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Unpaired electron

An unpaired electron is an that occupies an or singly, without a counterpart of in the same orbital, distinguishing it from paired electrons that fill orbitals in accordance with the . These electrons arise in atoms, ions, and molecules when the total number of electrons is odd or when orbital filling follows Hund's rule, prioritizing maximum spin multiplicity by placing electrons in separate orbitals with parallel spins before pairing. Unpaired electrons fundamentally influence the physical and chemical properties of matter, most notably by imparting paramagnetism to substances containing them, as the inherent magnetic moments from unpaired spins align with applied magnetic fields, unlike diamagnetic materials with all paired electrons. This property is particularly evident in transition metal complexes, where the number of unpaired d-electrons determines magnetic susceptibility and aids in structural characterization via techniques like electron paramagnetic resonance (EPR) spectroscopy. In chemical reactivity, unpaired electrons drive the behavior of free radicals, species with at least one unpaired electron that exhibit high reactivity due to their tendency to abstract atoms or electrons from other molecules to achieve stability. Such radicals are pivotal in , reactions, and , as well as in biological systems where they participate in signaling and oxidative damage; notable examples include the anion (O₂⁻), formed by one-electron reduction of oxygen, and (NO), a diatomic radical involved in and . Delocalized unpaired electrons, as in conjugated systems or metal clusters, further enhance stability and conductivity in materials like .

Fundamentals

Definition and Basic Concept

An unpaired electron is defined as an electron that occupies an orbital without a counterpart possessing opposite , thereby contributing to a net for the atom or in which it resides./Coordination_Chemistry/Structure_and_Nomenclature_of_Coordination_Compounds/Electron_Counting/Spin_Only_Magnetic_Moment) In , electrons adhere to the , which states that no two electrons in the same atom can have identical sets of four quantum numbers, including the m_s with values of +\frac{1}{2} or -\frac{1}{2}. Consequently, paired electrons sharing an orbital must have opposite spins, resulting in zero net for that pair, whereas an unpaired electron imparts a nonzero contribution to the total S > 0. This concept emerged in the 1920s amid the foundational developments in . Wolfgang Pauli formulated the exclusion principle in 1925 to explain atomic spectra anomalies, positing that electrons must occupy distinct quantum states. Shortly thereafter, and proposed the intrinsic of the in 1925 to account for in spectral lines, integrating it with Pauli's ideas. further advanced the framework in 1928 by deriving a relativistic quantum equation for the , which naturally incorporated as an intrinsic property, solidifying its role in . In high-spin configurations, where unpaired electrons align their parallel to minimize energy, the total is given by S = \frac{n}{2}, with n representing the number of unpaired electrons./20%3A_d-Block_Metal_Chemistry_-_Coordination_Complexes/20.10%3A_Magnetic_Properties/20.10A%3A_Magnetic_Susceptibility_and_the_Spin-only_Formula) For instance, the ground-state has an electron configuration of $1s^1, featuring a single unpaired electron and thus S = \frac{1}{2}. In contrast, the atom's configuration is $1s^2, with both electrons paired in the same orbital to opposite , yielding S = 0./Fundamentals/Atomic_Structure_and_Bonding/Atomic_Structure/1.3%3A_Atomic_Structure%3A_Electron_Configurations)

