High response organic ultraviolet photodetectors(UV-PDs) were demonstrated with 4,4',4”- tris[3-methyl-pheny(phenyl)amino]triphenylamine(m-MTDATA) and two Re(Ⅰ) complexes, (bathocuproine)- Re(CO)3CI(Re...High response organic ultraviolet photodetectors(UV-PDs) were demonstrated with 4,4',4”- tris[3-methyl-pheny(phenyl)amino]triphenylamine(m-MTDATA) and two Re(Ⅰ) complexes, (bathocuproine)- Re(CO)3CI(Re-BCP) and (bathophenanthroline)Re(CO)3Cl(Re-Bphen) to act as the electron donor and acceptor, re- spectively. UV-PDs have the configuration of indium tin oxide(ITO)/m-MTDATA(25 nm)/m-MTDATA:Re-complex (25-35 nm)/Re-complex(20 nm)/LiF(l nm)/Al(200 nm) with different blend layer thicknesses of 25, 30 and 35 nm. The optimized PD based on Re-Bphen offers a corrected-dark photocurrent up to 760μA/cm^2 at -10 V, corresponding to a response of 310 mA/W which is among the best values reported for organic UV-PDs. Excellent electron transport ability makes for such high photo-to-electron conversion.展开更多
It is of vital importance to improve the long-term and photostability of organic photovoltaics,including organic solar cells(OSCs)and organic photodetectors(OPDs),for their ultimate industrialization.Herein,two series...It is of vital importance to improve the long-term and photostability of organic photovoltaics,including organic solar cells(OSCs)and organic photodetectors(OPDs),for their ultimate industrialization.Herein,two series of terpolymers featuring with an antioxidant butylated hydroxytoluene(BHT)-terminated side chain,PTzBI-EHp-BTBHTx and N2200-BTBHTx(x=0.05,0.1,0.2),are designed and synthesized.It was found that incorporating appropriate ratio of benzothiadiazole(BT)with BHT side chains on the conjugated backbone would induce negligible effect on the molecular weight,absorption spectra and energy levels of polymers,however,which would obviously enhance the photostability of these polymers.Consequently,all-polymer solar cells(all-PSCs)and photodetectors were fabricated,and the all-PSC based on PTzBI-EHp-BTBHT0.05:N2200 realized an optimal power conversion efficiency(PCE)approaching~10%,outperforming the device based on pristine PTzBI-EHp:N2200.Impressively,the all-PSCs based on BHT-featuring terpolymers displayed alleviated PCEs degradation under continuous irradiation for 300 h due to the improved morphological and photostability of active layers.The OPDs based on BHT-featuring terpolymers achieved a lower dark current at−0.1 bias,which could be stabilized even after irradiation over 400 h.This study provides a feasible approach to develop terpolymers with antioxidant efficacy for improving the lifetime of OSCs and OPDs.展开更多
We report fabrication and characterization of organic heterojunction UV detectors based on N,N'-bis(naphthalen- 1-y1)-N,N'-bis (phenyl) benzidine (NPB) and fullerene C60. The effects of different thicknesses o...We report fabrication and characterization of organic heterojunction UV detectors based on N,N'-bis(naphthalen- 1-y1)-N,N'-bis (phenyl) benzidine (NPB) and fullerene C60. The effects of different thicknesses of NPB and C60 layers are studied and compared. Notably, the optimal thicknesses of electron acceptor C60 and electron donor NPB are 40 nm and 80 nm, respectively. The J V characteristic curves of the device demonstrate a three-order- of-magnitude difference when illuminated under a 350nm UV light and in the dark at -0.5 V. The device exhibits high sensitivity in the region of 320-380nm with the peak located around 35Onm. Especially, it shows excellent photo-response characteristic with a responsivity as high as 315 mA/W under the illumination of 192μW.cm 2 350nm UV light at -5 V. These results indicate that the NPB/C60 heterojunction structure device might be used as low-cost low-voltage UV photodetectors.展开更多
