More Like this

1. Nitrogen-induced shift of photoluminescence from green to blue emission for xylose-derived carbon dots

   https://doi.org/10.1088/2632-959X/aba771  

   Wang, Shanshan; Yang, Dong-Sheng; Yang, Fuqian (August 2020, Nano Express)

   Abstract The discovery of carbon dots opens a new avenue to the applications of nanomaterials in biosensing and bioimaging. In this work, we develop simple methods to prepare carbon nanoparticles from xylose and to tune the photoluminescence (PL) characteristics of the xylose-derived carbon nanoparticles via the combination of three different processes: hydrothermal carbonization (HTC), annealing at 850 °C and laser ablation (LA) in a NH₄OH solution. The HTC-synthesized carbon dots (CDs) exhibit green emission under the 365 nm UV excitation, the annealing of the HTC-synthesized CDs leads to complete loss of the PL characteristics, and the LA processing of the annealed carbon nanoparticles recovers the PL characteristics with blue shift in comparison to the HTC-synthesized CDs under the same UV excitation. the PL characteristics of the HTC-CDs and the LA-CDs are dependent on theπ-π* transition of C-containing surface-functional groups andπ-π* and n-π* transitions of N-containing surface-functional groups, respectively, which are responsible for the difference in the PL characteristics between the HTC-synthesized CDs and the LA-processed CDs. The approaches demonstrated in this work provide a viable method to introduce and tune surface-functional groups on the surface of carbon nanoparticles. 

   more » « less
2. Production and modification of hydrochar from anaerobically digested cattail for adsorbing ammonium and phosphorous in wastewater

   https://doi.org/10.2166 /wst.2021.378  

   Ghimire, S. (January 2021, Water science technology)

   Rauch, Wolfgang; null (Ed.)

   Water contamination by nitrogen and phosphorus ions has a direct consequence of eutrophication to the ecosystem. The objective of this study is to investigate the production of hydrochars by acetic acid or sodium hydroxide assisted hydrothermal carbonization (HTC), various activation methods, and the potential of hydrochar as an adsorbent to remove NH4+-N and PO43−-P from wastewater. The results showed that acetic acid or sodium hydroxide assisted HTC and activation with magnesium chloride or air could improve the surface properties of hydrochar. Acetic acid modification generated extensive oxygenated functional groups, while sodium hydroxide modification produced hydrochar with a high N/C ratio and surface aromaticity. Treating hydrochar with magnesium chloride could impregnate nano-magnesium particles on the hydrochar, thereby improving the ability to remove N and P. Air activation of hydrochar resulted in more oxygen containing functional groups. The NH4+-N and PO43−-P adsorption capacities of these hydrochars ranged from 92.6 to 122.4mg/g and 1.6 to 15.8mg/g, respectively. The adsorption capacity of hydrochars in swine wastewater is similar to the results of artificial wastewater. The results suggested that Mg-nanoparticle dispersion and oxygen-containing functional groups played a major role in adsorption than ion exchange and physisorption. 

   more » « less
3. Production and Modification of Hydrochar from Anaerobically Digested Cattail for Adsorbing Ammonium and Phosphorous in Wastewater

   https://doi.org/10.2166/wst.2021.378  

   Ghimire, s; Wang, l; Zhang, B; Xin, l; Shahbazi, A (October 2021, Water science technology)

   Rauch, W Liu (Ed.)

   Water contamination by nitrogen and phosphorus ions has a direct consequence of eutrophication to the ecosystem. The objective of this study is to investigate the production of hydrochars by acetic acid or sodium hydroxide assisted hydrothermal carbonization (HTC), various activation methods, and the potential of hydrochar as an adsorbent to remove NH4+-N and PO43--P from wastewater. The results showed that acetic acid or sodium hydroxide assisted HTC and activation with magnesium chloride or air could improve the surface properties of hydrochar. Acetic acid modification generated extensive oxygenated functional groups, while sodium hydroxide modification produced hydrochar with a high N/C ratio and surface aromaticity. Treating hydrochar with magnesium chloride could impregnate nano-magnesium particles on the hydrochar, thereby improving the ability to remove N and P. Air activation of hydrochar resulted in more oxygen containing functional groups. The NH4+-N and PO43--P adsorption capacities of these hydrochars ranged from 92.6 to 122.4mg/g and 1.6 to 15.8mg/g, respectively. The adsorption capacity of hydrochars in swine wastewater is similar to the results of artificial wastewater. The results suggested that Mg-nanoparticle dispersion and oxygen-containing functional groups played a major role in adsorption than ion exchange and physisorption. 

   more » « less
4. A novel MnFe2O4@CDs material of dual behavior: photothermal conversion performance and fluorescent probe. Capture, detection, and degradation of Atrazine

   https://doi.org/10.1016/j.jece.2025.116226  

   Olmos-Moya, Patricia M; Móntes, Eduardo; Ramírez, Leopoldo Vázquez; Sánchez, José Manuel; Álvarez-Valtierra, Leonardo; Solís, Christian Gómez; Molina_Guerrero, Carlos E; Alpuche-Avilés, Mario A; Pineda-Arellano, Carlos (June 2025, Journal of Environmental Chemical Engineering)

   Lim, Teik-Thye; Vilar, Vítor (Ed.)

