Molecular Engineering of Silicon Phthalocyanine to Improve the Charge Transport and Ammonia Sensing Properties of Organic Heterojunction Gas Sensors

Moorthy, Sujithkumar Ganesh; King, Benjamin; Kumar, Abhishek; Lesniewska, Éric; Lessard, Benoît H.; Bouvet, Marcel

doi:10.1002/adsr.202200030

Cited by 12 publications

(14 citation statements)

References 58 publications

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“…47 Even though double-layer heterojunctions are less sensitive than double lateral heterojunctions, 48,49 they exhibit better LOD due to lower noise. Thus, AM6/LuPc 2 exhibits a LOD comparable to the best ever reported for heterojunction devices, i.e., 100 ppb, based on fluorinated silicon phthalocyanine, 36 and even better under illumination. It is worth mentioning that the present sensors favorably compete with previously reported devices and operate in a humid atmosphere and at room temperature.…”

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confidence: 53%

“…This difference could be due to morphological differences between the heterojunctions, as already demonstrated with silicon phthalocyanine-based gas sensors. 36 Here, we observe an opposite response to humidity (current increase) and NH 3 (current decrease). So, it is difficult to predict the variation of the response to NH 3 upon changing the RH value.…”

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confidence: 57%

“…Up to now, 100 ppb has been reported with a silicon phthalocyanine-based heterojunction device, and between 100 and 500 ppb in a few examples. 36 Such response enhancement under light has already been reported, but only with inorganic conductometric gas sensors. 45 Two phenomena can occur in the present molecular material-based sensors.…”

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confidence: 90%

“…Such features were characteristic of bilayer organic heterojunction devices, originating from the accumulation of mobile charges at the interface. 11,36 Both sublayers are highly resistive compared to LuPc 2 . 37 Due to the poorly conductive sublayer, the injected charges from the electrode experienced high resistance, resulting in a smaller current at a lower voltage.…”

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confidence: 99%

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π-Extended Porphyrin–Phthalocyanine Heterojunction Devices Exhibiting High Ammonia Sensitivity with a Remarkable Light Effect

Ganesh Moorthy,

Arvidson,

Meunier-Prest

et al. 2024

ACS Sens.

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π-Extended porphyrins represent an attractive class of organic compounds because of their unique photophysical, optoelectronic, and physicochemical properties. Herein, crossconjugated (Ace-PQ-Ni) and linear-conjugated (AM6) porphyrins are used to build double-layer heterojunction devices by combining them with a lutetium bisphthalocyanine complex (LuPc 2 ). The heterojunction effect at the porphyrin−phthalocyanine interface plays a key role in the charge transport properties. Both devices exhibit exceptionally high ammonia sensitivity at room temperature and under ambient relative humidity, with limit of detection values of 156 and 115 ppb for Ace-PQ-Ni/LuPc 2 and AM6/LuPc 2 sensors, respectively. Interestingly, the Ace-PQ-Ni/LuPc 2 and AM6/LuPc 2 sensors display opposite effects upon light illumination. While the former sensors show largely decreased ammonia sensitivity under light illumination, the current variation of the latter under ammonia is remarkably enhanced with a multiplication factor of 13 and a limit of detection (LOD) of 83 ppb. The striking difference in their sensing properties upon light illumination is attributed to their different π-conjugation pathways (cross-conjugation versus linear conjugation).

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confidence: 53%

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confidence: 57%

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confidence: 90%

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confidence: 99%

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π-Extended Porphyrin–Phthalocyanine Heterojunction Devices Exhibiting High Ammonia Sensitivity with a Remarkable Light Effect

Ganesh Moorthy,

Arvidson,

Meunier-Prest

et al. 2024

ACS Sens.

