing sodium-22 through proton bombardment in the ^{22}Ne(p,n)^{22}Na reaction. This cyclotron-based process employs enriched neon-22 gas s to generate sodium-22, a positron-emitting isotope with a of 2.6 years, suitable for long-term applications in . Sodium-22 is employed as a source for scanners and in research involving positron studies, providing a stable reference for instrument validation and due to its well-characterized emissions, including positrons and a 1.275 MeV . Enriched stable isotopes of neon, such as and , are commonly incorporated into gas targets for cyclotron production of medical radioisotopes, offering advantages in yield and purity over solid or liquid alternatives. These targets typically operate under (up to several atmospheres) to achieve sufficient for beam interaction, with post-irradiation involving gas and chemical separation of the product nuclides. Safety considerations are paramount given neon's properties, including its volatility and low reactivity, which necessitate robust containment to prevent leaks, pressure ruptures, or unintended release during handling and irradiation; protocols include remote monitoring, shielding, and ventilation systems to mitigate and ensure compliance with radiological protection standards.

In geochronology and geochemistry

Cosmogenic ^{21}Ne is widely used in to determine the exposure ages of quartz-bearing rock surfaces, providing insights into the timing of glacial retreats, landslides, and tectonic uplift events. This stable isotope accumulates in minerals like through reactions induced by cosmic rays, with the exposure age calculated as t = \frac{^{21}\mathrm{Ne}}{P}, where ^{21}\mathrm{Ne} is the measured concentration and P is the production rate, typically around 10 atoms/g/yr at and high latitude for . This method has been applied to date surfaces in diverse settings, such as the Antarctic Dry Valleys and the , revealing exposure histories spanning from thousands to millions of years. against other nuclides like ^{10}Be ensures accuracy, with interlaboratory comparisons confirming production rate uncertainties below 10%. In landscape evolution studies, ratios involving cosmogenic ^{21}Ne and other , such as ^{21}Ne/^{3}He or ^{21}Ne/^{4}He, help quantify rates by distinguishing cosmogenic accumulation from radiogenic or inherited components, particularly in settings with variable shielding or sediment transport. For instance, in tectonically active regions like the , these ratios reveal millennial-scale rates of 1-10 mm/yr, linking to uplift and paleoclimate fluctuations such as glacial-interglacial cycles. In basin-wide analyses, cosmogenic ^{21}Ne concentrations in fluvial sediments integrate over large catchments, with applications in reconstructing paleotopography and tectonic forcing in areas like the . Neon isotopes serve as tracers of , with elevated ^{20}Ne/^{22}Ne ratios exceeding 13 in ocean island basalts indicating a component derived from the solar nebula, preserved in the deep since 's accretion. This solar-like signature contrasts with atmospheric neon (^{20}Ne/^{22}Ne ≈ 9.8) and reflects minimal fractionation during early . Additionally, nucleogenic ^{21}Ne, produced by and decay chains via (α,n) reactions, contributes to neon budgets, with ^{21}Ne/^{22}Ne ratios up to 0.1 in some hotspots, helping delineate deep Earth reservoirs and volatile recycling. In , neon isotope ratios in meteorites elucidate implantation and planetary processes; for example, solar-type ^{20}Ne/^{22}Ne ≈ 13.8 in breccias records exposure to particles over millions of years. In Martian meteorites and atmospheric samples, fractionated ^{20}Ne/^{22}Ne ratios around 10 suggest volatile from a primitive mantle enriched in chondritic components, with implications for and during the planet's early history. These signatures, preserved in shergottites, highlight neon's role in tracing solar system volatile origins and interplanetary transfer.