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Electron capture

Electron capture is a type of in which a proton-rich absorbs an inner-shell from the atom, converting the proton into a and emitting an in the process. Also known as K-capture or . This transformation decreases the of the by one while leaving the unchanged, resulting in a daughter of a different . The process typically involves an from the K or L shell and is mediated by the weak nuclear force, occurring in isotopes where the available decay energy is insufficient to allow . After capture, the resulting vacancy in the inner triggers a cascade of electron rearrangements, often producing characteristic X-rays, electrons, or radiation. is energetically favorable when the mass of the parent nucleus exceeds that of the daughter nucleus plus the , and it competes with other modes in proton-excess regions of the chart. Prominent examples of electron capture include the decay of potassium-40 to argon-40, which serves as the basis for potassium-argon geochronology, and beryllium-7 to lithium-7, a pure electron capture process. In medicine, isotopes like iodine-123, which decays to tellurium-123 via electron capture, are widely used in nuclear imaging techniques such as single-photon emission computed tomography (SPECT) due to their emission of low-energy gamma rays. Beyond terrestrial applications, electron capture plays a critical role in astrophysical environments, particularly in the evolution of massive stars. During the core collapse preceding a explosion, electron captures on heavy nuclei reduce , accelerating the infall and influencing the explosion dynamics and outcomes. This process is essential in dense stellar interiors, where it affects production and the formation of neutron-rich isotopes.

Definition and Process

Basic Definition

Electron capture is a type of process in which a proton-rich captures an inner-shell orbital electron, usually from the or shell, thereby converting a proton into a while emitting an . This decay mode is characteristic of unstable isotopes with a neutron-to-proton that is too low for , allowing the to achieve a more balanced composition through this weak interaction-mediated transformation. The process predominantly occurs in proton-rich nuclides where the energy available for decay, known as the Q-value, is insufficient to produce a positron-electron pair, specifically less than 1.022 MeV (twice the rest mass energy of 0.511 MeV). In such cases, electron capture serves as the primary pathway to reduce the , competing with or replacing when the latter is energetically forbidden. At the fundamental level, electron capture is governed by the weak , facilitated through the of a charged W boson, which enables the quark-level transition of an in the proton to a , accompanied by the electron's involvement in conservation via emission. The daughter nuclide resulting from this decay has an Z decreased by one compared to the parent, while retaining the same A, thus shifting the one position down in the periodic table. This contrasts briefly with beta minus decay, where an antineutrino is emitted instead of a , but both processes ultimately adjust the nucleus's proton-neutron balance.

Atomic and Nuclear Changes

In electron capture, a proton in the is transformed into a through the , mediated by the emission of a W that converts the proton while producing an . This decreases the by one, changing the from parent to daughter, such as in the of to argon-40. The nuclear recoil resulting from the sudden momentum transfer during this conversion imparts to the on the order of tens of , which is typically negligible compared to other energies but can influence the overall in precise measurements. The capture of an inner-shell electron, most commonly from the K-shell due to its proximity to the , creates a vacancy in the electron cloud, destabilizing the atomic structure. This hole is rapidly filled by electrons cascading from higher shells, leading to the emission of characteristic s with energies corresponding to the differences in binding energies between shells, or alternatively, Auger electrons if the energy is transferred to eject another electron rather than producing a . For instance, in beryllium-7 electron capture, the K-shell vacancy results in emissions around 0.1 keV, providing a signature for detection. The emitted electron neutrino carries away the available decay energy, reduced by the binding energy of the captured electron (typically 10-100 eV for inner shells), resulting in a monochromatic neutrino spectrum distinct from the continuous spectrum in beta decay. If the daughter nucleus is left in an excited state following the capture, it may subsequently de-excite by emitting gamma rays, with the probability depending on the nuclear structure and spin-parity changes. The binding energy of the captured electron significantly affects the decay rate, as captures from shells closer to the nucleus (e.g., K-shell) are more probable due to higher wavefunction overlap with the nucleus, with K-capture rates often dominating by factors of 5-10 over L-shell captures in light atoms. This shell dependence is quantified in decay probability calculations, where the ratio of K to L capture is approximately the ratio of their radial wavefunctions at the nucleus.

