Site Of Deposition Research Articles

Developmental stage and level of submersion in water impact the viability of lone star and winter tick eggs.

Female ticks deposit large egg clusters that range in size from hundreds to thousands. These egg clusters are restricted to a deposition site as they are stationary, usually under leaf litter and other debris. In some habitats, these sites can be exposed to periodic flooding. When the clusters of tick eggs are disturbed, they may float to the surface or remain underneath organic debris entirely submerged underwater. Here, we examined the viability of egg clusters from winter ticks, Dermacentor albipictus, and lone star ticks, Amblyomma americanum, when partially or fully submerged in water and in relation to the developmental stages of the eggs under lab conditions. In general, egg clusters that were older and partially submerged had a higher viability than fully submerged, younger eggs. Of the two species, A. americanum was more resistant to water exposure. These studies highlight that egg clusters for certain tick species can remain viable when exposed to water for at least two weeks. These resultsalso suggest that distribution by flooding of egg clusters could occur for some species and water submersion will differentially impact tick egg survival based on the specific developmental stage of exposure and species.

Influence of Precursor Structure on the Formation of Active Carbon Deposition Sites and Helical Graphite Cones Growth Mechanism

Influence of Precursor Structure on the Formation of Active Carbon Deposition Sites and Helical Graphite Cones Growth Mechanism

Evolution of Auriferous Fluids in the Kraaipan-Amalia Greenstone Belts: Evidence from Mineralogical and Isotopic Constraints

The Kraaipan and Amalia greenstone belts in South Africa occur in the western part of the Kaapvaal Craton. The two belts stretch discontinuously in an approximately north–south orientation over a distance of about 250 km from southern Botswana in the north to the Vaal River near Christiana in the south and are separated by a distance of about 90 km. Gold mineralization is hosted in banded iron formation at both the Kalahari Goldridge deposit (Kalgold) in the Kraaipan greenstone belt in the north and the Amalia deposit in the Amalia greenstone belt in the south, with the mineralization associated with quartz–carbonate veins. The footwalls of these deposits are generally composed of mafic volcanic schist and the hanging walls consisting of graywackes, schist and shale units. The Kalgold and Amalia gold deposits show some variation in the redox condition of the mineralizing system and fluid chemistry. The ore mineral assemblage is characterized by magnetite–pyrrhotite–pyrite at Kalgold, which is indicative of reducing conditions, and a magnetite–hematite–pyrite assemblage at Amalia that suggests a relatively oxidizing environment. Average mineralizing temperatures determined from chlorite geothermometry were relatively higher at the Kalahari Goldridge deposit ranging from 350 to 400 °C compared to the slightly cooler range of 330 to 390 °C at Amalia. The composition of the fluids derived from fluid inclusions is indicative of low salinity H2O--CO2±CH4-rich fluids at Kalgold against relatively H2O-CO2-rich fluids at Amalia. Evidence from strontium–carbon–oxygen isotopic ratios from carbonates suggests that differences in redox conditions in the deposits could be attributed to different flow pathways by an evolving fluid from a common source (with minimum 87Sr/86Sr = 0.70354) to the sites of gold deposition, with a significant ore fluid interaction with a thick sequence of carbonaceous meta-pelitic rock units at the Kalahari Goldridge deposit that is absent in the Amalia deposit.

A Multifunctional Na2Se/Zn-Mn Skeleton Enables Processable and Highly Reversible Sodium Metal Anode.