Electron Spin and Orbital Pairing

The electron possesses an intrinsic form of angular momentum known as spin, which is independent of its orbital motion around the nucleus. This spin is quantized and characterized by the spin quantum number s = \frac{1}{2}, resulting in a magnitude of spin angular momentum given by \sqrt{s(s+1)} \hbar = \frac{\sqrt{3}}{2} \hbar, where \hbar is the reduced Planck's constant. The projection of this angular momentum along the z-axis is described by the magnetic spin quantum number m_s = \pm \frac{1}{2}, corresponding to two possible spin states often denoted as spin-up (m_s = +\frac{1}{2}) and spin-down (m_s = -\frac{1}{2}). These spin states are visually represented in orbital diagrams using arrows: an upward arrow for spin-up electrons and a downward arrow for spin-down electrons. For instance, the s subshell, consisting of a single orbital, is depicted as one box that can accommodate up to two electrons with opposite spins. The p subshell features three orbitals, shown as three adjacent boxes, each capable of holding two electrons, while the d subshell has five such boxes. Electrons are placed into these boxes following specific rules, with arrows indicating their spin orientation to illustrate pairing or unpaired states. A subtle interaction known as spin-orbit coupling occurs between the electron's spin magnetic moment and the magnetic field generated by its orbital motion in the nuclear , leading to small energy splittings in atomic spectra; this relativistic effect becomes more pronounced in heavier atoms but is not derived from first principles here. In the process of filling atomic orbitals, the dictates that electrons occupy the lowest-energy available orbitals first, building up the electronic configuration from the outward. However, when an orbital is partially occupied, the choice between an incoming with an existing one or placing it in a higher-energy orbital depends on a balance between the orbital energy difference (\Delta E) and the pairing energy (P), which accounts for the increased electron-electron repulsion when two electrons share the same spatial orbital. If \Delta E < P, the electron prefers to remain unpaired in the higher orbital; otherwise, occurs to minimize total energy. Regarding energy implications, configurations with paired electrons generally lower the overall energy by filling lower-lying orbitals, but this pairing incurs a Coulombic repulsion cost without the benefit of exchange interaction between the oppositely spinning electrons in the same orbital. In contrast, for degenerate orbitals (sets of orbitals with equal energy, such as the three p or five d orbitals), unpaired electrons with parallel spins experience a favorable exchange stabilization: the quantum mechanical exchange energy arises from the antisymmetry of the wavefunction, effectively reducing electron-electron repulsion and lowering the energy of the configuration. This exchange effect can make high-spin, unpaired states the ground state when multiple degenerate orbitals are available.

Occurrence in Atoms

Atomic Electron Configurations

In atomic electron configurations, unpaired electrons occur when orbitals within a subshell are not fully paired according to the Pauli exclusion principle, particularly in partially filled p, d, or f subshells. For main group elements like carbon, the ground state configuration is $1s^2 2s^2 2p^2, where the two electrons in the 2p subshell occupy separate orbitals with parallel spins, resulting in two unpaired electrons./06%3A_The_Structure_of_Atoms/6.08%3A_Electron_Configurations/6.8.04%3A_Electron_Configurations_-_Hunds_Rule) In transition metals, such as iron, the ground state configuration is [Ar] 4s^2 3d^6, with the six 3d electrons distributing to yield four unpaired electrons in the high-spin arrangement. Exceptions to the aufbau principle arise due to the enhanced stability of half-filled or fully filled subshells, leading to configurations that promote more unpaired electrons. For chromium, the expected [Ar] 4s^2 3d^4 configuration is instead [Ar] 4s^1 3d^5, providing five unpaired electrons in the half-filled 3d subshell. Similarly, copper adopts [Ar] 4s^1 3d^{10} rather than [Ar] 4s^2 3d^9, resulting in one unpaired electron from the 4s orbital, as the full 3d subshell offers greater stability. The presence of unpaired electrons is quantified in term symbols, which describe the angular momentum states of atoms. The multiplicity, given by $2S + 1 where S is the total spin quantum number, directly indicates the number of unpaired electrons; for instance, a multiplicity of 3 corresponds to S = 1 and two unpaired electrons. For the ground state of carbon ($1s^2 2s^2 2p^2), the term symbol is ^3P, reflecting the triplet state from the two unpaired 2p electrons with parallel spins. Ionization or excitation can alter the number of unpaired electrons by removing or adding electrons to specific subshells. In iron, the neutral atom ([Ar] 4s^2 3d^6) has four unpaired electrons, but the Fe^{2+} ion ([Ar] 3d^6) retains four unpaired d electrons after losing the 4s electrons, while Fe^{3+} ([Ar] 3d^5) gains five unpaired electrons in the half-filled 3d subshell. Excited states may pair electrons or promote them to higher orbitals, potentially reducing or increasing unpaired counts depending on the energy input.