Theoretical Framework

Reaction Equation and Q-value

Electron capture is a nuclear decay process in which a proton-rich captures an inner-shell , transforming a proton into a neutron and emitting an electron neutrino. The general reaction equation is given by ^{A}_{Z}\mathrm{X} + e^{-} \rightarrow ^{A}_{Z-1}\mathrm{Y} + \nu_{e}, where ^{A}_{Z}\mathrm{X} denotes the parent with Z and A, e^{-} is the captured orbital (typically from the K-shell), ^{A}_{Z-1}\mathrm{Y} is the daughter , and \nu_{e} is the . The Q-value represents the total energy released in the process, which is shared primarily between the and the rearrangement following the capture. It is defined as the difference in rest masses between the initial and final states, expressed using es as Q_{\mathrm{EC}} = [M(^{A}_{Z}\mathrm{X}) - M(^{A}_{Z-1}\mathrm{Y})]c^{2}, where M denotes the and c is the ; this formulation accounts for the masses inherently, as the parent atom has Z s and the daughter has Z-1. A more precise calculation incorporates the B_{e} of the captured : Q = [M(^{A}_{Z}\mathrm{X}) - M(^{A}_{Z-1}\mathrm{Y})]c^{2} - B_{e}, though B_{e} is typically negligible compared to the nuclear mass difference (on the order of keV versus MeV). For the process to be energetically allowed, Q > 0; this contrasts with , which requires Q > 1.022 MeV to create the electron-positron pair. The probability of electron capture from specific atomic shells contributes to partial decay rates, with the total Q-value determining the overall feasibility but not the shell distribution directly. For low atomic numbers (Z \lesssim 30), K-shell capture dominates, accounting for approximately 80-90% of events, while L-shell capture comprises about 10-15% (L/K ratio \approx 0.1-0.12); higher shells (M, N) contribute negligibly due to their lower at the . The chemical environment can influence the electron capture rate primarily through variations in the at the due to screening effects and chemical in different molecular or solid-state surroundings. These effects typically alter the rate by less than 0.1%, though measurements for specific nuclides like ^{7}\mathrm{Be} suggest variations up to \sim 1\%, reflecting changes in on the eV scale. The impact on the Q-value via shifts is negligible.

Selection Rules and Probability

Electron capture transitions are governed by the selection rules of the , analogous to those in . For allowed transitions, the change in total satisfies ΔJ = 0, ±1 (with no 0 → 0 transitions permitted), while the remains unchanged (π_i π_f = +1). These rules arise from the (Fermi) and axial-vector (Gamow-Teller) components of the weak current: Fermi transitions enforce ΔJ = 0 with no change, whereas Gamow-Teller transitions allow ΔJ = 0, ±1 (excluding 0 → 0) also without change. The strength of these transitions is quantified by the logarithm of the comparative , log ft, which combines the with phase-space factors and serves as a measure of transition probability; lower log ft values indicate stronger, more probable decays, typically ranging from 3 to 5 for allowed transitions. Forbidden transitions, involving higher-order weak interactions (e.g., ΔJ > 1 or parity change), exhibit elevated log ft values (e.g., 5–7 for first-forbidden), leading to suppressed rates due to additional carried by higher multipoles. The nuclear matrix elements, determined by the overlap of initial and final nuclear wave functions, further modulate these strengths, with spin- (J^π) assignments of the states dictating whether a transition is allowed or forbidden. The probability of electron capture is proportional to the at the , |ψ(0)|^2, which is highest for s-orbitals (e.g., K-shell electrons) due to their non-zero probability at r = 0, decreasing sharply for p- and higher orbitals. The decay rate λ can be expressed as λ ∝ G^2 |M|^2 |ψ(0)|^2 f(Q), where G is the weak coupling constant, M the nuclear matrix element, and f(Q) the phase-space factor involving the Q-value (energy available for the ). Branching ratios favor inner shells (e.g., K-capture dominates over L- or M-), with ratios like L/K ≈ 0.1–0.2 for allowed transitions, influenced by atomic screening and relativistic effects but independent of nuclear structure for pure orbital probabilities.