The recent high-energy density sodium (Na) metal batteries (SMBs) are restricted by their processability, lifetime, and safety. These issues can be addressed by controlling the reactions at the Na metal by modifying the Na metal anode (SMA) with the sodiophilic hosts. Herein, a multifunctional Na2Se/Zn-Mn skeleton is introduced for SMA and fabricate a processable Na@Na2Se/Zn-Mn composite using repeated cold rolling/folding approach through the spontaneous reaction between Na metal and ZnMnSe alloy. This unique intermetallic composite has Zn and Mn metal sites for uniform deposition of Na, while Na2Se generates a stable SEI for rapid Na+ ion transport. It offers outstanding sodiophilicity, high processability, excellent mechanical strength, and high ionic conductivity due to the synergistic effect of multi-component, enabling stable Na plating/stripping at high current densities and areal capacities. An optimized Na2Se/Zn-Mn skeleton enables Na||Na symmetric cells to attain a high critical current density of 5.0mA cm-2 at 5.0 mAh cm-2 with an extended lifespan of 9000h at 1.0mA cm-2 at 1.0 mAh cm-2. Remarkably, when configured into a full cell with a Na3V2(PO4)3 cathode, the SMB displays an extended lifespan of 2000 cycles at 10 C and an impressive high-rate capacity of ≈61.6 mAh g-¹ at 30 C.

Effect of gypsum on transport of IMX-104 constituents in overland flow under simulated rainfall.

Residue of energetic formulations, which is deposited on military training grounds following incomplete detonation, poses biotic hazards. This residue can be transported off-site, adsorb to soil clays and organic matter, transform or degrade, or taken up by plants and animals. Its harmful effects can be mitigated by localizing the energetics at the site of initial deposition using soil amendments and allowing them to bio- and photodegrade in situ. Small plots with coarse loamy soil were used to study the effect of gypsum (CaSO4·2H2O) on transport and redistribution under simulated rainfall of various sizes of insensitive munition explosive (IMX)-104 particles, which consist of 3-nitro-1,2,4-triazol-5-one (NTO), 2,4-dinitroanisole (DNAN), hexahydro-1,3,5-trinitro-1,3,5-triazine (RDX), and octahydro-1,3,5,7-tertranitro-1,3,5,7-tetrazocine (HMX). The addition of gypsum more than doubled infiltration and decreased sediment loss by 16% compared to the control. The post-rainfall mass balance of IMX-104 in the order from greater to smaller pools was as follows: (1) soil surface retention, (2) off-site loss to overland flow, and (3) sub-surface infiltration. Overall, the application of gypsum significantly decreased concentration and the total mass loss of dissolved DNAN, RDX, and HMX in surface runoff. In addition, gypsum significantly decreased (for NTO, DNAN, and HMX) or delayed (for NTO, DNAN, RDX, and HMX) the peak discharge of <2mm particulate energetics. The infiltration of NTO in the gypsum treatment was fivefold greater than in the control. Moreover, DNAN and RDX were also present in infiltration, while in the gypsum-free control none were found. Gypsum shifted the total mass balance of energetics toward subsurface flow. This study indicates that gypsum may decrease off-site transport of energetic constituents in the soils that are subject to surface sealing.

RADT-42. DISSEMINATED TUMORAL AMYLOIDOSIS OF THE CRANIAL NERVES IN THE ABSENCE OF SYSTEMIC DISEASE: CASE REPORT

Abstract Tumoral amyloidosis, characterized by tumor-like deposits without systemic disease, is rare in the central nervous system. Most often located in the periventricular white matter, tumoral amyloidosis typically consist of immunoglobulin light chains (AL). While prior reports describe cases of tumoral amyloidosis isolated to the trigeminal nerve, we report herein a first known case of diffuse cranial nerve involvement. The patient is a 43-year-old man who presented with left trigeminal dysesthesias, which led to self-excoriation and erosion of the left naris. On exam, he had absent sensation in the V1-V3 distributions, left trochlear nerve palsy, and bilateral abducens nerve palsies. Imaging demonstrated significant thickening of the left trigeminal nerve and diffuse cisternal contrast enhancement of the other cranial nerves, including the oculomotor, abducens, facial, and glossopharyngeal nerves. Work-up began with a lumbar puncture that found elevated protein with otherwise benign results, including flow cytometry. He was therefore recommended to undergo open biopsy of the left trigeminal nerve and cavernous sinus. Pathology from this surgery demonstrated congo red- positive AL amyloid deposits. Following this pathologic diagnosis, he subsequently underwent a full workup for systemic amyloidosis including bone marrow biopsy, abdominal fat pad biopsy, and a PET CT scan. Biopsy of a long nodule was negative for amyloidosis. Systemic amyloid testing did not demonstrate non-CNS sites of amyloid deposition. Medical therapy with daratumumab, cyclophosphamide, bortezomib, and dexamethasone was started but then discontinued due to ineffectiveness. He underwent radiation treatment of 4500 cGy to the left cavernous sinus where the tumoral amyloidosis was most severe. He has had no further progression of his disease. Tumoral amyloidosis of the cranial nerves remains a rare and poorly-understood disease. Prior reports have described the disease isolated to the trigeminal nerve. This report raises attention to this diagnosis in cases of rare multi-nerve involvement and suggests that radiation may be a useful first-line treatment.

