不同形貌纳米SnO2的可控合成及催化发光传感器

本文以碳纳米管(CNT)为模板、采用液相沉积法、通过改变煅烧温度可控合成了SnO2-CNT复合纳米材料、SnO2纳米棒、SnO2纳米粒子等3种形貌的SnO2纳米材料,研究了3种形貌的SnO2纳米材料对乙酸乙酯催化发光的影响;通过考察3种不同形貌SnO2纳米材料的纳米尺度和结构,讨论了影响纳米材料催化发光特性的因素;研究了3种不同形貌SnO2纳米材料对乙酸乙酯催化发光图谱和强度的变化,建立了3种新型、高效的不同形貌纳米催化发光传感器。     

基于细胞仿生矿化合成纳米材料及其应用

近年来,随着纳米科学技术的发展,纳米材料的“绿色合成方法”研究显得愈发重要。基于细胞活体及其分泌物模拟生物矿化合成纳米材料已成为绿色合成纳米材料的研究前沿。该方法具有操作简单、安全经济和环境友好等优点,合成得到的纳米材料具有良好的分散性、稳定性和特殊的性能。该方法得到的纳米材料已在化学、材料学、生物医学等领域展现出了广泛的应用前景,引起了人们的极大关注。本文综述了应用细菌、真菌、植物及人体细胞等活体细胞或分泌物仿生矿化合成各种形貌及不同尺寸的无机纳米结构材料的研究进展;着重评述了纳米材料的仿生矿化合成方法、合成机制以及应用研究现状与前景,并对纳米材料基于细胞合成技术的发展趋势进行了展望。     

手性模板合成CdS纳米棒

由于纳米材料具有量子尺寸效应及大的比表面积等性质而使其在电子学[1]、光学[2]、催化[3]和陶瓷[4]等领域显示出诱人的应用前景. 近年来纳米材料的制备及纳米技术发展迅速, 特别是具有特殊光电活性的新型无机纳米材料的制备已引起人们的普遍关注. 现在合成纳米材料的方法主要包括反相胶束法[5]、 LB膜法[6]、嵌段共聚物法[7]和模板合成法[8]. 其中模板合成技术不仅可以通过设计新型的模板分子, 还可通过模板分子的不同自组装行为来调控纳米材料的尺寸和形貌. Stupp等[9]曾利用溶致液晶的六方中间相作为模板, 在其纳米孔隙中成功地合成了具有六方排列超晶格纳米结构的材料. 本文以双亲性丙氨酸衍生物为模板, 在不同的化学微环境下合成了结构不同的CdS纳米棒.     

电荷驱动水中氧化物纳米颗粒自组装的原位透射电子显微镜研究

<正>由于氧化物纳米材料具有较大的比表面积和表面活性,因此被广泛地应用于催化、能源储存、纳米器件等各种领域。人们通过各种不同的合成技术手段,实现对氧化物纳米材料表面形貌进行调控,进而获得具有优异性能的纳米材料。在各种纳米材料合成手段中,可控性自组装技术是一种有效调控纳米材料尺寸及形貌特征的方法,在纳米材料的合成以及制备方面具有较大的应用潜力1。纳米颗粒的自组装过程及其自组装的结构形态特征,常常受到纳米颗粒之间的范德华力、氢键、静电力、疏水性、偶极矩等相互作用的影响2–5。     

无机纳米晶的形貌调控及生长机理研究

形貌及尺寸规整可控的纳米晶体的合成是目前十分引人注目的纳米材料研究领域．制备合成中的形貌调控及其功能化是这些纳米材料能够得到应用的关键问题．研究者们希望在纳米晶的任一阶段均能实现控制并在期望的阶段停止,从而得到尺寸、形态、结构及组成确定的纳米晶体．本文综述了近年来无机纳米晶体的典型合成路径,深入探讨了纳米晶在成核、生长及熟化阶段的控制原理,研究了液相合成纳米材料过程中晶体结构与生长行为的相关性问题,并总结了几类具有代表性的低维、多维纳米晶体的形成规律和生长机理．探索纳米粒子的调控合成对于纳米材料的规模化生产及应用具有重要的理论价值和指导意义．     

