Researchers in India have made graphene field-effect transistors based on discrete inorganic structures that reportedly work for over 10 months. The approach has led them to produce a graphene logic inverter that is stable in ambient conditions.
Conventional electronics are silicon based, due to the ease of doping silicon with either electrons or holes. These two forms of silicon, n- and p-type, are the building blocks of electronic devices. However, it isn’t possible to make silicon electronics on the nanoscale, so many researchers are turning to materials like graphene.
Replicating the electronic success of silicon with 2D materials has proven difficult. Pristine graphene field-effect transistors tend to be p-type and previous attempts to make n-type graphene have used organic dopants. According to Chandramouli Subramaniam, from the Indian Institute of Technology (IIT) Bombay, the instability of organic dopants in ambient conditions creates graphene field-effect transistors with ‘unreliable and irreversible transfer characteristics.’
Subramaniam says ‘n-type doping of graphene has been eluding the scientific community,’ causing a bottleneck in researchers developing graphene semiconductor electronics. Now, the research team led by Subramaniam and his IIT Bombay colleague Maheswaran Shanmugam has used lanthanide complexes to make graphene-based logic inverters for the first time.
The devices are said to be stable for 7200 hours, an unprecedented length of time that stems from C-HÏ interactions. Previous work had used the ÏÏ interactions that arise from graphene’s delocalized structure to tune its electrical properties, but in this case, Subramaniam and Shanmugam have purposely suppressed these interactions. Their system hinges on C-HÏ interactions between the graphene and lanthanide dopants. The binding energy between the dopant and graphene is much larger than previous systems, and correlates directly to the stability of the graphene field-effect transistor.
Jingbo Li, an expert on graphene field-effect transistors from the Chinese Academy of Sciences in Beijing, says this study ‘may inspire [the use of] more fundamental supramolecular interactions in tuning the electrical properties of two-dimensional materials.’
Aside from the stability, other properties of the system are also impressive. The researchers report a voltage gain of 0.275 Subramaniam explains that this is ‘higher than other reports that utilize bottom gate electrodes [but] lower than reports that utilize top-gate electrodes.’ And the device’s power dissipation of 30μW is the ‘lowest compared to several other related systems’.
Going forward, the group will use their new method to improve voltage gain with top-gated structures and p-dopants, in hopes that it accelerates molecular electronics into real devices.