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Grotthuss mechanism

The Grotthuss mechanism is a fundamental process in proton conduction, describing how an excess proton diffuses anomalously rapidly through the hydrogen-bonded network of water or other polar solvents by successive proton-hopping events along hydrogen bonds, rather than through the slower vehicular diffusion of hydrated ions.^[1] This mechanism enables proton mobilities in water that are orders of magnitude higher than those of other ions, primarily involving structural rearrangements in the solvation shell of the proton.^[2] Proposed in 1806 by Theodor Grotthuss in his seminal work on the electrolytic decomposition of water, the mechanism envisioned protons being relayed collectively through chains of water molecules, akin to a "bucket brigade" of charge transfer without the net displacement of entire molecules.^[3] Originally framed in the context of electrolysis, where electric fields drive proton migration, Grotthuss's model laid the groundwork for understanding protolytic processes in aqueous solutions.^[4] Over the subsequent two centuries, refinements through spectroscopy, simulations, and theory have clarified its details, confirming its role in both acidic and basic environments.^[1] At the molecular level, the mechanism operates via interconversion between Eigen and Zundel configurations of the solvated proton: the Eigen form features a centralized H₃O⁺ ion with three strong hydrogen bonds to surrounding water molecules, while the Zundel form delocalizes the proton symmetrically between two water oxygens (H₅O₂⁺), facilitating transfer to the next acceptor site.^[1] Proton hops occur on picosecond timescales through quasiconcerted events involving 2–3 water molecules, often along transient "proton wires" in the three-dimensional hydrogen-bond network, with presolvation preparing the pathway and post-transfer relaxation restoring equilibrium.^[2] This structural diffusion contrasts with simple hopping models and accounts for the mechanism's efficiency, as evidenced by femtosecond spectroscopy and ab initio molecular dynamics simulations.^[5] The Grotthuss mechanism holds profound significance in chemistry and biology, underpinning rapid proton transport in enzymatic reactions, such as those in cytochrome c oxidase and ATP synthase, where it enables efficient energy transduction across membranes. In materials science, it inspires the design of proton-exchange membranes for fuel cells, like those in polymer electrolyte membrane (PEM) technologies, where facilitated conduction enhances performance and sustainability. Its principles extend beyond water to solid-state electrolytes and biomimetic systems, influencing advancements in clean energy and artificial photosynthesis.^[6]

History and Discovery

Original Proposal

In 1806, Theodor Grotthuss published his seminal work, "Sur la décomposition de l'eau et des corps qu'elle tient en dissolution à l'aide de l'électricité galvanique," in the Annales de Chimie, where he proposed a novel mechanism for proton conduction during the electrolysis of water. Grotthuss described electrolysis not as the physical migration of entire molecules but as a relay process in which hydrogen ions (protons) transfer sequentially through a structured arrangement of water molecules, enabling efficient charge transport without bulk diffusion.^[7] Central to Grotthuss's model was the concept of a "chain of affinity," envisioning water molecules polarized into positive hydrogen (h) and negative oxygen (o) poles that align under the influence of the electric field to form continuous pathways between electrodes. In this chain-like relay, a proton hops from one water molecule to an adjacent one by reorienting the dipoles, such that the receiving molecule's hydrogen bond facilitates the transfer while the donor is replenished from the neighboring molecule. Grotthuss paraphrased this dynamic as: "when a water molecule (o h) gives away its o at the positive pole its remaining h is immediately re-oxygenated by the arrival of an adjacent o whose h then recombines with another o, etc."^[7] This hypothesis emerged from Grotthuss's experiments with galvanic electricity, inspired by Alessandro Volta's electrochemical pile, amid early 19th-century debates on electrical conduction in fluids. At the time, observations showed anomalously high conductivity for hydrogen ions in water compared to other ions, which hydrodynamic models—positing simple ion drift—could not adequately explain. Grotthuss's chain mechanism resolved these discrepancies by attributing the enhanced mobility to the cooperative reorientation and proton hopping within hydrogen-bonded water structures, rather than independent particle movement.