Comparison to Other Decay Modes

Relation to Beta Minus and Plus Decay

Electron capture, beta minus decay, and beta plus decay collectively form the primary modes of beta decay, all driven by the weak nuclear force to adjust the neutron-to-proton ratio in unstable nuclei. In beta minus decay, a neutron transforms into a proton, emitting an electron and an electron antineutrino: n \to p + e^- + \bar{\nu}_e. Beta plus decay involves the inverse process at the quark level, where a proton converts to a neutron, releasing a positron and an electron neutrino: p \to n + e^+ + \nu_e. Electron capture proceeds similarly to beta plus decay but incorporates an orbital electron, such that a proton and electron combine to form a neutron and an electron neutrino: p + e^- \to n + \nu_e. These processes are unified theoretically as charged-current interactions mediated by the exchange of a W boson, which facilitates the flavor change of a down quark to an up quark (or vice versa) while conserving charge and lepton number. A key shared feature among these decay modes is the symmetry observed in mirror nuclei, where pairs or triplets of nuclei with swapped proton and neutron numbers exhibit analogous transitions with comparable strengths, particularly for Fermi () components. This symmetry leads to similar half-lives for corresponding transitions across the modes, reflecting the invariance of the strong and electromagnetic interactions under weak perturbations. For instance, in isobaric triplets, the comparative [ft](/page/FT) values—where f is the phase-space factor and t the partial half-life—reveal consistent patterns, with experimental log [ft](/page/FT) values for electron capture and beta plus decays often aligning closely with those of beta minus decays in the same multiplet, typically ranging from 4 to 6 for allowed transitions. These [ft](/page/FT) comparisons help calibrate the axial-vector coupling constant g_A and probe parameters. Unlike beta minus and beta plus decays, which produce a charged and result in a continuous energy spectrum for both the and due to , electron capture emits no and thus yields a discrete, monoenergetic with energy determined by the Q-value minus the of the captured . This two-body nature of electron capture simplifies the spectrum compared to the observed in the other modes. Q-values across these decays differ modestly due to atomic binding effects but maintain overall energetic similarity for isobaric analogs.

Factors Favoring Electron Capture

Electron capture becomes the favored or exclusive decay mode for proton-rich nuclei when the available , known as the Q-value, satisfies 0 < Q < 1.022 MeV. In this energy window, positron emission (β⁺ ) is energetically forbidden because it requires at least 1.022 MeV to account for the rest masses of the emitted positron and the accompanying neutrino, leaving electron capture as the only viable weak interaction process to convert a proton into a neutron. This condition is particularly relevant for neutron-deficient isotopes where the mass difference between parent and daughter nuclei is insufficient for β⁺ but adequate for electron capture, which does not produce additional particles beyond the neutrino. The probability of electron capture increases with the atomic number Z of the parent nucleus due to the higher density of s-orbital electrons near the nucleus. For higher-Z elements, the K-shell electron wavefunctions have greater penetration into the nuclear region, resulting in an electron density at the nucleus that scales approximately as Z³ for hydrogen-like atoms, thereby enhancing the overlap and capture rate compared to lower-Z counterparts. This Z-dependence makes electron capture the dominant decay mode for heavy nuclei (Z > 30), where the increased electron density compensates for the generally lower Q-values in such systems. Ionization states of the significantly influence electron capture rates by altering the availability of inner-shell electrons. In fully or highly ionized atoms, the removal of - and L-shell electrons reduces the at the , suppressing the decay rate; for instance, in highly ionized states, the rate can drop by a factor of up to 10 due to the scarcity of bound electrons for capture. Conversely, or lowly ionized atoms maintain higher capture probabilities, as the full complement of orbital electrons ensures sufficient near the . This effect is pronounced in environments like stellar plasmas, where partial can modulate rates, but complete stripping effectively halts bound-state electron capture. Subtle variations in chemical binding can also affect electron capture half-lives through changes in at the . For example, in beryllium-7 (⁷Be), which decays solely by K-shell electron capture, the half-life increases by 0.9 ± 0.2% when embedded in metallic compared to insulating environments, reflecting minor perturbations in the s-electron wavefunction due to chemical coordination. Such influences are typically small (on the order of 0.1–1%) and arise from the altered electronic structure in different compounds, but they highlight the sensitivity of electron capture to atomic-scale surroundings. In high-density environments, such as the interiors of , electron capture rates are enhanced by the elevated , which increases the for capture processes. The of degenerate electrons rises with density, boosting the capture probability on both bound and continuum electrons, often by orders of magnitude compared to terrestrial conditions. This enhancement is critical in astrophysical settings like core-collapse supernovae, where densities exceeding 10⁹ g/cm³ drive rapid electron captures that influence and collapse dynamics.