Role of Hund's Rule

Hund's rule, proposed by in 1925, states that for a given electron configuration in an atom, the ground state term is the one with the highest spin multiplicity, meaning electrons occupy degenerate orbitals singly with parallel spins before pairing up./Electronic_Structure_of_Atoms_and_Molecules/Electronic_Configurations/Hund%27s_Rules) This first part of the rule maximizes the total spin quantum number S, leading to the maximum number of unpaired electrons. The second part specifies that, among states with the same spin multiplicity, the one with the maximum total orbital angular momentum L has the lowest energy. The physical rationale for Hund's rule stems from the quantum mechanical interaction, which stabilizes configurations with parallel electron spins by reducing electron-electron repulsion. When two electrons have parallel spins, the Pauli exclusion principle prevents them from occupying the same spatial region, effectively lowering the Coulomb repulsion compared to antiparallel spins. This stabilization arises from the exchange energy term, which contributes -K for each pair of parallel spins, where K > 0 is the positive exchange integral representing the overlap of their wavefunctions. This principle is illustrated in atomic configurations such as , with a 2p³ subshell where the three electrons singly occupy the p_x, p_y, and p_z orbitals with parallel s, yielding three unpaired electrons and a multiplicity of 4 (⁴S )./Electronic_Structure_of_Atoms_and_Molecules/Electronic_Configurations/Hund%27s_Rules) In , the 3d⁵ configuration features five unpaired electrons in the d orbitals with parallel s, resulting in a high- with multiplicity 6 (⁶S)./Electronic_Structure_of_Atoms_and_Molecules/Electronic_Configurations/Hund%27s_Rules) However, the rule can be violated in excited states, where energy levels are closer and other interactions dominate, or in heavy atoms due to strong spin-orbit coupling, which mixes states and inverts the expected ordering.

Occurrence in Molecules

Free Radicals and Odd-Electron Species

Free radicals, also known as odd-electron species, are molecules or ions that possess an odd number of electrons, resulting in at least one unpaired electron in their valence shell. This unpaired electron imparts distinctive electronic properties, distinguishing free radicals from typical even-electron molecules. A classic example is the methyl radical, •CH₃, where the carbon atom has an unpaired electron in a p orbital, leading to a planar sp²-hybridized structure. Free radicals are classified based on the type of orbital containing the unpaired electron, primarily into σ-radicals and π-radicals. In σ-radicals, the unpaired electron occupies a σ orbital, as seen in alkyl radicals like the methyl radical, where the electron is localized on a carbon atom involved in σ-bonding. π-Radicals feature the unpaired electron in a π system, allowing for delocalization; the allyl radical, CH₂=CH-CH₂•, exemplifies this, with the unpaired electron distributed across the conjugated π framework for enhanced stability. Some free radicals exhibit persistence due to steric hindrance or stabilization, such as (2,2,6,6-tetramethylpiperidin-1-yl)oxyl, a nitroxide radical stable under ambient conditions for extended periods. These species form through processes that generate an odd number of , notably homolytic cleavage of a , where each fragment retains one electron from the shared pair. For instance, the of gas yields two chlorine atom radicals: Cl₂ → 2•Cl. In , odd-electron ions arise as molecular ions (M⁺•) from , representing radical cations with an unpaired electron. Lewis structures for free radicals depict the unpaired electron as a single dot adjacent to the atomic symbol, illustrating the open-shell configuration. In delocalized systems, structures show the unpaired electron shifting positions to reflect its distribution; the benzyl radical, C₆H₅CH₂•, demonstrates this with multiple forms where the electron delocalizes into the aromatic ring, stabilizing the species.

