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Mixed P3HT/PCBM Organic Thin-Film Transistors： Relation between Morphology and Electrical Characteristics

Journal of Chemistry and Chemical Engineering 2014年第5期8卷 476-481页

作者： Khairul Anuar Mohamad Afishah Alias Ismail Saad bablu kumar gosh Katsuhiro Uesugi Hisashi Fukuda Nanoelectronics Device and Materials Research Group Universiti Malaysia Sabah Sabah 88400 Malaysia Muroran Institute of Technology Muroran 050-8585 Japan

The mixed P3HT （poly（3-hexylthiophene）） and [6,6]-PCBM （phenyl C61-butyric acid methyl ester） organic thin films were investigated for electronic structure using UV-Vis spectrophotometer and PESA （photo-electron spectroscopy in air）. Furthermore, ESR （electron spin resonance） and AFM （atomic force microscopy） were used to investigate the surface morphology and molecular orientation, respectively. ESR analysis indicated the molecular orientation of the P3HT crystalline in the blend thin films, which the crystalline oriented normal to the substrate with distribution of 35°. AFM images indicated that the surface morphology of P3HT film was affected by the presence of PCBM nanoparticles. Solution-processed OTFTs （organic thin-film transistors） based on P3HT/PCBM blend thin film in a top source-drain contact structure was fabricated, and the electrical characteristics of the devices were also investigated. A unipolar property with p-channel characteristics were obtained in glove box measurement.

关键词： Organic semiconductor P3HT PCBM P3HT/PCBM blend thin film organic thin-film transistor.

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Electrical properties of 0-30.5(Ba_(0.7)Ca_(0.3))TiO_(3)-0.5Ba(Zr_(0.2)Ti_(0.8))O_(3)/PVDF nanocomposites

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Journal of Advanced Dielectrics 2018年第4期8卷 35-42页

作者： bablu K.Pandey Amit kumar K.P.Chandra A.R Kulkarni S.K Jayaswal K.Prasad University Department of Physics T.M.Bhagalpur University Bhagalpur 812007 India Department of Mechanical Engineering Birla Institute of Technology Mesra(Patna Campus) Patna 800014India Department of Physics S.M.College Bhagalpur 812001India Department of Metallurgical Engineering and Materials Science Indian Institute of Technology Mumbai 400076 India

Lead-free x(0.50(Ba_(0.7)Ca_(0.3)TiO_(3)-0.50Ba(Zr_(0.2)Ti_(0.8)O_(3)-(1-x)PVDF ceramic–polymer nanocomposites with x=0.025,0.05,0.10,0.15,0.20,0.25 were prepared using melt-mixing *** distribution of nanoceramic filler particles(0.50(Ba_(0.7)Ca_(0.3)TiO_(3)-0.50Ba(Zr_(0.2)Ti_(0.8)O_(3)in the PVDF matrix were examined using scanning electron *** analysis indicated the negative temperature coefficient of resistance character of all the test *** concentrationdependent piezoelectric coefficient(d33Þdata followed exponential growth types of *** data for ac conductivity were found to obey Jonscher’s power *** correlated barrier hopping(CBH)model was found to explain the mechanism of charge transport occurring in the *** low value of loss tangent(-10^(-2))along with the high value of d_(33) foreshadowing the prospect of present nanocomposite is a better nonlead option for piezo-sensing/detection applications,especially in bio-medical area.

关键词： Random composite medium dielectric properties piezoelectric properties impedance analysis.

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Biotransformation,multifunctional recycling mechanism of nanostructures,and evaluation of the safety of nanoscale materials

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Particuology 2023年第11期82卷 76-86页

作者： Debjyoti Talukdar Parveen kumar Benu Chaudhary Deepak Sharma Nishant Yadav Obaid Afzal Abdulmalik Saleh Alfawaz Altamimi Waleed Hassan Almalki Sami IAlzarea Imran Kazmi Ashutosh Pareek Gaurav Gupta Madan Mohan Gupta Department of Medical Research Armenian Russian International University“Mkhitar Gosh”YerevanArmenia Shri Ram College of Pharmacy KarnalHaryanaIndia Guru Gobind Singh College of Pharmacy YamunanagarHaryanaIndia Department of Pharmaceutical Technology SOMSAdamas UniversityBarasat-Barracpore RoadKolkataWest BengalIndia B.S.Anangpuria Institute of Pharmacy FaridabadHaryanaIndia Department of Pharmaceutical Chemistry College of PharmacyPrince Sattam Bin Abdulaziz UniversityAl Kharj11942Saudi Arabia Department of Pharmacology College of PharmacyUmm Al-Qura UniversityMakkahSaudi Arabia Department of Pharmacology College of PharmacyJouf UniversitySakakaAl-JoufSaudi Arabia Department of Biochemistry Faculty of ScienceKing Abdulaziz UniversityJeddahSaudi Arabia Department of Pharmacy Banasthali VidyapithBanasthali-RajasthanIndia School of Pharmacy Suresh Gyan Vihar UniversityJagatpura302017Mahal RoadJaipurIndia Department of Pharmacology Saveetha Dental CollegeSaveetha Institute of Medical and Technical SciencesSaveetha UniversityChennaiIndia Uttaranchal Institute of Pharmaceutical Sciences Uttaranchal UniversityDehradunIndia School of Pharmacy Faculty of Medical SciencesThe University of the West IndiesSt.AugustineTrinidad and Tobago

Current evidence of concept analyses recommending nanotechnology for biomedical uses abounds in recent research. The area of biotechnology interfaces with nanostructures, reconfigures their composition, and alters their characteristics;which influences the dispersion of the particles, the biotransformation they cause, and their potential toxic effect. It is vital to link the idea of the lifecycle of nanostructures to the biological impacts and use methodologies to identify, estimate, and track the gradual bioprocessing of nanostructures in vivo, from a body-wide level to a nanoscopic size. This is necessary because understanding how nanostructures processing, degradation, persistence, and recycling predict potential exposure risks. The safe implementation of nanotechnology-based products in biomedical applications necessitates an extensive understanding of the recycling and transformations of nanomaterials in a living organism. Long-term fate in the body is crucial, as it governs potential environmental risks to human health. Strategies may be used to manage the long-term outcome of nanostructures in an organism since, in addition to composition, their design also affects how long they last and how easily they degrade. The lifespan of nanoparticles, a flexible and biocompatible category of nanostructures that have made it into clinical trials, is the subject of this article. Strategies may be used to manage the long-term outcome of nanoparticles in an organism since, in addition to composition, their design also affects how long they last and how easily they degrade. This review explained the safety of nanoscale materials, biotransformation, and the multifunctional recycling mechanism of nanostructures.

关键词： Nanostructure Nanoparticle Biotransformation Toxiceffect Environmental risk

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