An overview of feasibilities and challenge of conductive cellulose for rechargeable lithium based battery

Ummartyotin, Sarute; Manuspiya, Hathaikarn

doi:10.1016/j.rser.2015.05.014

Cited by 42 publications

(21 citation statements)

References 127 publications

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“…Table 1 exhibits elemental analysis of activated carbon after surface modification on conventional reaction of zinc chloride [1], [2], [3]. The percent yield of activated carbon after zinc chloride modification was estimated to be 40–48 wt %.…”

Section: Experimental Design Materials and Methodsmentioning

confidence: 99%

Utilization of zinc chloride for surface modification of activated carbon derived from Jatropha curcas L. for absorbent material

Pratumpong

Toommee

2016

Data in Brief

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The objective of this research is to produce the low-cost activated carbon from Jatropha curcas L. by chemical activation using zinc chloride ZnCl2. The effects of the impregnation ratio on the surface and chemical properties of activated carbon were investigated. The impregnation ratio was selected at the range of 1:1–10:1 for investigation. The optimum conditions resulted in an activated carbon with a carbon content of 80% wt, while the specific surface area evaluated using nitrogen adsorption isotherm corresponds to 600 m2/g.

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Section: Experimental Design Materials and Methodsmentioning

confidence: 99%

Utilization of zinc chloride for surface modification of activated carbon derived from Jatropha curcas L. for absorbent material

Pratumpong

Toommee

2016

Data in Brief

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“…It also has attractive features of high degree of crystallinity, high degree of polymerization (14,400), and high specific area (37 m 2 /g) [11][12][13]. From the past, our research group was focused on the development of bacterial cellulose and the study of its application [2,4,14,15]. One successful project was involved in the development of bacterial cellulose as a flexible substrate for electronic device.…”

Section: Introductionmentioning

confidence: 99%

Eggshell and Bacterial Cellulose Composite Membrane as Absorbent Material in Active Packaging

Ummartyotin

Pisitsak

Pechyen

2016

International Journal of Polymer Science

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Bacterial cellulose and eggshell composite was successfully developed. Eggshell was mixed with bacterial cellulose suspension and it was casted as a composite film. CaCO 3 derived from eggshell was compared with its commercial availability. It can be noted that good dispersion of eggshell particle was prepared. Eggshell particle was irregular in shape with a variation in size. It existed in bacterial cellulose network. Characterization on composite was focused on thermal and mechanical properties. It showed that flexibility and thermal stability of composite were enhanced. No significant effect of mechanical properties was therefore observed. The thermal stability of composite was stable up to 300 ∘ C. The adsorption experiment on water and vegetable oil capacity was performed. The enhancement on adsorption was due to the existence of eggshell in bacterial cellulose composite. It exhibited the potential to be a good candidate for absorbent material in active packaging.

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“…The possibility of producing conductive cellulose brings many new areas of applications with it. Cellulose with low electrical resistance can be used for energy devices like batteries, super capacitors and solar cells, whereas metal hybrid films can be also employed for electrochemical electrodes . For example, bacterial cellulose has been used as a substrate for flexible anodes in supercapacitors.…”

Section: Applications For Functionalized Cellulosementioning

confidence: 99%

Functionalized Cellulose for Water Purification, Antimicrobial Applications, and Sensors

Bethke

Palantöken

Andrei

et al. 2018

Adv Funct Materials

201

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As the most abundant natural polymer, cellulose presents a unique advantage for large-scale applications. To fully unlock its potential, the introduction of desired functional groups onto the cellulose backbone is required, which can be realized by either chemical bonding or physical surface interactions. This review gives an overview of the chemistry behind the state-of-the-art functionalization methods (e.g., oxidation, esterification, grafting) for cellulose in its various forms, from nanocrystals to bacterial cellulose. The existing and foreseeable applications of the obtained products are presented in detail, spanning from water purification and antibacterial action, to sensing, energy harvesting, and catalysis. A special emphasis is put on the interactions of functionalized cellulose with heavy metals, focusing on copper as a prime example. For the latter, its toxicity can either have a harmful influence on aquatic life, or it can be conveniently employed for microbial disinfection. The reader is further introduced to recent sensing technologies based on functionalized cellulose, which are becoming crucial for the near future especially with the emergence of the internet of things. By revealing the potential of water filters and conductive clothing for mass implementation, the near future of cellulose-based technologies is also discussed.not suitable for drinking water treatment in rural areas or not applicable on a large scale. Other methods involving materials which have high adsorption capacities for pollutants, for example activated charcoal have been explored. [27,28] Nevertheless, there are no universal adsorbents for all pollutants, meaning that superior alternatives are still required. In recent years, biodegradable adsorbents such as cellulose and chitosan have attracted much attention for the removal of heavy metals.In particular cellulose has a number of advantages, which include high abundance, low cost, easy access, nontoxicity and biodegradability. It is particularly suited for the removal of low concentrations of heavy metals which occur in contaminated ground or tap water. [26] Beyond the aspects of copper removal from water, in this review we indicate how the metal's increased toxicity for microbial life can present an advantage for medical applications. Moreover, we also take a closer look at further applications of functionalized cellulose, including catalysis and sensing, which can make a great impact regarding energy conversion and management. The inclusion of conductive cellulose sensors within the internet of things global network is of particular interest, since an accurate weather forecast can provide swift adjustments in the usage of the often intermittent renewable energy sources. In order to understand what confers functionalized cellulose its versatility for broad applications, we first exemplify the functionalization techniques on a molecular basis.

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An overview of feasibilities and challenge of conductive cellulose for rechargeable lithium based battery

Cited by 42 publications

References 127 publications

Utilization of zinc chloride for surface modification of activated carbon derived from Jatropha curcas L. for absorbent material

Utilization of zinc chloride for surface modification of activated carbon derived from Jatropha curcas L. for absorbent material

Eggshell and Bacterial Cellulose Composite Membrane as Absorbent Material in Active Packaging

Functionalized Cellulose for Water Purification, Antimicrobial Applications, and Sensors

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