将纳米纤维素添加在塑料中,科学家们必须发现最有效点:最佳量的纳米颗粒间的相互作用能够产生最大强度、达到最新的特性。
As nanocellulose disperses within plastic, scientists must find the sweet spot: the right amount of nanoparticle-matrix interaction that yields the strongest, lightest property.
纳米粒子对玉米秸秆腐解过程中纤维素酶活性有极显著和显著的抑制作用。
The cellulase activity was mostly inhibited, and the inhibition in the former was significant.
为此,本文选用具有生物相容性且来源广泛的纤维素醚与单体共聚,着重于环境响应的智能化聚合物纳米胶束的制备。
Therefore, in this thesis we adopted cellulose aether which is bio-compatibility and high-yield source to prepare responsive copolymer nanomicelle.
制备细菌纤维素,观察纳米细菌纤维素的超微结构特点。
To prepare the biomaterial bacterial cellulose (BC) and observe the characteristic of its ultra-structure.
通过酸水解纤维素可以得到 纳米 纤维素晶须(CNC)。
The cellulose naonocrystals(CNC) can be prepared by acid hydrolysis of the biomass.
通过酸水解纤维素可以得到 纳米 纤维素晶须(CNC)。
The cellulose naonocrystals(CNC) can be prepared by acid hydrolysis of the biomass.
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