Evolution of Understanding

In the 19th century, experimental confirmations through electrolysis studies solidified the basis for the Grotthuss mechanism by linking it to the observed anomalously high proton mobilities in aqueous solutions. Michael Faraday's systematic investigations of electrolytic conduction, culminating in his laws of electrolysis published in 1834, demonstrated that hydrogen ions migrated several times faster than other common ions like potassium or chloride, implying a facilitated transport process rather than simple ionic drift. These findings provided early empirical validation for chain-like proton transfer in water, as initially envisioned by Grotthuss in 1806.^[3] Early 20th-century theoretical advancements built on these observations by incorporating models of molecular dipoles to explain sequential proton transfers. Peter Debye's work in the 1920s on dielectric relaxation and dipole orientation in polar liquids, including water, supported the idea of hydrogen-bonded chains where aligned dipoles enable efficient charge propagation without bulk molecular displacement. These dipole models highlighted how electrostatic interactions could drive cooperative reorientations, facilitating the relay-like movement of protons along water networks. A pivotal milestone occurred in the 1930s with the development of hydration shell models that described the microscopic structure of excess protons in water. John D. Bernal and Ralph H. Fowler's 1933 theory proposed that the excess proton exists primarily as a hydronium ion (H₃O⁺) within a first hydration shell of three to four oriented water molecules, forming a dynamic cluster that allows proton hopping through bond breaking and reforming. This structural insight explained the high conductivity by emphasizing the role of localized reorientations in enabling rapid charge transfer, placing the Grotthuss concept on a quantum mechanical foundation.^[8] Mid-20th-century spectroscopic techniques provided compelling evidence distinguishing proton hopping from vehicular diffusion mechanisms. Nuclear magnetic resonance (NMR) studies in the 1950s and 1960s, including measurements of spin-lattice relaxation times, revealed proton exchange rates on the order of 10^{12} s^{-1} (picosecond timescales) in pure water, far exceeding expectations for whole-molecule diffusion and aligning with the predicted dynamics of structural hopping in hydrogen-bonded chains. Complementary infrared (IR) spectroscopy during this period detected broadened O-H stretching bands and low-frequency modes attributable to delocalized protons in transient Zundel-like (H₅O₂⁺) configurations, confirming the involvement of collective solvent rearrangements in the transport process.^[9]^[1]

Fundamental Mechanism

Proton Hopping Process

The proton hopping process in the Grotthuss mechanism involves the structural diffusion of an excess proton through a chain of water molecules, where the proton is transferred in a series of elementary steps rather than migrating as a free species.^[10] This relay-like transfer enables rapid conduction by rearranging the hydrogen bond network, allowing the proton to "hop" from one hydronium ion to an adjacent water molecule.^[11] The process begins with the excess proton in the Eigen configuration, denoted as H₉O₄⁺, where a central hydronium ion (H₃O⁺) is strongly hydrogen-bonded to three surrounding water molecules in a pyramidal arrangement.^[12] This configuration represents the protonated state, with the excess charge localized on the central oxygen. In the subsequent tautomerization step, the Eigen cation transitions to the Zundel configuration, H₅O₂⁺, where the excess proton is delocalized and symmetrically shared between two water molecules oriented in a linear O–H–O bridge.^[10] This Zundel intermediate facilitates the proton's transfer by weakening the bonds on both sides, enabling a concerted rearrangement.^[13] The proton transfer then proceeds as a relay: the hydronium ion in the current Eigen or distorted Eigen state donates its excess proton to a neighboring water molecule via the Zundel-like transition, forming a new hydronium ion while the original site reorients to become a water molecule.^[11] This can be simplified as:

\mathrm{H_3O^+ + H_2O \rightarrow H_2O + H_3O^+}

accompanied by hydrogen bond network rearrangement to propagate the charge.^[10] The hydrogen bonding networks serve as the medium that aligns water molecules into transient "proton wires" for this hopping.^[10] These steps occur with low activation energies, typically 0.07–0.11 eV for the Eigen-to-Zundel interconversion and associated hopping, due to the concerted nature of the bond breaking and forming in the solvation shell.^[9] This minimal barrier underscores the efficiency of the mechanism, allowing ultrafast transfer rates on the picosecond timescale.^[11]

