Flexible Single‐Substrate Integrated Active‐Matrix Pyroelectric Sensor

Gold, Herbert; Petritz, Andreas; Karner‐Petritz, Esther; Tschepp, Andreas; Groten, Jonas; Prietl, Christine; Scheipl, Gregor; Zirkl, Martin; Stadlober, Barbara

doi:10.1002/pssr.201900277

Cited by 15 publications

(25 citation statements)

References 37 publications

(56 reference statements)

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“…PNDPE layers have already been used in previous studies as the gate dielectric in p-and n-channel based OTFTs. [16,37,38] However, in these studies, either rigid glass substrates or very thick PNDPE layers as much as a few µm were used; in addition, ICs were not fabricated. This study demonstrates the HFDP for V th control in OTFTs on the same substrate for high-performance ICs with the use of ultrathin PNDPE gate dielectrics.…”

Section: Introductionmentioning

confidence: 99%

“…Flexible electronic devices often require integrated circuits (ICs) for signal processing; thus, the development of flexible ICs is crucial in the practical applications of flexible electric devices.Organic thin-film transistors (OTFTs) are attractive candidates in the development of flexible ICs because they can be fabricated on flexible, and even stretchable substrates, with low-cost and largearea fabrication processes. [16][17][18] Their individual electric properties have been analyzed and reported over the past few decades, focusing on threshold voltage (V th ), [19][20][21][22][23][24][25][26][27][28] mobility, [29][30][31] and stability, [32,33] which were primarily controlled or improved by modulating the behavior of charge carriers at the interface between the gate dielectrics and semiconductors. Particularly, V th is one of the key characteristics which affects the performance of the ICs considering that in the early stages the silicon-based ICs was produced using only V th controlled n-channel transistors.…”

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confidence: 99%

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Heterogeneous Functional Dielectric Patterns for Charge‐Carrier Modulation in Ultraflexible Organic Integrated Circuits

et al. 2021

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has been expanded in the recent years owing to the unique properties of organic materials, such as biodegradability [11,12] and stretchability. [13][14][15] This allows for easier access to useful unobtained information that has not been extracted by conventional silicon technology. Flexible electronic devices often require integrated circuits (ICs) for signal processing; thus, the development of flexible ICs is crucial in the practical applications of flexible electric devices.Organic thin-film transistors (OTFTs) are attractive candidates in the development of flexible ICs because they can be fabricated on flexible, and even stretchable substrates, with low-cost and largearea fabrication processes. [16][17][18] Their individual electric properties have been analyzed and reported over the past few decades, focusing on threshold voltage (V th ), [19][20][21][22][23][24][25][26][27][28] mobility, [29][30][31] and stability, [32,33] which were primarily controlled or improved by modulating the behavior of charge carriers at the interface between the gate dielectrics and semiconductors. Particularly, V th is one of the key characteristics which affects the performance of the ICs considering that in the early stages the silicon-based ICs was produced using only V th controlled n-channel transistors. [34] Therefore, the V th control using charge-carrier modulation is essential in OTFTs as well as silicon transistors.To maximize the performance metrics of the ICs, for example, the reliability, amplification gain, and operation Flexible electronics have gained considerable attention for application in wearable devices. Organic transistors are potential candidates to develop flexible integrated circuits (ICs). A primary technique for maximizing their reliability, gain, and operation speed is the modulation of charge-carrier behavior in the respective transistors fabricated on the same substrate. In this work, heterogeneous functional dielectric patterns (HFDP) of ultrathin polymer gate dielectrics of poly((±)endo,exo-bicyclo[2.2.1]hept-ene-2,3-dicarboxylic acid, diphenylester) (PNDPE) are introduced. The HFDP that are obtained via the photo-Fries rearrangement by ultraviolet radiation in the homogeneous PNDPE provide a functional area for charge-carrier modulation. This leads to programmable threshold voltage control over a wide range (−1.5 to +0.2 V) in the transistors with a high patterning resolution, at 2 V operational voltage. The transistors also exhibit high operational stability over 140 days and under the bias-stress duration of 1800 s. With the HFDP, the performance metrics of ICs, for example, the noise margin and gain of the zero-V GS load inverters and the oscillation frequency of ring oscillators are improved to 80%, 1200, and 2.5 kHz, respectively, which are the highest among the previously reported zero-V GS -based organic circuits. The HFDP can be applied to much complex and ultraflexible ICs.

