High performance photolithographically-patterned polymer thin-film transistors gated with an ionic liquid/poly(ionic liquid) blend ion gel

Thiburce, Quentin; Porcarelli, Luca; Mecerreyes, David; Campbell, Alasdair J.

doi:10.1063/1.4985629

Cited by 25 publications

(27 citation statements)

References 42 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The V G dependences of the channel‐width‐normalized transconductance ( g m / W ) at V D = 1 and 0.1 V, respectively, for the same device are shown in Figure d and Figure S5b in the Supporting Information. For an ideal transistor, g m / W should be independent of V G beyond threshold, but as is typical for EGTs, g m / W is peaked, as discussed further below. Maximum channel‐width‐normalized transconductance ( g m / W) max is the peak value of the Figure d plot.…”

Section: Resultsmentioning

confidence: 99%

“…Electrolyte‐gated transistors (EGTs), including electric double layer transistors (EDLTs) and organic electrochemical transistors (OECTs), are being developed by a number of research groups for applications in sensing and printed electronics . Attractive features of EGTs are their very high transconductances and low voltage characteristics, both of which derive from the huge specific capacitance of the electrolyte gate dielectrics that they employ, which varies from ≈10 μF cm −2 in the double layer operating regime to over 100 μF cm −2 in the electrochemical regime …”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Sub‐3 V ZnO Electrolyte‐Gated Transistors and Circuits with Screen‐Printed and Photo‐Crosslinked Ion Gel Gate Dielectrics: New Routes to Improved Performance

Bidoky

Tang

et al. 2019

Adv Funct Materials

View full text Add to dashboard Cite

A facile, high-resolution patterning process is introduced for fabrication of electrolyte-gated transistors (EGTs) and circuits using a photo-crosslinkable ion gel and stencil-based screen printing. The photo-crosslinkable gel is based on a triblock copolymer incorporating UV-sensitive terminal azide functionality and a common ionic liquid. Using this material in conjunction with conventional photolithography and stenciling techniques, well-defined 0.5-1 µm thick ion gel films are patterned on semiconductor channels as narrow as 10 µm. The resulting n-type ZnO EGTs display high electron mobility (>2 cm 2 Vs −1 ) and on/off current ratios (>10 5 ). Further, EGT-based inverters exhibit static gains >23 at supply voltages below 3 V, and five-stage EGT ring oscillator circuits display dynamic propagation delays of 50 µs per stage. In general, the screen printing and photo-crosslinking strategy provides a clean room-compatible method to fabricate EGT circuits with improved sensitivity (gain) and computational power (gain × oscillating frequency). Detailed device analysis indicates that significantly shorter delay times, of order 1 µs, can be obtained by improving the ion gel conductance.

show abstract

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Sub‐3 V ZnO Electrolyte‐Gated Transistors and Circuits with Screen‐Printed and Photo‐Crosslinked Ion Gel Gate Dielectrics: New Routes to Improved Performance

Bidoky

Tang

et al. 2019

Adv Funct Materials

View full text Add to dashboard Cite

show abstract

“…Organic transistors that can operate below 1 V have been demonstrated, [70,82,85,86,[108][109][110][111][112] but many research efforts have focused on devices involving electrolyte gate insulators, including ionic liquid, poly (ionic liquid), and electrochemical transistors. [108,109,111,112] The electrolyte gate insulator will form electrical double layers (EDLs) at both the electrolyte/semiconductor and electrolyte/gate electrode interfaces due to the ion movement under gate bias. Within each EDL, the redistributed ions are balanced by the electronic charges from the semiconductor or gate electrode, respectively, and the distance between the ionic and electrical charges is less than 1 nm, equivalent to a large-value capacitor.…”

Section: Wwwadvancedsciencenewscommentioning

confidence: 99%

Organic Field‐Effect Transistor for Energy‐Related Applications: Low‐Power‐Consumption Devices, Near‐Infrared Phototransistors, and Organic Thermoelectric Devices

