Highly reversible zinc metal anode enabled by strong Brønsted acid and hydrophobic interfacial chemistry.

Uncontrollable zinc (Zn) plating and hydrogen evolution greatly undermine Zn anode reversibility. Previous electrolyte designs focus on suppressing H2O reactivity, however, the accumulation of alkaline byproducts during battery calendar aging and cycling still deteriorates the battery performance. Here, we present a direct strategy to tackle such problems using a strong Brønsted acid, bis(trifluoromethanesulfonyl)imide (HTFSI), as the electrolyte additive. This approach reformulates battery interfacial chemistry on both electrodes, suppresses continuous corrosion reactions and promotes uniform Zn deposition. The enrichment of hydrophobic TFSI- anions at the Zn|electrolyte interface creates an H2O-deficient micro-environment, thus inhibiting Zn corrosion reactions and inducing a ZnS-rich interphase. This highly acidic electrolyte demonstrates high Zn plating/stripping Coulombic efficiency up to 99.7% at 1 mA cm-2 ( > 99.8% under higher current density and areal capacity). Additionally, Zn | |ZnV6O9 full cells exhibit a high capacity retention of 76.8% after 2000 cycles.

Localized Alkaline Environment via In Situ Electrostatic Confinement for Enhanced CO2-to-Ethylene Conversion in Neutral Medium.

Electrocatalytic CO2 reduction reaction (CO2RR) is one of the most promising routes to facilitate carbon neutrality. An alkaline electrolyte is typically needed to promote the production of valuable multi-carbon molecules (such as ethylene). However, the reaction between CO2 and OH- consumes a significant quantity of CO2/alkali and causes the rapid decay of CO2RR selectivity and stability. Here, we design a catalyst-electrolyte interface with an effective electrostatic confinement of in situ generated OH- to improve ethylene electrosynthesis from CO2 in neutral medium. In situ Raman measurements indicate the direct correlation between ethylene selectivity and the intensities of surface Cu-CO and Cu-OH species, suggesting the promoted C-C coupling with the surface enrichment of OH-. Thus, we report a CO2-to-ethylene Faradaic efficiency (FE) of 70% and a partial current density of 350 mA cm-2 at -0.89 V vs the reversible hydrogen electrode. Furthermore, the system demonstrated a 50 h stable operation at 300 mA cm-2 with an average ethylene FE of ∼68%. This study offers a universal strategy to tune the reaction micro-environment, and a significantly improved ethylene FE of 64.5% was obtained even in acidic electrolytes (pH = 2).

Regulating Frozen Electrolyte Structure with Colloidal Dispersion for Low Temperature Aqueous Batteries.

Electrolyte freezing under low temperatures is a critical challenge for the development of aqueous batteries (ABs). While lowering the freezing point of the electrolyte has caught major research efforts, limited attention has been paid to the structural evolution during the electrolyte freezing process and regulating the frozen electrolyte structure for low temperature ABs. Here, we reveal the formation process of interconnected liquid regions for ion transport in frozen electrolytes with various in situ variable-temperature technologies. More importantly, the low-temperature performance of ABs was significantly improved with the colloidal electrolyte design using graphene oxide quantum dots (GOQDs), which effectively inhibits the growth of ice crystals and expands the interconnected liquid regions for facial ion transport. This work provides new insights and a promising strategy for the electrolyte design of low-temperature ABs.

Plastic Monolithic Mixed-Conducting Interlayer for Dendrite-Free Solid-State Batteries.

Solid-state electrolytes (SSEs) hold a critical role in enabling high-energy-density and safe rechargeable batteries with Li metal anode. Unfortunately, nonuniform lithium deposition and dendrite penetration due to poor interfacial solid-solid contact are hindering their practical applications. Here, solid-state lithium naphthalenide (Li-Naph(s)) is introduced as a plastic monolithic mixed-conducting interlayer (PMMCI) between the garnet electrolyte and the Li anode via a facile cold process. The thin PMMCI shows a well-ordered layered crystalline structure with excellent mixed-conducting capability for both Li+ (4.38 × 10-3  S cm-1 ) and delocalized electrons (1.01 × 10-3  S cm-1 ). In contrast to previous composite interlayers, this monolithic material enables an intrinsically homogenous electric field and Li+ transport at the Li/garnet interface, thus significantly reducing the interfacial resistance and achieving uniform and dendrite-free Li anode plating/stripping. As a result, Li symmetric cells with the PMMCI-modified garnet electrolyte show highly stable cycling for 1200 h at 0.2 mA cm-2 and 500 h at a high current density of 1 mA cm-2 . The findings provide a new interface design strategy for solid-state batteries using monolithic mixed-conducting interlayers.

