Lithium Deposition Mechanism under Different Thermal Conditions Unraveled via an Optimized Phase Field Model.

As one of the most important physical fields for battery operation, the regulatory effect of temperature on the growth of lithium dendrites should be studied. In this paper, we develop an optimized phase field model to explore the effect of temperature on the growth of Li dendrites in Li metal batteries. We incorporated full lithium deposition kinetics, including atom diffusion and solid electrolyte interface restriction on interface kinetics, into the model and revealed their significance in determining the transformation of the lithium deposition morphology from moss-like to dendrite-like.

Surface Nd Sites Boost Charge Transfer of FeO Photoanodes for Enhanced Solar Water Oxidation.

Photoelectrochemical (PEC) water splitting for hydrogen production is a promising technology for sustainable energy generation. In this work, we introduce Nd sites boost the PEC performance of FeO photoanodes through a precise gas-phase cation exchange process, which substitutes surface Fe atoms with Nd. The incorporation of Nd significantly enhances charge transfer properties, increases carrier concentration, and reduces internal resistance, leading to a substantial increase in photocurrent density from 0.

Polarization Switching from Valence Trapping in an Oxo-Bridged Trinuclear Iron Complex.

Switching electric polarization by external stimuli constitutes a technical foundation for various applications. Here, we reported the observation of polarization-switching behavior in an oxo-bridged mixed-valence complex [FeO(piv)(py)] (piv = pivalate, py = pyridine). Detailed variable-temperature Mössbauer spectral analyses unambiguously confirm the occurrence of an electron localization-delocalization transition between two inequivalent Fe sites.

Positive Feedback Regulation between KLF5 and XPO1 Promotes Cell Cycle Progression of Basal like Breast Cancer.

Basal-like breast cancer (BLBC), overlapping with the subgroup of estrogen receptor (ER), progesterone receptor (PR), and HER2 triple-negative breast cancer, has the worst prognosis and limited therapeutics. The XPO1 gene encodes nuclear export protein 1, a promising anticancer target which mediates nucleus-cytoplasm transport of nuclear export signal containing proteins such as tumor suppressor RB1 and some RNAs. Despite drugs targeting XPO1 are used in clinical, the regulation of XPO1 expression and functional mechanism is poorly understood, especially in BLBC.

Reliability and Validity of the Consultation and Relational Empathy (CARE) Scale.

Background: The patient's perception of physician empathy has a positive influence on patient behavior and treatment effects. The scale of Consultation and Relational Empathy (CARE) scale has been widely used to measure patients' perceptions of doctor empathy. However, the CARE scale lacks a standardized Mandarin version.

Assessment of the Properties and Mechanism of Three Lotus (Nelumbo nucifera Gaertn.) Parts for Sleep Improvement.

Lotus leaves (LL), petals (LP), and seeds (LS) are believed to have properties that can improve sleep. However, their efficacy in improving sleep has not been fully validated. This study aimed to investigate the multitarget mechanisms of extracts from these lotus parts for sleep improvement using chemical analysis, bioactivity assessment, meta-analysis, network pharmacology evaluation, and molecular docking.

A Triple-Responsive and Dual-NIR Emissive Fluorescence Probe for Precise Cancer Imaging and Therapy by Activating Pyroptosis Pathway.

Revealing changes in the tumor microenvironment is crucial for understanding cancer and developing sensitive methods for precise cancer imaging and diagnosis. Intracellular hydrogen peroxide (HO) and microenvironmental factors (e.g.

Capturing High-Energy Polymeric Nitrogen Structures Stabilized by Lutetium at Ambient Conditions.

Polynitrogen with high energy and environmental friendliness has exhibited potential application in military and civilian fields. In this study, first-principle calculations were employed to conduct a comprehensive investigation of the nitrogen-rich Lu-N compounds. The research yielded ten novel polynitrides: 2/-LuN, 1̅-LuN, 1̅-LuN, 2/-LuN, 1̅-LuN, 1̅-LuN, 1̅-LuN, -LuN, 4/-LuN, and -LuN.

Integrating physiological, metabolome and transcriptome revealed the response of maize seeds to combined cold and high soil moisture stresses.

Combined cold and high moisture stress (CHS) is a prevalent abiotic stress during maize sowing in northeast China, severely affecting the growth of seedlings and seed germination. However, the mechanism underlying seed growth responses to CHS remains unclear. We used Jidan441 (JD441, CHS-resistant) and Jidan558 (JD558, CHS-sensitive) as experimental materials.