贵金属杂化纳米材料的合成及性能研究进展

近年来,杂化纳米材料的出现极大地拓展了纳米材料的应用范围,其特殊的结构、性能、尺寸和形貌使其不仅保持了各组分材料的特性及功能,更涌现了不同于各组分材料所不具备的新颖的、多样化的特殊性能和应用潜能,因此其制备方法和性能应用已经成为了研究热点.运用纳米技术将贵金属纳米粒子与其他性能优异的物质结合形成的贵金属杂化纳米材料被广泛运用到电化学、光催化、免疫传感、生物催化和医药化学等领域.本文综述了贵金属杂化纳米材料的制备方法、结构组成、性能特点、应用前景以及最新的发展趋势,重点介绍了贵金属杂化纳米材料的合成及应用.     

一种新型纺锤状α-Fe_2O_3纳米晶的合成、表征及其表面性能(英文)

合成了一种新型的具有单晶结构的α-Fe2O3纳米晶(NFO-1).在我们的合成方法中,样品的形貌和结构在低反应浓度体系中运用无机盐和有机模板进行双重调控,同时用溶剂挥发诱导自组装(EISA)来加速反应和在不改变形貌结构的前提下获得高产率样品.所得α-Fe2O3纳米晶的形貌和结构对其表面修饰功能有明显的影响,NFO-1因其特殊的纺锤状形貌而与表面功能试剂(多巴胺)之间的化学作用有明显的增强.并且,本文所描述的合成方法同样适用于其他过渡金属氧化物纳米单晶的合成.我们预期,这种方法可为新型纳米材料的合成提供新的途径.     

基于纳米SnO2材料的二维纳米催化发光传感器研制及其测定甲基叔丁基醚的应用

以碳纳米管(CNT)为模板,采用液相沉积法可控合成了SnO2-CNT复合纳米材料、SnO2纳米棒两种形貌的SnO2纳米材料,研究了它们对甲醇、MTBE催化发光的影响.通过考察两种不同形貌SnO2纳米材料的结构、比表面积与其催化发光的关系,建立了一种二维纳米催化发光传感器,并测定了MTBE产品的纯度和其中的甲醇含量,甲醇...     

微乳法制备Co3O4纳米材料及其形成机理研究

采用Co(NH3)6Cl3为钴源,利用微乳法制备了Co3O4的纳米材料,可控合成了尺寸均一的边长约40～50 nm纳米立方和直径约400 nm的纳米球.并且考察了反应条件对产物形貌的影响,水与CTAB的摩尔比(w)和反应物浓度对产物形貌有着很大的影响,而反应温度对产物形貌基本没有影响.随着w值的增加,合成的纳米材料的尺...     

多孔朵状Fe_3O_4纳米微球的制备及其性能研究

<正>众所周知,纳米材料的尺寸大小、晶型、形貌构型等结构特征对材料的化学物理性能有重要的影响[1],由于特殊形貌的新材料所具有独特、新颖、高效的化学物理等方面的性质以及在众多领域中的潜在应用[2],特别是3D花状空心纳米结构新物质[3-4],新形貌物质的纳米材料的制备方法和应用特性已经吸引了世界上材料领域的广泛兴趣和关注[5]。目前为止,合成3D纳米结构的方法有自组装法、三维导向连接法以及水热法等,即通过使用有     

The art of two-dimensional soft nanomaterials

The discovery of graphene has triggered the explosive development of two-dimensional(2D) nanomaterials, including both inorganic and organic species. Benefiting from the simple elemental composition, inorganic 2D nanomaterials were the center research in the past decade, which has long shadowed the research of 2D organic(or soft) nanomaterials. Although many kinds of2D soft nanomaterials have been successfully prepared, a unified definition for them is still impossible due to the complicate and quite different chemical structures between each other and even relying on totally different techniques to distinguish them. Since our first review on 2D soft nanomaterials in 2015, this field has moved forward with big success. In this review, we will focus on the development of 2D soft nanomaterials after 2015. In order to deliver better overview of this field, new and comprehensive classification is used in this review: 2D aromatic molecules, graphene and graphene nanoribbons, graphyne and graphdiyne,BxCyNznanosheets, 2D polymers, 2D supramolecules, crystalline 2D assemblies, 2D covalent organic frameworks, 2D metalorganic frameworks, sandwich-like 2D porous polymers, 2D polymer nanosheets, etc. The focus of this review lies on synthetic strategies and the challenges of characterization, definition and fundamental understanding.     