The domain purity,material crystallinity and distribution at the interface between the active layer and the transport layer have an important impact on the performance of organic solar cells(OSCs)and organic photodete...The domain purity,material crystallinity and distribution at the interface between the active layer and the transport layer have an important impact on the performance of organic solar cells(OSCs)and organic photodetectors(OPDs),while this focal issue has received less attention in previous studies.From this perspective,a new method to simultaneously enhance the performance of OSC and OPD is proposed,namely,using a sequential deposition method to first construct a compact stacking structure of dualdonor(D18-Cl:PTO2)eutectic in the donor layer,and then induce the ordered deposition of the acceptor(Y6).Compared with the conventional bulk heterojunction(BHJ),the active layer realized by this method not only improves the crystallinity and stacking order of the constituent material on the surface of the transport layer,but also regulates a good vertical distribution,which is conducive to improving the charge transport and extraction efficiency,reducing the leakage current,and enhancing the stability of the device.As a result,the OSC device based on the D18-Cl:PTO2/Y6 structure achieves a power conversion efficiency of up to 17.65%and good light-degradation stability,which is much better than that of BHJbased OSC(PCE of 16.37%).For the OPD,the dark current at reverse bias is reduced by more than an order of magnitude,and the maximum responsivity is improved to 0.52 A/W through the optimization of the donor phase at the interface.Moreover,the strategy does not require additional post-processing compared to the BHJ preparation,which reduces the device construction cost and process complexity,providing an effective way for developing high-performance organic optoelectronic devices.展开更多
Comprehensive Summary Near infrared light organic photodetectors have attracted tremendous attention due to their tailorable response,ease of processing,compatibility with flexible substrate,room temperature operation...Comprehensive Summary Near infrared light organic photodetectors have attracted tremendous attention due to their tailorable response,ease of processing,compatibility with flexible substrate,room temperature operation and broad applications such as remote sensing,health monitoring,artificial vision,night vision,and so on.Recently,the great improvement obtained on the important figures of merit performances has made organic photodetectors catch up and even surpass those of inorganic photodetectors in some respects.In this review,after a brief illustration of the organic photodetectors'figures of merit performances,we summarize the research progress of panchromatic and narrowband near infrared light organic photodetectors from their working mechanism,strategies to achieve narrowband near infrared light organic photodetectors,to some practical applications.Finally,we discuss the development challenge of the near infrared light organic photodetectors.展开更多
Organic near-infrared(NIR)photodetectors with essential applications in medical diagnostics,night vision,remote sensing,and optical communications have attracted intensive research interest.Compared with most conventi...Organic near-infrared(NIR)photodetectors with essential applications in medical diagnostics,night vision,remote sensing,and optical communications have attracted intensive research interest.Compared with most conventional inorganic counterparts,organic semiconductors usually have higher absorption coefficients,and their thin active layer could be sufficient to absorb most incident light for effective photogeneration.However,due to the relatively poor charge mobility of organic materials,it remains challenging to inhibit the photogenerated exciton recombination and effectively extract carriers to their respective electrodes.Herein,this challenge was addressed by increasing matrix conductivities of a ternary active layer(D–A–D structure NIR