Examples of Electron Capture

Common Terrestrial Isotopes

(⁴⁰K) undergoes electron capture with a branching ratio of approximately 89.3%, decaying to argon-40 (⁴⁰Ar) with a of 1.25 billion years for this mode. This process is the basis for potassium-argon dating in , allowing age determination of rocks and archaeological artifacts up to several billion years old. Beryllium-7 (⁷Be) decays exclusively via electron capture to lithium-7 (⁷Li), with a of 53.22 days and a Q-value of 861.8 keV. Produced primarily by in the upper atmosphere, ⁷Be serves as a tracer for atmospheric mixing and detection experiments, such as those using the reaction ⁷Be(p,γ)⁸B in the Sun. The decay is pure electron capture even in fully ionized states, making it insensitive to .

Astrophysical and Rare Cases

In astrophysical environments, electron capture plays a critical role in the evolution of massive , particularly those in the mass range of 8 to 10 solar masses. These stars develop oxygen-neon-magnesium (O-Ne-Mg) cores after helium burning, forming degenerate white dwarfs if they lose their envelopes through stellar winds. At high densities approaching 10^{10} g/cm³ near the , the degenerate electron gas becomes relativistic, enhancing electron capture rates on and magnesium nuclei. This process reduces electron , leading to core collapse and triggering electron-capture supernovae that produce neutron stars. The , remnant of the supernova , is a candidate for such an event from a progenitor of approximately 9 solar masses. Aluminum-26, produced in explosive nucleosynthesis during core-collapse supernovae and stars, has a of 717,000 years and a total Q-value of 4.004 MeV. The primary decay mode is (about 82%) to the 1.809 MeV of magnesium-26, with electron capture accounting for about 18% to excited states including that level, followed by gamma deexcitation. This decay is a major source of the 1.809 MeV gamma-ray line observed in the , enabling mapping of sites across the via . Rare isotopes like nickel-59, with a of 76,000 years decaying via electron capture to cobalt-59 (Q-value 1.073 MeV), serve as signatures of the rapid neutron-capture (r-process) in mergers. These mergers eject neutron-rich material, synthesizing nickel-59 among other heavy elements beyond iron; its long lifetime allows detection in merger remnants and kilonovae, contributing to the observed abundances of r-process residuals in the . Highly forbidden electron capture occurs in holmium-163, which decays to dysprosium-163 with a total of 4,570 years and a low Q-value of approximately 2.8 keV, restricting captures to outer shells. The ground-state transition (7/2⁻ to 5/2⁺) violates selection rules due to change and constraints, making it first-forbidden; partial half-lives for M-shell captures reach about 40,000 years. This decay is studied for mass measurements via microcalorimetry, as the low energy amplifies neutrino effects on the spectrum. In the cosmological context of (BBN), capture and related weak interactions contribute to the relic flux by influencing the neutron-to-proton ratio freeze-out at temperatures around 1 MeV. Processes such as proton + + ν_e help maintain weak equilibrium before decoupling, with the emitted neutrinos adding to the alongside those from pair annihilations. This flux affects BBN light element yields, such as and , through its role in expansion rate and baryon-to-photon ratio constraints.

