Your search keyword '"Li, Yanpeng"' showing total 11 results

1. Enhancing immobilized Chlorella vulgaris growth with novel buoyant barium alginate bubble beads.

Author

Liu Y, Zhang G, Li Y, Wu X, Shang S, and Che W

Subjects

Hexuronic Acids chemistry, Biomass, Cells, Immobilized metabolism, Barium chemistry, Microalgae growth & development, Microspheres, Bioreactors, Carbon Dioxide, Chlorella vulgaris growth & development, Alginates chemistry, Glucuronic Acid chemistry

Abstract

Microalgae immobilization in alginate beads shows promise for biomass production and water pollution control. However, carrier instability and mass transfer limitations are challenges. This study introduces buoyant barium alginate bubble beads (BABB), which offer exceptional stability and enhance Chlorella vulgaris growth. In just 12 days, compared to traditional calcium alginate beads, BABB achieved a 20 % biomass increase while minimizing cell leakage and simplifying harvesting. BABB optimization involved co-immobilization with BG-11 medium, enrichment of CO 2 in internal bubbles, and the integration of Fe nanoparticles (FeNPs). In the open raceway pond reactor, these optimizations resulted in a 39 % increase in biomass over 7 days compared to the unoptimized setup in closed flasks. Furthermore, enhancements in pigment and organic matter production were observed, along with improved removal of ammonia nitrogen and phosphate. These results highlight the overall advantages of BABB for microalgae immobilization, offering a scientific foundation for their effective utilization., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 Elsevier Ltd. All rights reserved.)

Published

2024

2. Removal of harmful algal blooms in freshwater by buoyant-bead flotation using chitosan-coated fly ash cenospheres.

Author

Zou X, Xu K, Xue Y, Qu Y, and Li Y

Subjects

Coal Ash, Ecosystem, Flocculation, Fresh Water, Harmful Algal Bloom, Chitosan, Chlorella vulgaris

Abstract

Harmful algal blooms (HABs) are a growing problem worldwide, damaging human and ecosystem health. In this study, a novel buoyant-bead flotation (BBF) method using chitosan-coated fly ash cenospheres (CFACs) was developed to remove HABs in freshwater. To achieve a high removal efficiency of harmful algae (Chlorella vulgaris, Scenedesmus quadricauda, and Microcystis aeruginosa), this study investigated the effects of chitosan/fly ash ratios in CFAC composite, CFAC concentration, flotation time, and pH values on the microalgae removal. The optimized ratio of CFACs is 0.1:12, and the optimized CFAC concentration is 0.3-0.7 g L -1 . However, the lower or higher ratios (0.1:4, 0.1:8, 0.1:16) result in microalgae reaching a zero-point charge too late or early, which failed to effectively remove HABs with an appropriate coal fly ash dosage. An optimized removal efficiency of 98.50% for Microcystis aeruginosa was reached at pH of 6.0. The optimized efficiency of Scenedesmus quadricauda and Chlorella vulgaris was 99.37% and 91.63%, respectively, at pH of 8.0. At neutral pH conditions, the surface charge of microalgae cells and CFACs are different, promoting aggregate formation. When CFACs were used to remove microalgae, aggregate size significantly influenced removal efficiency. Meanwhile, at the optimized pH and concentration, the removal efficiency of all three algal species exceeded 90.00% in 5 min. The study highlights an efficient and inexpensive method for removing HABs and obtains the optimized operational conditions.

Published

2020

3. Effects of multi-temperature regimes on cultivation of microalgae in municipal wastewater to simultaneously remove nutrients and produce biomass.

Author

Xu K, Zou X, Wen H, Xue Y, Qu Y, and Li Y

Subjects

Biomass, Lipids analysis, Polysaccharides analysis, Proteins analysis, Wastewater chemistry, Chlorella vulgaris growth & development, Chlorella vulgaris radiation effects, Organic Chemicals metabolism, Temperature, Wastewater microbiology, Water Pollutants, Chemical metabolism, Water Purification methods