absorber[2TT-oC6B]:poly(N,N′-bis-4-butylphenyl-N,N′-bisphenyl)benzidin[PolyTPD]:[6,6]-phenyl-C61-butyric acid methyl ester[PCBM]=1:1:1)upon in situ incident light illumination,significantly accelerating charge transport through percolated interpenetrating paths.The greatly enhanced photoconductivity under illumination is intrinsically related to the unique donor–acceptor molecular structures of PolyTPD and 2TT-oC6B,whereas stable intermolecular interaction has been verified by systematic molecular dynamics simulation.In addition,an ultrafast charge transfer time of 0.56 ps from the NIR aggregation-induced luminogens of 2TT-oC6B absorber to PolyTPD and PCBM measured by femtosecond transient absorption spectroscopy is beneficial for effective exciton dissociation.The solution-processed organic NIR photodetector exhibits a fast response time of 83μs and a linear dynamic range value of 111 dB under illumination of 830 nm.Therefore,our work has opened up a pioneering window to enhance photoconductivity through in situ photoirradiation and benefit NIR photodetectors as well as other optoelectronic devices.展开更多
Organic optoelectronic materials enable cutting-edge,low-cost organic photodiodes,including organic solar cells(OSCs)for energy conversion and organic photodetectors(OPDs)for image sensors.The bulk heterojunction(BHJ)...Organic optoelectronic materials enable cutting-edge,low-cost organic photodiodes,including organic solar cells(OSCs)for energy conversion and organic photodetectors(OPDs)for image sensors.The bulk heterojunction(BHJ)structure,derived by blending donor and acceptor materials in a single solution,has dominated in the construction of active layer,but its morphological evolution during film formation poses a great challenge for obtaining an ideal nanoscale morphology to maximize exciton dissociation and minimize nongeminate recom-bination.Solution sequential deposition(SSD)can deliver favorable p–i–n vertical component distribution with abundant donor/acceptor interfaces and relatively neat donor and acceptor phases near electrodes,making it highly promising for excellent device performance and long-term stability.Focusing on the p–i–n structure,this review provides a systematic retrospect on regulating this morphology in SSD by summarizing solvent selection and additive strategies.These methods have been successfully implemented to achieve well-defined morphology in ternary OSCs,all-polymer solar cells,and OPDs.To provide a practical perspective,comparative studies of device stability with BHJ and SSD film are also discussed,and we review influential progress in blade-coating techniques and large-area modules to shed light on industrial production.Finally,challenging issues are out-lined for further research toward eventual commercialization.展开更多
We choose 8-hydroxyquinoline derivative-metal complexes(Beq,Mgq,and Znq) as the acceptors(A) and 4,4',4”-tri-(2-methylphenyl phenylamino) triphenylaine(m-MTDATA) as the donor(D) respectively to study the e...We choose 8-hydroxyquinoline derivative-metal complexes(Beq,Mgq,and Znq) as the acceptors(A) and 4,4',4”-tri-(2-methylphenyl phenylamino) triphenylaine(m-MTDATA) as the donor(D) respectively to study the existing energy transfer process in the organic ultraviolet(UV) photodetector(PD),which has an important influence on the sensitivity of PDs.The energy transfer process from D to A without exciplex formation is discussed,differing from the working mechanism of previous PDs with Gaq[Zisheng Su,Wenlian Li,Bei Chu,Tianle Li,Jianzhuo Zhu,Guang Zhang,Fei Yan,Xiao Li,Yiren Chen and Chun-Sing Lee 2008 Appl.Phys.Lett.93 103309)]and REq[J.B.Wang,W.L.Li,B.Chu,L.L.Chen,G.Zhang,Z.S.Su,Y.R.Chen,D.F.Yang,J.Z.Zhu,S.H.Wu,F.Yan,H.H.Liu,C.S.Lee 2010 Org.Electron.111301]used as an A material.Under 365-nm UV irradiation with an intensity of 1.2 mW/cm^2,the m-MTDATA:Beq blend device with a weight ratio of 1:1 shows a response of 192 mAAV with a detectivity of 6.5 × 10^(11) Jones,which exceeds those of PDs based on Mgq(146 mA/W) and Znq(182 mA/W) due to better energy level alignment between m-MTDATA/Beq and lower radiative decay.More photophysics processes of the PDs involved are discussed in detail.展开更多