Biradicals and Non-Kekulé Structures

Biradicals, also referred to as s, are molecular species featuring two unpaired electrons that occupy two nearly degenerate molecular orbitals, resulting in distinct electronic configurations. These unpaired electrons are typically weakly interacting, which imparts significant diradical character to the and influences its reactivity. A prominent example is the oxygen (O₂), whose is a triplet with two unpaired electrons in antibonding π* orbitals, making it paramagnetic and kinetically persistent despite its diradical nature. Non-Kekulé structures form an important class of biradicals, characterized by bonding patterns that defy conventional Kekulé representations of alternating single and double bonds. Instead, these molecules exhibit unconventional electron delocalization, often involving non-bonding orbitals. Trimethylenemethane (TMM), for instance, is a prototypical non-Kekulé biradical with two degenerate non-bonding orbitals, leading to a highly symmetric yet reactive electronic structure. This configuration arises from the orthogonal π systems in TMM, preventing standard aromatic or Kekulé stabilization. In biradicals, the two unpaired electrons can couple to form either a (antiparallel spins) or a (parallel spins), with the energy ordering governed by an extension of Hund's rule to molecular systems. This rule favors the as the in cases of degenerate or near-degenerate orbitals, as parallel spins minimize Pauli repulsion and lower the overall energy. Methylene (CH₂) illustrates this principle, possessing a denoted as ³B₁, where the two non-bonding electrons occupy orthogonal p-orbitals with parallel spins. The energy difference between these states, known as the singlet-triplet gap (ΔE_{ST}), is determined by twice the exchange integral K: \Delta E_{ST} = 2K This gap quantifies the stabilization of the triplet relative to the singlet due to the positive exchange energy K. In trimethylenemethane, the triplet state is similarly the ground state, with ΔE_{ST} ≈ 16 kcal/mol, underscoring the role of weak orbital overlap in maintaining the biradical's triplet preference.

Physical and Chemical Properties

Magnetic Properties

Unpaired electrons impart a permanent magnetic moment to atoms or molecules primarily through their spin angular momentum, resulting in paramagnetism when an external magnetic field is applied. In the absence of a field, these moments are randomly oriented due to thermal agitation, leading to zero net magnetization. However, the field aligns the moments partially, producing a positive magnetic susceptibility that is temperature-dependent. This contrasts with diamagnetism in systems with fully paired electrons, where no net moment exists, and the applied field induces temporary currents that generate an opposing magnetic field, yielding a weak negative susceptibility. For instance, molecular oxygen (O₂) exhibits paramagnetism due to two unpaired electrons in its ground state, while nitrogen (N₂), with all electrons paired, is diamagnetic. The χ of paramagnetic materials follows , expressed as χ = C/T, where T is the temperature and C is the . For spin-only contributions from unpaired electrons, C = N μ₀ μ_B² g² S(S+1)/(3k), with N the of magnetic centers, μ₀ the permeability of free space, μ_B the , g the (approximately 2 for free electrons), S the total , and k Boltzmann's . The effective μ_eff quantifies this behavior and is given by μ_eff = g √[S(S+1)] μ_B. For example, in Gd³⁺ ions with seven unpaired 4f electrons (S = 7/2 and g ≈ 2), μ_eff ≈ 7.94 μ_B, reflecting the high moment from maximal spin alignment per Hund's rule. In solid-state systems, interactions between magnetic moments modify the simple Curie behavior, leading to Curie-Weiss law: χ = C/(T – θ), where θ is the Weiss constant that accounts for ferromagnetic (positive θ) or antiferromagnetic (negative θ) coupling. This deviation arises from interactions between neighboring unpaired electrons, influencing the at lower temperatures without altering the intrinsic paramagnetic nature.

