Poly[2-(3-thienyl)ethyloxy-4-butylsulfonate] sodium salt is the sodium salt of poly[2-(3-thienyl)ethyloxy-4-butylsulfonate]. Poly[2-(3-thienyl)ethyloxy-4-butylsulfonate], commonly known as PTES, is a versatile and promising material that has captivated the interest of researchers and industry professionals across various fields. With its unique chemical structure and exceptional properties, PTES offers exciting possibilities in the realms of organic electronics, energy storage, and biomedical applications. This article explores the diverse range of opportunities afforded by PTES, showcasing its immense potential for innovation and practical applications.
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| ACM1100243400-1 | Poly{[N,N'-bis(2-octyldodecyl)naphthalene-1,4,5,8-bis(dicarboximide)-2,6-diyl]-alt-5,5'-(2,2'-bithiophene)} | 1100243-40-0 | INQUIRY |
| ACM110851655-1 | Poly(3-decyl-thiophene-2,5-diyl) | 110851-65-5 | INQUIRY |
Poly[2-(3-thienyl)ethyloxy-4-butylsulfonate] sodium salt (PTES) holds immense potential for advancements in organic electronic devices, especially in the fields of organic photovoltaics (OPVs) and organic field-effect transistors (OFETs). PTES exhibits exceptional charge carrier mobility and efficient charge transport properties, making it an ideal candidate for use as an active layer in these devices.
![Poly[2-(3-thienyl)ethyloxy-4-butylsulfonate] Sodium Salt and Its Multiple Applications](/upload/image/poly-2-3-thienyl-ethyloxy-4-butylsulfonate-sodium-salt-and-its-multiple-applications-1.jpg)
In OPVs, PTES has shown significant improvements in device performance due to its favorable electronic properties and compatibility with solution processing techniques. Research has shown that PTES-based OPVs exhibit enhanced power conversion efficiencies, attributed to high charge carrier mobilities and improved morphology of the active layer. PTES facilitates efficient charge separation and extraction, leading to enhanced photovoltaic performance.
Moreover, PTES offers advantages in terms of processability and scalability. It can be synthesized through solution-based techniques such as spin-coating or inkjet printing, enabling large-scale production and cost-effective manufacturing of electronic devices. PTES-based devices also exhibit good stability under ambient conditions, ensuring long-term functionality and reliability.
The exceptional performance and processability of PTES in organic electronic devices present promising opportunities for the development of next-generation technologies. Researchers and industry experts are actively studying the underlying mechanisms and optimizing the synthesis and processing techniques to further enhance the performance and commercial viability of PTES-based devices.
Poly[2-(3-thienyl)ethyloxy-4-butylsulfonate] sodium salt (PTES) showcases promising potential for energy storage applications, including supercapacitors and batteries. PTES stands out due to its exceptional charge storage capabilities, stability, and high cycling stability.
Supercapacitors, also known as ultracapacitors or electrochemical capacitors, are energy storage devices that bridge the gap between traditional capacitors and batteries. PTES has gained attention as a promising material for supercapacitor electrodes due to its high specific capacitance, which is a measure of how much charge it can store per unit of material.
Furthermore, PTES demonstrates excellent stability and high cycling stability, crucial factors for energy storage devices. It exhibits minimal degradation and excellent charge-discharge efficiency throughout numerous charge-discharge cycles. This cycling stability ensures reliable performance over the long term, making PTES a candidate for durable and efficient energy storage solutions.
PTES is also being explored for use in battery applications. Batteries are essential for energy storage, and the development of advanced materials is vital for improving their energy density, cycling stability, and charging efficiency. PTES offers advantages as an electrode material in batteries, particularly in terms of its electrochemical properties and stability. Researchers have demonstrated the potential of using PTES as both the anode and cathode material in various types of batteries, such as lithium-ion batteries, sodium-ion batteries, and hybrid supercapacitors-batteries34. PTES-powered batteries exhibit promising charging-discharging capacities and excellent cycling stability. Leveraging the unique characteristics of PTES in battery technology may open up new avenues for high-performance energy storage devices.
The unique attributes of PTES have sparked interest in its potential applications in the biomedical field. Researchers are exploring the use of PTES in drug delivery systems and tissue engineering scaffolds due to its desirable biocompatibility and tunable degradation rate. PTES demonstrates remarkable encapsulation and controlled release capabilities for drugs, showcasing its potential in targeted therapies and personalized medicine. Furthermore, PTES-based scaffolds provide a conducive environment for cell growth and tissue regeneration, making it a material of interest for tissue engineering applications.
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