光谱仪是科研中应用最广泛的光学仪器之一,常用于测量和分析光谱成分.为了实现宽且连续的光谱响应范围,光谱仪需将多种不同波长响应范围的光敏二极管联合起来使用.本文中,我们基于吸收光谱互补的设计思路将一种新型的窄带隙受体(COTIC-4...光谱仪是科研中应用最广泛的光学仪器之一,常用于测量和分析光谱成分.为了实现宽且连续的光谱响应范围,光谱仪需将多种不同波长响应范围的光敏二极管联合起来使用.本文中,我们基于吸收光谱互补的设计思路将一种新型的窄带隙受体(COTIC-4Cl)与聚合物给体(PCE10)相结合,并引入PC71BM作为第三组分,开发了高性能宽波段的有机光敏二极管(OPD).基于三元混合的光探测器显示出300至1200 nm的宽光谱响应,超出了传统硅基光电二极管的响应范围(300–1100 nm).此外,在波长1100 nm处,该器件表现出5×10^(12)Jones的探测率和0.3 A W-1的响应率,并且截止频率大于1 MHz,线性动态范围大于120 d B,是目前报道的OPD中性能最好的器件之一.为了验证OPD在光谱仪中应用的可行性,我们将该器件用作光谱仪的关键部件,可以在300–1200 nm波长范围成功测量样品的吸收光谱.这些结果预示,高性能宽波段的OPDs在下一代光谱仪中的应用前景十分广阔.展开更多
The versatile nature of organic conjugated materials renders their flawless integration into a diverse family of optoelectronic devices with light-harvesting,photodetection,or light-emitting capabilities.Classes of ma...The versatile nature of organic conjugated materials renders their flawless integration into a diverse family of optoelectronic devices with light-harvesting,photodetection,or light-emitting capabilities.Classes of materials that offer the possibilities of two or more distinct optoelectronic functions are particularly attractive as they enable smart applications while providing the benefits of the ease of fabrication using low-cost processes.Here,we develop a novel,multi-purpose conjugated small molecule by combining boron-azadipyrromethene(aza-BODIPY)as electron acceptor with triphenylamine(TPA)as end-capping donor units.The implemented donor–acceptor–donor(D–A–D)configuration,in the form of TPA-azaBODIPY-TPA,preserves ideal charge transfer characteristics with appropriate excitation energy levels,with the additional ability to be used as either a charge transporting interlayer or light-sensing semiconducting layer in optoelectronic devices.To demonstrate its versatility,we first show that TPA-azaBODIPY-TPA can act as an excellent hole transport layer in methylammonium lead triiodide(MAPbI3)-based perovskite solar cells with measured power conversion efficiencies exceeding 17%,outperforming control solar cells with PEDOT:PSS by nearly 60%.Furthermore,the optical bandgap of 1.49 eV is shown to provide significant photodetection in the wavelength range of up to 800 nm where TPA-azaBODIPY-TPA functions as donor in near-infrared organic photodetectors(OPDs)composed of fullerene derivatives.Overall,the established versatility of TPA-azaBODIPY-TPA,combined with its robust thermal stability as well as excellent solubility and processability,provides a new guide for developing highly efficient multi-purpose electronic materials for the next-generation of smart optoelectronic devices.展开更多
基金Supported by the National Natural Science Foundation of China(No.60978059)the Program for New Century Excellent Talents in Universities of China(No.NCET-10-0176)+1 种基金the Key Project of Ministry of Education of China(No.210053)the Natural Science Foundation of Jilin Province,China(Nos.20101543 and 20100549)
文摘High response organic ultraviolet photodetectors(UV-PDs) were demonstrated with 4,4',4”- tris[3-methyl-pheny(phenyl)amino]triphenylamine(m-MTDATA) and two Re(Ⅰ) complexes, (bathocuproine)- Re(CO)3CI(Re-BCP) and (bathophenanthroline)Re(CO)3Cl(Re-Bphen) to act as the electron donor and acceptor, re- spectively. UV-PDs have the configuration of indium tin oxide(ITO)/m-MTDATA(25 nm)/m-MTDATA:Re-complex (25-35 nm)/Re-complex(20 nm)/LiF(l nm)/Al(200 nm) with different blend layer thicknesses of 25, 30 and 35 nm. The optimized PD based on Re-Bphen offers a corrected-dark photocurrent up to 760μA/cm^2 at -10 V, corresponding to a response of 310 mA/W which is among the best values reported for organic UV-PDs. Excellent electron transport ability makes for such high photo-to-electron conversion.