   The detection and removal of Atrazine (ATZN), a pesticide of environmental concern, requires more efficient methods to facilitate its degradation. The adequate structural morphology, high specific surface area, great photothermal conversion performance, higher amount of oxygenated functional groups, and intense and stable fluorescence signals are considered as favorable properties of the materials used in the in the proposal of physicochemical methods for detection, capture and degradation of nitrogenous herbicides. Herein, the design, preparation, and characterization of MnFe2O4@CDs as a dual-functional material is reported. Due to its optical, photothermal, textural and surface chemistry properties, the material is able to capture, detect, and degrade the herbicide "Atrazine" in synthetic samples. The preparation of the proposed composites, formed by particles of bimetallic oxides (Mn-Fe2O4) and a covering of carbon dots (CDs), was confirmed using various characterization techniques including SEM, TEMHR, RAMAN, FTIR, UV-Visible, Photoluminescence, DRX, N2 adsorption-desorption isotherms, superficial chemistry, and photothermal. The study revealed that the ATZN capture occurs through hydrogen bonding interaction between −COOH and −COH functional groups exposed on CDs surface and amine groups −NH− of the herbicide. Furthermore, the CDs behave as fluorescent markers of single-channel employed to detect ATZN and to monitor the capture-degradation process. The MnFe2O4@CDs composite was integrated as the main thermoactive material into a photothermal reactor on which was incident a NIR laser. The high near-infrared absorption of the Mn-Fe2O4 particles resulting in an efficient photothermal conversion; which in turn, increase the temperature of the surrounding medium. The increase in temperature promotes the activation of persulfate (PS) at the interface of the MnFe2O4@CDs−PS system producing SO4• − radicals as oxidizing agents of atrazine. Our results demonstrate that the process may effectively degrade 99 % of atrazine for a concentration of CATZN [20 mM], when NIR light irradiated by 45 min and the system reaches a temperature of ca. 53 ºC. Additionally, the degradation of ATZN was confirmed by analysis of total organic carbon (TOC). The fluorometric analytical assay by CDs-base fluorescence probes allowed following the FL signal at 520 nm(λexit = 375 nm) for the capture “turn on” and degradation “turn off” of atrazine. Finally, as a comparison, we highlight the significant efficiency shown by the process studied here, compared to other similar atrazine degradation processes previously reported. 

   more » « less
5. The Impact of Sintering Atmosphere and Temperature on the Phase Evolution of High Surface Area LSCF Prepared by In Situ Carbon Templating

   https://doi.org/10.1149/1945-7111/abf062  

   Muhoza, Sixbert P.; Taylor, Thomas H.; Song, Xueyan; Gross, Michael D. (March 2021, Journal of The Electrochemical Society)

   The thermochemical stability of lanthanum strontium cobalt ferrite (LSCF) processed between 1000 °C–1200 °C via the in situ carbon templating method was studied. This method generates high surface area ceramics at traditional solid oxide fuel cell (SOFC) sintering temperatures by generating a carbon template in situ and subsequently removing the template by oxidation at 700 °C. Argon processed samples produced an amorphous carbon template, whereas nitrogen tended to form graphitic carbon. Prior to the oxidation step, nitrogen samples comprised larger La 2 O 3 crystallites (22–40 nm) compared to argon (9–17 nm). Upon oxidation, argon samples resulted in a pure LSCF phase with surface areas in the 21–29 m 2 ·g −1 range, whereas nitrogen samples contained significant impurities. This demonstrates that the size of La 2 O 3 crystallites formed during inert processing limited the ability to produce a pure LSCF phase. Symmetrical cells comprising nano-LSCF electrodes generated by the templating method were compared to cells sintered directly in air. Impedance results suggest that nano-LSCF cells and cells processed in air were dominated by interfacial charge transfer resistance and gas diffusion, respectively. The results map out conditions for preparing and integrating high surface area, nanostructured LSCF into SOFC electrodes at traditional sintering temperatures. Strategies for improving the interfacial resistance of nano-LSCF electrodes are discussed. 

   more » « less