Heparan sulphate binding controls in vivo half-life of the HpARI protein family

The parasitic nematode Heligmosomoides polygyrus bakeri secretes the HpARI family, which bind to IL-33, either suppressing (HpARI1 and HpARI2) or enhancing (HpARI3) responses to the cytokine. We previously showed that HpARI2 also bound to DNA via its first complement control protein (CCP1) domain. Here, we find that HpARI1 can also bind DNA, while HpARI3 cannot. Through the production of HpARI2/HpARI3 CCP1 domain-swapped chimeras, DNA-binding ability can be transferred, and correlates with in vivo half-life of administered proteins. We found that HpARI1 and HpARI2 (but not HpARI3) also binds to the extracellular matrix component heparan sulphate (HS), and structural modelling showed a basic charged patch in the CCP1 domain of HpARI1 and HpARI2 (but not HpARI3) which could facilitate these interactions. Finally, a mutant of HpARI2 was produced which lacked DNA and HS binding, and was also shown to have a short half-life in vivo. Therefore, we propose that during infection the suppressive HpARI1 and HpARI2 proteins have long-lasting effects at the site of deposition due to DNA and/or extracellular matrix interactions, while HpARI3 has a shorter half-life due to a lack of these interactions.

Heparan sulphate binding controls in vivo half-life of the HpARI protein family.

The parasitic nematode Heligmosomoides polygyrus bakeri secretes the HpARI family, which bind to IL-33, either suppressing (HpARI1 and HpARI2) or enhancing (HpARI3) responses to the cytokine. We previously showed that HpARI2 also bound to DNA via its first complement control protein (CCP1) domain. Here, we find that HpARI1 can also bind DNA, while HpARI3 cannot. Through the production of HpARI2/HpARI3 CCP1 domain-swapped chimeras, DNA-binding ability can be transferred, and correlates with in vivo half-life of administered proteins. We found that HpARI1 and HpARI2 (but not HpARI3) also binds to the extracellular matrix component heparan sulphate (HS), and structural modelling showed a basic charged patch in the CCP1 domain of HpARI1 and HpARI2 (but not HpARI3) which could facilitate these interactions. Finally, a mutant of HpARI2 was produced which lacked DNA and HS binding, and was also shown to have a short half-life in vivo. Therefore, we propose that during infection the suppressive HpARI1 and HpARI2 proteins have long-lasting effects at the site of deposition due to DNA and/or extracellular matrix interactions, while HpARI3 has a shorter half-life due to a lack of these interactions.