基金The work was financially supported by National Key Research and Development Program of China(2019YFA0705900,2022YFB4200400)funded by MOSTthe Basic and Applied Basic Research Major Program of Guangdong Province(No.2019B030302007)+2 种基金the National Natural Science Foundation of China(No.U21A6002)Guangdong-Hong Kong-Macao joint laboratory of optoelectronic and magnetic functional materials(No.2019B121205002)C.Z.acknowledges the financial support by Basic and Applied Basic Research Major Program of Guangdong Province(No.202201010270).
文摘It is of vital importance to improve the long-term and photostability of organic photovoltaics,including organic solar cells(OSCs)and organic photodetectors(OPDs),for their ultimate industrialization.Herein,two series of terpolymers featuring with an antioxidant butylated hydroxytoluene(BHT)-terminated side chain,PTzBI-EHp-BTBHTx and N2200-BTBHTx(x=0.05,0.1,0.2),are designed and synthesized.It was found that incorporating appropriate ratio of benzothiadiazole(BT)with BHT side chains on the conjugated backbone would induce negligible effect on the molecular weight,absorption spectra and energy levels of polymers,however,which would obviously enhance the photostability of these polymers.Consequently,all-polymer solar cells(all-PSCs)and photodetectors were fabricated,and the all-PSC based on PTzBI-EHp-BTBHT0.05:N2200 realized an optimal power conversion efficiency(PCE)approaching~10%,outperforming the device based on pristine PTzBI-EHp:N2200.Impressively,the all-PSCs based on BHT-featuring terpolymers displayed alleviated PCEs degradation under continuous irradiation for 300 h due to the improved morphological and photostability of active layers.The OPDs based on BHT-featuring terpolymers achieved a lower dark current at−0.1 bias,which could be stabilized even after irradiation over 400 h.This study provides a feasible approach to develop terpolymers with antioxidant efficacy for improving the lifetime of OSCs and OPDs.
基金Supported by the National Natural Science Foundation of China under Grant Nos 61274068 and 61404058the Project of Science and Technology Development Plan of Jilin Province under Grant Nos 20150204003GX and 20130206021GXthe Project of Science and Technology Plan of Changchun City under Grant No 14KG020
文摘We report fabrication and characterization of organic heterojunction UV detectors based on N,N'-bis(naphthalen- 1-y1)-N,N'-bis (phenyl) benzidine (NPB) and fullerene C60. The effects of different thicknesses of NPB and C60 layers are studied and compared. Notably, the optimal thicknesses of electron acceptor C60 and electron donor NPB are 40 nm and 80 nm, respectively. The J V characteristic curves of the device demonstrate a three-order- of-magnitude difference when illuminated under a 350nm UV light and in the dark at -0.5 V. The device exhibits high sensitivity in the region of 320-380nm with the peak located around 35Onm. Especially, it shows excellent photo-response characteristic with a responsivity as high as 315 mA/W under the illumination of 192μW.cm 2 350nm UV light at -5 V. These results indicate that the NPB/C60 heterojunction structure device might be used as low-cost low-voltage UV photodetectors.
