Low-water-permeability foils based on bio-renewable cellulose derivatives†

Tanner J. Hickman, Li Tao, Natalie Stingelin and J. Carson Meredith
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Abstract

Packaging is one of the largest contributors to plastic waste. Hence, polymers produced from renewable sources have become attractive to substitute or fully replace petroleum-based plastics in packaging materials. However, the properties of some of the prime candidates—e.g., cellulose and its derivatives—rapidly deteriorate already at a modest relative humidity rendering them impractical for use in packaging products. Here, we show by the example of carboxymethyl cellulose that chemical crosslinking with citric acid can be exploited to precisely control the moisture sensitivity of cellulose-based structures. Specifically, we demonstrate that the water vapor transmission rate (WVTR) of carboxymethyl cellulose can be manipulated in a controlled fashion over three orders of magnitude. Thereby, the lowest WVTR value, obtained for an optimal crosslinker content, is one order of magnitude lower than that measured for poly(ethylene terephthalate) even at a relatively humidity of up to 65%. Our work, thus, clearly illustrates that cellulose-based materials can be made insensitive to humidity, which is not only of great importance for providing a solution towards more sustainable plastic packaging but, generally, for expanding the scope of applications of cellulose and its derivatives, allowing us to leverage their natural abundance, chemical versatility, and biodegradability.

Abstract Image

基于生物可再生纤维素衍生物的低透水性箔片†。
包装是塑料垃圾的最大来源之一。因此,用可再生资源生产的聚合物来替代或完全替代包装材料中的石油基塑料已变得很有吸引力。然而,一些主要候选材料(如纤维素及其衍生物)的性能在相对湿度适中的情况下就会迅速恶化,因此不适合用于包装产品。在这里,我们以羧甲基纤维素为例,说明可以利用柠檬酸的化学交联来精确控制纤维素基结构的湿度敏感性。具体来说,我们证明了羧甲基纤维素的水蒸气透过率(WVTR)可以在三个数量级以上的范围内进行控制。因此,即使在相对湿度高达 65% 的情况下,最佳交联剂含量下的最低 WVTR 值也比聚对苯二甲酸乙二醇酯的 WVTR 值低一个数量级。因此,我们的工作清楚地表明,纤维素基材料可以对湿度不敏感,这不仅对提供更可持续的塑料包装解决方案具有重要意义,而且从总体上说,对扩大纤维素及其衍生物的应用范围也具有重要意义,使我们能够充分利用其天然丰富性、化学多功能性和生物可降解性。
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CiteScore
0.60
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