Reactivity and Stability

Unpaired electrons confer high reactivity to species containing them, primarily because the electron seeks to pair through reactions such as to unsaturated bonds or of atoms from other molecules. This reactivity often results in rate constants approaching the diffusion-controlled limit, typically on the order of $10^{9} to $10^{10} L mol^{-1} s^{-1}, as seen in the (•OH), which reacts rapidly with a wide range of and inorganic substrates in aqueous environments. Such diffusion-controlled reflect the minimal barriers for these processes, driven by the energetic favorability of forming paired-electron products. The stability of radicals bearing unpaired electrons is influenced by several factors that reduce their tendency to dimerize or react further, including spin delocalization through or conjugation, which distributes the unpaired electron over multiple atoms and lowers the overall of the . For instance, the phenoxyl radical achieves enhanced stability via delocalization of the unpaired electron across the aromatic ring, as evidenced by electron studies showing significant spin density on and positions. Similarly, steric hindrance plays a crucial role, as in the case of the radical (2,2,6,6-tetramethylpiperidin-1-yloxyl), where bulky methyl groups shield the nitroxide center, preventing bimolecular reactions and allowing persistence in solution for extended periods. Conjugation further contributes by stabilizing adjacent bonds, often reflected in lower bond dissociation energies (BDEs) for radical formation; for example, the BDE for the allylic C-H bond is approximately 88 kcal/mol, compared to 105 kcal/mol for the methyl C-H bond, indicating greater ease of forming the resonance-stabilized allyl . These stability variations manifest in disparate half-lives for different radicals under typical conditions. The methyl radical, lacking stabilization, exhibits a short lifetime of about $10^{-6} s in due to rapid dimerization or abstraction reactions. In contrast, the radical (2,2-diphenyl-1-picrylhydrazyl) is persistent, with half-lives extending to days or even weeks in aerated , owing to extensive delocalization and steric protection that inhibit reactivity. Radicals with unpaired electrons frequently participate in chain reactions, where propagation steps—such as hydrogen abstraction or to monomers—sustain the process in systems like free-radical or , enabling efficient transformation of large quantities of substrate through repeated radical generation and consumption cycles.

Detection and Measurement

Electron Paramagnetic Resonance

Electron paramagnetic resonance (EPR), also known as electron spin resonance (ESR), is a spectroscopic technique that detects and characterizes unpaired electrons by measuring the absorption of microwave radiation by paramagnetic species in a static magnetic field. The method exploits the magnetic moment of the unpaired electron, which aligns with or against the applied field, leading to two energy levels split by the Zeeman interaction. This splitting, ΔE = g μ_B B, where g is the electron g-factor (approximately 2.0023 for a free electron), μ_B is the Bohr magneton, and B is the magnetic field strength, allows transitions between levels when the microwave frequency matches the energy difference. A key feature of EPR spectra is the hyperfine structure arising from the interaction between the unpaired electron and nearby spins, which further splits the resonance lines. For nuclei with I, the electron signal splits into 2I + 1 equally spaced lines of equal intensity; for example, the radical (•H), with a nuclear I = 1/2 for ¹H, exhibits a characteristic 1:1 intensity due to this hyperfine coupling, with a splitting constant of approximately 50.7 mT. In solid samples, the hyperfine interaction often shows , reflecting the orientation dependence of the electron-nuclear coupling tensor, which provides insights into the local molecular environment. EPR instrumentation typically employs either continuous wave (CW) mode, where a steady field modulates the sample in a resonant , or pulsed mode, which uses short pulses to enable time-domain experiments like electron spin echo for studying relaxation dynamics. CW- is simpler and widely used for routine spectra, while pulsed EPR offers higher time for transient species. The technique's allows detection of as few as ~10¹¹ unpaired under standard X-band conditions (9-10 GHz), making it suitable for dilute samples. In applications to unpaired electrons, EPR distinguishes radical types through the g-factor: organic π-radicals typically show g ≈ 2.002, close to the free-electron value, whereas complexes with d-electrons exhibit g > 2 due to spin-orbit coupling, enabling identification of species like semiquinones versus metal-centered radicals.

