BackgroundTo date, great strides have been made in elucidating the role of thermochemical pretreatments in the chemical and structural features of plant cell walls; however, there is no clear picture of the plant recalcitrance and its relationship to deconstruction. Previous studies precluded full answers due to the challenge of multiscale features of plant cell wall organization. Complementing the previous efforts, we undertook a systematic, multiscale, and integrated approach to track the effect of microwave-assisted H2SO4 and NaOH treatments on the hierarchical structure of plants, i.e., from a nano- to micrometer scale. We focused on the investigation of the highly recalcitrant sclerenchyma cell walls from sugarcane bagasse.ResultsThrough atomic force microscopy and X-ray diffraction analyses, remarkable details of the assembly of cellulose microfibrils not previously seen were revealed. Following the H2SO4 treatment, we observed that cellulose microfibrils were almost double the width of the alkali pretreated sample at the temperature of 160 °C. Such enlargement led to a greater contact between cellulose chains, with a subsequent molecule alignment, as indicated by the X-ray diffraction (XRD) results with the conspicuous expansion of the average crystallite size. The delignification process had little effect on the local nanometer-sized arrangement of cellulose molecules. However, the rigidity and parallel alignment of cellulose microfibrils were partially degraded. The XRD analysis also agrees with these findings as evidenced by large momentum transfer vectors (q > 20 nm−1), interpreted as indicators of the long-range order of cell wall components, which were similar for all the studied samples except with application of the NaOH treatment at 160 °C. These changes were followed by the eventual swelling of the fiber cell walls.ConclusionsBased on an integrated approach, we presented multidimensional architectural models of cell wall deconstruction resulting from microwave-assisted pretreatments. We provided direct evidence supporting the idea that hemicellulose is the main barrier for the swelling of cellulose microfibrils, whereas lignin adds rigidity to cell walls. Our findings shed light on the design of more efficient strategies, not only for the conversion of biomass to fuels but also for the production of nanocellulose, which has great potential for several applications such as composites, rheology modifiers, and pharmaceuticals.
ResumoNeste trabalho, foram sintetizados e caracterizados nanofios de prata que posteriormente foram usados para produção de uma tinta condutora cuja, caracterização elétrica foi medida através de valores de tensão versus corrente. A primeira fase do trabalho consiste na obtenção dos nanofios pelo método poliol. Nesta fase, fez-se uma análise da estrutura dos fios, com o objetivo de verificar a uniformidade (forma e tamanho). Para estudos da estrutura utilizou-se a microscopia ótica (MO) e microscopia eletrônica de varredura (MEV). Também utilizou-se a espectroscopia de Ultravioleta-Visível (Uv-Vis) para identificação dos nanofios no produto obtido. A segunda fase, consiste no desenvolvimento da tinta condutora, onde nanofios foram redispersados em uma mistura de solventes e CTAB em banho de ultrassom, para obtenção de valores de tensão superficial e viscosidade. Por fim, medidas de corrente contínua da tinta, permitiram a construção da curva tensão versus corrente, da qual se obteve o valor da resistência elétrica. Através da curva foi possível comprovar o caráter condutor da tinta e pela linearidade da curva, verificou-se que a tinta produzida é considerada um material ôhmico. Palavras-chave: Nanofios de prata; Tinta condutora; Resistência elétrica; Lei de ohms. SILVER NANOWIRES SYNTHESIS FOR THE MANUFACTURE OF CONDUCTIVE INKS AbstractIn this work, we were synthesized and characterized silver nanowires were subsequently used for producing a conductive ink which, electrical characterization was measured by voltage versus current values. The first stage of the work is to obtain the nanowires by polyol method. At this stage, an analysis was made of the yarn structure with the aim of verifying the consistency (size and shape). For studies of the structure used the optical microscopy (OM) and scanning electron microscopy (SEM). It also used the ultraviolet-visible spectroscopy (UV-Vis) for identification of the nanowires in the product. The second stage consists in the development of conductive ink, which nanowires were again dispersed in a mixture of solvents and CTAB in an ultrasound bath, to obtain surface tension and viscosity values. Finally, continuous current measurements ink, allowed the construction of the voltage versus current curve, from which was obtained the value of the electrical resistance. Through the curve was possible to prove the driver nature of the ink and linearity of the curve, it was found that the ink produced is considered an ohmic material.
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