Moisture sorption and diffusion in historical cellulose-based materials

Kupczak, Arkadiusz; Bratasz, Łukasz; Kryściak-Czerwenka, Joanna; Kozłowski, Roman

doi:10.1007/s10570-018-1772-9

Cited by 12 publications

(5 citation statements)

References 26 publications

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“…31 The mass loss peak at 100 °C is attributed to the residual water bonding to the hydrophilic sulfonic groups, which is difficult to be completely removed by the drying process. 32 The mass loss peak at 200 °C has been attributed to the degradation of polysaccharide (hemicelluloses) that is typically present as a byproduct of the NaLS manufacturing process. 8 The strongest mass loss peak at 300 °C belongs to NaLS degradation.…”

Section: Resultsmentioning

confidence: 99%

Multifunctional Green Sensor Prepared by Direct Laser Writing of Modified Wood Component

Niu

Yao

Shi

et al. 2019

Ind. Eng. Chem. Res.

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The carbonization process of the cheap and renewable biomass–sodium lignosulfonate (NaLS) as a green carbon sources by an in-situ environmentally friendly processing methoddirect laser writing carbonization (DLWc)was investigated. With various characterization methods the film formation conditions and laser processing parameters were investigated for their effect on physical and chemical structures, electrical, piezoresistive, and humidity response behaviors of the carbon patterns. Besides its intrinsic piezoresistivity, the resistance of the DLWc created carbon feature can also respond to moisture change. With these dual characteristics, the carbon patterns were successfully applied as piezoresistive and humidity sensors. A high gauge factor of 120 was achieved for the piezoresistive sensor made of a square-shaped carbon pattern. The work presented in this study indicates that the application of DLWc to carbonize NaLS can create green carbon patterns suitable for a variety of force and humidity related sensing applications.

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Section: Resultsmentioning

confidence: 99%

Multifunctional Green Sensor Prepared by Direct Laser Writing of Modified Wood Component

Niu

Yao

Shi

et al. 2019

Ind. Eng. Chem. Res.

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“…Nevertheless, the structural features of the building (i.e., thick stone walls) maintain the RH at low levels and the hygric inertia ensures moisture balance by limiting relative humidity variations. The low RH variability in the library and the showcase, as well as the consequent smoothening of the short-term fluctuations could be attributed to the buffering capacity of the paper (Kupczak et al, 2018).…”

Section: Temperature and Relative Humiditymentioning

confidence: 94%

Indoor Air Quality Assessment at the Library of the National Observatory of Athens, Greece

Drougka

Liakakou

Σακκά

et al. 2020

Aerosol Air Qual. Res.

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Indoor environmental factors, such as microclimatic conditions (viz., the temperature and relative humidity) and pollutant concentrations, crucially affect the exhibits and artworks in a museum. To evaluate the air quality inside the library hosted by the Museum of Geoastrophysics of the National Observatory of Athens, a monitoring campaign was performed during summertime (August 2016). The findings were compared against scientifically accepted standards and recommended conditions for repositories and paperwork exhibition areas. The temperature and the relative humidity proved to be the most critical threats to the book collection, with the measured temperatures exceeding the recommended limits. Both parameters also displayed diurnal fluctuations, which are not recommended. Synergistically, these uncontrolled conditions contribute to book deterioration on a long-term basis, resulting in color and mechanical damage to the fibers and the growth of mold. Furthermore, despite only moderate infiltration, the library exhibited unacceptably high levels of pollutants, such as SO2, NO 2 and O 3 , which also cause the embrittlement and discoloration of paper as well as a weakening or powdering of leather book covers.

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“…The films were quickly weighed ( W a ) after taking them out and then dried at 60 °C in an oven for 12 h to a constant weight, weighed ( W b ). The moisture adsorption ( M , g/g) was calculated according to eq . − Each test was performed in triplicate and averaged. …”

Section: Experimental Sectionmentioning

confidence: 99%

Construction and Performance of a Nanocellulose–Graphene-Based Humidity Sensor with a Fast Response and Excellent Stability

Gong

Liu

et al. 2022

ACS Appl. Polym. Mater.

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Humidity sensors have been widely applied in environmental monitoring, respiratory monitoring, electronic skin, noncontact switch, etc. However, weak interface interactions between a flexible substrate and conductive fillers will deteriorate the sensing performance. Herein, a flexible, rapid-response, and durable humidity sensor was proposed via employing cellulose nanofiber (CNF)-dispersed graphene (Gr) as a humidity sensing layer, which could be easily filtered onto a coessential CNF film (CNFF) to form the humidity sensor. CNFs as a dispersant and bonder strengthened the adhesion of graphene on the surface of the CNFF substrate. Simultaneously, CNFs as a reservoir provided abundant adsorption sites to capture water molecules and promoted electron transfer from adsorbed water molecules to graphene, further amplifying electrical signals by a hygroscopic expansion of the sensing layer under humidity conditions. Benefiting from this unique composition and structure, the prepared humidity sensor exhibited a rapid response (45 s) and recovery time (33 s), low hysteresis (4%), wide RH detection range (15−99%), and long-term stability (15 days). Further, the sensor could monitor the humidity of human skin and human breath, indicating a versatile noncontact humidity sensing function by altering its component proportion of CNF-to-Gr on demand.

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Moisture sorption and diffusion in historical cellulose-based materials

Cited by 12 publications

References 26 publications

Multifunctional Green Sensor Prepared by Direct Laser Writing of Modified Wood Component

Multifunctional Green Sensor Prepared by Direct Laser Writing of Modified Wood Component

Indoor Air Quality Assessment at the Library of the National Observatory of Athens, Greece

Construction and Performance of a Nanocellulose–Graphene-Based Humidity Sensor with a Fast Response and Excellent Stability

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