基金supported by the National Natural Science Foundation of China(NSFC,Nos.62075029,52130304,62105055 and U2032128)the International Cooperation and Exchange Project of Science and Technology Department of Sichuan Province(No.2020YFH0063)+2 种基金The China Postdoctoral Science Foundation(Nos.2020TQ0058 and 2021M7006)the Fundamental Research Funds for the Central Universities(No.ZYGX2021J017)Shanghai Natural Science Foundation(No.19ZR1463300)。
文摘The domain purity,material crystallinity and distribution at the interface between the active layer and the transport layer have an important impact on the performance of organic solar cells(OSCs)and organic photodetectors(OPDs),while this focal issue has received less attention in previous studies.From this perspective,a new method to simultaneously enhance the performance of OSC and OPD is proposed,namely,using a sequential deposition method to first construct a compact stacking structure of dualdonor(D18-Cl:PTO2)eutectic in the donor layer,and then induce the ordered deposition of the acceptor(Y6).Compared with the conventional bulk heterojunction(BHJ),the active layer realized by this method not only improves the crystallinity and stacking order of the constituent material on the surface of the transport layer,but also regulates a good vertical distribution,which is conducive to improving the charge transport and extraction efficiency,reducing the leakage current,and enhancing the stability of the device.As a result,the OSC device based on the D18-Cl:PTO2/Y6 structure achieves a power conversion efficiency of up to 17.65%and good light-degradation stability,which is much better than that of BHJbased OSC(PCE of 16.37%).For the OPD,the dark current at reverse bias is reduced by more than an order of magnitude,and the maximum responsivity is improved to 0.52 A/W through the optimization of the donor phase at the interface.Moreover,the strategy does not require additional post-processing compared to the BHJ preparation,which reduces the device construction cost and process complexity,providing an effective way for developing high-performance organic optoelectronic devices.
基金the financial support from the National Natural Science Foundation of China(Grant Nos.21975059,22135001,21721002)the Strategic Priority Research Program of Chinese Academy of Sciences(No.XDB36000000)+1 种基金International Partnership Program of the Chinese Academy of Sciences(No.121D11KYSB20190080)Open project of the State Key Laboratory of Electronic Thin Films and Integrated Devices,University of Electronic Science and Technology of China(No.KFJ202101).
文摘Comprehensive Summary Near infrared light organic photodetectors have attracted tremendous attention due to their tailorable response,ease of processing,compatibility with flexible substrate,room temperature operation and broad applications such as remote sensing,health monitoring,artificial vision,night vision,and so on.Recently,the great improvement obtained on the important figures of merit performances has made organic photodetectors catch up and even surpass those of inorganic photodetectors in some respects.In this review,after a brief illustration of the organic photodetectors'figures of merit performances,we summarize the research progress of panchromatic and narrowband near infrared light organic photodetectors from their working mechanism,strategies to achieve narrowband near infrared light organic photodetectors,to some practical applications.Finally,we discuss the development challenge of the near infrared light organic photodetectors.
基金National Natural Science Foundation of China,Grant/Award Numbers:21788102,03012800001Research Grants Council of Hong Kong,Grant/Award Numbers:16307020,16305518,16305618,C6014-20W+3 种基金Innovation and Technology Commission,Grant/Award Number:ITC-CNERC14SC01Shenzhen Science and Technology Innovation Committee,Grant/Award Numbers:JCYJ20190809172615277,GJHZ20210705143204013Science and Technology Development Fund of Macao SAR,Grant/Award Number:FDCT-0044/2020/A1Guangdong Basic and Applied Basic Research Foundation,Grant/Award Number:2020A1515111065。
文摘Organic near-infrared(NIR)photodetectors with essential applications in medical diagnostics,night vision,remote sensing,and optical communications have attracted intensive research interest.Compared with most conventional inorganic counterparts,organic semiconductors usually have higher absorption coefficients,and their thin active layer could be sufficient to absorb most incident light for effective photogeneration.However,due to the relatively poor charge mobility of organic materials,it remains challenging to inhibit the photogenerated exciton recombination and effectively extract carriers to their respective electrodes.Herein,this challenge was addressed by increasing matrix conductivities of a ternary active layer(D–A–D structure NIR absorber[2TT-oC6B]:poly(N,N′-bis-4-butylphenyl-N,N′-bisphenyl)benzidin[PolyTPD]:[6,6]-phenyl-C61-butyric acid methyl ester[PCBM]=1:1:1)upon in situ incident light illumination,significantly accelerating charge transport through percolated interpenetrating paths.The greatly enhanced photoconductivity under illumination is intrinsically related to the unique donor–acceptor molecular structures of PolyTPD and 2TT-oC6B,whereas stable intermolecular interaction has been verified by systematic molecular dynamics simulation.In addition,an ultrafast charge transfer time of 0.56 ps from the NIR aggregation-induced luminogens of 2TT-oC6B absorber to PolyTPD and PCBM measured by femtosecond transient absorption spectroscopy is beneficial for effective exciton dissociation.The solution-processed organic NIR photodetector exhibits a fast response time of 83μs and a linear dynamic range value of 111 dB under illumination of 830 nm.Therefore,our work has opened up a pioneering window to enhance photoconductivity through in situ photoirradiation and benefit NIR photodetectors as well as other optoelectronic devices.
