1、Copper (I) Iodide Thin Films: Deposition Methods and Hole

CuI can be employed to create thin films with >80% transparency within the visible range (400–750 nm) and utilizing various low-temperature, scalable deposition techniques.

2、Copper (i)–iodide cluster structures as functional and processable

We describe the most typical ways of preparation, structures, and properties, with particular attention to the processability of the material as a fundamental aspect of the integration of the materials into real devices.

3、Synthesis and Characterization of Copper (I) Iodide Nanoparticles via

From the SEM and XRD results, we confirmed that the DMF played role as a stabilizing agent.

4、Copper(I) Iodide as a Resin Modifier

Among these, copper (I) iodide (CuI), an inorganic additive, has demonstrated significant potential in resin modification due to its unique physicochemical properties.

5、Copper Iodide Thin Films and Their Applications

Owing to their adjustable electrical properties and compatibility with low‐temperature deposition techniques, these films have found applications in transparent electronics, photovoltaic devices,...

Copper (I) Iodide: A Catalyst for Innovation in Materials Science

One of the significant contributions of CuI to materials science is its application in the fabrication of thin-film devices. These films are integral to technologies such as transistors, lasers, and solar cells, where CuI can act as a crucial layer due to its semiconductor properties.

Copper(I) Iodide Thin Films: Deposition Methods and Hole

CuI can be employed to create thin films with >80% transparency within the visible range (400–750 nm) and utilizing various low-temperature, scalable deposition techniques.

Catalytic application of copper iodide nanoparticles in organic

In this category, copper iodide nanoparticles (CuI NPs) have received a lot of interest among synthetic chemists due to their valuable advantageous such as high atom economy, inexpensive, simple preparation, readily available and reusability of the catalyst.

Solution

Among them, cuprous iodide (CuI) is a very promising hole-selective layer, however, very little research has been conducted for c-Si solar cells. In this work, we have demonstrated that solution-processed CuI films act as effective full-area hole-selective contact layers for p-Si solar cells.

Impact of iodide ions in the transformation of Cu

Though the iodide ion is well-known as a shape-directing agent, the study emphasizes the role of alkylamine in the shape-shifting of 1D Cu nanowires to 2D Cu nanoplates in conjunction with the iodide source.

With the advancement of technology, polymer materials have increasingly become indispensable in modern industries. Among these, resins—a critical class of high-molecular-weight materials—are widely utilized across various fields due to their excellent physical and chemical properties. resins inherently suffer from limitations such as poor heat resistance and insufficient mechanical strength, which constrain their performance in specialized applications. To address these challenges, scientists have continuously explored modification methods to enhance the comprehensive properties of resins. Against this backdrop, copper(I) iodide (CuI), a material with unique characteristics, has been introduced into the field of resin modification, opening new possibilities for improving resin performance.

Copper(I) Iodide (CuI): Properties and Structure Copper(I) iodide is an inorganic compound with the molecular formula CuI. At room temperature, it forms colorless crystals with a metallic luster and is prone to oxidation in air, turning brown due to the formation of copper(II) oxide. The crystal structure of CuI belongs to the face-centered cubic (FCC) system, where copper ions occupy the eight vertex positions of the cube, while iodide ions fill the interstitial sites. The presence of iodide ions endows CuI with distinctive electronic properties, enabling photocatalytic reactions under light exposure. These reactions generate reactive oxygen species (ROS), which can degrade organic pollutants, thereby offering environmental protection benefits.

Application of CuI in Resin Modification The use of CuI in resin modification primarily leverages its photocatalytic properties to enhance resin performance. Key approaches include:

1. Photocatalytic Degradation: Under light, CuI produces ROS that react with organic pollutants in resins, breaking them down into harmless small molecules. This not only reduces environmental pollution but also improves the safety of resin materials.
2. Antibacterial and Antifungal Properties: CuI exhibits antimicrobial effects. Coating resin surfaces with a CuI film inhibits bacterial and fungal growth, prolonging resin lifespan.
3. Self-Cleaning Function: The photocatalytic activity of CuI enables resin surfaces to achieve self-cleaning effects under light. This enhances stain resistance and lowers maintenance costs.
4. Improved Thermal Stability: CuI remains stable at high temperatures, allowing modified resins to maintain performance under harsher conditions.
5. Enhanced Mechanical Performance: While CuI does not directly participate in resin curing, it improves mechanical properties by promoting interactions between the resin matrix and fillers, increasing strength and toughness.

Preparation and Processing To maximize CuI’s effectiveness, its dosage and morphology must be controlled during preparation. Parameters such as solution concentration, reaction time, and stirring speed influence CuI dispersion and uniformity. Composite methods like blending, spraying, or immersion can integrate CuI with resin matrices.

As a material with unique properties, CuI holds significant potential in resin modification. Through optimized methods and process control, resin performance can be comprehensively improved. With ongoing technological progress, future research and applications are expected to drive innovation in resin modification, delivering greater convenience and benefits to society.