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Section: Introductionmentioning

confidence: 99%

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confidence: 99%

Heterogeneous Functional Dielectric Patterns for Charge‐Carrier Modulation in Ultraflexible Organic Integrated Circuits

et al. 2021

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“…A change in temperature affects the self-polarization over the pyroelectric material, leading to electrical currents to compensate for those changes [19][20][21] . However, pyroelectric signals are transient and quickly decay to zero after a change in temperature has taken place, which is not suitable for long-term temperature monitoring [22][23][24][25] . By contrast, recently developed ionic thermoelectric sensors 26 can provide self-generated open-circuit voltages that are stable over time.…”

Section: Introductionmentioning

confidence: 99%

Ultrasensitive electrolyte-assisted temperature sensor

et al. 2020

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Heat sensors form an important class of devices that are used across multiple fields and sectors. For applications such as electronic skin and health monitoring, it is particularly advantageous if the output electronic signals are not only high, stable, and reproducible, but also self-generated to minimize power consumption. Here, we present an ultrasensitive heat sensing concept that fulfills these criteria while also being compatible with scalable low-cost manufacturing on flexible substrates. The concept resembles a traditional thermocouple, but with separated electrodes bridged by a gel-like electrolyte and with orders of magnitudes higher signals (around 11 mV K−1). The sensor pixels provide stable and reproducible signals upon heating, which, for example, could be used for heat mapping. Further modification to plasmonic nanohole metasurface electrodes made the sensors capable of also detecting light-induced heating. Finally, we present devices on flexible substrates and show that they can be used to detect human touch.

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“…[ 124 ] The work demonstrates a lightweight, effective, low cost device using a few common materials and a straightforward approach. This work then spurred much of the research described here in flexible piezoelectric transistor arrays for sensing, including a recent work by Gold et al [ 144 ] Presented as a proof of concept, the pyroelectric effect of PVDF‐TrFE is leveraged in this work to measure proximal human motion between 5 and 20 cm away with a high signal to noise ratio of 28 dB. The device has a 3x3 sensor matrix, where an active matrix approach is used to observe the response of a specific sensing capacitor.…”

Section: Mechanical Sensorsmentioning

confidence: 98%

“…[ 125 ] In some active matrix arrays, the transistors are simply used to address a specific piezoelectric capacitor for sensing. [ 124,143,144 ] In this case, the piezoelectric element is connected to the source or drain of one transistor in the active matrix and the piezoelectric response is read out when that transistor is activated. In this approach, there is no immediate amplification of the charge, and any needed amplification will have to be added in off‐chip electronics.…”

Section: Mechanical Sensorsmentioning

confidence: 99%

Organic Thin Film Transistors in Mechanical Sensors

Lamport

Cavallari

Kam

et al. 2020

Adv Funct Materials

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The marriage of organic thin‐film transistors (OTFTs) and flexible mechanical sensors has enabled previously restricted applications to become a reality. Counterintuitively, the addition of an OTFT at each sensing element can reduce the overall complexity so that large‐area, low‐noise sensors can be fabricated. The best‐performing instance of this is the active matrix, used in display applications for many of the same reasons, and nearly any type of flexible mechanical sensor can be incorporated into these structures. In this Progress Report, some of the flexible sensor devices that have taken advantage of these mechanical properties are highlighted, examining the advantages that OTFTs offer in the hybrid integration of local amplification and switching. In particular, the current research on resistive pressure sensors, capacitive pressure sensors, resistive or piezoresistive strain sensors, and piezoelectric sensors is identified and enumerated.

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Flexible Single‐Substrate Integrated Active‐Matrix Pyroelectric Sensor

Cited by 15 publications

References 37 publications

Heterogeneous Functional Dielectric Patterns for Charge‐Carrier Modulation in Ultraflexible Organic Integrated Circuits

Heterogeneous Functional Dielectric Patterns for Charge‐Carrier Modulation in Ultraflexible Organic Integrated Circuits

Ultrasensitive electrolyte-assisted temperature sensor

Organic Thin Film Transistors in Mechanical Sensors

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