Role of Hydrogen Bonding Networks

The hydrogen bonding network in liquid water exhibits a locally tetrahedral structure, akin to that in ice, where each water molecule forms on average four hydrogen bonds with neighboring molecules, enabling the formation of transient proton-conducting chains or wires essential for the Grotthuss mechanism.^[14] This arrangement arises from the directional nature of hydrogen bonds, with O-H···O angles close to 109.5° and bond lengths around 2.8 Å, creating a dynamic lattice that supports sequential proton relay without requiring the physical diffusion of entire hydronium ions.^[15] In this network, excess protons are delocalized along linear or branched chains of water molecules, facilitating efficient charge transport.^[16] The dynamic nature of these hydrogen bonds is crucial, with average lifetimes on the order of 1 ps, allowing rapid reconfiguration and breaking/reforming that underpins the proton relay in the Grotthuss mechanism.^[17] This short timescale, determined from ab initio molecular dynamics simulations, reflects the constant fluctuation of the network, where bonds persist briefly before switching partners, enabling the structural diffusion of protons through collective rearrangements rather than isolated molecular motions.^[18] Such dynamics ensure that the network remains fluid, preventing rigidity that could impede proton hopping, which occurs within these reconfiguring bonds.^[19] The solvation environment further enhances this process, with the hydronium ion (H₃O⁺) coordinated by a first solvation shell of three water molecules forming strong hydrogen bonds, stabilizing the Eigen cation structure (H₉O₄⁺).^[16] These inner-shell waters are oriented to donate bonds to the central oxygen, while the second solvation shell, involving additional waters, facilitates proton delocalization by providing acceptor sites for transfer, thus extending the effective range of the hydrogen bond network.^[20] In non-aqueous solvents such as alcohols, the Grotthuss mechanism extends to analogous hydrogen-bonded chains, but with higher energy barriers due to longer hydrogen bond lifetimes and reduced network fluidity compared to water.^[21] For instance, in methanol, proton hopping occurs via similar relay mechanisms, yet the overall conductivity is lower because of stronger solvation preferences and less efficient bond dynamics, which hinder rapid reconfiguration.^[21] In biological hydrogen-bond chains, such as those in protein channels, fixed geometries impose even greater barriers, relying on constrained water wires or side-chain networks for proton conduction, though still invoking Grotthuss-like transfer with diminished efficiency relative to bulk aqueous systems.^[22]

Physical and Chemical Properties

Anomalous Proton Diffusion

The proton mobility in water exhibits anomalous behavior, being approximately 7 times higher than that of typical monovalent ions such as Na⁺, with a diffusion coefficient of D_{\ce{H+}} \approx 9.3 \times 10^{-9} m²/s at 25°C.^[23]^[24] This elevated value contrasts sharply with the diffusion coefficients of other ions, which range from 1.3 to 2.0 × 10^{-9} m²/s for common cations like Na⁺ and K⁺ under similar conditions.^[25] The anomaly stems from the Grotthuss mechanism's structural diffusion, in which the excess proton hops rapidly along hydrogen-bonded water chains rather than relying solely on vehicular motion of the hydronium ion.^[23] This hopping process leads to extended mean square displacements over short timescales, distinguishing proton transport from the normal diffusive behavior observed for other species. In molecular dynamics simulations, the mean square displacement \langle r^2 \rangle of the excess proton initially follows a superdiffusive regime, characterized by \langle r^2 \rangle \propto t^\alpha where \alpha > 1, reflecting ballistic-like phases during coordinated proton transfers before transitioning to linear Fickian diffusion at longer times.^[19] Pulsed-field gradient NMR experiments in dilute acidic solutions provide direct evidence of this non-Fickian diffusion, capturing the effective proton self-diffusion coefficient and revealing deviations from simple Brownian motion due to the cooperative, chain-like hopping.^[26] These measurements confirm the dominance of structural over vehicular contributions to proton mobility, underscoring the role of transient hydrogen-bond rearrangements in achieving the observed transport efficiency.^[23]

