1.Co-Innovation Center of Efficient Processing and Utilization of Forest Resources,Nanjing Forestry University,Nanjing 210037,Jiangsu,China
2.Ministry of Education (MOE)Key Laboratory of Wooden Material Science and Application, Beijing Forestry University,Beijing 100083,China
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董友明,谭艺,李建章.光谱成像技术在木材改性研究领域的应用进展[J].木材科学与技术,2021,35(06):1-8.
DONG You-ming,TAN Yi,LI Jian-zhang.Application of Imaging Spectroscopy in Wood Modification Research[J].Chinese Journal of Wood Science and Technology,2021,35(06):1-8.
木材改性技术是木材提质增效的主要手段。改性剂筛选、改性工艺优化以及改性机理解析等都离不开先进的表征分析技术。光谱成像技术将光谱分析技术与显微成像技术相结合,能够精确表征样品物理化学结构,甚至微观性能,已成为木材改性研究的重要工具。针对近年来光谱成像技术在木材改性研究领域的应用现状,本文主要从红外光谱成像、拉曼光谱成像和激光共聚焦显微成像技术等方面进行了综述,并对此类技术在木材改性研究领域的应用前景进行了展望。
Wood modification is an efficient approach to improve wood properties and function wood. The main research topics of wood modification include the types of modifiers, optimization of the modification process, and investigation of modifying mechanism, which all depend on the advanced characterization and analysis techniques. Imaging spectrometry which is combining a spectrometer with an optical microscope, provides insights of chemical compositions in context with microstructure at the micrometer level, particularly the micro-mechanical properties. It has become an important tool for wood characterization. In this review, the application of imaging spectrometry techniques on wood modification are summarized, mainly including infrared microspectroscopy, Raman microspectroscopy, and confocal laser scanning microscopy. Additionally, the existing problems of the imaging spectrometry techniques used for wood modification are presented, as well as the potential development are outlooked.
木材改性光谱成像技术红外光谱成像拉曼光谱成像激光共聚焦显微成像应用进展
wood modificationmicrospectroscopyinfrared microspectroscopyraman microspectroscopyconfocal laser scanning microscopyapplication progress
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