Enabling high-performance multivalent metal-ion batteries: current advances and future prospects.

The battery market is primarily dominated by lithium technology, which faces severe challenges because of the low abundance and high cost of lithium metal. In this regard, multivalent metal-ion batteries (MVIBs) enabled by multivalent metal ions ( Zn, Mg, Ca, Al, ) have received great attention as an alternative to traditional lithium-ion batteries (Li-ion batteries) due to the high abundance and low cost of multivalent metals, high safety and higher volumetric capacities. However, the successful application of these battery chemistries requires careful control over electrode and electrolyte chemistries due to the higher charge density and slower kinetics of multivalent metal ions, structural instability of the electrode materials, and interfacial resistance, This review comprehensively explores the recent advancements in electrode and electrolyte materials as well as separators for MVIBs, highlighting the potential of MVIBs to outperform Li-ion batteries regarding cost, energy density and safety.

The Negative Role of Proton Insertion on the Lifetime of Vanadium-Based Aqueous Zinc Batteries.

Vanadium oxides are attracted cathodes for aqueous zinc batteries owing to their high capacity. However, the limited cyclability of vanadium-based oxide cathodes, especially at low current densities, impedes their practical application. Here, it is revealed that proton insertion is responsible for the limited lifetime of vanadium oxides.

Circularly Polarized Organic Light-Emitting Diode Based on Device Functional Layer Materials.

Circularly polarized light-emitting devices have found extensive application prospects in 3D displays and optoelectronic information. Among them, circularly polarized organic light-emitting diodes (CP-OLED), as a rising star of circularly polarized light-emitting devices, achieved good research results. However, the preparation of CP-OLED with a high electroluminescence asymmetry factor and high external quantum efficiency is a hot and difficult research topic.

Supramolecular Modulation of Tumor Microenvironment Through Host-Guest Recognition and Metal Coordination to Potentiate Cancer Chemoimmunotherapy.

The massive amount of indoleamine 2,3-dioxygenase 1 (IDO-1) in tumor cells and tumor-associated immune cells forms a feedback loop that maintains immunosuppressive tumor microenvironment (ITM) and causes immune escape, resulting in the poor prognosis of platinum chemotherapeutics. However, the effective systemic administration of platinum drugs and IDO-1 inhibitors is strictly limited by their distinct chemical construction, different pharmacokinetic profiles, and heterogeneous distributions. Herein, a novel supramolecular method with the capability to modulate tumor microenvironment is proposed aiming at potentiating the antitumor efficacy of chemoimmunotherapy.

Nuclear to Cytoplasmic Transport Is a Druggable Dependency in HDAC7-driven Small Cell Lung Cancer.

Immunotherapy has gained approval for use in small cell lung cancer (SCLC), yet only a subset of patients (10-20%) experience meaningful benefits, underscoring the urgent need for more effective therapeutic approaches. This work discovers a distinct HDAC7-high SCLC phenotype characterized by enhanced proliferative potential, which recurs across various subtypes and serves as a predictor of poorer survival outcomes. By analyzing public datasets, this work finds a strong correlation between c-Myc and HDAC7.

Multiscale Collaborative Optimization for Composite Solid Electrolyte to Achieve High-Performance Lithium Metal Batteries.

Composite solid electrolytes (CSEs) possess significant advantages over individual polymer or inorganic solid electrolytes. However, conventional CSEs suffer from multiple scale issues, including interruptions in ionic transport pathways, incompatibility at heterogeneous interface, and the excessive thickness of electrolytes. Herein, a novel CSE with ultrathin structure (22 µm) based on the strategy of multiscale collaborative optimization (MC-CSE) is designed.

PRDX6 Prevents NNMT Ubiquitination and Degradation as a Nonenzymatic Mechanism to Promote Ovarian Cancer Progression.

Cancer cells cope with oxidative stress for their proliferation and metastasis by equipping antioxidant systems, among which the antioxidant enzymes peroxiredoxins (PRDXs) play crucial roles. However, whether PRDXs exhibit nonenzymatic functions remains unclear. Here, it is shown that the 1-cysteine PRDX (PRDX6) upregulates nicotinamide N-methyltransferase (NNMT) to promote the growth and metastasis of ovarian cancer cells, independently of PRDX6's enzymatic activities.

