A Printed Gate Controlled Electrochemical Capacitor-Diode (G-CAPode) for AC Filtering Applications

Christin Gellrich , Przemyslaw Galek , Leonid Shupletsov , Nick Niese , Ahmed Bahrawy , Julia Grothe , Stefan Kaskel

SusMat ›› 2025, Vol. 5 ›› Issue (3) : e70006

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SusMat ›› 2025, Vol. 5 ›› Issue (3) : e70006 DOI: 10.1002/sus2.70006
RESEARCH ARTICLE

A Printed Gate Controlled Electrochemical Capacitor-Diode (G-CAPode) for AC Filtering Applications

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Abstract

For the first time, a printable, miniaturized, and gate-controlled electrochemical capacitor-diode (G-CAPode) is presented. The heart of the device consists of a recently developed asymmetric electrical double-layer capacitor system based on selective, size-dependent ion adsorption. Due to the introduction of a sieving carbon with ultramicroporous pores (d = 0.69 nm) as one electrode material, an effective blocking of ions with sizes below the pore size of the carbon can be achieved, leading to a unidirectional charging comparable to a diode (CAPode). This “working capacitor” (W-Cap) was further expanded by introducing a third (“gate”) electrode enabling a control of the current and voltage output of the W-Cap depending on the applied gate bias between the gate electrode and counter electrode of the W-Cap resembling transistor features. By varying the gate bias voltage, the potentials and therefore the working window of the W-Cap electrodes are shifted to more positive or negative potentials, leading to an increase or decrease of the G-CAPode capacitance. The printed G-CAPode was tested as a switchable device analogous to an I-MOS varactor for the adjustable filtering of AC signals in a high-pass filter and band-pass filter application. This investigation opens the possibility to couple capacitive (energy storage), diodic (current rectification), and transistor (voltage-controlled switching) characteristics in one device and also addresses its process integration via 3D printing.

Keywords

3D printing / ionic diodes / ionic transistors / signal filtering / ultracapacitors / varactors

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Christin Gellrich, Przemyslaw Galek, Leonid Shupletsov, Nick Niese, Ahmed Bahrawy, Julia Grothe, Stefan Kaskel. A Printed Gate Controlled Electrochemical Capacitor-Diode (G-CAPode) for AC Filtering Applications. SusMat, 2025, 5(3): e70006 DOI:10.1002/sus2.70006

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2025 The Author(s). SusMat published by Sichuan University and John Wiley & Sons Australia, Ltd.

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