Organic light emitting diodes (OLEDs) have attracted extensive attention and research interest in advanced display and solid-state lighting due to their self-luminescence, low drive voltage, wide color gamut, surface luminescence, flexibility and rapid response. One of the primary colors of OLED, the development of blue emitter still lagging far behind. Interestingly, 9,9'-bianthracene as a promising blue-emitting for high-performance fluorescent OLEDs exhibits excellent optoelectronic performance in recent years. Here, we review the progress with the development of 9,9'-anthracene-based blue fluorescent materials and gain insight into their contribution towards enhanced OLED performance. Different approaches to achieve blue emission from molecular design including isomerization, fluorine substitution, asymmetrical structuring, and steric hindrance effects are discussed, with particular focus on device efficiency and stability. Furthermore, an outlook for future challenges and opportunities of OLEDs from the development of new molecular structures, understanding of luminescence mechanisms as well as innovation in flexible and large-scale panels is provided.

Nowadays stretchable electronic devices have become a hot research topic in the field of information electronics because of their excellent mechanical and electrical properties. As the high-speed electron transmission channel in stretching electronic devices, stretchable conductive materials play a crucial role in realizing the functions of stretching electronic devices. Liquid metal has become a hot research object in the field of stretchable conductive composites in recent years because of its intrinsic flexibility and excellent conductivity. Liquid metal is a room temperature liquid conductive material, which exhibits excellent stretchability and tunability due to its inherent high conductivity, fluidity, and ductility. Liquid metal-based stretchable conductive composites preparation and patterning techniques have been reported and many stretchable devices with excellent combination of mechanical and electrical properties have been prepared. In view of the general structural characteristics of liquid metal-based stretchable composites, the key to the preparation is how to solve the interfacial non-impregnation problem caused by the physical property differences between different materials. Therefore, starting from the common types of composites, this paper firstly briefly introduces the components and physical properties of liquid metals generally used, as well as the stretchable polymer matrix materials usually employed. Then, the composite methods of conductive materials and elastomer materials in liquid metal-based electrodes are reviewed from the two ways of "passive" and "active" to deal with the problem of non-wetting at the interface, as well as the blending and dispersion method and the new modification method. Finally, the latest research progress is introduced, and the current status of liquid metal research is summarized.

Contents

1 Introduction

2 Liquid metal-based flexible device material composition

2.1 Liquid metal and its composite materials

2.2 Flexible substrate material

3 Preparation method of liquid metal-based flexible conductive composites

3.1 Passive internal embedding method

3.2 Active surface structure modification method

3.3 Direct blending composite method

3.4 New methods for the preparation and patterning of liquid metal electrodes

4 Conclusion and outlook

Plastic products represented by polyethylene terephthalate (PET) have become an important part of modern life and global economy. In order to solve the resource waste and environmental problems caused by PET waste and to realize high-value recycling of materials, there is an urgent need to explore low-cost green and efficient conversion and recycling methods. Chemical depolymerization can deal with low-value, mixed, and contaminated plastics, recover polymer monomers through different chemical reactions or chemically upgrade and recycle to produce new products with high value-added, realizing the closed-loop recycling of plastic waste and high value-added applications,which is a key way to establish a circular polymer economy. This paper reviews the latest research progress of chemical depolymerization process of PET waste, analyzes the problems of chemical depolymerization technology of PET waste, and looks forward to the future development trend of chemical depolymerization process of PET waste.

Contents

1 Introduction

2 Chemical recovery methods

2.1 Hydrolysis

2.2 Alcoholysis

2.3 Ammonolysis and aminolysis

2.4 Supercritical depolymerization

3 Conclusion and outlook

Oxidative carbonylation reactions are powerful methodologies for producing carbonyl derivatives, which show advantages such as wide source of raw materials and a diverse range of products. In recent years, with the concept of environmental protection deeply rooted, developing efficient and green oxidative carbonylation reactions with carbon monoxide and oxygen as reactants, attracts much interest in this field. The C(sp)-H bonds of terminal alkynes exhibit excellent reactivity in oxidative carbonylation reactions, which could form a series of unsaturated carbonyl compounds. This review introduces the oxidative carbonylation reaction of terminal alkynes and their applications in total synthesis, including oxidative alkoxycarbonylation, oxidative aminocarbonylation, and oxidative carbonylation-cyclization, with the focus on the reaction mechanism of carbonylation and metal oxidation. Finally, the future development trends of this field are prospected.

Contents

1 Introduction

2 Oxidative alkoxycarbonylation

3 Oxidative aminocarbonylation

4 Oxidative carbonylation-cyclization

5 Application of oxidative carbonylation in total synthesis

6 Conclusion and outlook

Perchlorate, a persistent inorganic pollutant in water, poses a global environmental challenge due to its high solubility, mobility, and stability, making it difficult to degrade in the environment. Contamination by perchlorate has become a worldwide environmental issue, as residues of perchlorate in surface water and groundwater enter food and drinking water through various pathways, posing potential health risks. Chemical and biological methods have been extensively studied for perchlorate removal, each with its unique advantages and challenges. This paper systematically summarizes the recent research progress in chemical and biological treatment technologies for removing perchlorate from water, elaborating on the mechanisms, influencing factors, and advantages and disadvantages of these technologies. Chemical degradation, catalytic reduction, and electrochemical reduction are effective methods for treating perchlorate pollution. Organic electron donors such as acetate, glycerol, ethanol, and methane, as well as inorganic electron donors such as hydrogen and elemental sulfur, are widely used in the biological degradation process of perchlorate. Chemical methods provide rapid reduction rates and convenient implementation, while biological methods offer environmentally friendly solutions and long-term sustainable potential. However, both methods have limitations. In recent years, researchers have begun to explore combined removal techniques that integrate chemical and biological methods to enhance the remediation efficiency of perchlorate pollution. This paper reviews the research progress of three combined removal techniques: adsorption-biological method, bio-electrochemical method, and chemical reduction-biological method. In addition, future research directions are discussed, including engineering implementation studies, materials and microbiology research, practical application studies, and in-depth exploration of perchlorate degradation mechanisms. These studies will provide important theoretical and practical guidance for the effective management of perchlorate pollution.