Luminescent Carrageenan Hydrogels Containing Lanthanopolyoxometalates

Fateixa, Sara; Carvalho, Rui S.; Daniel‐da‐Silva, Ana L.; Nogueira, Helena I. S.; Trindade, Tito

doi:10.1002/ejic.201700888

Cited by 6 publications

(5 citation statements)

References 70 publications

(25 reference statements)

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“…The CG 50 Er z membranes display UV/blue and NIR emission ascribed to the κ-Cg-based host and to the Er 3+ ( 4 I 15/2 → 4 I 13/2 transition), respectively, as illustrated in Figure a and b for a selected sample. The excitation spectrum monitored around the broad-band host emission peak (420 nm) reveals two main excitation paths at 280 and 360 nm (inset in Figure a).…”

Section: Resultsmentioning

confidence: 99%

Sustainable Dual-Mode Smart Windows for Energy-Efficient Buildings

Nunes

Saraiva

Pereira

et al. 2019

ACS Appl. Energy Mater.

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Electrochromic devices (ECDs) combining visible/near-infrared (NIR) transparent amorphous indium zinc oxide (a-IZO) external layers with innovative NIR-emitting electrolytes composed of red seaweed-derived κ-carrageenan (κ-Cg) polysaccharide, glycerol (Gly), and erbium triflate (ErTrif3·xH2O) are proposed as a valuable technological solution for the development of smart windows providing less heating demand, less glare and more indoors human comfort for the new generation of energy-efficient buildings. The electrolyte preparation is cheap, clean, and fast. The optimized sample including 50 wt% Gly/κ-Cg and 40 wt% ErTrif3·xH2O/κ-Cg exhibits the highest ionic conductivity (1.5 × 10–4 S cm–1 at 20 °C) and displays ultraviolet (UV)/blue and NIR emissions associated with the κ-Cg-based host and the Er3+ ions (4I15/2 → 4I13/2), respectively. The 5-layer configuration ECD tested demonstrated fast switching time (50 s), high electrochromic contrast (transmittance variations of 46/51% at 550/1000 nm), high optical density change (0.89/0.75 at 550/1000 nm), outstanding coloration efficiency (450th cycle = –15902/–13400 cm2 C–1 and +3072/+2589 cm2 C–1 at 550/1000 nm for coloration and bleaching, respectively), excellent electrochemical stability, and self-healing after mechanical damage. The ECD encompasses two voltage-operated modes: semibright warm (+3.0 V, transmittances of 52/61% at 550/1000 nm) and dark cold (−3.0 V, transmittances of 7/11% at 550/1000 nm).

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Section: Resultsmentioning

confidence: 99%

Sustainable Dual-Mode Smart Windows for Energy-Efficient Buildings

Nunes

Saraiva

Pereira

et al. 2019

ACS Appl. Energy Mater.

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“…These carrageenan-based hydrogels demonstrate enhanced photoluminescence properties, with the integration of lanthanopolyoxometalates improving both their luminescent characteristics and mechanical strength. This renders them promising candidates for applications in optical devices [25]. Expanding upon the capabilities of microfluidics, a novel approach employs a thermo-reversible gelling polymer to facilitate the sorting of DNA molecules.…”

Section: Sensing and Biosensingmentioning

confidence: 99%

“…Material innovation continues with enhancements in the mechanical and optical properties of hydrogels [25,45] and the development of smart materials for chemical and biological sensing [76]. The integration of quantum dots and nanomaterials into hydrogels enables precise detection of enzymes, pollutants, and metal ions [61,84,85], and hydrogels responsive to pH, temperature, and metal ions are tailored to diverse applications [62,72,86].…”

Section: Collective Outcomesmentioning

confidence: 99%

“…Tailored hydrogels are developed for specific functions, including ion sensing, catalysis, drug delivery, and photocatalytic hydrogen production, highlighting the focus on biocompatibility and biomimetics with materials like collagen and peptides for applications in drug delivery, tissue engineering, and high-load-bearing scenarios [3,5,9,12,[20][21][22][23]. The research extends into lanthanide-doped and luminescent hydrogels, driven by their potential in environmental sensing and medical imaging [24,25].…”

Section: Introductionmentioning

confidence: 99%

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Enhancing Hydrogels with Quantum Dots

Omidian,

Wilson

2024

J. Compos. Sci.

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This manuscript explores the interdisciplinary integration of quantum dot–hydrogel composites and smart materials and their applications across a spectrum of fields, including biomedical engineering, environmental sensing, and energy harvesting. It covers the synthesis of novel materials like fluorescent hydrogel nanocomposites that display enhanced chemical stability, mechanical strength, and thermal resistance, highlighting their utility in environmental monitoring and catalysis. In the biomedical sector, innovations include hydrogel composites for targeted drug delivery and advanced therapies such as photothermal DNA hydrogels for tumor treatment. This review also discusses the application of these materials in imaging, diagnostics, and the development of smart sensors capable of detecting various biological and environmental changes. Its scope further extends to optoelectronics and the design of energy-efficient systems, underscoring the versatile functionalities of hydrogels in modern technological applications. Challenges remain in scaling up these technologies for commercial use and ensuring their long-term stability and safety, necessitating future research focused on sustainable, scalable solutions that can be integrated into existing systems.

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“…Luminescent transparent composite films based on LnPOMs and filmogenic polysaccharides have been prepared by us, using pullulan and a water‐soluble cationic chitosan derivative . Thermosensitive polysaccharides such as carrageenan hydrogels have also been used in the preparation of LnPOM composites . Agarose films containing [Eu(SiW 10 MoO 39 ) 2 ] 13– and [Eu(W 5 O 18 ) 2 ] 9– (EuW10) were reported by Yao et al, The structural combination of a polymer hydrogel network with a nanoparticle or in this case with a nanosized POM anion, will provide a superior functionality to the composite material with potential applications in diverse fields .…”

Section: Introductionmentioning

confidence: 99%

Raman and Fluorescence Imaging of Polyoxometalate Composite Agarose Films

et al. 2019

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Composite agarose films were prepared with Eu III containing polyoxometalates, in particular the organic-inorganic hybrid [Eu(W 5 O 18 ) 2 (pic) 4 ] 13-(Hpic = 3-hydroxypicolinic acid) and a Mo blue Eu III derivative. The latter compound shows interesting Eu III based photoluminescence properties, described for a molybdenum blue compound for the first time. Imaging Eur.479 Figure 4. Emission spectra recorded in a single spot characteristic of the film EuW10/agr (a) and in two spots of the film EuW10pic/agr showing the emission from the filmogenic areas (b) and from the crystallites (c).

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Luminescent Carrageenan Hydrogels Containing Lanthanopolyoxometalates

Cited by 6 publications

References 70 publications

Sustainable Dual-Mode Smart Windows for Energy-Efficient Buildings

Sustainable Dual-Mode Smart Windows for Energy-Efficient Buildings

Enhancing Hydrogels with Quantum Dots

Raman and Fluorescence Imaging of Polyoxometalate Composite Agarose Films

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