Charge Transport Behavior and Ultrasensitive Photoresponse Performance of Exfoliated F<sub>16</sub>CuPc Nanoflakes

Hao, Yan; Li, Yang; Qin, Jiaqian; Hu, Ping; Zhen, Liang; Xu, Cheng‐Yan

doi:10.1002/adom.201901097

Cited by 5 publications

(5 citation statements)

References 59 publications

(88 reference statements)

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“…The electron mobility of 1T‐TaSe 2 ‐contacted device at room temperature is determined to be 0.28 cm 2 V −1 s −1 , larger than that of evaporated Au‐contacted device (0.21 cm 2 V −1 s −1 ). [ 41 ] We then focus on the output characterizations of these two devices. The output curves of evaporated Au‐contacted OFET at room temperature show a nonlinear character as depicted in Figure 2f, while those of 1T‐TaSe 2 ‐contacted devices exhibit obvious linearity with V ds ranging from −5 to 5 V, as presented in Figure 2e, indicating decreased barrier at the contact interface.…”

Section: Resultsmentioning

confidence: 99%

“…[ 9,30,51 ] Compared with evaporated Au contact, 1T‐TaSe 2 contact enables the efficient charge transport within F 16 CuPc for that the superior band‐like charge transport regime is broaden. [ 41 ] The µ – T relation fitted by MTR mechanism can be expressed as Equation ()

μ = μ_{0} α \exp (- \frac{E_{normalT}}{k_{B} T})

…”

Section: Resultsmentioning

confidence: 99%

“…It is observed that both devices exhibit high sensitivity to light even at quite a low source–drain voltage of 1 V, consistent with our previous work, where the optoelectronic performance of F 16 CuPc‐based OPT has been greatly improved by using 2D single‐crystalline F 16 CuPc nanoflake as the channel. [ 41 ] To further explore the optoelectronic performance of 1T‐TaSe 2 ‐contacted device, responsivity ( R ) and specific detectivity ( D *, assuming that the noise of dark current is the major noise source) were evaluated. Responsivity and specific detectivity are defined by Equations () and (), respectively

R = \frac{I_{light} - I_{dark}}{P_{inc} \cdot A}

D * = \frac{R A^{1 / 2}}{{false(2 q I_{dark} false)}^{1 / 2}}

where the I light and I dark represent the source–drain currents under illumination and dark conditions, respectively, P inc is the power density of incident light and A is the effective illumination area.…”

Section: Resultsmentioning

confidence: 99%

“…Most visible‐light OPTs operate on relatively high voltages to deliver high R and D *, whereas F 16 CuPc nanoflake‐based OPT with vdW contact shows superior performance to most visible‐light OPTs even at a very low operating voltage ( V ds = 1 V), which offers new opportunities for emerging photodectectors. [ 41,57–67 ]…”

Section: Resultsmentioning

confidence: 99%

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Lowering the Contact Barriers of 2D Organic F₁₆CuPc Field‐Effect Transistors by Introducing Van der Waals Contacts

Hao

Qin

et al. 2021

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2D organic crystals exhibit efficient charge transport and field‐effect characteristics, making them promising candidates for high‐performance nanoelectronics. However, the strong Fermi level pinning (FLP) effect and large Schottky barrier between organic semiconductors and metals largely limit device performance. Herein, by carrying out temperature‐dependent transport and Kelvin probe force microscopy measurements, it is demonstrated that the introducing of 2D metallic 1T‐TaSe2 with matched band‐alignment as electrodes for F16CuPc nanoflake filed‐effect transistors leads to enhanced field‐effect characteristics, especially lowered Schottky barrier height and contact resistance at the contact and highly efficient charge transport within the channel, which are attributed to the significantly suppressed FLP effect and appropriate band alignment at the nonbonding van der Waals (vdW) hetero‐interface. Moreover, by taking advantage of the improved contact behavior with 1T‐TaSe2 contact, the optoelectronic performance of F16CuPc nanoflake‐based phototransistor is drastically improved, with a maximum photoresponsivity of 387 A W−1 and detectivity of 3.7 × 1014 Jones at quite a low Vds of 1 V, which is more competitive than those of the reported organic photodetectors and phototransistors. The work provides an avenue to improve the electrical and optoelectronic properties of 2D organic devices by introducing 2D metals with appropriate work function for vdW contacts.