Untwisting Strategy of MOF Nanosheets in Ultrathin Film Membrane for High Molecular Separation Performance.

Oriented 2D metal-organic framework (MOF) membranes hold considerable promise for industrial separation processes. Nevertheless, the lattice misalignment caused by the twisted stacking of 2D nanosheets reduces the in-plane pore size and exerts a significant impact on the membrane separation performance. Precisely regulating the stacking pattern of oriented 2D MOF membranes remains a significant challenge.

In Operando Raman Spectroscopy Reveals Li-Ion Solvation in Lithium Metal Batteries.

Inhomogeneous lithium (Li) deposition and unstable solid electrolyte interphase are the main causes of short cycle life and safety issues in Li metal batteries (LMBs). Developing a 3D structured matrix current collector and novel electrolyte are feasible strategies to tackle these issues. Ether-based electrolytes are widely used in LMBs.

Gelatin-Induced Synthesis of Strain-Engineered Spherical CuO Nanoparticles for Efficient Nitrate Reduction to Ammonia.

The electrochemical reduction of nitrate to ammonia offers an environmentally sustainable pathway for nitrogen fixation. However, achieving both efficiency and selectivity in nitrate reduction presents a formidable challenge, due to the involvement of sluggish multielectron transfer processes. Herein, the successful synthesis of spherical Cu₂O nanoparticles (s-Cu₂O) exhibiting significant compressive strain effects, achieved through a one-pot method using gelatin as a structural modifier, is reported.

Cranial bone maneuver ameliorates Alzheimer's disease pathology via enhancing meningeal lymphatic drainage function.

Introduction: Alzheimer's disease (AD) is a progressive neurodegenerative disease and the leading cause of dementia. Recent research highlights meningeal lymphatics as key regulators in neurological diseases, suggesting that enhancing their drainage function could be a potential therapeutic strategy for AD. Our proof-of-concept study demonstrated that cranial bone transport can improve meningeal lymphatic drainage function and promote ischemic stroke recovery.

Solar-Driven Conversion of Nitrogen and Water to Solid Fertilizer in an Outdoor 1 m Panel Reactor.

Harnessing solar energy to convert molecular N into nitrogen-rich chemicals (e.g., ammonia) provides a potential pathway for the manufacture of "solar fertilizers".

Effectively Guiding Cell Elongation and Alignment by Constructing Micro/Nano Hierarchical Patterned Titania on Titanium Substrate.

Based on the innate sensitivity of cell to substrate topographical cues, modulating cell-directed growth behavior is crucial for promoting tissue repair and reconstruction. Although photolithography technology has been extensively employed to fabricate a variety of anisotropic patterned structures to guide cell growth, it remains a great challenge to design high-resolution micro/nano hierarchical structures directly onto medical titanium (Ti)-based implants. Herein, we present a rapid, reliable and reproducible approach combining photolithography and hydrothermal technology to construct a micro/nano hierarchical structure including anisotropic micro-strips and a porous structure composed of TiO nanotubes features.

Precursor-Induced Growth of Highly-Oriented Nanowire Arrays.

The unique optical, electrical, and thermal properties of 1D nanowires have sparked significant interest in growing high-quality 1D materials. Nanowire arrays and aligned growth offer scalability and maintain anisotropic properties, making them promising for research and applications. However, mass-producing high-quality nanowire arrays remains a challenge.

Targeting Mesothelin Enhances Personalized Neoantigen Vaccine Induced Antitumor Immune Response in Orthotopic Pancreatic Cancer Mouse Models.

The immunosuppressive microenvironment in pancreatic cancer, characterized by low tumor-specific T cells and excessive fibrosis, limits the effectiveness of immunotherapy. Here, three datasets and multi-immunofluorescence staining of tissue microarrays in pancreatic cancer indicate that mesothelin (MSLN) expression negatively correlates with cytotoxic T cells in tumor. Anti-MSLN antibody (αMSLN) treatment of pancreatic cancer in vivo can significantly increase T cell infiltration.

Inversion of Circularly Polarized Luminescence in the Left-Handed Chitosan-Templated Co-assemblies.

Circularly polarized luminescence (CPL) materials are attractive due to their unique applications in fields such as 3D displays, information encryption, and chiroptical switches. Natural biomolecules-based CPL materials are gaining plenty of attention due to their chiral diversity and sustainability. However, it is still challenging to construct CPL materials with opposite CPL signs from a single natural biomolecule due to its inherent chirality.