Abstract

Coupling algal cultivation with wastewater treatment due to their potentials to alleviate energy crisis and reduce environmental burden has attracted the increased attention in recent years. However, these microalgal-based processes are challenging since daily and seasonal temperature fluctuation may affect microalgal growth in wastewater, and the effects of the temperature regimes on microalgal biomass production and wastewater nutrient removal remain unclear. In this study, Chlorella vulgaris was continuously cultured for 15 days in municipal wastewater to investigate the effects on the algal biomass and wastewater nutrient removal in three temperature regimes: (1) low temperature (4 °C), (2) high temperature (35 °C), and (3) alternating high-low temperature (35 °C in the day: 4 °C at night). Compared with the other two temperature regimes, the high-low temperature conditions generated the most biomass (1.62 g L -1 ), the highest biomass production rate (99.21 mg L -1 day -1 ), and most efficient removal of COD, TN, NH 3 -N, and TP (83.0%, 96.5%, 97.8%, and 99.2%, respectively). In addition, the polysaccharides, proteins, lipid content, and fatty acid methyl ester composition analysis indicates that in alternating high-low temperature condition, biomass production increased the potential for biofuel production, and there was the highest lipid content (26.4% of total dry biomass). The results showed that the nutrients except COD were all efficiently removed in these temperature conditions, and the alternating high-low temperature condition showed great potential to generate algal biomass and alleviate the wastewater nutrients. This study provides some valuable information for large-scale algal cultivation in wastewater and microalgal-based wastewater treatments.

Published

2019

4. Efficient microalgae harvesting using a thermal flotation method with response surface methodology.

Author

Zou X, Xu K, Wen H, Xue Y, Qu Y, and Li Y

Subjects

Biofuels, Biomass, Flocculation, Spectroscopy, Fourier Transform Infrared, Chlorella vulgaris, Microalgae

Abstract

Thermal pre-flocculation to enable dispersed air flotation is an economical and ecofriendly technology for harvesting microalgae from water. However, the underlying mechanism and optimal conditions for this method remain unclear. In this study, Chlorella vulgaris (C. vulgaris) and Scenedesmus obliquus (S. obliquus) were harvested using a thermal flotation process. The surface structure and characteristics (morphology, electricity, and hydrophobicity) of the microalgae were analyzed using FT-IR (Fourier transform infrared spectroscopy), SEM (scanning electron microscopy), zeta potential, and a hydrophobic test. Further, response surface methodology (RSM) was used to optimize the flotation process. The hydrophobicity of S. obliquus exceeded that of C. vulgaris; as such, under the thermal pre-flocculation, S. obliquus (88.16%) was harvested more efficiently than C. vulgaris (47.16%). Thermal pre-flocculation denatured the lipids, carbohydrate, and proteins of microalgal cell surfaces. This resulted in a decrease in the electrostatic repulsion between the cells and air bubbles. The highest harvesting efficiency was 91.96% at 70 °C, 1,412 rpm, and 13.36 min. The results of this study demonstrate the potential for economic and ecofriendly harvesting of microalgae for biofuels and other bioproducts industries.

Published

2019

5. Buoy-bead flotation application for the harvesting of microalgae and mechanistic analysis of significant factors.

Author

Wen H, Zou X, Xu K, Shen Z, Ren X, and Li Y

Subjects

Flocculation, Biomass, Chlorella vulgaris growth & development, Microalgae growth & development, Microspheres

Abstract

Harvesting technology has a significant influence on the microalgal biomass industry. This study develops a buoy-bead flotation method and analyzes the factors impacting flotation. Experimental results show that adding sodium borosilicate as an alternative microsphere material can result in 58.5% harvesting efficiency, a 25.65% increase over the foam flotation average. The Plackett-Burman design experimental results reveal that pH conditions, microsphere diameter, and the speed of agitation are the three most important factors affecting harvesting efficiency. The interaction between these three factors was all found to be significant, which indicates that the harvesting efficiency was affected by a combination of multiple factors. Analyses of the Extended Derjaguin-Landau-Vewey-Overbeek (XDLVO) theory show that the Van der Waals interactions are the key factor in the attachment of algae and microspheres. A harvesting efficiency of 89.9% can be achieved at pH 10, with 56 µm dimeter microspheres and an agitation speed of 114 rpm.

Published

2019

6. Buoy-bead flotation harvesting of the microalgae Chlorella vulgaris using surface-layered polymeric microspheres: A novel approach.