Quantum and Structural Effects

In the Grotthuss mechanism, proton delocalization is prominently exemplified by the Zundel cation (H₅O₂⁺), where the excess proton is shared symmetrically between two flanking water molecules through a low-barrier hydrogen bond, forming a fluxional defect in the hydrogen-bonded network. This delocalized state facilitates rapid charge transfer without the proton physically diffusing long distances, as the shared proton configuration allows for facile interconversion between equivalent structures. Ab initio simulations have shown that this delocalization arises from the dynamic balance of hydrogen bonds, with the proton oscillating between the oxygen atoms at distances around 2.5 Å, stabilizing the intermediate during hopping events.^[27] Quantum tunneling further influences the proton hopping process by enabling the proton to penetrate energy barriers that would be prohibitive in classical treatments, thereby enhancing the overall transfer rate. Studies incorporating path-integral quantum effects into simulations indicate that tunneling lowers effective barriers and can increase the hopping rate by a factor of approximately 2 compared to classical models.^[28] This quantum correction is particularly relevant in the low-barrier regime of Zundel-like configurations, where zero-point motion and tunneling facilitate the Eigen-Zundel interconversion central to the mechanism.^[9] The Grotthuss mechanism exhibits temperature dependence, persisting in both liquid water and ice but with reduced rates in the solid phase due to restricted molecular reorientation and fewer fluctuating hydrogen-bond defects. In pure ice, the proton mobility is lower than in liquid water, as early reports of higher values were attributed to impurities; the ordered lattice limits wire formation and results in diffusion coefficients roughly an order of magnitude lower at comparable temperatures, though the hopping process remains operative. In liquid water at room temperature, proton diffusion proceeds efficiently through dynamic networks.^[20] This structural rigidity in ice highlights the role of thermal fluctuations in sustaining delocalized states and efficient transfer. Ab initio molecular dynamics simulations conducted in the 1990s and 2000s have elucidated the fluctuating nature of proton wires, revealing that hydrogen-bond networks undergo transient rearrangements to form short-lived chains enabling sequential hops. These studies, using Car-Parrinello methods, demonstrate how rare solvent fluctuations drive the formation and breakage of bonds, supporting delocalized proton motion without stable long-range wires.^[29] Such insights underscore the dynamic, defect-mediated character of the mechanism, where structural effects like bond asymmetry influence tunneling probabilities and overall efficiency.^[27]

Modern Developments and Alternatives

Recent Experimental Insights

In 2022, ultrafast spectroscopy experiments led by Ehud Pines provided direct evidence for the involvement of approximately 3 water molecules in the inner solvation complex of the concerted proton transfer process central to the Grotthuss mechanism, with the hydration shell extending to approximately H₁₇O₈⁺, resolving a longstanding debate on the molecular scale of hydration structures beyond the traditional Eigen and Zundel models.^[30] Using soft X-ray absorption spectroscopy at the oxygen K-edge combined with ab initio molecular dynamics simulations, the study revealed a hydration shell extending to approximately H₁₇O₈⁺, where proximal waters form strong covalent-like bonds with the proton while distal waters contribute through electric field interactions, enabling efficient charge delocalization.^[30] This work demonstrated that proton solvation involves a dynamic cluster of at least seven waters in the extended shell, facilitating ultrafast structural rearrangements on picosecond timescales essential for the hopping mechanism.^[30] Advancements in femtosecond infrared (IR) and two-dimensional (2D) IR spectroscopy during the 2010s, notably by Mark A. Johnson, captured real-time snapshots of proton hopping in aqueous environments, confirming the sequential transfer along hydrogen-bonded networks.^[31] In a 2019 study, 2D IR chemical exchange spectroscopy tracked proton migration onto acceptor water molecules, revealing exchange lifetimes on the order of 1.6 picoseconds and highlighting the role of transient Zundel cations (H₅O₂⁺) as intermediates in the Grotthuss pathway.^[31] Earlier 2016 experiments using similar techniques provided spectroscopic evidence for the structural diffusion of protons through water chains, showing how vibrational excitations drive the reconfiguration of hydrogen bonds to propagate the charge defect. These observations underscored the mechanism's reliance on collective solvent motions rather than isolated molecular events. Post-2010 computational simulations employing enhanced density functional theory (DFT) methods have further validated the necessity of multi-water chains in the Grotthuss process, moving beyond simplistic 2-4 molecule models to incorporate larger solvation environments. A 2017 ab initio molecular dynamics analysis of proton diffusion trajectories demonstrated that hopping events correlate with coordinated rearrangements involving 4-6 surrounding waters, with quantum delocalization effects enhancing transfer rates in extended networks.^[32] These DFT-based approaches, often integrated with machine-learned potentials for larger systems, refuted overly reductive views by emphasizing the collective response of the solvent, where proton mobility emerges from the interplay of local bonding and global hydrogen bond dynamics. Such insights have implications for understanding anomalous diffusion, affirming the dominance of Grotthuss transport while highlighting quantum effects validated in recent spectroscopic experiments.^[32] More recent studies as of 2025 have further advanced understanding of proton solvation intermediates. For instance, a July 2025 investigation using advanced spectroscopy unveiled the intermediate hydrated proton states in water, providing direct evidence for ultrafast interconversions between Eigen and Zundel forms in the Grotthuss mechanism.^[33] Additionally, research in 2025 has explored Grotthuss-type transport in novel materials, such as pyrochlore structures for energy storage and graphene oxide membranes for fuel cells, offering new experimental validations of proton hopping in confined environments.^[34]^[35]