Diagnosing Autoimmune Bullous Diseases—An Indian Perspective

Abstract Introduction: Autoimmune bullous diseases (AIBDs) are a group of illnesses characterized by autoantibodies targeting adhesion molecules in the skin and mucosa. Accurate diagnosis of the specific subtype of AIBD is crucial for effective management and predicting prognosis, especially in cases with an increased risk of malignancy. However, differentiating between subtypes can be challenging due to overlapping symptoms. Overview of diagnostic tests: Direct immunofluorescence microscopy (DIF) detects in vivo bound antibodies in perilesional tissue biopsies and provides details about the probable site of autoantibody deposition within the skin/mucosae, immunoglobulin type, and pattern of antibody deposition. Indirect immunofluorescence (IIF) microscopy with organ substrate is a minimally invasive serological test that detects circulating autoantibodies. Enzyme-linked immunosorbent assay (ELISA) quantifies serum autoantibodies against specific autoantigens. Quantitative ELISA is useful for diagnosis, monitoring therapy, and assessing disease activity. Commercially available ELISA kits, including the multi-variant ones, can detect antibodies associated with AIBDs. BIOCHIP is a technique based on IIF that offers a sensitive and specific diagnostic alternative to ELISA. It uses microarrays with multiple antigenic substrates to simultaneously screen common AIBDs. The BIOCHIP slides contain different substrates, allowing the identification of multiple types of autoantibodies in a single test. Indian context: While these diagnostic tests offer valuable insights into target antigens, antibody patterns, and disease subtypes, it is important to note that the availability of these tests is limited in most centers across India. This limitation can be attributed to factors such as the relatively higher cost of these investigations, challenges related to the stability of immuno-reactants, and a shortage of trained personnel capable of performing such tests. Conclusion: This review discusses the diagnosis of AIBDs based on resources available in India, as of today. It also provides with practically applicable diagnostic algorithms for pragmatic diagnosis of AIBDs in Indian scenario.

New prospects for 89Zr-immuno-PET in brain applications – Alpha-synucleinopathies

BackgroundRecently, 89Zr-immuno-PET imaging of therapeutic antibodies, actively transported over the blood-brain-barrier via transferrin-mediated transcytosis, was demonstrated using the chelator DFO*. In these studies, aducanumab targeting amyloid-beta was fused with a transferrin binding unit: a single-chain Fab fragment derived from 8D3 (scFab8D3). Alpha-synuclein is a hallmark protein of several neurodegenerative diseases such as Parkinson's Disease, Lewy-Body-Dementia, and Multiple System Atrophy. 89Zr-immuno-PET imaging of alpha-synuclein can be a valuable tool for image-guided drug development and assessment of target engagement. The goal of this study was to compare two currently used constructs of 8D3 for targeting potential, namely a single moiety of scFab8D3 fused to the alpha-synuclein antibody HLu-3 (HLu-3-scFab8D3) versus HLu-3 fused with two 8D3 single-chain variable fragments (HLu-3-(scFv8D3)2), by 89Zr-immuno-PET in an alpha-synuclein pre-formed fibril (PFF) deposition model. HLu-3 and the HIV-targeting B12-scFab8D3 were used as controls. The best-performing compound was further investigated in an animal model with predominantly intraneural target aggregation. MethodsAntibodies were conjugated with DFO* using DFO*-NCS and subsequently radiolabeled with 89Zr. Assessment of binding affinity was done by alpha-synuclein ELISA and with FACS analysis using mTfR1 expressing CHO-S cells. Radioimmunoconjugates were first evaluated in an extracellular alpha-synuclein deposition model established by intracranial injection of non-sonicated PFFs into the left striatum of C57Bl/6 WT mice, whereas saline was injected into the contralateral side as control. PET imaging was performed 1, 3, and 7 days post-injection, followed by ex vivo biodistribution, autoradiography and immunofluorescence analysis. Based on the results from these studies, the better-performing antibody candidate was tested similarly in an alpha-synuclein seeding model. The seeding model has intraneural alpha-synuclein aggregation and was established by intracranial injection of sonicated PFFs into both striata of F28tg mice, which overexpress human wild-type alpha-synuclein. Untreated F28tg and C57Bl/6 WT mice served as controls. ResultsThe radioconjugate was produced in sufficient radiochemical yields and purity. There was no impairment of binding affinity towards alpha-synuclein, and acceptable binding with negligible losses to mTfR1. PET imaging with [89Zr]Zr-HLu-3-scFab8D3 and [89Zr]Zr-HLu-3-(scFv8D3)2 in the deposition model showed uptake at the site of alpha-synuclein deposits. However, uptake was variable between mice. Reliable PET quantification was hampered due to the small deposition volume (~2 μL). Immunofluorescence revealed specific alpha-synuclein target engagement of both constructs with PFF deposits in the striatum, in contrast to the [89Zr]Zr-B12-scFab8D3 control. Unexpectedly, ex vivo autoradiography showed uptake in some controls ([89Zr]Zr-B12-scFab8D3 in the contralateral striatum without PFFs), potentially related to astrocyte activation at the injection sides. Ex vivo and PET brain uptake was higher for [89Zr]Zr-HLu-3-scFab8D3 when compared to [89Zr]Zr-HLu-3-(scFv8D3)2 and was therefore selected for further testing in the alpha-synuclein seeding model. No significant difference in in vivo and ex vivo brain uptake of [89Zr]Zr-HLu-3-scFab8D3 between PFF-injected F28tg, F28tg and C57Bl/6 mice was observed. Furthermore, ex vivo immunofluorescence and autoradiography showed no specific alpha-synuclein target engagement. ConclusionsSuccessful target engagement of [89Zr]Zr-HLu-3-scFab8D3 and [89Zr]Zr-HLu-3-(scFv8D3)2 with alpha-synuclein was shown in a PFF deposition model. PET imaging showed variable results, and in vivo detection of the depositions was possible in some cases. Due to the better performance in the deposition model, [89Zr]Zr-HLu-3-scFab8D3 was further investigated in an alpha-synuclein seeding model with intraneural Lewy-body pathology, showing no difference between the control groups and PFF-seeded mice. Furthermore, immunostaining of seeded F28tg mice manifested sufficient intraneural alpha-synuclein pathology but no corresponding antibody accumulation. These results underscore the ongoing challenge of imaging intraneural inclusions via immuno-PET.

