A high-yield vacuum-evaporation-based R2R-compatible fabrication route for organic electronic circuits

Research output: Contribution to journalArticlepeer-review

Standard Standard

A high-yield vacuum-evaporation-based R2R-compatible fabrication route for organic electronic circuits. / Patchett, E.R.; Patchett, E.F.; Williams, A. et al.
In: Organic Electronics, Vol. 15, No. 7, 24.04.2014, p. 1493-1502.

Research output: Contribution to journalArticlepeer-review

HarvardHarvard

Patchett, ER, Patchett, EF, Williams, A, Ding, Z, Abbas, G, Assender, HE, Morrison, JJ, Yeates, SG & Taylor, DM 2014, 'A high-yield vacuum-evaporation-based R2R-compatible fabrication route for organic electronic circuits', Organic Electronics, vol. 15, no. 7, pp. 1493-1502. https://doi.org/10.1016/j.orgel.2014.03.043

APA

Patchett, E. R., Patchett, E. F., Williams, A., Ding, Z., Abbas, G., Assender, H. E., Morrison, J. J., Yeates, S. G., & Taylor, D. M. (2014). A high-yield vacuum-evaporation-based R2R-compatible fabrication route for organic electronic circuits. Organic Electronics, 15(7), 1493-1502. https://doi.org/10.1016/j.orgel.2014.03.043

CBE

Patchett ER, Patchett EF, Williams A, Ding Z, Abbas G, Assender HE, Morrison JJ, Yeates SG, Taylor DM. 2014. A high-yield vacuum-evaporation-based R2R-compatible fabrication route for organic electronic circuits. Organic Electronics. 15(7):1493-1502. https://doi.org/10.1016/j.orgel.2014.03.043

MLA

VancouverVancouver

Patchett ER, Patchett EF, Williams A, Ding Z, Abbas G, Assender HE et al. A high-yield vacuum-evaporation-based R2R-compatible fabrication route for organic electronic circuits. Organic Electronics. 2014 Apr 24;15(7):1493-1502. doi: 10.1016/j.orgel.2014.03.043

Author

Patchett, E.R. ; Patchett, E.F. ; Williams, A. et al. / A high-yield vacuum-evaporation-based R2R-compatible fabrication route for organic electronic circuits. In: Organic Electronics. 2014 ; Vol. 15, No. 7. pp. 1493-1502.

RIS

TY - JOUR

T1 - A high-yield vacuum-evaporation-based R2R-compatible fabrication route for organic electronic circuits

AU - Patchett, E.R.

AU - Patchett, E.F.

AU - Williams, A.

AU - Ding, Z.

AU - Abbas, G.

AU - Assender, H.E.

AU - Morrison, J.J.

AU - Yeates, S.G.

AU - Taylor, D.M.

PY - 2014/4/24

Y1 - 2014/4/24

N2 - Advances are described in a vacuum-evaporation-based approach for the roll-to-roll (R2R) production of organic thin film transistors (TFTs) and circuits. Results from 90-transistor arrays formed directly onto a plasma-polymerised diacrylate gate dielectric are compared with those formed on polystyrene-buffered diacrylate. The latter approach resulted in stable, reproducible transistors with yields in excess of 90%. The resulting TFTs had low turn-on voltage, on–off ratios ∼106 and mobility ∼1 cm2/V s in the linear regime, as expected for dinaphtho[2,3-b:2′,3′-f] thieno[3,2-b]thiophene the air stable small molecule used as the active semiconductor. We show that when device design is constrained by the generally poor registration ability of R2R processes, parasitic source–drain currents can lead to a >50% increase in the mobility extracted from the resulting TFTs, the increases being especially marked in low channel width devices. Batches of 27 saturated-load inverters were fabricated with 100% yield and their behaviour successfully reproduced using TFT parameters extracted with Silvaco’s UOTFT Model. 5- and 7-stage ring oscillator (RO) outputs ranged from ∼120 Hz to >2 kHz with rail voltages, VDD, increasing from −15 V to −90 V. From simulations an order of magnitude increase in frequency could be expected by reducing parasitic gate capacitances. During 8 h of continuous operation at VDD = −60 V, the frequency of a 7-stage RO remained almost constant at ∼1.4 kHz albeit that the output signal amplitude decreased from ∼22 V to ∼10 V. Over the next 30 days of intermittent operation further degradation in performance occurred although an unused RO showed no deterioration over the same period.

AB - Advances are described in a vacuum-evaporation-based approach for the roll-to-roll (R2R) production of organic thin film transistors (TFTs) and circuits. Results from 90-transistor arrays formed directly onto a plasma-polymerised diacrylate gate dielectric are compared with those formed on polystyrene-buffered diacrylate. The latter approach resulted in stable, reproducible transistors with yields in excess of 90%. The resulting TFTs had low turn-on voltage, on–off ratios ∼106 and mobility ∼1 cm2/V s in the linear regime, as expected for dinaphtho[2,3-b:2′,3′-f] thieno[3,2-b]thiophene the air stable small molecule used as the active semiconductor. We show that when device design is constrained by the generally poor registration ability of R2R processes, parasitic source–drain currents can lead to a >50% increase in the mobility extracted from the resulting TFTs, the increases being especially marked in low channel width devices. Batches of 27 saturated-load inverters were fabricated with 100% yield and their behaviour successfully reproduced using TFT parameters extracted with Silvaco’s UOTFT Model. 5- and 7-stage ring oscillator (RO) outputs ranged from ∼120 Hz to >2 kHz with rail voltages, VDD, increasing from −15 V to −90 V. From simulations an order of magnitude increase in frequency could be expected by reducing parasitic gate capacitances. During 8 h of continuous operation at VDD = −60 V, the frequency of a 7-stage RO remained almost constant at ∼1.4 kHz albeit that the output signal amplitude decreased from ∼22 V to ∼10 V. Over the next 30 days of intermittent operation further degradation in performance occurred although an unused RO showed no deterioration over the same period.

U2 - 10.1016/j.orgel.2014.03.043

DO - 10.1016/j.orgel.2014.03.043

M3 - Article

VL - 15

SP - 1493

EP - 1502

JO - Organic Electronics

JF - Organic Electronics

SN - 1566-1199

IS - 7

ER -