基金supported by the National Key Research and Development Program of China(No.2019YFA0705900)funded by MOST,the Basic and Applied Basic Research Major Program of Guangdong Province(No.2019B030302007)the Natural Science Foundation of China(No.21875073,52122307)the Distinguished Young Scientists Program of Guangdong Province(No.2019B151502021).
文摘Organic optoelectronic materials enable cutting-edge,low-cost organic photodiodes,including organic solar cells(OSCs)for energy conversion and organic photodetectors(OPDs)for image sensors.The bulk heterojunction(BHJ)structure,derived by blending donor and acceptor materials in a single solution,has dominated in the construction of active layer,but its morphological evolution during film formation poses a great challenge for obtaining an ideal nanoscale morphology to maximize exciton dissociation and minimize nongeminate recom-bination.Solution sequential deposition(SSD)can deliver favorable p–i–n vertical component distribution with abundant donor/acceptor interfaces and relatively neat donor and acceptor phases near electrodes,making it highly promising for excellent device performance and long-term stability.Focusing on the p–i–n structure,this review provides a systematic retrospect on regulating this morphology in SSD by summarizing solvent selection and additive strategies.These methods have been successfully implemented to achieve well-defined morphology in ternary OSCs,all-polymer solar cells,and OPDs.To provide a practical perspective,comparative studies of device stability with BHJ and SSD film are also discussed,and we review influential progress in blade-coating techniques and large-area modules to shed light on industrial production.Finally,challenging issues are out-lined for further research toward eventual commercialization.
基金supported by the National Natural Science Foundation of China(Grant Nos.61371046,61405026,61474016,and 61421002)China Postdoctoral Science Foundation(Grant No.2014M552330)
文摘We choose 8-hydroxyquinoline derivative-metal complexes(Beq,Mgq,and Znq) as the acceptors(A) and 4,4',4”-tri-(2-methylphenyl phenylamino) triphenylaine(m-MTDATA) as the donor(D) respectively to study the existing energy transfer process in the organic ultraviolet(UV) photodetector(PD),which has an important influence on the sensitivity of PDs.The energy transfer process from D to A without exciplex formation is discussed,differing from the working mechanism of previous PDs with Gaq[Zisheng Su,Wenlian Li,Bei Chu,Tianle Li,Jianzhuo Zhu,Guang Zhang,Fei Yan,Xiao Li,Yiren Chen and Chun-Sing Lee 2008 Appl.Phys.Lett.93 103309)]and REq[J.B.Wang,W.L.Li,B.Chu,L.L.Chen,G.Zhang,Z.S.Su,Y.R.Chen,D.F.Yang,J.Z.Zhu,S.H.Wu,F.Yan,H.H.Liu,C.S.Lee 2010 Org.Electron.111301]used as an A material.Under 365-nm UV irradiation with an intensity of 1.2 mW/cm^2,the m-MTDATA:Beq blend device with a weight ratio of 1:1 shows a response of 192 mAAV with a detectivity of 6.5 × 10^(11) Jones,which exceeds those of PDs based on Mgq(146 mA/W) and Znq(182 mA/W) due to better energy level alignment between m-MTDATA/Beq and lower radiative decay.More photophysics processes of the PDs involved are discussed in detail.