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“…25 In majority of the cases, the top layer was lutetium bis-phthalocyanine (LuPc 2 ) because of its radical nature, imparting high charge carrier density, except in few cases when porphyrin tapes were coated as an alternative to LuPc 2 . 19 Hosts of low-conducting MPc, MP, and similar macrocycles were used as a sublayer, investigating the role of the central metal atom, 26 the peripheral substituents, 27 and the axial ligands 28 on the device charge transport properties and finally the sensing behavior toward NH 3 . MSDI heterojunction devices displayed high sensitivity toward NH 3 with limits of detection going down to 250 ppb in the case of the Co(Cl 8 Pc)/LuPc 2 heterojunction.…”

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confidence: 99%

Tuning of Interfacial Charge Transport in Organic Heterostructures via Aryl Electrografting for Efficient Gas Sensors

Kumar,

Nwosu,

Meunier-Prest

et al. 2024

ACS Appl. Mater. Interfaces

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Modulation of interfacial conductivity in organic heterostructures is a highly promising strategy to improve the performance of electronic devices. In this endeavor, the present work reports the fabrication of a bilayer heterojunction device, combining octafluoro copper phthalocyanine (CuF 8 Pc) and lutetium bis-phthalocyanine (LuPc 2 ) and tunes the charge transport at the Cu(F 8 Pc)-(LuPc 2 ) interface by aryl electrografting on the device electrode to improve the device NH 3 -sensing properties. Dimethoxybenzene (DMB) and tetrafluoro benzene (TFB) electrografted by an aryldiazonium electroreduction method form a fewnanometer-thick organic film on ITO. The conductivity of the heterojunction devices formed by coating a Cu(F 8 Pc)/LuPc 2 bilayer over the aryl-grafted electrode strongly varies according to the electronic effects of the substituents in the aryl. Accordingly, DMB increases while TFB decreases the mobile charges accumulation at the Cu(F 8 Pc)-(LuPc 2 ) interface. This is explained by the perfect alignment of the frontier molecular orbitals of DMB and Cu(F 8 Pc), facilitating charge injection into the Cu(F 8 Pc) layer. On the contrary, TFB behaves like a strong acceptor and reduces the mobile charges accumulation at the Cu(F 8 Pc)-(LuPc 2 ) interface. Such interfacial conductivity variation influences the device NH 3 -sensing properties, which increase because of DMB grafting and decrease in the presence of TFB. DMB-based heterojunction devices contain four times higher active sites for NH 3 adsorption and could detect NH 3 down to 1 ppm with limited interference from humidity, making them suitable for real environment NH 3 detection.

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Axial Phenoxylation of Aluminum Phthalocyanines for Improved Cannabinoid Sensitivity in OTFT Sensors

Lamontagne,

Cranston,

Comeau

et al. 2024

Advanced Science

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Cannabis producers, consumers, and regulators need fast, accurate, point‐of‐use sensors to detect Δ9‐tetrahydrocannabinol (THC) and cannabidiol (CBD) from both liquid and vapor source samples, and phthalocyanine‐based organic thin‐film transistors (OTFTs) provide a cost‐effective solution. Chloro aluminum phthalocyanine (Cl‐AlPc) has emerged as a promising material due to its unique coordinating interactions with cannabinoids, allowing for superior sensitivity. This work explores the molecular engineering of AlPc to tune and enhance these interactions, where a series of novel phenxoylated R‐AlPcs are synthesized and integrated into OTFTs, which are then exposed to THC and CBD solution and vapor samples. While the R‐AlPc substituted molecules have a comparable baseline device performance to Cl‐AlPc, their new crystal structures and weakened intermolecular interactions increase sensitivity to THC. Grazing‐incidence wide‐angle X‐ray scattering (GIWAXS) and atomic force microscopy (AFM) are used to investigate this film restructuring, where a significant shift in the crystal structure, grain size, and film roughness is detected for the R‐AlPc molecules that do not occur with Cl‐AlPc. This significant crystal reorganization and film restructuring are the driving force behind the improved sensitivity to cannabinoids relative to Cl‐AlPc and demonstrate that analyte–semiconductor interactions can be enhanced through chemical modification to create more responsive OTFT sensors.

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Molecular Engineering of Silicon Phthalocyanine to Improve the Charge Transport and Ammonia Sensing Properties of Organic Heterojunction Gas Sensors

Cited by 12 publications

References 58 publications

π-Extended Porphyrin–Phthalocyanine Heterojunction Devices Exhibiting High Ammonia Sensitivity with a Remarkable Light Effect

π-Extended Porphyrin–Phthalocyanine Heterojunction Devices Exhibiting High Ammonia Sensitivity with a Remarkable Light Effect

Tuning of Interfacial Charge Transport in Organic Heterostructures via Aryl Electrografting for Efficient Gas Sensors

Axial Phenoxylation of Aluminum Phthalocyanines for Improved Cannabinoid Sensitivity in OTFT Sensors

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