Applications

Nuclear Medicine and Imaging

Electron capture (EC) isotopes play a pivotal role in nuclear medicine as radiotracers for diagnostic imaging, leveraging their emission of characteristic X-rays and gamma rays for single-photon emission computed tomography (SPECT). Chromium-51 (^{51}Cr), with a half-life of 27.7 days, is commonly used to label red blood cells, enabling measurements of blood volume, red cell survival, and gastrointestinal protein loss or bleeding. Gallium-67 (^{67}Ga), with a half-life of 78 hours, accumulates in inflammatory lesions and tumors due to its affinity for iron-binding proteins like transferrin, facilitating SPECT imaging of infections, lymphomas, and other malignancies. These EC tracers offer advantages over positron emitters in SPECT applications, as they avoid the high-energy 511 keV annihilation radiation produced by positron-electron interactions, reducing the need for specialized coincidence detection and allowing use of standard gamma cameras with lower-energy emissions (typically 70–400 keV) for more accessible and cost-effective imaging. In hybrid PET/SPECT imaging systems, EC nuclides enhance multimodal diagnostics by providing complementary functional data; for instance, the gamma emissions accompanying EC decay (from atomic shell rearrangements or daughter de-excitation) can be co-registered with signals for improved localization in and . (^{64}Cu), produced via irradiation of enriched ^{64}Ni targets (e.g., ^{64}Ni(p,n)^{64}Cu reaction at 11–15 MeV proton energy, yielding up to 100 MBq/μA·h) or reactor methods like ^{63}Cu(n,γ)^{64}Cu, exemplifies this versatility with its partial EC branch (43% of decays, 12.7 hours) alongside β⁺ emission, enabling theranostic applications in imaging of copper metabolism disorders and tumors. For therapeutic applications, the low-energy X-rays (e.g., 5–6 keV from K-shell vacancies) and Auger electrons emitted during EC provide high linear energy transfer (LET) over nanometer-scale ranges, ideal for targeted radionuclide therapy with reduced collateral damage to healthy tissues. Dosimetry models, such as the Medical Internal Radiation Dose (MIRD) formalism, quantify absorbed doses at cellular levels, emphasizing nuclear localization for efficacy; research on ^{55}Fe analogs (emitting ~5 Auger electrons per decay) demonstrates potent DNA damage in preclinical models when conjugated to biomolecules. Post-2010 advances in Auger electron therapy have focused on EC emitters like ^{111}In and ^{161}Tb for cancer treatment, with clinical trials showing low toxicity—e.g., phase I/II VIOLET study of ^{161}Tb-PSMA-I&T (NCT05521412) in metastatic castration-resistant prostate cancer reported a 70% PSA50 response rate in patients at doses up to 7.4 GBq (data cutoff February 2024, presented at ASCO 2025), and the ongoing Auger Molecular Therapy (AMT; NCT04807257) trial for cutaneous lesions.