基金supported by the National Key R&D Program of China (2022YFA1203304)the Minstry of Science and Technology of China (2022YFB4200400 and 2019YFA0705900)the National Natural Science Foundation of China (21935007 and 52025033)。
基金financially supported by the Natural Science Foundation of Guangdong Province (2019B030302007, 2020A1515011028 and 2017A030306011)the National Natural Science Foundation of China (51933003 and 22005102)+2 种基金the Program for Science and Technology Development of Dongguan (2019622163009)Dongguan Innovative Research Team Program (2018607201002)financial support from China Postdoctoral Science Foundation (2020M682696)
文摘光谱仪是科研中应用最广泛的光学仪器之一,常用于测量和分析光谱成分.为了实现宽且连续的光谱响应范围,光谱仪需将多种不同波长响应范围的光敏二极管联合起来使用.本文中,我们基于吸收光谱互补的设计思路将一种新型的窄带隙受体(COTIC-4Cl)与聚合物给体(PCE10)相结合,并引入PC71BM作为第三组分,开发了高性能宽波段的有机光敏二极管(OPD).基于三元混合的光探测器显示出300至1200 nm的宽光谱响应,超出了传统硅基光电二极管的响应范围(300–1100 nm).此外,在波长1100 nm处,该器件表现出5×10^(12)Jones的探测率和0.3 A W-1的响应率,并且截止频率大于1 MHz,线性动态范围大于120 d B,是目前报道的OPD中性能最好的器件之一.为了验证OPD在光谱仪中应用的可行性,我们将该器件用作光谱仪的关键部件,可以在300–1200 nm波长范围成功测量样品的吸收光谱.这些结果预示,高性能宽波段的OPDs在下一代光谱仪中的应用前景十分广阔.
基金Singapore Ministry of Education Academic Research Fund Tier 2,Grant/Award Number:MOE2019-T2-1-085Australian Research Council,Grant/Award Number:FT130101337+1 种基金QUT core funding,Grant/Award Number:QUT/322120-0301/07Australia India Strategic Research Fund,Grant/Award Number:AISRF53820。
文摘The versatile nature of organic conjugated materials renders their flawless integration into a diverse family of optoelectronic devices with light-harvesting,photodetection,or light-emitting capabilities.Classes of materials that offer the possibilities of two or more distinct optoelectronic functions are particularly attractive as they enable smart applications while providing the benefits of the ease of fabrication using low-cost processes.Here,we develop a novel,multi-purpose conjugated small molecule by combining boron-azadipyrromethene(aza-BODIPY)as electron acceptor with triphenylamine(TPA)as end-capping donor units.The implemented donor–acceptor–donor(D–A–D)configuration,in the form of TPA-azaBODIPY-TPA,preserves ideal charge transfer characteristics with appropriate excitation energy levels,with the additional ability to be used as either a charge transporting interlayer or light-sensing semiconducting layer in optoelectronic devices.To demonstrate its versatility,we first show that TPA-azaBODIPY-TPA can act as an excellent hole transport layer in methylammonium lead triiodide(MAPbI3)-based perovskite solar cells with measured power conversion efficiencies exceeding 17%,outperforming control solar cells with PEDOT:PSS by nearly 60%.Furthermore,the optical bandgap of 1.49 eV is shown to provide significant photodetection in the wavelength range of up to 800 nm where TPA-azaBODIPY-TPA functions as donor in near-infrared organic photodetectors(OPDs)composed of fullerene derivatives.Overall,the established versatility of TPA-azaBODIPY-TPA,combined with its robust thermal stability as well as excellent solubility and processability,provides a new guide for developing highly efficient multi-purpose electronic materials for the next-generation of smart optoelectronic devices.
