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 20240224802 titled 'ORGANIC MOLECULES FOR OPTOELECTRONIC DEVICES

The abstract of the patent application describes an organic molecule with a specific structure and its use in optoelectronic devices.

The organic molecule has a structure represented by formula i, where n, m, p, and q are integers that sum up to 1.
The molecule includes various functional groups such as direct bonds, alkyl, aryl, and heteroaryl groups.
The molecule can be used in optoelectronic devices for various applications.

Potential Applications: - Optoelectronic devices such as organic light-emitting diodes (OLEDs) and organic photovoltaics (OPVs). - Organic semiconductors for flexible electronics. - Sensing applications in environmental monitoring or healthcare.

Problems Solved: - Enhancing the efficiency and performance of optoelectronic devices. - Improving the stability and durability of organic materials in electronic applications.

Benefits: - Increased energy efficiency in electronic devices. - Reduced environmental impact compared to traditional materials. - Potential cost savings in manufacturing processes.

Commercial Applications: Title: "Innovative Organic Molecule for Advanced Optoelectronic Devices" This technology can be utilized in the production of high-performance OLED displays, flexible solar panels, and sensors for various industries. The market implications include advancements in consumer electronics, renewable energy, and healthcare technologies.

Questions about the technology: 1. How does the structure of the organic molecule impact its performance in optoelectronic devices? - The specific arrangement of functional groups in the molecule can influence its electronic properties, such as charge transport and light emission. 2. What are the potential challenges in scaling up the production of devices using this organic molecule? - Issues related to cost, stability, and compatibility with existing manufacturing processes may arise when transitioning from lab-scale to commercial production.

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.