Competing Transport Mechanisms

The vehicular mechanism represents an alternative to the Grotthuss process for proton transport, wherein protons diffuse as hydrated species like H₃O⁺ through Brownian motion without relying on sequential hydrogen bond rearrangements. This mode predominates in environments lacking extensive hydrogen bonding networks, such as dilute solutions or non-aqueous media, where the proton's mobility is limited by the diffusion of its carrier molecule.^[5] In contrast to proton hopping, which enables rapid charge transfer in structured water, the vehicular pathway yields slower overall conduction, with proton diffusion coefficients comparable to those of the solvent molecules themselves.^[5] Comparisons between the mechanisms highlight the superior efficiency of Grotthuss transport in hydrogen-bonded networks, where it contributes to proton diffusion rates approximately 4 times higher than vehicular diffusion alone in pure water.^[36] For instance, the total proton diffusion coefficient in dilute aqueous solutions reaches about 9.3 × 10⁻⁹ m²/s, largely due to hopping, while vehicular components align with values roughly 2.3 × 10⁻⁹ m²/s, similar to water's self-diffusion.^[36]^[37] However, in non-polar solvents, the absence of hydrogen bonds suppresses hopping entirely, rendering vehicular transport the sole viable pathway and resulting in conductivities orders of magnitude lower than in protic media.^[38] Hybrid models integrate both vehicular and Grotthuss elements, particularly in confined systems like polymer electrolyte membranes or protein interiors, where spatial constraints limit continuous hydrogen bond chains and favor short-range diffusion of proton carriers alongside occasional hops.^[39] In such settings, vehicular contributions become more significant when hydration levels are low or geometries disrupt network formation, as observed in simulations of phosphonic acid-based membranes.^[39] Evidence for the prevalence of alternatives emerges in low-temperature regimes, where thermal barriers slow hydrogen bond reorientation, reducing hopping rates and elevating the relative role of vehicular motion, as demonstrated in cryogenic spectroscopy of protonated clusters.^[40] Similarly, aprotic environments, lacking proton-accepting sites, exhibit diminished hopping efficiency, with transport reverting to carrier diffusion, as seen in ionic liquids and non-hydrogen-bonding solvents.^[38]

Applications

Biological Systems

The Grotthuss mechanism is integral to proton transport in biological systems, enabling rapid and efficient movement of protons through aqueous environments within enzymes, membranes, and cellular structures. This process supports critical functions such as energy production and pH balance by allowing protons to "hop" along hydrogen-bonded chains of water molecules or amino acid residues, far exceeding the rates of simple diffusion. In these contexts, the mechanism exploits the dynamic nature of water networks to achieve high-speed conduction without requiring the physical relocation of entire hydronium ions. In membrane proteins like bacteriorhodopsin and cytochrome c oxidase, the Grotthuss mechanism operates through structured proton wires composed of water molecules and polar residues, facilitating vectorial proton translocation across lipid bilayers. In bacteriorhodopsin, a light-driven proton pump in archaea, proton release and uptake occur via hydrated channels where sequential hops along water chains drive the photocycle, achieving turnover rates on the order of 10^2 to 10^3 s^{-1} per cycle, with individual transfer steps approaching 10^6 s^{-1}. Similarly, in cytochrome c oxidase, the terminal enzyme of the respiratory chain, pumped protons traverse dedicated pathways like the D-channel using Grotthuss shuttling through hydrogen-bonded water networks, coupling electron transfer to proton pumping at rates of approximately 10^3 s^{-1} per catalytic cycle. These proton wires, stabilized by key residues such as arginine and glutamate, ensure directional transport essential for generating electrochemical gradients. The mechanism also contributes to cellular pH regulation through its involvement in ATP synthase and ion channels. In ATP synthase, the F_O subunit facilitates proton flow via Grotthuss-like transfer through aqueous half-channels in subunit a, enabling c-ring rotation and ATP synthesis at physiological rates of approximately 100-300 s^{-1} (corresponding to proton flows of several hundred protons per second based on stoichiometry).^[41] This supports pH homeostasis across mitochondrial and bacterial membranes. Voltage-gated proton channels, such as Hv1, employ Grotthuss hopping along water wires to extrude protons during metabolic acidosis or phagocyte activation, shifting intracellular pH by compensating for H^+ production and preventing excessive acidification. This selective conduction, modulated by pH gradients, underscores the mechanism's role in rapid acid-base balance. From an evolutionary perspective, the Grotthuss mechanism has enabled efficient energy transduction in aqueous bioenvironments, with conserved water-mediated pathways in ATP synthases tracing back to alphaproteobacterial ancestors of mitochondria, allowing adaptation to oxidative phosphorylation demands. Representative examples include DNA charge transfer, where water-assisted Grotthuss-like proton shifts facilitate base pair tautomerism and mutagenesis, and aquaporins, in which the mechanism's potential for hopping is suppressed by electrostatic barriers to exclude protons while permitting water flux, thus preserving membrane integrity. These instances highlight how biological systems have optimized hydrogen bonding networks, akin to those in protein chains, to harness the mechanism for survival.