Phase engineering two-dimensional nanostructures for electrocatalytic hydrogen evolution reaction

Hydrogen(H₂) is considered to be a promising substitute for fossil fuels. Two-dimensional(2D) nanomaterials have exhibited an efficient electrocatalytic capacity to catalyze hydrogen evolution reaction(HER).Particularly, phase engineering of 2D nanomaterials is opening a novel research direction to endow 2D nanostructures with fascinating properties for deep applications in catalyzing HER. In this review, we briefly summarize the research progress and present the current challenges on...     

《新型二维纳米材料》专辑序言——新型二维纳米材料:掀起未来技术革命

Two-dimensional(2D) nanomaterials possess sheet-like structures with the thickness of nanoscale, but the lateral size is infinite. In 2004, Andre Geim and co-workers at the University of Manchester successfully exfoliated a sheet of graphene from graphite by the micromechanical cleavage technique, which marked the beginning of 2D nanomaterials. Given the ultrahigh carrier mobility, excellent mechanical property, good thermal stability, superior thermal conductivities and huge specific surface area of graphene, it causes general exploration of other graphene-like 2D nanomaterials.===The 2D feature is unique to access unprecedented physical, chemical, electronic and optical properties. For example, the electron confinement in two dimensions makes them ideal candidates for the fundamental study in condensed matter physics and electronic/optoelectronic devices; the large lateral size endows them with huge surface area and high exposure of active sites. Due to their unique properties, 2D nanomaterials have promising applications in energy storage and conversion, electronic devices, catalytic reaction, sensing and biomedicine. By now, nearly 20 types of 2D nanomaterials have been studied, such as graphene, graphitic carbon nitride(g-C₃N₄), transition metal dichalcogenides(TMDs), transition metal carbides/nitrides(MXenes), layered double hydroxides(LDHs), transition metal oxides(TMOs), Ⅲ to Ⅵ layered semiconductor(MX₄), and perovskite-type hybrids(AMX₃).===In this special issue of the novel 2D nanomaterials, we selected 12 related articles in reviews, research papers and brief communications involving supercapacitor, electrochemical catalysis, sensing, battery, fluorescence, water treatment and antiflaming performance of 2D nanomaterials. We hope that readers will have a deep understanding of the current development of 2D nanomaterials, and find it beneficial to their future researches.===Toward this end, I greatly appreciate the outstanding contribution of all authors, as well as the strenuous efforts from the editorial staff members.     

Two-dimensional transition metal chalcogenide nanomaterials for cancer diagnosis and treatment

For more than a decade, the exfoliation of graphene and other layered materials has led to a tremendous amount of research in two-dimensional (2D) materials, among which 2D transition metal chalcogenides (TMCs) nanomaterials have attracted much attention in a wide range of applications including photoelectric devices, lithium-ion batteries, catalysis, and energy conversion and storage owing to their unique photoelectric physical properties. With such large specific surface area, strong near-infrared (NIR) absorption and abundant chemical element composition, 2D TMCs nanomaterials have become good candidates in biomedical imaging and cancer treatment. This review systematically summarizes recent progress on 2D TMCs nanomaterials, which includes their synthesis methods and applications in cancer treatment. At the end of this review, we also highlight the future prospects and challenges of 2D TMCs nanomaterials. It is expected that this work can provide the readers with a detailed overview of the synthesis of 2D TMCs and inspire more novel functional biomaterials based on 2D TMCs for cancer treatment in the future.     

Exfoliation of 2D Materials for Energy and Environmental Applications

The fascinating properties of single-layer graphene isolated by mechanical exfoliation have inspired extensive research efforts toward two-dimensional (2D) materials. Layered compounds serve as precursors for atomically thin 2D materials (briefly, 2D nanomaterials) owing to their strong intraplane chemical bonding but weak interplane van der Waals interactions. There are newly emerging 2D materials beyond graphene, and it is becoming increasingly important to develop cost-effective, scalable methods for producing 2D nanomaterials with controlled microstructures and properties. The variety of developed synthetic techniques can be categorized into two classes: bottom-up and top-down approaches. Of top-down approaches, the exfoliation of bulk 2D materials into single or few layers is the most common. This review highlights chemical and physical exfoliation methods that allow for the production of 2D nanomaterials in large quantities. In addition, remarkable examples of utilizing exfoliated 2D nanomaterials in energy and environmental applications are introduced.     