Ren

Yang

Gao

et al. 2018

Advanced Energy Materials

106

View full text Add to dashboard Cite

The operating frequency of ring oscillators or radio-frequency identification tags made by OFETs have surpassed MHz. [27,28] With the growing level of integration and the operating frequency of OFETs, the power dissipation issue can no longer be ignored. Considering the material composition of most organic semiconductors, controlling the temperature rise within a reasonable range is important to avoid the unwanted degradation of organic materials and therefore maintain stable device operation. In addition, OFETs fabricated on flexi ble substrates somehow limit the use of conventional batteries. To avoid externally wiring the batteries, flexible OFET-based circuits can be expected to be self-powered by integrating them with organic solar cells, thermoelectric modules, or triboelectric nanogenerators. [29,30] All of these demands require OFETs operating with extremely low power consumption. Rapid progress has been made in this field, and research efforts have focused on reducing the operating voltage of OFETs, [31][32][33] enhancing the switching efficiency of transistors, [34][35][36][37] and demonstrating several novel device concepts for low-power applications. [38][39][40][41][42] Despite the switching function, OFETs can also be utilized in emerging energy-related applications, such as near-infrared (NIR) photodetectors and organic thermoelectric devices dueThe organic field-effect transistor (OFET) is the basic building block of integrated circuits. The charge carrier mobility and operating frequency of OFETs have continued to increase; therefore, the power dissipation of OFETs can no longer be ignored. Many research efforts have been made to develop low-power-consumption OFETs and complementary circuits. Despite the switching function, OFETs can also be utilized in emerging energy-related applications, such as near-infrared (NIR) photodetectors and organic thermoelectric devices. Organic phototransistors show considerably higher photo responsivity than other photodetector architectures due to field-effect charge modulation. The photoinduced gate modulating largely suppresses the dark current while simultaneously providing gain. These characteristics may favor NIR light detection and suggest that the organic phototransistor is a promising candidate for optoelectronic applications in the NIR regime. For organic thermoelectric applications, OFETs can work as a powerful tool for examining the charge and energy transport in the organic semiconductor, thus giving insight into organic thermoelectric studies. In this review, the authors highlight recent advances in OFET-related energy topics, including lowpower-consumption OFETs, NIR photodetectors, and organic thermoelectric devices. The remaining challenges in the field will also be discussed.

show abstract

“…Room Temperature Ionic Liquids (RTILs) such as C2MIM EtSo4 are an alternative to water‐based electrolytes . So far, ionic liquids have been used extensively in electrolyte gated organic field‐effect transistors . In general, the slow polarization response of electrolytes limits the switching speed of these transistors to a few hertz at room temperature.…”

Section: Introductionmentioning

confidence: 99%

“…[23,10] So far, ionic liquids have been used extensively in electrolyte gated organic field-effect transistors. [24][25][26][27] In general, the slow polarization response of electrolytes limits the switching speed of these transistors to a few hertz at room temperature. To decrease the polarization time with a large specific capacitance, different ionic liquids were used, [28] which show different frequency-dependent double layer capacitances.…”

Section: Introductionmentioning

confidence: 99%

Organic Electrochemical Transistors Based on Room Temperature Ionic Liquids: Performance and Stability

Kaphle

Liu

Keum

et al. 2018

Physica Status Solidi (a)

View full text Add to dashboard Cite

Organic electrochemical transistors (OECTs) are becoming a key device in the field of organic bioelectronics. For many applications of OECTs, in particular for enzymatic sensing, a complex mixture of room temperature ionic liquids (RTILs) combined with other electrolytes is used as a gate electrolyte, making the interpretation of experimental trends challenging. Here, the switching mechanism of OECTs using such RTILs is studied. It shows that ions smaller in size than the ions contained in the RTIL (e.g., Na+) have to be added to the ionic liquid to ensure switching of the OECTs. Furthermore, it is shown that OECTs based on RTILs exhibit noticeable gate‐bias stress effects and a hysteresis in the electrical transfer characteristics. A model based on incomplete charging/discharging of the effective gate capacitance during operation of the OECT and a dispersion in the ion mobilities is proposed to explain these instabilities, and thus it shows that the hysteresis can be minimized by optimizing the geometry of the device. Overall, a better understanding of the underlying mechanisms of switching and stability of OECTs based on RTILs is the first step toward various applications such as lactate acid sensors and neurotransmitter recording.

show abstract

High performance photolithographically-patterned polymer thin-film transistors gated with an ionic liquid/poly(ionic liquid) blend ion gel

Cited by 25 publications

References 42 publications

Sub‐3 V ZnO Electrolyte‐Gated Transistors and Circuits with Screen‐Printed and Photo‐Crosslinked Ion Gel Gate Dielectrics: New Routes to Improved Performance

Sub‐3 V ZnO Electrolyte‐Gated Transistors and Circuits with Screen‐Printed and Photo‐Crosslinked Ion Gel Gate Dielectrics: New Routes to Improved Performance

Organic Field‐Effect Transistor for Energy‐Related Applications: Low‐Power‐Consumption Devices, Near‐Infrared Phototransistors, and Organic Thermoelectric Devices

Organic Electrochemical Transistors Based on Room Temperature Ionic Liquids: Performance and Stability

Contact Info

Product

Resources

About