Cellulose paper support with dual-layered nano–microstructures for enhanced plasmonic photothermal heating and solar vapor generation

Huang, Yintong; Morishita, Yoshitaka; Uetani, Koji; Nogi, Masaya; Koga, Hirotaka

doi:10.1039/d0na00163e

Cited by 15 publications

(19 citation statements)

References 25 publications

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“…[203] However, for the substrate design, the pore sizes, wettability, and density are all important factors to be considered. Artificial porous materials including carbon cloths, [175] foams, [204] aerogels, [194] polymers, [205] papers, [206] etc., and natural materials with inherent microchannels and low thermal conductivity, e.g., wood, [207] bamboo, [208] etc., have been adopted to allow for good water transport and heat localization. The latter is crucial for interfacial evaporation under low optical concentration, for which the realization necessitates four structural characteristics including absorption across the solar spectrum, thermal insulation, hydrophilic behavior, and interconnected pores.…”

Section: Nanoparticle Assemblies With Substrate Designsmentioning

confidence: 99%

Thermoplasmonics in Solar Energy Conversion: Materials, Nanostructured Designs, and Applications

Yang

Wang

et al. 2022

Advanced Materials

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The indispensable requirement for sustainable development of human society has forced almost all countries to seek highly efficient and cost‐effective ways to harvest and convert solar energy. Though continuous progress has advanced, it remains a daunting challenge to achieve full‐spectrum solar absorption and maximize the conversion efficiency of sunlight. Recently, thermoplasmonics has emerged as a promising solution, which involves several beneficial effects including enhanced light absorption and scattering, generation and relaxation of hot carriers, as well as localized/collective heating, offering tremendous opportunities for optimized energy conversion. Besides, all these functionalities can be tailored via elaborated designs of materials and nanostructures. Here, first the fundamental physics governing thermoplasmonics is presented and then the strategies for both material selection and nanostructured designs toward more efficient energy conversion are summarized. Based on this, recent progress in thermoplasmonic applications including solar evaporation, photothermal chemistry, and thermophotovoltaic is reviewed. Finally, the corresponding challenges and prospects are discussed.

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Section: Nanoparticle Assemblies With Substrate Designsmentioning

confidence: 99%

Thermoplasmonics in Solar Energy Conversion: Materials, Nanostructured Designs, and Applications

Yang

Wang

et al. 2022

Advanced Materials

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“…Cellulose nanofibers with a width of 22 ± 8 nm and carboxylate content of 0.08 ± 0.02 mmol g –1 were prepared from never-dried pulp (softwood bleached kraft pulp) by employing the method described in our previous report. 46 First, an aqueous suspension of the pulp (0.3 wt %, 2 L) was treated using a high-pressure water-jet system equipped with a counter-collision chamber (Star Burst, HJP-25005E, Sugino Machine Co., Ltd., Uozu, Japan). The pulp suspension was ejected from a nozzle with a diameter of 0.10 mm under a high pressure of 245 MPa with 100 passes.…”

Section: Methodsmentioning

confidence: 99%

Nanocellulose Paper Semiconductor with a 3D Network Structure and Its Nano–Micro–Macro Trans-Scale Design

et al. 2022

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Semiconducting nanomaterials with 3D network structures exhibit various fascinating properties such as electrical conduction, high permeability, and large surface areas, which are beneficial for adsorption, separation, and sensing applications. However, research on these materials is substantially restricted by the limited trans-scalability of their structural design and tunability of electrical conductivity. To overcome this challenge, a pyrolyzed cellulose nanofiber paper (CNP) semiconductor with a 3D network structure is proposed. Its nano–micro–macro trans-scale structural design is achieved by a combination of iodine-mediated morphology-retaining pyrolysis with spatially controlled drying of a cellulose nanofiber dispersion and paper-crafting techniques, such as microembossing, origami , and kirigami . The electrical conduction of this semiconductor is widely and systematically tuned, via the temperature-controlled progressive pyrolysis of CNP, from insulating (10 12 Ω cm) to quasimetallic (10 –2 Ω cm), which considerably exceeds that attained in other previously reported nanomaterials with 3D networks. The pyrolyzed CNP semiconductor provides not only the tailorable functionality for applications ranging from water-vapor-selective sensors to enzymatic biofuel cell electrodes but also the designability of macroscopic device configurations for stretchable and wearable applications. This study provides a pathway to realize structurally and functionally designable semiconducting nanomaterials and all-nanocellulose semiconducting technology for diverse electronics.

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“…The solar thermal heating performances of the carbonized nanopaper were evaluated by measuring the nanopaper surface temperatures under solar light irradiation, according to a method detailed in our previous report. 45 Prior to the temperature measurements, the emissivity of each nanopaper was evaluated using black body tape exhibiting an emissivity of 0.95 (HB-250, OPTEX Co., Ltd., Shiga, Japan) as a reference. The nanopaper and black tape were heated using a temperature controller (SBX-303, Sakaguchi E.H. VOC Corp., Tokyo, Japan) to 75 °C.…”

Section: ■ Conclusionmentioning

confidence: 99%

Semicarbonized Subwavelength-Nanopore-Structured Nanocellulose Paper for Applications in Solar Thermal Heating

et al. 2022

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Recently, there has been remarkable progress in solar thermal heating by applying biomass-derived carbons, which can absorb and convert solar light into thermal energy. The design of subwavelength nanoporous and molecular structures of biomassderived carbons is required for suppressed reflection and enhanced absorption of solar light. However, such designs are difficult because conventional biomass-derived carbons exhibit intrinsic microstructures and are prepared under specific carbonization conditions. In this study, a wood cellulose nanofiber-derived carbon is proposed to tailor both subwavelength nanoporous and molecular structures. Cellulose nanofibers are first constructed into a paper, denoted as "nanopaper", exhibiting subwavelength nanoporous structures by tailoring the pore spaces between cellulose nanofibers. The as-prepared nanopaper is then carbonized at various controlled temperatures to tailor the cellulose molecular structure, i.e., grow graphitic carbon domains. The graphitic carbon domains grown by semicarbonization at 500 °C adequately balance solar absorption and reflection, while the subwavelength nanoporous structures suppress solar reflection. Thus, the semicarbonized nanopaper with tailored nanoporous and molecular structures exhibits superior solar thermal heating to competitive nanocarbons, also affording thermoelectric power generation. This study can guide the structural and functional design of bionanocarbons for solar thermal heating.

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Cellulose paper support with dual-layered nano–microstructures for enhanced plasmonic photothermal heating and solar vapor generation

Cited by 15 publications

References 25 publications

Thermoplasmonics in Solar Energy Conversion: Materials, Nanostructured Designs, and Applications

Thermoplasmonics in Solar Energy Conversion: Materials, Nanostructured Designs, and Applications

Nanocellulose Paper Semiconductor with a 3D Network Structure and Its Nano–Micro–Macro Trans-Scale Design

Semicarbonized Subwavelength-Nanopore-Structured Nanocellulose Paper for Applications in Solar Thermal Heating

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