Other Spectroscopic Methods

Ultraviolet-visible (UV-Vis) spectroscopy provides indirect evidence for unpaired electrons in complexes through broad bands arising from d-d . These occur when ligands split the degenerate d-orbitals into sets of different energies, such as t₂g and e_g in octahedral fields, allowing electrons to absorb visible light and promote between these levels only if unpaired d-electrons are present to enable the spin-allowed processes. For instance, the [Ti(H₂O)₆]³⁺ complex, featuring a d¹ with one unpaired electron, exhibits a characteristic broad maximum at approximately 500 nm, corresponding to the ²T₂g → ²E_g and confirming the paramagnetic nature of the species. Magnetic circular dichroism (MCD) enhances the detection of unpaired electrons in paramagnetic species by measuring the of left- and right-circularly polarized light under an applied . This arises from Zeeman splitting of ground and excited states, with C-terms dominating at low temperatures due to spin-orbit coupling between states involving unpaired electrons, thereby amplifying weak signals from d-d transitions that are often obscured in conventional spectra. In paramagnetic metal centers, such as those in copper proteins like , MCD reveals intense signals for metal-centered transitions, aiding in the assignment of electronic states linked to unpaired d-electrons. Mössbauer spectroscopy, using the ⁵⁷Fe isotope, probes unpaired electrons by distinguishing high-spin (HS) and low-spin (LS) states through differences in isomer shift (δ) and quadrupole splitting (ΔE_Q). In HS Fe(II) complexes, higher δ values (typically 0.9–1.3 mm/s) and larger ΔE_Q (2.0–2.7 mm/s) reflect greater s-electron density and asymmetric electric field gradients from more unpaired electrons in the 3d orbitals, whereas LS states show lower δ (-0.1 to 0.2 mm/s) and smaller ΔE_Q (0.2–1.9 mm/s) due to paired electrons. For example, in Fe(II)[C(SiMe₃)₃]₂, Mössbauer parameters confirm the HS state with a large hyperfine field of 157.5 T at 20 K, indicating four unpaired electrons. These spectroscopic methods infer the presence and effects of unpaired electrons via electronic transitions or nuclear hyperfine interactions rather than directly detecting spin flips, serving as valuable complements to more targeted approaches.

Significance and Applications

In Organic and Inorganic Chemistry

Unpaired electrons play a pivotal role in organic synthesis through radical reactions, where they enable selective bond formations that are challenging with traditional ionic methods. A landmark example is the Barton decarboxylation, developed by Derek H. R. Barton in 1983, which converts carboxylic acids to hydrocarbons via thiohydroxamate esters that decarboxylate under radical conditions, generating carbon-centered radicals with unpaired electrons for subsequent functionalization. This method has been widely adopted for complex molecule synthesis due to its mild conditions and compatibility with sensitive functional groups. Similarly, atom transfer radical polymerization (ATRP), pioneered by Krzysztof Matyjaszewski in 1995, relies on transition metal catalysts to generate alkyl radicals with unpaired electrons from initiators, allowing precise control over polymer chain length and architecture in living polymerization processes. Common initiators, such as alkyl halides, undergo reversible homolytic cleavage to produce these radicals, facilitating applications in materials like block copolymers. In mechanistic , single-electron transfer (SET) processes involving unpaired electrons are fundamental to many transformations, often serving as key steps in radical chain propagations. The exemplifies this, where anodic oxidation of salts leads to and formation of alkyl s via initial SET, followed by to yield dimers; this , first reported in 1849, provided early evidence for intermediates in electrolysis. Such SET mechanisms underpin a variety of synthetic strategies, including those using initiators like (AIBN), which thermally decomposes to gas and isopropyl s with unpaired electrons, initiating radical polymerizations or cyclizations. The historical discovery of persistent radicals marked a turning point in understanding unpaired electrons in organic chemistry. In 1900, Moses Gomberg reported the triphenylmethyl radical (\ce{(C6H5)3C^\bullet}), generated from the dissociation of hexaphenylethane, as the first stable organic free radical, challenging the tetravalent carbon paradigm and opening the field of radical chemistry. In inorganic chemistry, unpaired electrons in coordination complexes arise from d-orbital configurations, influencing reactivity and electronic properties. For instance, iron(II) in heme exhibits high-spin (four unpaired electrons, S = 2) or low-spin (zero unpaired electrons, S = 0) states depending on ligand field strength, with the high-spin form common in deoxygenated states due to weaker field ligands like water. Organometallic radicals, such as the cobalt tetracarbonyl radical (\ce{^\bullet Co(CO)4}), feature a 19-electron configuration with an unpaired electron in a metal-centered orbital, enabling unique reactivity in catalytic cycles like hydroformylation.