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Section: Resultsmentioning

confidence: 99%

μ = μ_{0} α \exp (- \frac{E_{normalT}}{k_{B} T})

…”

Section: Resultsmentioning

confidence: 99%

R = \frac{I_{light} - I_{dark}}{P_{inc} \cdot A}

D * = \frac{R A^{1 / 2}}{{false(2 q I_{dark} false)}^{1 / 2}}

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

See 2 more Smart Citations

Lowering the Contact Barriers of 2D Organic F₁₆CuPc Field‐Effect Transistors by Introducing Van der Waals Contacts

Hao

Qin

et al. 2021

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“…In organic semiconductors, the multiple trap and release (MTR) model is widely used to explain the transport characteristics of carriers . The model considers that the carriers are bound by the local states in the forbidden band of semiconductor when they transport in the extended state.…”

Section: Values Of the Device Performance Parameters (Average Values mentioning

confidence: 99%

Nanowire Junction Induced High Threshold Voltage in Poly(3‐hexylthiophene) Mesoscale Crystalline Thin‐Film Transistors with Significantly Enhanced Mobility

Deng

Jiang

Sun

et al. 2020

Physica Rapid Research Ltrs

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Fabrication of nanowires in polymer films can dramatically enhance the mobility of thin‐film transistors (TFTs). Unlike the popular method of forming nanowires after spin‐coating films, here a water‐bath method to fabricate the micrometer‐long nanowires in the poly(3‐hexylthiophene) (P3HT) solution is introduced, which is suitable for large‐area printing electronic application. The resulting transistor exhibits significantly enhanced mobility and excellent device stability. However, the threshold voltage of the device is increased, compared with the amorphous film device. The underlying mechanism of the mesoscale crystalline induced threshold voltage increase has been rarely studied. The temperature‐dependent characteristics imply that the activation energy of the device with nanowires is higher than that of the amorphous one, indicating nanowires can introduce deep traps. This suggests that the charge transport is mainly limited by the deep traps at the junctions between the nanowires considering the trap density inside the nanowires is significantly low. The deep traps introduced by the junctions can increase the threshold voltage as the device needs higher voltage to fill these traps in the channel before the device is turned on. This explains why the devices with nanowires have an increased threshold voltage while their mobilities are dramatically enhanced.

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Boosting Bidirectional Photoresponse with Wavelength Selectivity through Ambipolar Transport Modulation

Xue,

Gong,

Yan

et al. 2024

Adv Funct Materials

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Negative photoconductive phototransistors, referring to transistors that exhibit a decrease in photocurrent under illumination, have the potential to revolutionize optoelectronic applications involving light, such as optoelectronic logic circuits and visual neural simulation. Currently, achieving negative photoconductivity (NPC) requires complex material design or interface structure construction. However, achieving precise control over NPC behaviors poses a significant challenge. Herein, a simple yet effective strategy is demonstrated for realizing controllable NPC responses in organic phototransistors through ambipolar transport modulation. Due to the controversy between the preferred exciton dissociation/charge separation direction and the gate electric field driven charge drift direction, the main semiconductor channel (n‐ or p‐channel) exhibits NPC behavior under illumination. The validity of this mechanism has been confirmed through intensive studies by varying the component and combination of the p‐n heterostructure. Moreover, devices utilizing ambipolar transport exhibit a wavelength‐selectivity NPC response due to the absorption characteristics of the combined semiconductor materials. Most encouragingly, by incorporating both negative and positve photoconductivity along with wavelength‐selective responses, high‐contrast image sensing, information encryption and decryption, as well as optoelectronic logic circuit design is successfully achieved. This work promotes the design and development of bidirectional optoelectronic devices and offers a new route for developing attractive multifunctional optoelectronic devices.

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Charge Transport Behavior and Ultrasensitive Photoresponse Performance of Exfoliated F₁₆CuPc Nanoflakes

Cited by 5 publications

References 59 publications

Lowering the Contact Barriers of 2D Organic F₁₆CuPc Field‐Effect Transistors by Introducing Van der Waals Contacts

Lowering the Contact Barriers of 2D Organic F₁₆CuPc Field‐Effect Transistors by Introducing Van der Waals Contacts

Nanowire Junction Induced High Threshold Voltage in Poly(3‐hexylthiophene) Mesoscale Crystalline Thin‐Film Transistors with Significantly Enhanced Mobility

Boosting Bidirectional Photoresponse with Wavelength Selectivity through Ambipolar Transport Modulation

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Charge Transport Behavior and Ultrasensitive Photoresponse Performance of Exfoliated F16CuPc Nanoflakes

Cited by 5 publications

References 59 publications

Lowering the Contact Barriers of 2D Organic F16CuPc Field‐Effect Transistors by Introducing Van der Waals Contacts

Lowering the Contact Barriers of 2D Organic F16CuPc Field‐Effect Transistors by Introducing Van der Waals Contacts

Nanowire Junction Induced High Threshold Voltage in Poly(3‐hexylthiophene) Mesoscale Crystalline Thin‐Film Transistors with Significantly Enhanced Mobility

Boosting Bidirectional Photoresponse with Wavelength Selectivity through Ambipolar Transport Modulation

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Product

Resources

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Charge Transport Behavior and Ultrasensitive Photoresponse Performance of Exfoliated F₁₆CuPc Nanoflakes

Lowering the Contact Barriers of 2D Organic F₁₆CuPc Field‐Effect Transistors by Introducing Van der Waals Contacts

Lowering the Contact Barriers of 2D Organic F₁₆CuPc Field‐Effect Transistors by Introducing Van der Waals Contacts