An Overcrowded Water-Ion Solvation Structure for a Robust Anode Interphase in Aqueous Lithium-Ion Batteries.

The water-in-salt electrolyte (WISE) features intimate interactions between a cation and anion, which induces the formation of an anion-derived solid electrolyte interphase (SEI) and expands the aqueous electrolyte voltage window to >3.0 V. Although further increasing the salt concentration (even to >60 molality (m)) can gradually improve water stability, issues about cost and practical feasibility are concerned. An alternative approach is to intensify ion-solvent interactions in the inner solvation structure by shielding off outward electrostatic attractions from nearby ions. Here, we design an "overcrowded" electrolyte using the non-polar, hydrogen-bonding 1,4-dioxane (DX) as an overcrowding agent, thereby achieving a robust LiF-enriched SEI and wide electrolyte operation window (3.7 V) with a low salt concentration (<2 m). As a result, the electrochemical performance of aqueous Li4Ti5O12/LiMn2O4 full cells can be substantially improved (88.5% capacity retention after 200 cycles, at 0.57 C). This study points out a promising strategy to develop low-cost and stable high-voltage aqueous batteries.

Prevalence of coccidian infection in suckling piglets in China.

To determine the prevalence of coccidian infection in suckling piglets in China, fecal samples from 779 litters of suckling piglets were collected on 80 different farms in 17 provinces from September 2009 to December 2010. These samples were examined through saturated saline flotation technique. The prevalences of coccidian infection ranged from 0 to 32.5% among different provinces and the average was 16.7% (130/779). The highest prevalence of 19.9% (69/346) was found in 8-14 day-old litters of suckling piglets. Seven coccidian species were detected in the positive litters of suckling piglets, including Isospora suis (63.9%), Eimeria debliecki (46.9%), Eimeria polita (19.2%), Eimeria suis (20.8%), Eimeria perminuta (13.9%), Eimeria scabra (4.6%), and Eimeria yanglingensis (1.5%). 55.4% of the positive litters of suckling piglet infected more than one coccidian species. The results of this investigation will provide the relevant basic data for control strategies against porcine coccidiosis on pig farms in China.

Immunogenicity and protective efficacy of two recombinant pseudorabies viruses expressing Toxoplasma gondii SAG1 and MIC3 proteins.

Toxoplasma gondii is one of the most common parasitic pathogens in humans and warm-blooded animals, causing toxoplasmosis. One of the efficient ways to control this disease is immunization. In this study, two recombinant pseudorabies virus (PRV) expressing TgSAG1 (rPRV-SAG1) and TgMIC3 (rPRV-MIC3) based on the PRV vaccine strain were developed by homologous recombination and used for immunizing BALB/c mice. Ninety BALB/c mice were randomly divided into five groups including four experimental groups (inoculated twice in 4 weeks interval with PRV TK-/gG-/EGFP+, rPRV-SAG1, rPRV-MIC3, rPRV-SAG1+rPRV-MIC3, respectively) and one control group (inoculated with medium). All mice vaccinated with rPRV developed a high level of specific antibody responses against T. gondii lysate antigen (TLA), a strong increase of the splenocyte proliferative response, and significant levels of IFN-γ and IL-2 production. These results demonstrated that rPRV could induce significant humoral and cellular Th1 immune responses. Moreover, rPRV immunization induced partial protection against a lethal challenge with T. gondii RH strain, and neutralizing antibodies against PRV in a BALB/c mouse model. The mice immunized with the rPRV-SAG1 and rPRV-MIC3 cocktail could develop higher T. gondii-specific IgG antibodies and lymphocyte proliferative responses and conferred more efficient protection against T. gondii challenge. These results suggested that expression of protective antigens of T. gondii in PRV is a novel approach towards the development of a vaccine against both animal pseudorabies and toxoplasmosis.