Magmatic and rock-leaching contributions to the metal load in hydrothermal fluids at þeistareykir, Iceland

Magmatic-hydrothermal systems are key environments to study the transfer of elements from the deep Earth to the surface and the mobilization and re-distribution of elements within the crust. These systems have been recognized as potential active analogue sites for ore deposition. The source of fluids and their metal load is split between the relative contributions from degassing of underlying magma and interactions between the hydrothermal fluid and the host rock. Here, we combine analyses of noble gases and volatile metals in fluids and rocks from the þeistareykir geothermal field (NE Iceland) to provide constraints on the relative contribution of these two sources. Helium isotope data suggest 80–85% originated from magma degassing. The 3He/4He ratio, corrected for atmospheric contamination (Rc/Ra) correlates with volatile metal abundances in surface fluids and indicates that Bi and Hg are predominantly derived from magma degassing. It is also shown that the deep geothermal reservoir fluid is dominated by magmatic input, except for Mn, Fe, Co, Cu, Ti and V, using the elemental signature of magmatic degassing and water-rock interaction. The spatial variations in Rc/Ra and surface fluid volatile metal contents among the wells suggest an impact of the local and regional structures on the fluid's pathway from depth to surface.

Zincophilic Sites Enriched Hydrogen-bonded Organic Framework as Multifunctional Regulating Interfacial Layers for Stable Zinc Metal Batteries.