Electrochemiluminescence bioassays based on carbon nitride nanomaterials and 2D transition metal carbides

Electrochemiluminescence (ECL) is a powerful technique for bioassays. To meet the growing demand for bioassays, it is necessary to develop new ECL emitters and co-reaction acceleration strategies to improve detection sensitivity and expand the application scope. Carbon nitride nanomaterials and 2D transition metal carbides, as newly emerging carbon-based nanomaterials, have been increasingly used for ECL bioassays due to their attractive optical and electrochemical properties as well as diversity. In this minireview, we summarized the latest advances in ECL bioassays using carbon nitride nanomaterials and 2D transition metal carbides in the past two years. Finally, we briefly discuss the future trends and challenges of carbon-based nanomaterials for ECL bioanalysis.     

一维铁磁金属纳米材料的制备、结构调控及其磁性能

一维铁磁金属纳米材料不但具有普通纳米粒子的各种特殊效应,而且具有独特的形状各向异性和磁各向异性,是构筑新型电磁功能材料的重要组元,在高密度磁记录、敏感元器件、电磁波吸收、催化剂、医学和生物功能材料等领域具有重要的应用。本文以一维铁磁金属纳米材料的制备技术为评述线索,重点论述了一维铁磁金属纳米材料的形貌参数（包括直径、长度、长径比）,晶面取向等微观结构的调控方法以及结构对磁性能的影响规律,指出发展新型的一维铁磁纳米材料的结构控制方法,研究一维材料的定向排布及组装技术,并从更深层次揭示一维结构与性能的关系以及开发一维铁磁纳米材料在各领域的实际应用是未来研究的主要发展方向。     

Two-Dimensional Nanomaterials for Photothermal Therapy

Two-dimensional (2D) nanomaterials are currently explored as novel photothermal agents because of their ultrathin structure, high specific surface area, and unique optoelectronic properties. In addition to single photothermal therapy (PTT), 2D nanomaterials have demonstrated significant potential in PTT-based synergistic therapies. In this Minireview, we summarize the recent progress in 2D nanomaterials for enhanced photothermal cancer therapy over the last five years. Their unique optical properties, typical synthesis methods, and surface modification are also covered. Emphasis is placed on their PTT and PTT-synergized chemotherapy, photodynamic therapy, and immunotherapy. The major challenges of 2D photothermal agents are addressed and the promising prospects are also presented.     

Two‐Dimensional Nanomaterials for Photothermal Therapy

Two‐dimensional (2D) nanomaterials are currently explored as novel photothermal agents because of their ultrathin structure, high specific surface area, and unique optoelectronic properties. In addition to single photothermal therapy (PTT), 2D nanomaterials have demonstrated significant potential in PTT‐based synergistic therapies. In this Minireview, we summarize the recent progress in 2D nanomaterials for enhanced photothermal cancer therapy over the last five years. Their unique optical properties, typical synthesis methods, and surface modification are also covered. Emphasis is placed on their PTT and PTT‐synergized chemotherapy, photodynamic therapy, and immunotherapy. The major challenges of 2D photothermal agents are addressed and the promising prospects are also presented.     

Emerging Two-Dimensional Nanomaterials for Cancer Therapy

Two-dimensional (2D) nanomaterials have drawn tremendous attention due to their unique physicochemical properties and promising applications in the fields of electronics, energy storage, and catalysis. Recently, the biomedicine community has gradually started to recognize the great potential of these nanostructured materials for biomedical applications – in particular those related to cancer therapy. In this review, we provide a brief overview of a few representative 2D nanomaterials, discuss their preparation strategies and physicochemical properties, and highlight their applications in cancer nanomedicine. We expect that this review will shed some light on the new opportunities associated with 2D nanomaterials for biomedical research.