Author

Xu K, Zou X, Wen H, Xue Y, Zhao S, and Li Y

Subjects

Biomass, Chlorella, Flocculation, Microalgae, Chlorella vulgaris, Microspheres

Abstract

To improve microalgae harvesting efficiency and to reduce the addition of chemicals in the buoy-bead flotation process, a novel buoy-bead flotation approach has been developed for harvesting Chlorella vulgaris, using surface-layered polymeric microspheres (SLPMs). Next, the detachment of microalgae cell-SLPM aggregates and the reusability of SLPMs were investigated. The experimental results showed that a maximum harvesting efficiency of 98.43% was achieved at a SLPM dosage of 0.7 g/L and a pH of 9, and harvesting efficiency quickly decreased with increasing ionic strength. A detachment efficiency of 78.46% and a concentration factor of 19.56 were achieved at an ionic strength of 700 mM and a mixing speed of 3000 rpm without changing the pH. Reused SLPMs can still reach an efficiency of 72.13% after five cycles. The presented results show that this method can potentially be applied for large-scale microalgae harvesting., (Copyright © 2018 Elsevier Ltd. All rights reserved.)

Published

2018

7. Investigation on the role of surfactants in bubble-algae interaction in flotation harvesting of Chlorella vulgaris.

Author

Shen Z, Li Y, Wen H, Ren X, Liu J, and Yang L

Subjects

Adsorption physiology, Biomass, Chlorella vulgaris physiology, Flocculation, Chlorella vulgaris metabolism, Microalgae physiology, Surface-Active Agents metabolism

Abstract

In this work, a fundamental study was carried out on the role of surfactants in bubble-algae interaction to improve the understanding of how surfactants influence the flotation performance. Flotation tests for harvesting Chlorella vulgaris were first conducted using two surfactants, hexadecyltrimethyl ammonium bromide (C 16 TAB) and tea saponin. The effect of surfactants on harvesting efficiency was found to depend on their type and concentration. The present results also indicated that C 16 TAB exhibited higher harvesting efficiency than tea saponin. The adsorption experiments of surfactants onto C. vulgaris and the characterization measurements of algae surface were then carried out to reveal underlying interaction mechanisms between surfactants and algae in air flotation process. The results confirmed the adsorption process of surfactants onto C. vulgaris was feasible, spontaneous and endothermic. Subsequently, two mechanism models were proposed to qualitatively establish the interaction relationship among algae, surfactants and bubbles in the flotation. According to two models, C 16 TAB could neutralize the algal potential, while tea saponin converted algal surface from hydrophilic into hydrophobic. Overall, two surfactants used here could facilitate attachment of C. vulgaris onto bubbles, making the algae easier to be harvested, thereby increasing the flotation recovery.

Published

2018

8. Mixotrophic cultivation of microalgae to enhance the biomass and lipid production with synergistic effect of red light and phytohormone IAA.

Author

Chang, Wenjuan, Li, Yanpeng, Qu, Yanhui, Liu, Yi, Zhang, Gaoshan, Zhao, Yan, and Liu, Siyu

Subjects

*BIOMASS production, *MICROALGAE, *SODIUM nitrate, *ALGAL growth, *ALGAL cells, *CHLORELLA vulgaris, *BRASSINOSTEROIDS

Abstract

Microalgal cultivation still presents a big challenge in commercial application due to the small size and low density of microalgae. The effect of phytohormones or light spectra on enhancing microalgal growth has been individually demonstrated at the bench scale. However, the synergistic action of phytohormones and light spectra on algal growth and lipid production remains unclear. In this study, the optimal carbon and nitrogen concentrations, as well as the optimum dosage of the phytohormone indole-3-acetic acid (IAA), for the growth of Chlorella vulgaris were first evaluated under mixotrophic cultivation. A light spectrum experiment was then conducted in an incubator equipped with white and red light. Results show that optimal mixotrophic cultivation conditions were 10 g L−1 glucose, 2250 mg L−1 sodium nitrate and 10 mg L−1 IAA. Under the optimum IAA treatment and irradiation with red light, the highest biomass, lipid content and lipid productivity were 28.34%, 3.53 g L−1 and 140.04 mg L−1 d−1, respectively. As compared to white light, the synergistic action of red light and IAA stimulated biomass production and lipid accumulation by algal cell metabolism and carbon source bioconversion. Furthermore, the post-optimized C. vulgaris had the potential for biodiesel production. These results provide new insights for the highly efficient cultivation of microalgae. [Display omitted] • C & N sources were tested to optimize the conditions for mixotrophic cultivation. • IAA increased biomass production by 11% and lipid yield by 16%, versus no IAA. • Red light promoted the increase of biomass under optimal C & N source conditions. • Synergy of IAA and red light greatly enhanced algal biomass and lipid accumulation. [ABSTRACT FROM AUTHOR]

