Electrocapacitive Deionization: Mechanisms,Electrodes, and Cell Designs

Capacitive deionization (CDI) is an emerging water desalination technology for removing different ionic species from water, which is based on electric charge compensation by these charged species. CDI is becoming popular because it is more energy-efficient and cost-effective than other technologies, such as reverse osmosis and distillation, specifically in dealing with brackish water having low or moderate salt concentrations. Over the past decade, the CDI research field has witnessed significant advances in the used electrode materials, cell architectures, and associated mechanisms for desalination applications. This review article first discusses ion storage/removal mechanisms in carbon and Faradaic materials aided by advanced in situ analysis techniques and computations. It then summarizes research progress toward electrode materials in terms of structure, surface chemistry, and composition. More still, it discusses CDI cell architectures by highlighting their different cell design concepts. Finally, current challenges and future research directions are summarized to provide guidelines for future CDI research.     

Symmetry Breaking in Monometallic Nanocrystals toward Broadband and Direct Electron Transfer Enhanced Plasmonic Photocatalysis

Metallic nanocrystals manifest themselves as fascinating light absorbers for applications in plasmon-enhanced photocatalysis and solar energy harvesting. The essential challenges lie in harvesting the full-spectrum solar light and harnessing the plasmon-induced hot carriers at the metal–acceptor interface. To this end, a cooperative overpotential and underpotential deposition strategy is proposed to mitigate both the challenges. Specifically, by utilizing both ionic additive and thiol passivator to introduce symmetry-breaking growth over gold icosahedral nanocrystals, the microscopic origin can be attributed to the site-specific nucleation of stacking faults and dislocations. By adopting asymmetric crystal shape and unique surface facets, such nanocrystals attain high activity toward photocatalytic ammonia borane hydrolysis, arising from combined broadband plasmonic properties and enhanced direct transfer of hot electrons across the metal–adsorbate interface.     

Heterogeneous Bimetallic Mo-NiPx/NiSy as a Highly Efficient Electrocatalyst for Robust Overall Water Splitting

Highly efficient electrocatalysts composed of earth-abundant elements are desired for water-splitting to produce clean and renewable chemical fuel. Herein, a heteroatomic-doped multi-phase Mo-doped nickel phosphide/nickel sulfide (Mo-NiP_x/NiS_y) nanowire electrocatalyst is designed by a successive phosphorization and sulfuration method for boosting overall water splitting (both oxygen and hydrogen evolution reactions (HER)) in alkaline solution. As expected, the Mo-NiP_x/NiS_y electrode possesses low overpotentials both at low and high current densities in HER, while the Mo-NiP_x/NiS_y heterostructure exhibits high active performance with ultra-low overpotentials of 137, 182, and 250 mV at the current density of 10, 100, and 400 mA cm⁻² in 1 m KOH solution, respectively, in oxygen evolution reaction. In particular, the as-prepared Mo-NiP_x/NiS_y electrodes exhibit remarkable full water splitting performance at both low and high current densities of 10, 100, and 400 mA cm⁻² with 1.42, 1.70, and 2.36 V, respectively, which is comparable to commercial electrolysis.     

Ultrasonic Cavitation-Assisted and Acid-Activated Transcytosis of Liposomes for Universal Active Tumor Penetration

Active tumor penetration has been recently recognized as a promising strategy to resolve the limitation of nanomedicine in terms of tumor penetration, but it is challenging to develop active transporting nanocarriers. Here, an ultrasonic cavitation-assisted and acid-activatable active transporting liposome for a broad range of tumors is reported. The active transporting liposome (size and charge dual-conversional gemcitabine prodrug-integrated liposomal nanodroplet (SCGLN)) overcomes the tight blood vessel walls with the aid of ultrasonic cavitation. The SCGLN subsequently transforms from micro-size to nano-size under prolonged ultrasound radiation. Once in the acidic tumor microenvironment, the nanosized SCGLN undergoes negative-to-positive charge-reversal and triggers the cationization-initiated transcytosis to penetrate deep into tumor parenchyma. The gemcitabine-loaded SCGLN exhibits potent antitumor activity in multiple poorly permeable tumor models, which completely erases subcutaneous U251 glioma and stops the progression of orthotopic BxPC3 pancreatic ductal adenocarcinoma. This study presents a promising and universal strategy to develop active penetrating nanomedicines for efficient drug delivery in the low permeable tumor.     

