ORGANIC MOLECULES FOR OPTOELECTRONIC DEVICES

Organization Name

Inventor(s)

[[:Category:Sebastian D�ck of Heidelberg (DE)|Sebastian D�ck of Heidelberg (DE)]][[Category:Sebastian D�ck of Heidelberg (DE)]]

Daniel Zink of Graben-Neudorf (DE)

Arun Pandian Vellaiyappan of Karlsruhe (DE)

ORGANIC MOLECULES FOR OPTOELECTRONIC DEVICES - A simplified explanation of the abstract

This abstract first appeared for US patent application 18556629 titled 'ORGANIC MOLECULES FOR OPTOELECTRONIC DEVICES

The abstract of the patent application describes an organic molecule and optoelectronic devices that incorporate this molecule. The molecule has a specific structure outlined in Formula I, with various components and configurations.

The organic molecule has a defined structure represented by Formula I.
The molecule includes specific elements such as Z, R, and R' with distinct characteristics and configurations.
Optoelectronic devices utilizing this organic molecule can exhibit unique properties and performance.
The molecule's structure allows for versatility and customization in device design and functionality.
The patent application aims to protect the use and application of this organic molecule in optoelectronic devices.

Potential Applications: The organic molecule can be used in various optoelectronic devices such as organic light-emitting diodes (OLEDs), organic photovoltaic cells, and organic field-effect transistors. The molecule's properties make it suitable for applications in display technologies, sensors, and energy harvesting devices. The versatility of the molecule allows for potential use in flexible and wearable electronics, as well as in advanced lighting systems.

Problems Solved: The organic molecule addresses the need for efficient and high-performance materials in optoelectronic devices. By providing a specific structure and composition, the molecule can enhance the functionality and durability of these devices. The molecule's properties can help overcome limitations in current optoelectronic technologies, such as low efficiency and limited design flexibility.

Benefits: Improved performance and efficiency in optoelectronic devices. Enhanced design flexibility and customization options. Potential cost savings in device manufacturing and operation. Contribution to the advancement of sustainable and energy-efficient technologies.

Commercial Applications: The organic molecule can be utilized in the production of commercial optoelectronic devices, leading to enhanced performance and functionality. The technology can cater to industries such as consumer electronics, lighting, renewable energy, and healthcare. Market implications include the potential for new product development, increased competitiveness, and expanded market reach.

Questions about the technology: 1. How does the specific structure of the organic molecule contribute to its performance in optoelectronic devices? 2. What potential challenges or limitations could arise in the commercialization of devices incorporating this molecule?

Original Abstract Submitted

An organic molecule and optoelectronic devices including the organic molecule are disclosed. The organic molecule has a structure of Formula I, where n, m, p, and q are integers selected from 0 and 1, wherein n+m=1 and p+q=1; Z is independently selected from the group consisting of a direct bond, CRR, C═CRR, C═O, C═NR, NR, O, SiRR, S, S(O) and S(O); Ris independently selected from the group consisting of C-C-alkyl and C-C-aryl, which is optionally substituted with one or more C-C-alkyl substituents; and Ris independently selected form the group consisting of hydrogen, deuterium, N(R), OR, Si(R), C-C-alkyl, C-C-aryl, and C-C-heteroaryl.