To construct an efficient regulating layer for Zn anodes that can simultaneously address the issues of dendritic growth and side reactions is highly demanded for stable zinc metal batteries (ZMBs). Herein, we fabricate a hydrogen-bonded organic framework (HOF) enriched with zincophilic sites as a multifunctional layer to regulate Zn anodes with controlled spatial ion flux and stable interfacial chemistry (MA-BTA@Zn). The framework with abundant H-bonds helps capture H2O and remove the solvated shells on [Zn(H2O)6]2+, leading to suppressed side reactions. The HOF layer also helps form electrolyte-philic surfaces and expose Zn (002) crystal planes which benefit for rapid conduction and uniform deposition of Zn2+, and weakened sides reactions. Additionally, the electrochemically active zincophilic sites (C=O, -NH2 and triazine groups) favor the targeted guidance and penetration of Zn2+ and provide advantageous sites for uniform Zn deposition. High Young's modulus of the HOF layer further contributes to a high interfacial flexibility and stability against Zn plating-associated stress. The MA-BTA@Zn symmetric cells thereby obtain a substantially extended battery life over 1000 h at 4 mA cm-2. The MA-BTA@Zn||Cu half-cell demonstrates a highly reversible Zn stripping/plating process over 1500 cycles with impressive average Coulombic efficiency (CE) of 99.5% at 10 mA cm-2.

Zincophilic Sites Enriched Hydrogen‐Bonded Organic Framework as Multifunctional Regulating Interfacial Layers for Stable Zinc Metal Batteries

AbstractTo construct an efficient regulating layer for Zn anodes that can simultaneously address the issues of dendritic growth and side reactions is highly demanded for stable zinc metal batteries (ZMBs). Herein, we fabricate a hydrogen‐bonded organic framework (HOF) enriched with zincophilic sites as a multifunctional layer to regulate Zn anodes with controlled spatial ion flux and stable interfacial chemistry (MA‐BTA@Zn). The framework with abundant H‐bonds helps capture H2O and remove the solvated shells on [Zn(H2O)6]2+, leading to suppressed side reactions. The HOF layer also helps form electrolyte‐philic surfaces and expose Zn (002) crystal planes which benefit for rapid conduction and uniform deposition of Zn2+, and weakened sides reactions. Additionally, the electrochemically active zincophilic sites (C=O, −NH2 and triazine groups) favor the targeted guidance and penetration of Zn2+ and provide advantageous sites for uniform Zn deposition. High Young's modulus of the HOF layer further contributes to a high interfacial flexibility and stability against Zn plating‐associated stress. The MA‐BTA@Zn symmetric cells thereby obtain a substantially extended battery life over 1000 h at 4 mA cm−2. The MA‐BTA@Zn||Cu half‐cell demonstrates a highly reversible Zn stripping/plating process over 1500 cycles with impressive average Coulombic efficiency (CE) of 99.5 % at 10 mA cm−2.

Effect of additives on the microstructure and properties of pulsed electrodeposited copper foils

ABSTRACT A low-roughness ultra-thin copper foil was prepared by pulsed electrodeposition with a duty cycle 60%, pulse frequency of 600 Hz on titanium. The influence of sodium 3,3'-dithiodipropane sulphonate (SPS), hydroxyethyl cellulose (HEC), gelatin and collagen additives on the microstructure, mechanical properties and electrochemical behaviour of electrolytic copper foil was explored. Furthermore, the reaction mechanism of SPS and collagen additives on electrodeposited copper were discussed. The results showed that at 0.08 g L−1 collagen concentration, the lowest thickness, the highest microhardness and the optimal surface roughness were achieved (5.12 μm, 279.63 HV and 1.885 μm, respectively). X-ray diffraction results confirmed that electrolytic copper foils prepared when SPS was introduced into the blank solution had a preferred orientation of (220) texture, which benefitted from the synergistic effect of copper ions and additives. The intermediates formed by the additive and Cu+ occupied the active sites on the cathode surface that increased the nucleation sites for deposition. In addition, the formed complexes can act as a barrier to narrow ion deposition channels and inhibit the growth of Cu ions.

Significant role of secondary electrons in the formation of a multi-body chemical species spur produced by water radiolysis.

