Ln(III)-Functionalized Metal–Organic Frameworks Hybrid System: Luminescence Properties and Sensor for <i>trans</i>,<i>trans</i>-Muconic Acid as a Biomarker of Benzene

Qu, Xiang-Long; Yan, Bing

doi:10.1021/acs.inorgchem.8b00912

Cited by 84 publications

(49 citation statements)

References 66 publications

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“…In recent years, a large number of luminescent MOFs have been reported for this purpose. [ 5,13–24 ] Moreover, for uses in nanotechnology, it is mandatory that MOFs are anchored on solid substrates, being particularly evident in the case of optoelectronic applications. [ 25,26 ] According to specialized reviews such as those from Wöll group, [ 27 ] it is distinguishable the surface‐supported metal–organic frameworks (SURMOFs) devices, fabricated using layer‐by‐layer (LbL) methodologies, where the orientation and film thickness can be well‐controlled.…”

Section: Figurementioning

confidence: 99%

“…[ 32 ] For example, by a rational combination of the blue, red, and green emission colors white‐light emission was achieved with Ln 3+ intercalated into the pore system, for example, the MOFs [ 24,33 ] Eu 3+ ,Tb 3+ @ZJU‐1 or Eu/Tb@IFP‐1 and IFP‐6 with CIE coordinates close to ideal white light, [ 24,33 ] among others. [ 15,17 ] Also, another strategy to produce SSWL devices is the incorporation of lanthanide‐coordination compounds into HKUST‐1 films. [ 34 ]…”

Section: Figurementioning

confidence: 99%

“…In the literature, luminescent MOFs play an important role for white‐light emission with a significant number of examples of white‐light emitters for powdered/bulk MOFs that exhibit emission of white light or close to the white point (for more information, see Table S1, Supporting Information). [ 13–24 ] However the implementation of thin films and eventually SURMOFs is scarcely reported.…”

Section: Figurementioning

confidence: 99%

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SURMOF Devices Based on Heteroepitaxial Architectures with White‐Light Emission and Luminescent Thermal‐Dependent Performance

Chen

Sedykh

Gómez³

et al. 2020

Adv Materials Inter

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The prolific topic of development of solidstate lighting devices has focused over the last years on solid-state white light (SSWL) emitting materials, mainly due the long operation lifetime and excellent harvesting and saving energy. [1] Even today, incandescent and mercury-based fluorescent materials are employed as white-light sources due to their superior warm-white light impression. Moreover, the fabrication of environmentally safe white light-emitting diode (LEDs) with a "warm-white" impression remains still a challenge. Many of the "white" organic light-emitting diode/ LED materials cover only part of the visible spectrum and lack the required efficacy of 150-200 lm W −1 for white-light performance. [2] For this reason, the design of a new generation of SSWL materials is of continuous interest in materials science, especially in areas such as full-color flat-panel electroluminescent displays for mobile devices, optical telecommunications, lighting, and backlighting for liquid-crystals displays. [3] Besides, high-quality white-light performance requires the Commission International de l'Eclairage (CIE) x,y coordinates 0.333, 0.333, with a correlated color temperature (CCT) into the 2500-6500 K, and color rendering index above 80 which are standard requirements for lighting applications. [4] One of the explored strategies to obtain white light is by combining red, green, and blue (RGB) sources to cover the visible region (400-700 nm) in the electromagnetic spectrum. [5] Also, metal-organic frameworks (MOFs) have been the focus of interest due to their potential applications in gas storage/ separation , [6] catalysis, [7] optics, [8] magnetism, [9] sensing, [10] and biomedicine. [4,11,12] Due to a permanent porosity, structural diversity, functionalization capabilities and then, tunable luminescence, MOF possess interesting properties for the development of SSWL composites. In recent years, a large number of luminescent MOFs have been reported for this purpose. [5,13-24] Moreover, for uses in nanotechnology, it is mandatory that MOFs are anchored on solid substrates, being particularly evident in the case of optoelectronic applications. [25,26] According to specialized reviews such as those from Wöll group, [27] it is distinguishable the surface-supported metal-organic frameworks (SURMOFs) devices, fabricated using layer-by-layer (LbL) A new set of Ln-MOF (lanthanide-metal-organic framework) thin films, known as Ln-SURMOFs (surface-supported MOFs), is fabricated with a layer-by-layer, in order to generate solid-state white-lighting devices. A three-component approach is carried out for a rational combination of red, green, and blue (RGB) emitting Eu 3+ , Tb 3+ , and Gd 3+ containing layers in order to achieve white-light emission. The Ln-SURMOFs are fully characterized by powder X-ray diffraction, infrared reflection-absorption spectroscopy, scanning electron microscopy, and photoluminescence spectroscopy (excitationemission and chromaticity determination according to Commission International de l'Eclairage, C...

