Investigation and Modeling of the Electrical Bias Stress in Electrolyte‐Gated Organic Transistors

Abstract: is coupled with the gate electrode via an electrolyte. The application of a bias to a polarizable gate electrode may either induce the formation of two electrical double layers or allow the intercalations of ions in the OSC film. In the first case, the transistors are operating in the field-effect mode and they are called electrolyte-gated organic field-effect transistors (EGOFETs), while in the second case, an electrochemical doping occurs and the devices are named organic electrochemical transistors (OECTs).… Show more

“…The application of different materials, geometries and fabrication techniques, together with a deeper understanding of device physics, allows for the tailoring of the device performances to the specific applications, reaching unprecedented results. The Italian production in this field reflects a generalized trend, with the exploration of materials ranging from small molecules and polymeric OSC [ 39 , 53 , 54 , 55 , 56 ], to polymeric OMIECs [ 57 , 58 , 59 ]. The use of OSCs or OMIECs gated via an electrolyte has proven to be a successful configuration for applications in bioelectronics [ 60 ].…”

“…From a technological point of view, fabrication techniques derived from silicon technology are exploited [ 39 , 57 , 63 , 64 , 65 , 66 ], as well as 2D and 3D printing technologies [ 7 , 54 , 67 , 68 , 69 , 70 , 71 ]. Moreover, increasingly accurate models have been developed in order to better understand the physical mechanisms governing the device operations, both in terms of the electrolyte-gating working mechanisms and in terms of the biosensor’s response to a given analyte [ 55 , 56 , 59 , 72 ]. In the following subsections, the cutting-edge progress achieved by the Italian Organic Bioelectronics community concerning the fabrication and modelling of novel organic transistor-based sensors will be described.…”

“…The S/D fabrication starts with a thin film deposition (Cr or Ti are used as an adhesion layer prior the Au deposition), followed by a photolithographic step and wet etching [ 39 ]. Alternatively, a lift-off process may be employed, starting with photolithography followed by thin film deposition and lift-off of the photoresist [ 59 ].…”

“…This is fundamental to prevent short circuits during the operation of the transistor in contact with an electrolyte. A passivation layer may be deposited via chemical vapor deposition (CVD) [ 83 ], e-beam evaporation [ 59 ] or spin-coating [ 66 ], depending on the material of choice. A lithography/etching process (or alternatively a lift-off process) is necessary in this step in order to open windows in the passivation.…”

“…These are needed to allow for the OSC/OMIEC to contact the electrodes, and to connect the contact pads with the external world. The described process is summarized in Figure 4 , where a double lift-off process was employed to define S/D electrodes and passivation windows (in this case, Al 2 O 3 deposited via e-beam evaporation) [ 59 ].…”

Organic Bioelectronics Development in Italy: A Review

“…The application of different materials, geometries and fabrication techniques, together with a deeper understanding of device physics, allows for the tailoring of the device performances to the specific applications, reaching unprecedented results. The Italian production in this field reflects a generalized trend, with the exploration of materials ranging from small molecules and polymeric OSC [ 39 , 53 , 54 , 55 , 56 ], to polymeric OMIECs [ 57 , 58 , 59 ]. The use of OSCs or OMIECs gated via an electrolyte has proven to be a successful configuration for applications in bioelectronics [ 60 ].…”

“…From a technological point of view, fabrication techniques derived from silicon technology are exploited [ 39 , 57 , 63 , 64 , 65 , 66 ], as well as 2D and 3D printing technologies [ 7 , 54 , 67 , 68 , 69 , 70 , 71 ]. Moreover, increasingly accurate models have been developed in order to better understand the physical mechanisms governing the device operations, both in terms of the electrolyte-gating working mechanisms and in terms of the biosensor’s response to a given analyte [ 55 , 56 , 59 , 72 ]. In the following subsections, the cutting-edge progress achieved by the Italian Organic Bioelectronics community concerning the fabrication and modelling of novel organic transistor-based sensors will be described.…”

“…The S/D fabrication starts with a thin film deposition (Cr or Ti are used as an adhesion layer prior the Au deposition), followed by a photolithographic step and wet etching [ 39 ]. Alternatively, a lift-off process may be employed, starting with photolithography followed by thin film deposition and lift-off of the photoresist [ 59 ].…”

“…This is fundamental to prevent short circuits during the operation of the transistor in contact with an electrolyte. A passivation layer may be deposited via chemical vapor deposition (CVD) [ 83 ], e-beam evaporation [ 59 ] or spin-coating [ 66 ], depending on the material of choice. A lithography/etching process (or alternatively a lift-off process) is necessary in this step in order to open windows in the passivation.…”

“…These are needed to allow for the OSC/OMIEC to contact the electrodes, and to connect the contact pads with the external world. The described process is summarized in Figure 4 , where a double lift-off process was employed to define S/D electrodes and passivation windows (in this case, Al 2 O 3 deposited via e-beam evaporation) [ 59 ].…”

Organic Bioelectronics Development in Italy: A Review

PEDOT:PSS deposition in OECTs: Inkjet printing, aerosol jet printing and spin coating

BTBT-based organic semiconducting materials for EGOFETs with prolonged shelf-life stability