Scientific insights into water photolysis and radiolysis are essential for estimating the direct and indirect effects of deoxyribonucleic acid (DNA) damage. Secondary electrons from radiolysis intricately associated with both effects. In our previous paper, we simulated the femtosecond (1 × 10- 15s) dynamics of secondary electrons ejected by energy depositions of 11-19eV into water via high-energy electron transport using a time-dependent simulation code. The results contribute to the understanding of simple "intra-spur" chemical reactions of tree-body chemical species (hydrated electrons, hydronium ion and OH radical) in subsequent chemical processes. Herein, we simulate the dynamics of the electrons ejected by energy depositions of 20-30eV. The present results contribute to the understanding of complex "inter-spur" chemical reactions of the multi-body chemical species as well as for the formation of complex DNA damage with redox site and strand break on DNA. The simulation results present the earliest formation mechanism of an unclear multi-body chemical species spur when secondary electrons induce further ionisations or electronic excitations. The formation involves electron-water collisions, i.e. ionisation, electronic excitation, molecular excitation and elastic scattering. Our simulation results indicate that (1) most secondary electrons delocalise to ~ 12nm, and multiple collisions are sometimes induced in a water molecule at 22eV deposition energy. (2) The secondary electrons begin to induce diffuse band excitation of water around a few nm from the initial energy deposition site and delocalise to ~ 8nm at deposition energies ~ 25eV. (3) The secondary electron can cause one additional ionisation or electronic excitation at deposition energies > 30eV, forming a multi-body chemical species spur. Thus, we propose that the type and density of chemical species produced by water radiolysis strongly depend on the deposition energy. From our results, we discuss formation of complex DNA damage.

Direct immunofluorescence in bullous disorders: A mini-review

Background: Immunofluorescence microscopy is an invaluable tool for different lesions in dermatopathology. These lesions include bullous lesions, vasculitis, and connective tissue disorders/systemic lupus erythematosus. In this review, we take a look at bullous disorders. Some of these diagnoses are not possible on routine histopathology alone and require immunofluorescence for confirmation. Different diseases can be diagnosed according to the immunoglobulins/complements, sites of deposition (dermo-epidermal / intercellular spaces / dermal), and their patterns (linear, granular). Knowing the exact type of lesion can help guide treatment accordingly.

Ag-Mediated Growth of Au/Ag-Cu Ternary Heterostructures for Selective Electrochemical CO2 Reduction.

Copper (Cu)-based nanocatalysts play crucial roles in the electrochemical CO2 reduction reaction (ECO2RR) for sustainable energy resources. Particularly, Cu-based nanostructures incorporating Au and Ag are promising, offering enhanced activity, selectivity, and stability. However, precise control over the structure and composition of heterostructures remains challenging, hindering the development of highly efficient catalysts. Herein, we present a silver (Ag) transition-layer-mediated approach to synthesize ternary heterostructures with two specific morphologies, namely, Au/Ag-Cu-side and Au/Ag-Cu-tip, which exhibit different Ag-Cu interface epitaxial patterns. The two heterostructures achieve high C2 product selectivity in ECO2RR. Especially, the Au/Ag-Cu-side structure achieves 50.3% C2 selectivity with 35.5% ethanol, while the tip structure shows higher ethylene selectivity. Our study reveals the impact of the Ag layer in directing deposition sites on heterostructure growth and further facilitating the design of multicomponent Cu-based catalysts with enhanced structural integrity and ECO2RR performance.

2D Microporous Polymers/Reduced Graphene Oxide with Built-In Lithiophilic Sites for Uniform Lithium Deposition in Lithium Metal Anode.

Lithium (Li) metal is an attractive anode material for use in high-energy lithium-sulfur and lithium-air batteries. However, its practical application is severely impeded by excessive dendrite growth, huge volume changes, and severe side reactions. Herein, a novel Li metal anode composed of lithiophilic two dimensional (2D) conjugated microporous polymer (Li-CMP) and reduced graphene oxide (rGO) sandwiches (Li-CMP@rGO) for Li metal batteries (LiMBs) is reported. In the Li-CMP@rGO anode, the conductive rGO facilitates the charge transfer while the functionalized-CMP provides Li nucleation sites within the micropores, thereby preventing dendrite growth. As a result, the Li-CMP@rGO anode can be cycled smoothly at 6mA cm-2 of current density with a platting capacity of 2 mAh cm-2 for 1000h. A Coulombic efficiency of 98.4% is achieved over 350 cycles with a low overpotential of 28mV. In a full cell with LiFePO4 cathode, the Li-CMP@rGO anode also exhibited good cycling stability compared to CMP@rGO and CMP/Super-P. As expected, the simulation results reveal that Li-CMP@rGO has a strong affinity for Li ions compared to CMP@rGO. The strategies adopted in this work can open new avenues for designing hybrid porous host materials for developing safe and stable Li metal anodes.

