Add to ORKGOrganic electronics is an extensively studied subject opening new horizons in electronics technology. It has attracted great attention as a technology to enable flexible electronic devices through solution processing of organic and polymeric materials. However, patterning of organic materials to construct device components still remains one of the major hurdles to be overcome due to problems with chemical processing. Fundamentally this challenge originates from the limited number of options regarding orthogonal solvents. Recently, we have identified supercritical carbon dioxide (scCO2) and segregated hydrofluoroethers (HFEs) as universal, non-damaging solvents for most non-fluorinated polymeric materials. These unconventional solvents expan...
The emergence of organic semiconductors is exciting since it promises to open up for straightforward...
Despite having favorable optoelectronic and thermomechanical properties, the wide application of sem...
As lithography moves toward feature sizes of 22 nm and smaller and pushing for applications beyond t...
The concept of chemical orthogonality has long been practiced in the field of inorganic semiconducto...
The particular challenge of micropatterning organic materials has stimulated numerous approaches for...
After deposition, solution-processed organic materials are susceptible to redissolution by similar s...
Organic electronics is a newly developed field that promises inexpensive, mechanically-flexible, lar...
A study was conducted to demonstrate a new approach for chemicalprocessing of organic electronic mat...
Photolithography is a high-throughput, cost-effective patterning technology. However, the applicatio...
Patterning organic semiconductors via traditional solution-based microfabrication techniques is prec...
As feature sizes continue to shrink, the need for new materials and new processes for next-generatio...
The ability to pattern functional polymers at different length scales is important for the advanceme...
The sub-micrometer patterning of poly(3,4-ehylenedioxythiophenet): poly(styrene sulfonate) (PEDOT:PS...
We implemented and developed a number of different mechanical patterning methods, including soft hot...
The authors kindly acknowledge the financial support by the Free State of Saxony, the Sächsische Auf...
The emergence of organic semiconductors is exciting since it promises to open up for straightforward...
Despite having favorable optoelectronic and thermomechanical properties, the wide application of sem...
As lithography moves toward feature sizes of 22 nm and smaller and pushing for applications beyond t...
The concept of chemical orthogonality has long been practiced in the field of inorganic semiconducto...
The particular challenge of micropatterning organic materials has stimulated numerous approaches for...
After deposition, solution-processed organic materials are susceptible to redissolution by similar s...
Organic electronics is a newly developed field that promises inexpensive, mechanically-flexible, lar...
A study was conducted to demonstrate a new approach for chemicalprocessing of organic electronic mat...
Photolithography is a high-throughput, cost-effective patterning technology. However, the applicatio...
Patterning organic semiconductors via traditional solution-based microfabrication techniques is prec...
As feature sizes continue to shrink, the need for new materials and new processes for next-generatio...
The ability to pattern functional polymers at different length scales is important for the advanceme...
The sub-micrometer patterning of poly(3,4-ehylenedioxythiophenet): poly(styrene sulfonate) (PEDOT:PS...
We implemented and developed a number of different mechanical patterning methods, including soft hot...
The authors kindly acknowledge the financial support by the Free State of Saxony, the Sächsische Auf...
The emergence of organic semiconductors is exciting since it promises to open up for straightforward...
Despite having favorable optoelectronic and thermomechanical properties, the wide application of sem...
As lithography moves toward feature sizes of 22 nm and smaller and pushing for applications beyond t...