Astrophysics and Nucleosynthesis

In the context of , electron capture (EC) plays a pivotal role in the core collapse phase of massive stars leading to Type II supernovae. During the collapse of the iron core in stars with initial masses exceeding about 8 solar masses, the increasing density raises the electron , enabling EC reactions on free protons and bound nuclei, which convert protons to neutrons and release electron s. These s carry away a significant fraction of the , approximately 99% of the total, and their diffusion through the stellar envelope powers the explosion via the delayed neutrino mechanism. Observations of neutrino bursts from in the , detected by Kamiokande-II and other experiments, provided direct evidence for this process, with around 20 antineutrinos observed over about 10 seconds, consistent with EC-dominated neutronization during the initial collapse phase. Electron capture also contributes to processes in astrophysical environments, particularly at the endpoints of proton-rich reaction flows. In the p-process, which synthesizes the 35 stable neutron-deficient p-nuclei heavier than iron through sequences of proton captures, photodisintegrations, and decays in explosive astrophysical sites like Type Ia supernovae or core-collapse supernovae, EC reactions on proton-rich waiting-point nuclei can bypass barriers and complete the production of certain p-s by facilitating branchings in the reaction network. Additionally, the radioactive ^{26}Al, produced primarily in core-collapse supernovae via proton or captures on lighter elements, decays predominantly through EC (with a of about 0.717 million years) to ^{26}Mg, leaving an detectable in found in meteorites. These grains, such as and types, preserve initial ^{26}Al/^{27}Al ratios that trace supernova ejecta mixing and serve as probes of nucleosynthetic heterogeneity in the early solar system. In white dwarfs, electron capture regulates cooling by enabling neutrino emission in their dense interiors. For carbon-oxygen white dwarfs, on ^{16}O and other isotopes at temperatures above 10^8 K and densities around 10^9 g/cm³ initiates neutrino pair production through the Urca , where is followed by , releasing neutrino-antineutrino pairs that escape the and dominate the at early cooling stages. This is particularly significant in low-metallicity white dwarfs or those accreting material, where it can shorten cooling timescales by factors of 2–3 compared to photon-dominated phases, influencing the luminosity function of white dwarfs in galactic populations. Recent hydrodynamic simulations in the 2020s have highlighted electron capture's influence on rapid neutron-capture (r-process) nucleosynthesis in binary mergers. In the post-merger remnant, high densities (exceeding 10^{12} g/cm³) promote EC on seed nuclei in the ejected material, reducing the electron fraction (Y_e) and enhancing neutron richness, which boosts r-process yields of heavy elements like and by up to 20–50% in certain outflow trajectories. Integrations of gravitational-wave data from // detections between 2023 and 2025, including events like GW230529, have constrained merger properties, allowing models to refine EC rates and predict light curves that match observed electromagnetic counterparts, thereby validating EC's role in setting the initial conditions for r-process abundance patterns. Although minor compared to other reactions, electron capture contributes to Big Bang nucleosynthesis (BBN) by affecting light element abundances in the early . Specifically, ^{7}Be, produced via the ^{3}He(^{4}He, \gamma)^{7}Be reaction during BBN at temperatures around 0.1 MeV, primarily decays through EC to ^{7}Li once the cools sufficiently for electron availability (at redshifts z \approx 10^5), converting nearly all primordial ^{7}Be into observable ^{7}Li and setting the baseline lithium-7 yield to about 10^{-10} by number relative to . This EC decay, with a of 53 days in neutral atoms, occurs post-BBN but within the recombination , fine-tuning the final ^7Li/H ratio without significantly altering or abundances.

Historical Development

Theoretical Foundations

The theoretical foundations of electron capture emerged in the early 1930s as part of the developing understanding of weak interactions governing nuclear beta processes. In 1934, Gian Carlo Wick proposed the concept of inverse beta decay, describing the process where a proton captures an atomic electron to form a neutron and emit a neutrino (p + e⁻ → n + ν_e), extending the framework of beta decay to include this capture mode as a natural counterpart to electron emission. This idea built on the neutrino hypothesis introduced by Pauli in 1930 to resolve energy conservation issues in beta decay spectra, providing a mechanism for neutrino involvement without positron emission. Wick's formulation used second quantization techniques to predict the kinematics and rates for such captures, laying groundwork for later refinements in weak interaction theory. Concurrently, Enrico Fermi's seminal 1934 theory of formalized the as a contact four-fermion process, treating the as a point source emitting an and antineutrino (or vice versa for inverse processes). Fermi explicitly extended this model to electron capture, predicting it as the inverse of neutron where an orbital is absorbed, transforming a proton to a with emission, and emphasizing the role of electron wavefunction overlap at the . This theory not only unified beta minus and capture modes under a single but also introduced selection rules based on and conservation, assuming the weak force respected these symmetries at the time. Hideki Yukawa's 1935 meson exchange theory for nuclear forces further influenced these developments by introducing the paradigm of virtual particle mediation in nuclear interactions, which paralleled the neutrino's role in weak processes and helped conceptualize neutrino emission as an exchange-mediated emission in beta variants like capture. Post-World War II advancements in the 1950s integrated more rigorously into models. These efforts culminated in the formulation of the V-A (vector-axial vector) structure of the weak current, proposed by and in 1958, which incorporated maximal parity violation observed in weak decays. The V-A theory explained electron capture's parity selection rules by assigning left-handed to participating fermions, forbidding certain mirror-image transitions and aligning capture rates with experimental asymmetries in beta spectra, thus solidifying its place within the universal framework. Selection rules derived from V-A, such as ΔJ = 0 or 1 (no 0→0) for allowed captures, follow directly from the theory's current structure.