Technological Uses

The Grotthuss mechanism plays a central role in proton exchange membrane fuel cells (PEMFCs), where materials like Nafion enable efficient proton transport through hydrated channels via hopping, achieving conductivities of approximately 0.1 S/cm under optimal conditions of high humidity and temperatures around 80°C.^[42]^[43] This hopping-dominated conduction in Nafion's sulfonic acid groups facilitates high power densities in PEMFCs, making it a benchmark material for clean hydrogen-based energy conversion.^[43] In proton batteries, developed prominently in the 2020s, the mechanism enables ultrafast charging by supporting rapid proton diffusion in organic conductors and electrode materials. For instance, hybrid cathodes like H₂MoO₃ combined with polyaniline leverage Grotthuss hopping for superfast proton conduction, achieving high-rate performance even in frozen aqueous electrolytes and demonstrating cycle stabilities over thousands of cycles.^[44] Recent advancements as of 2025 include Grotthuss mechanism-dominated proton storage in pyrochlore-type WO₃·0.5H₂O materials, enhancing energy density and rate capability in such batteries.^[34] Similarly, topochemistry-based electrodes, such as those using CuFe-layered double hydroxides, exploit defect-mediated proton hopping for diffusion-free transport, outperforming traditional lithium-ion systems in rate capability.^[45] The Grotthuss mechanism enhances efficiency in electrochemical devices for water splitting, particularly in acid electrolysis, by accelerating proton transfer at electrode-electrolyte interfaces. In membrane-free decoupled systems, Grotthuss topochemistry in high-rate electrodes promotes rapid hydrogen evolution, reducing overpotentials and enabling scalable hydrogen production with current densities exceeding 1 A/cm².^[46] For sensors, proton-conducting films incorporating the mechanism improve sensitivity in pH and humidity detection by enabling quick response times through efficient ion hopping in hydrated networks.^[47] Despite these advances, scalability of the Grotthuss mechanism remains challenging in non-aqueous media, where reduced hydrogen-bond networks limit hopping efficiency compared to aqueous environments.^[48] Biomimetic designs, such as artificial proton channels embedded in hydrogen-bonded organic frameworks, address this by mimicking natural water wires to stabilize proton paths and boost conduction in low-water conditions.^[49]

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Dec 15, 2023 · Detailed analyses demonstrate the Grotthuss mechanism of ultrafast proton conduction in H2MoO3/PANI. The constructed proton full cell based on H ...Missing: 2020s | Show results with:2020s
[43]
[PDF] Diffusion-free Grotthuss topochemistry for high-rate and long-life ...
Taken together, the characterization and simulation results clearly support the correlation between Grotthuss mechanism and high-rate capability of CuFe-TBA.Missing: post- | Show results with:post-
[44]
Decoupled electrolysis for hydrogen production and hydrazine ...
Feb 13, 2024 · A high‐rate electrode with Grotthuss topochemistry for membrane‐free decoupled acid water electrolysis. Adv. Energy Mater. 2021;11:2102057 ...
[45]
Ion and Proton Transport In Aqueous/Nonaqueous Acidic Ionic ...
Jun 24, 2021 · ... Grotthuss mechanism, widely recognized as the quickest distribution of protonic defect. (6) The critical issue in this strategy is a proper ...Introduction · Experimental Section · Synthesis Of IlsMissing: scalability | Show results with:scalability
[46]
Constructing Biomimetic Channels in Hydrogen‐Bonded Organic ...
Mar 14, 2025 · Here, we first demonstrate that post-synthesis can create unoccupied carboxylic acid groups in HOFs, stabilizing water molecules and forming continuous proton ...