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Section: Figurementioning

confidence: 99%

Section: Figurementioning

confidence: 99%

Section: Figurementioning

confidence: 99%

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SURMOF Devices Based on Heteroepitaxial Architectures with White‐Light Emission and Luminescent Thermal‐Dependent Performance

Chen

Sedykh

Gómez³

et al. 2020

Adv Materials Inter

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“…Trans, trans-muconic acid (tt-MA) and S-phenylmercapturic acid (S-PMA) are the most commonly used urinary biomarkers associated with benzene exposure in humans to be detected from urine or blood [7][8][9]. The American Conference of Governmental Industrial Hygienists (ACGIH) has recommended tt-MA as a biological exposure index (BEI) which is suitable urinary biomarker of benzene at high concentrations (above 1 ppm) [1,[10][11][12]. It appears that tt-MA is a more specific biomarker than other metabolites at high levels of benzene exposure.…”

Section: Introductionmentioning

confidence: 99%

Different Analytical Techniques, Pretreatment Methods and Adsorbent Materials for the Determination of Trans, Trans-Muconic Acid in Urine Samples

2020

2020 2nd International Symposium on the Frontiers of Biotechnology and Bioengineering (FBB 2020)

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“…Among these materials, lanthanide coordination polymers are excellent candidates for designing multi‐color luminescent materials due to their unique, plentiful, and efficient emission of different colors . Up to now, reports of while‐light emission from lanthanide metal organic frameworks share some common strategies: (i) three‐component approach, which is based on isomorphous solid solution‐type mix‐Ln‐CPs, such as in blue emission La 3+ /Gd 3+ ‐coordinated ligand codoped with the red and green emissions of Eu 3+ and Tb 3+ by fine‐tuning the Ln 3+ ions molar ratios;, (ii) two‐component approach, in which two distinct Ln 3+ ions coexist in a single phase of the white‐light emitting materials , . For example, in Eu 3+ ‐doped Gd 3+ isostructural CPs color‐tunable luminescence and white‐light emission are realized by varying the excitation wavelength; (iii) mono‐ or homometallic lanthanide complexes, which usually comprise a single Ln 3+ ions with multiple emitting peaks, or, wisely, by the delicate design of homolanthanide complexes incorporating appropriate organic ligands or dyes for compensating emitting light …”

Section: Introductionmentioning

confidence: 99%

Novel Composites of Graphitic‐phase Nitrogen Carbon/Lanthanide Coordination Polymers as White Light‐emitting Phosphor

Bao

Dong

et al. 2019

Zeitschrift anorg allge chemie

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Lanthanide coordination polymers (Ln‐CPs) are excellent candidates for designing white light materials due to their adjustable fluorescent characteristic by decorating organic ligands, changing metal centers and including guests. However, low quantum yield, weak blue emission, high prices and supply risks have hindered the application and developments of the pure Ln‐CPs materials. Herein, we have designed a new white color composite material capable of white light‐emission upon excitation at 338 nm, which fabricated by compositing a graphitic‐phase nitrogen carbon (g‐C3N4) treated with nitric acid and lanthanide‐based complexes, with the photoluminescencequantum yield (QY) in solid state reaching 11.7 %. WLEDs constructed by depositing the (g‐C3N4)0.783/Eu0.133/Tb0.083‐dbpt [dbpt = 3‐(3,5‐dicarboxylphenyl)‐5‐(pyrazinyl)‐1H‐1,2,4‐triazole] composites on a commercial UV LED chip feature a CIE chromaticity coordinate at (0.33, 0.33), high color rendering index (CRI) of 94.6. Compared to conventional white light‐emission Ln‐CPs materials of La0.928Eu0.045Tb0.027‐dbpt and La0.896Eu0.104‐dbpt reveals that (g‐C3N4)0.783/Eu0.133/Tb0.083‐dbpt composites have higher QY and CRI values.

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Ln(III)-Functionalized Metal–Organic Frameworks Hybrid System: Luminescence Properties and Sensor for trans,trans-Muconic Acid as a Biomarker of Benzene

Cited by 84 publications

References 66 publications

SURMOF Devices Based on Heteroepitaxial Architectures with White‐Light Emission and Luminescent Thermal‐Dependent Performance

SURMOF Devices Based on Heteroepitaxial Architectures with White‐Light Emission and Luminescent Thermal‐Dependent Performance

Different Analytical Techniques, Pretreatment Methods and Adsorbent Materials for the Determination of Trans, Trans-Muconic Acid in Urine Samples

Novel Composites of Graphitic‐phase Nitrogen Carbon/Lanthanide Coordination Polymers as White Light‐emitting Phosphor

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