Key Experimental Observations

The first experimental observation of electron capture occurred in 1937 when Luis W. Alvarez reported evidence for the process in the decay of vanadium-48 (^{48}V) using a to track charged particles from neutron-irradiated materials. Alvarez noted the absence of expected particles and the emission of characteristic X-rays from atomic shell rearrangements, which aligned with theoretical predictions and supported the hypothesis proposed by to conserve energy, momentum, and in . This detection, detailed in subsequent publications, marked the initial empirical confirmation of electron capture as a distinct nuclear decay mode. In the 1950s, precision measurements of beryllium-7 (^{7}Be) decay provided key insights into electron capture branching ratios, confirming that the isotope decays exclusively (100%) via this mode with no observable beta-minus or beta-plus branches. Experiments involving nuclear recoil spectra from neutrino emission in thin deposits of ^{7}Be on substrates like demonstrated the monochromatic nature of the recoiling , consistent with a two-body decay (nucleus + ) following K-shell capture. These studies, conducted with scintillation counters and proportional detectors, refined the to approximately 53 days and established ^{7}Be as a benchmark for pure electron capture, influencing early detection efforts. The saw advancements in the and characterization of medical isotopes like gallium-67 (^{67}Ga), produced via proton bombardment of enriched zinc-68 targets, with verifications confirming its 78.3-hour decay primarily by electron capture to stable zinc-67. Initial productions at facilities like yielded samples with high purity, and measurements identified key emission lines at 93 keV, 185 keV, and 300 keV from atomic relaxation and nuclear deexcitation, enabling its use in applications. These verifications, including precise branching ratios for L- and M-shell captures, solidified ^{67}Ga's role in verifying electron capture mechanisms under controlled conditions. In the to , the Borexino detector at the achieved groundbreaking measurements of solar ^{7}Be neutrinos originating from electron capture in the Sun's proton-proton chain, with a analysis reporting a flux of (4.93 \pm 0.35) \times 10^9 cm^{-2} s^{-1} in agreement with standard solar models. The experiment's ultralow-background liquid detected the 0.862 MeV monoenergetic neutrinos via on electrons, providing the first real-time spectral confirmation of electron capture rates in stellar interiors and constraining solar core metallicity. Complementing this, Penning trap mass spectrometry from 2015 to 2024 delivered precise Q-value determinations for electron capture in astrophysically relevant isotopes like aluminum-26 (^{26}Al), with measurements reducing uncertainties to below 0.1 keV for the ground-state transition to magnesium-26, aiding models for gamma-ray observations from the . Confirmations of forbidden electron capture transitions emerged from 1990s to 2020s spectroscopic studies of dysprosium-163 (^{163}Dy) deexcitation following the electron capture of holmium-163, particularly in neutrino mass experiments like ECHo and NuMECs. Microcalorimetric and bolometric detectors resolved the atomic relaxation spectrum, revealing shake-off and shake-up effects in forbidden M1 and higher-order transitions, with the upper endpoint distortion below the 2.5 keV Q-value yielding mass limits under 2 eV/c^2. These observations, combining high-resolution and , validated theoretical models for hindered capture probabilities in deformed nuclei and low-energy regimes.