Carla Aguirre scite author profile

Graphene field effect transistors (FETs) are extremely sensitive to gas exposure. Charge transfer doping of graphene FETs by atmospheric gas is ubiquitous but not yet understood. We have used graphene FETs to probe minute changes in electrochemical potential during high-purity gas exposure experiments. Our study shows quantitatively that electrochemistry involving adsorbed water, graphene, and the substrate is responsible for doping. We not only identify the water/oxygen redox couple as the underlying mechanism but also capture the kinetics of this reaction. The graphene FET is highlighted here as an extremely sensitive potentiometer for probing electrochemical reactions at interfaces, arising from the unique density of states of graphene. This work establishes a fundamental basis on which new electrochemical nanoprobes and gas sensors can be developed with graphene.

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The Role of the Oxygen/Water Redox Couple in Suppressing Electron Conduction in Field‐Effect Transistors

Aguirre

et al. 2009

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The back-gated field-effect transistor (FET) configuration has been central to the study of the electronic transport properties of organic and nanoscale materials. [1][2][3] Three-terminal transport measurements using this geometry are facilitated by using a degenerately doped silicon wafer covered with a thin silicon oxide layer as the substrate. It has been widely assumed that the substrate did not influence the measurement of the intrinsic properties of the material under study. However, Chua et al. [4] recently demonstrated that changing the nature of the dielectric led to ambipolar behavior in FETs made from organic semiconductors that were previously thought to be exclusively hole (p-type) conductors. Silanol groups present on the SiO 2 surface were singled out as the culprits for generating electron traps responsible for suppressing electron (n-type) conduction in these devices. Here we show that the substrate-induced suppression of n-type behavior is not unique to organic FETs, but influences the measurements of all devices fabricated on SiO 2 /Si substrates. By using carbon nanotubes as the testbed, we investigated the impact of the chemical nature of the substrate and of ambient adsorbates on the field-effect switching behavior of both nanoscale and thin-film FETs. Our study revealed that the reduction of n-type conduction occurs when an adsorbed water layer containing solvated oxygen is present on the SiO 2 surface. This finding demonstrates that an electrochemical charge transfer reaction between the semiconducting channel and the aqueous oxygen redox couple is the underlying phenomenon governing the suppression of electron conduction in carbon nanotube devices. This effect should be taken into account when interpreting three-terminal measurements conducted on SiO 2 /Si substrates. We anticipate that the design of electronic devices, [5] chemical sensors, [6] and biosensors [7] that are based on the FET configuration will be largely influenced by the charge transfer mechanism that has been brought to light by this study.Individual carbon nanotube field-effect transistors (CFETs) are the most extensively studied molecular-scale FETs to date.

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Carbon nanotube sheets as electrodes in organic light-emitting diodes

et al. 2006

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High performance organic light-emitting diodes ͑OLEDs͒ were implemented on transparent and conductive single-wall carbon nanotube sheets. At the maximum achieved brightness of 2800 cd m −2 the luminance efficiency of our carbon nanotube-based OLED is 1.4 cd A −1 which is comparable to the 1.9 cd A −1 measured for an optimized indium tin oxide anode device made under the same experimental conditions. A thin parylene buffer layer between the carbon nanotube anode and the hole transport layer is required in order to readily achieve the measured performance.

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Carla Aguirre

Probing Charge Transfer at Surfaces Using Graphene Transistors

The Role of the Oxygen/Water Redox Couple in Suppressing Electron Conduction in Field‐Effect Transistors

Carbon nanotube sheets as electrodes in organic light-emitting diodes

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