三维点云中关键点的配准与优化算法

传统三维(3D)点云配准过程中存在配准误差高、计算量大及耗时长等问题,针对该问题,提出了一种3D点云中关键点的配准与优化算法.在关键点选取阶段,用边缘点检测算法剔除边缘关键点,以提高关键点特征描述的全面性和重复性,降低3D点云配准误差.在3D点云配准阶段,用K-维树(KD-tree)加速的最近邻算法和迭代最近点算法剔除...     

SDN协同控制器的智能内生技术研究与实现

面对业务多样化、数据海量化、云网一体化等新需求新挑战,云网运营的思路和方式都在发生着变革,SDN控制器作为新一代云网运营系统的核心能力,与人工智能技术深度融合,研究意图解析、云网智能感知、保障、优化与自动执行的全流程闭环自治能力关键技术与应用实践,形成SDN控制器的智能内生能力。首先,阐明了SDN控制器智能内生研发的背景与意义;其次,说明了智能内生的能力架构及核心能力分布,逐步形成全流程闭环的云网自治;最后,聚焦5G切片、SRv6新业务新技术的场景用例,进一步解析了在智能感知、自主保障、自动优化等方面的重点技术及应用效果。通过关键能力研发、实施验证及技术标准化, SDN控制器智能内生技术逐步成熟,赋能云网智慧运营。     

pH‐Responsive,Light‐Triggered on‐Demand Antibiotic Release from Functional Metal–Organic Framework for Bacterial Infection Combination Therapy

To satisfy the ever‐growing demand in bacterial infection therapy and other fields of science, great effort is being devoted to the development of methods to precisely control drug release and achieve targeted use of an active substance at the right time and place. Here, a new strategy for bacterial infection combination therapy based on the light‐responsive zeolitic imidazolate framework (ZIF) is reported. A pH‐jump reagent is modified into the porous structure of ZIF nanoparticles as a gatekeeper, allowing the UV‐light (365 nm) responsive in situ production of acid, which subsequently induces pH‐dependent degradation of ZIF and promotes the release of the antibiotic loaded in the mesopores. The combination of the UV‐light, the pH‐triggered precise antibiotic release, and the zinc ions enables the light‐activated nanocomposite to significantly inhibit bacteria‐induced wound infection and accelerate wound healing, indicating a switchable and synergistic antibacterial effect. The light irradiated accumulation of acid ensures the controlled release of antibiotic and controlled degradation of ZIF, suggesting the therapeutic potential of the metal–organic frameworks‐based smart platform for controlling bacterial infection.     

Gold Nanorods Electrostatically Binding Nucleic Acid Probe for In Vivo MicroRNA Amplified Detection and Photoacoustic Imaging‐Guided Photothermal Therapy

Developing a comprehensive platform which has both diagnosis and therapeutic strategies is necessary for efficient tumor treatment. In this work, a F uel I mproved micro R NA E xplorer (FIRE) probe with signal amplification capability is designed for sensitive detection of microRNA‐21 (miR‐21), which is upregulated in most tumor cells. Besides, FIRE could be loaded by polyethylenimine (PEI)‐modified gold nanorods (AuNR‐PEI) via facile electrostatic interaction, which could avoid the complicated processes commonly used to covalently conjugate nucleic acid probes onto AuNRs. The as‐fabricated AuNR‐PEI/FIRE system could efficiently distinguish tumor cells from non‐tumor cells. The fluorescence signals in MCF‐7 breast carcinoma and HeLa cervical carcinoma cells treated with AuNR‐PEI/FIRE are enhanced 7‐ and 4.5‐fold, respectively, compared with non‐amplification system. AuNR‐PEI/FIRE improves tumor detection ability in vivo and exhibits excellent tumor inhibition efficacy under the fluorescence imaging and photoacoustic imaging guided photothermal therapy. This is the first time to utilize the combined application of amplified nucleic acid detection and photothermal effect derived from gold nanorods together with PA imaging in a facile manner to provide a promising theranostic strategy for accurate diagnosis and tumor therapy.