In-situ construction of high-performance artificial solid electrolyte interface layer on anode surfaces for anode-free lithium metal batteries

The electrochemical performance of lithium metal batteries (LMBs) was hampered by the uncontrolled growth of lithium (Li) dendrites. To address this issue, the extensive application of artificial solid electrolyte interphase (SEI) coatings on anode surfaces emerged as an effective solution. Electrospinning, as an innovative technique for fabricating artificial SEI layers on the surface of copper (Cu) foil, effectively mitigated Li volume strain during cycling. In this study, an electrospun organic–inorganic composite nanofiber membrane was in-situ fabricated on Cu foil, serving as an artificial SEI layer (CuWs) for anode-free LMBs (AF-LMBs) to enhance battery performance. Lithiophilic polyvinylpyrrolidone was used as the polymer matrix, and Cu nitrate served as the inorganic functional particles capable of in-situ redox reactions. The CuWs with their three-dimensional (3D) network structure accommodated electrode volume changes and suppressed Li dendrite growth during Li deposition and stripping. Additionally, CuWs facilitated the in-situ generation of Li nitrate (LiNO3), which helped stabilize SEI layer and enhance Li utilization. The release sites of LiNO3 on the nanofibers enabled the in-situ reduction of metallic Cu, providing nucleation sites for Li deposition and forming the 3D ion–electron hybrid conductive networks. This CuWs layer reduced interfacial resistance and nucleation barriers, promoting uniform Li+ distribution on the anode surface. Li-Cu cells incorporating CuWs exhibited remarkable cycling stability, enduring over 460 cycles at 1.0 mA cm−2 and 1.0 mAh cm−2 with an average Coulombic efficiency of over 98.6 %. In Li-poor cells, the LFP|PE|CuWs achieved stable cycling for more than 30 cycles at 1.0 C, with a capacity retention rate of 92.0 %. These findings demonstrated that the CuWs membrane significantly enhanced the electrochemical performance of Li-poor cells and provided a novel artificial SEI protective strategy for advanced AF-LMBs with high energy density.

Tailoring Zn2+ Flux by an Ion Acceleration Layer Modified Separator for High-Rate Long-Lasting Zn Metal Anodes.

A large concentration gradient originating from sluggish ion transport on the surface of Zn metal anodes will result in uneven Zn2+ flux, giving rise to severe dendrite growth, especially at high current density. Herein, an ion acceleration layer is introduced by a facile separator engineering strategy to realize modulated Zn2+ flux and dendrite-free deposition. Zinc hexacyanoferrate as the modifying agent featuring strong zincophilicity and rapid diffusion tunnel can enable fast trap for Zn2+ near the electrode surface and immediate transport onto deposition sites, respectively. The ion acceleration effect is substantiated by improved ion conductivity, decreased activated energy, and promoted Zn2+ transference number, which can moderate concentration gradient to guide homogenous Zn2+ flux distribution. As a result, the separator engineering guarantees Zn||Zn symmetrical cells with long-term stability of 2700 h at 2 mA cm-2, and 1770 h at a large current density of 10 mA cm-2. Moreover, cycling stability and rate capability for full cells with different cathodes can be substantially promoted by the modified separator, validating its superior practical feasibility. This study supplies a new scalable approach to tailoring ion flux near the electrode surface to enable robust Zn metal anodes at a high current density.