In Materials and Biological Systems

In materials science, unpaired electrons play a pivotal role in enabling novel functionalities, particularly in single-molecule magnets (SMMs) and conducting polymers. SMMs, such as the archetypal Mn₁₂-acetate cluster [Mn₁₂O₁₂(O₂CMe)₁₆(H₂O)₄], exhibit a high ground-state spin of S=10 due to ferromagnetic coupling among the unpaired electrons on eight Mn³⁺ and four Mn⁴⁺ ions, allowing them to retain magnetization at the molecular level for potential high-density data storage applications. These clusters demonstrate slow relaxation of magnetization, a key property for nanoscale memory devices, with blocking temperatures up to several Kelvin in optimized variants. Similarly, organic radicals incorporated into conducting polymers, such as those based on persistent trityl methyl (PTM) or tempo units, provide intrinsic electrical conductivity through delocalization of unpaired electrons along the polymer backbone, facilitating applications in flexible electronics and batteries.30488-5) For instance, poly(nitroxide radical)s achieve conductivities on the order of 10⁻³ S/cm via hopping mechanisms between radical sites, offering lightweight alternatives to traditional inorganic conductors. In spintronics, unpaired electrons enable spin-dependent transport without net charge flow, harnessing the electron's spin degree of freedom for information processing in molecular-scale devices. Organic molecular wires, such as those featuring stable radicals like verdazyl or nitroxides, support coherent spin propagation over distances exceeding 10 nm by minimizing spin-orbit scattering, as demonstrated in break-junction experiments where magnetoresistance ratios reach 300% at low temperatures. This pure spin current arises from the injection and detection of spin-polarized electrons via ferromagnetic contacts, with unpaired spins in the molecular bridge preserving coherence through weak hyperfine interactions. Such systems hold promise for low-power spin valves and logic elements, where the magnetic properties of unpaired electrons—covered elsewhere—underpin the spin injection efficiency. Biologically, unpaired electrons are central to reactive oxygen species (ROS) and enzymatic catalysis, influencing cellular processes and pathology. The superoxide anion (•O₂⁻), a primary ROS generated during mitochondrial electron transport, features an unpaired electron in its π* orbital, driving oxidative stress by abstracting hydrogen atoms from lipids, proteins, and DNA, which contributes to inflammation and aging-related diseases. In enzymes like class I ribonucleotide reductase (RNR), a stable tyrosyl radical (Tyr•) on the R2 subunit, generated via a di-iron cofactor, initiates deoxyribonucleotide synthesis by abstracting a hydrogen from the substrate on the R1 subunit, a process essential for DNA replication. This radical, with a lifetime of hours in vivo, exemplifies controlled radical chemistry in biology. Health implications arise from dysregulated free radicals, where unpaired electrons in hydroxyl (•OH) or peroxyl (ROO•) species induce DNA strand breaks and base modifications, elevating cancer risk; antioxidants like vitamin C or E mitigate this by donating electrons to neutralize radicals without generating new ones. For example, superoxide dismutase enzymes convert •O₂⁻ to less reactive H₂O₂, preventing genomic instability.

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