A major step forward in organic electronics
Complementary logic circuits based on high-performance n-type organic electrochemical transistor
Summary:
These are the worlds first complementary electrochemical logic circuits.
Researchers at the Laboratory of Organic
Electronics, Linköping University, have developed the world's first
complementary electrochemical logic circuits that can function stably
for long periods in water. This is a highly significant breakthrough in
the development of bioelectronics.
The first printable organic electrochemical transistors were
presented by researchers at LiU as early as 2002, and research since
then has progressed rapidly. Several organic electronic components, such
as light-emitting diodes and electrochromic displays, are already
commercially available.
The dominating material used until now has been PEDOT:PSS, which is a p-type material, in which the charge carriers are holes. In order to construct effective electron components, a complementary material, n-type, is required, in which the charge carriers are electrons.
It has been difficult to find a sufficiently stable polymer material, one that can operate in water media and in which the long polymer chains can sustain high current when the material is doped.
In an article in the scientific journal Advanced Materials, Simone Fabiano, head of research in the Organic Nanoelectronics group at the Laboratory of Organic Electronics, presents, together with his colleagues, results from an n-type conducting material in which the ladder-type structure of the polymer backbone favours ambient stability and high current when doped. One example is BBL, poly(benzimidazobenzophenanthroline), a material often used in solar cell research.
Postdoctoral researcher Hengda Sun has found a method to create thick films of the material. The thicker the film, the greater the conductivity.
"We have used spray-coating to produce films up to 200 nm thick. These can reach extremely high conductivities," says Simone Fabiano.
The method can also be successfully used together with printed electronics across large surfaces.
Hengda Sun has also shown that the circuits function for long periods, both in the presence of oxygen and water.
"This may appear at first glance to be a small advance in a specialised field, but what is great about it is that it has major consequences for many applications. We can now construct complementary logic circuits -- inverters, sensors and other components -- that function in moist surroundings," says Simone Fabiano.
"Resistors are needed in logical circuits that are based solely on p-type electrochemical transistors. These are rather bulky, and this limits the applications that can be achieved. With an n-type material in our toolbox, we can produce complementary circuits that occupy the available space much more efficiently, since resistors are no longer required in the logical circuits," says Magnus Berggren, professor of organic electronics and head of the Laboratory for Organic Electronics.
Applications of the organic components include logic circuits that can be printed on textile or paper, various types of cheap sensor, non-rigid and flexible displays, and -- not least -- the huge field of bioelectronics. Polymers that conduct both ions and electrons are the bridge needed between the ion-conducting systems in the body and the electronic components of, for example, sensors.
The dominating material used until now has been PEDOT:PSS, which is a p-type material, in which the charge carriers are holes. In order to construct effective electron components, a complementary material, n-type, is required, in which the charge carriers are electrons.
It has been difficult to find a sufficiently stable polymer material, one that can operate in water media and in which the long polymer chains can sustain high current when the material is doped.
In an article in the scientific journal Advanced Materials, Simone Fabiano, head of research in the Organic Nanoelectronics group at the Laboratory of Organic Electronics, presents, together with his colleagues, results from an n-type conducting material in which the ladder-type structure of the polymer backbone favours ambient stability and high current when doped. One example is BBL, poly(benzimidazobenzophenanthroline), a material often used in solar cell research.
Postdoctoral researcher Hengda Sun has found a method to create thick films of the material. The thicker the film, the greater the conductivity.
"We have used spray-coating to produce films up to 200 nm thick. These can reach extremely high conductivities," says Simone Fabiano.
The method can also be successfully used together with printed electronics across large surfaces.
Hengda Sun has also shown that the circuits function for long periods, both in the presence of oxygen and water.
"This may appear at first glance to be a small advance in a specialised field, but what is great about it is that it has major consequences for many applications. We can now construct complementary logic circuits -- inverters, sensors and other components -- that function in moist surroundings," says Simone Fabiano.
"Resistors are needed in logical circuits that are based solely on p-type electrochemical transistors. These are rather bulky, and this limits the applications that can be achieved. With an n-type material in our toolbox, we can produce complementary circuits that occupy the available space much more efficiently, since resistors are no longer required in the logical circuits," says Magnus Berggren, professor of organic electronics and head of the Laboratory for Organic Electronics.
Applications of the organic components include logic circuits that can be printed on textile or paper, various types of cheap sensor, non-rigid and flexible displays, and -- not least -- the huge field of bioelectronics. Polymers that conduct both ions and electrons are the bridge needed between the ion-conducting systems in the body and the electronic components of, for example, sensors.
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