Published

2022

9. A novel magnetic buoyant-bead flotation method for the removal of typical microalgae from harmful algal blooms.

Author

Zhao, Yan, Wu, Xuexue, Chang, Wenjuan, Che, Wenlu, Liu, Yi, and Li, Yanpeng

Subjects

IRON oxides, CHLORELLA vulgaris, ALGAL blooms, FOURIER transform infrared spectroscopy, MICROALGAE, PLANKTON blooms, X-ray photoelectron spectroscopy

Abstract

In recent years, harmful algal blooms（HABs）caused by the eutrophication of water bodies have been occurring, which not only damage the ecological environment, but also threaten human health. To control HABs simply and efficiently, a novel magnetic buoyant-bead flotation method was developed in this study. A magnetic floatable bead of Fe 3 O 4 /CCP was first prepared, and then was characterized by X-ray diffraction, Fourier transform infrared spectroscopy, vibrating sample magnetometer and X-ray photoelectron spectroscopy. Subsequently, this study examined the removal effects of three kinds of floatable bead (closed-cell perlite (CCP), Fe 3 O 4 /CCP and Fe 3 O 4 /CCP +CPAM) on three typical microalgae (Chlorella vulgaris , Microcystis aeruginosa and Anabaena flos-aquae) in water bloom. The results confirmed that the removal rate of Fe 3 O 4 /CCP +CPAM was 27.28%, 45.79% and 42.71% higher than that of Fe 3 O 4 /CCP in the removal of three microalgae, respectively, while it was 32.26%, 50.49% and 46.91% higher than that of CCP, respectively. In addition, CPAM concentration, the amount of Fe 3 O 4 /CCP, stirring time, and stirring speed were found to have significant effects on the removal of three microalgae. The orthogonal experiments further revealed that the CPAM concentration exerted the most significant impact on the removal rate while using the proposed magnetic buoyant-bead flotation method. Under the optimal experimental conditions, the removal rate of C. vulgaris , M. aeruginosa and A. flos-aquae using Fe 3 O 4 /CCP was 98.01%, 97.96% and 97.58%, respectively. Finally, the removal mechanism of microalgae by the combination of Fe 3 O 4 /CCP+CPAM was given. This study can provide a new idea for effectively removing harmful microalgae from water blooms or harvesting the microalgae. [Display omitted] • A new magnetic bead Fe 3 O 4 /CCP was prepared by using Fe 3 O 4 and closed-cell perlite. • The removal rate of microalgae was improved using Fe 3 O 4 /CCP and cationic polyacrylamide. • The microalgae and Fe 3 O 4 /CCP were easily separated from water body by applying a magnetic field. • Under the optimal conditions, the removal rate of microalgae exceeded 97.58%. [ABSTRACT FROM AUTHOR]

Published

2023

10. Efficient Bioflocculation of Chlorella vulgaris with a Chitosan and Walnut Protein Extract.

Author

Xu, Kaiwei, Zou, Xiaotong, Mouradov, Aidyn, Spangenberg, German, Chang, Wenjuan, and Li, Yanpeng

Subjects

WALNUT, CHITOSAN, CHLORELLA vulgaris, BIOMASS production, FOURIER transform infrared spectroscopy, CLIMATE change, COST of living

Abstract

Simple Summary: With the increase in population size, global climate changes, and the improvement of living standards, the fossil fuel resources may run out in the future. Microalgae have been considered the next generation of sustainable and renewable feedstock to produce biofuel and a large spectrum of high-value products, such as healthy oils, carotenoids, and proteins. Unlike terrestrial plants, the production of added-value chemicals from microalgal species is not seasonal; they can be grown under climate-independent conditions in bioreactors; can use wastewater as a source of nutrients, contributing to wastewater treatment; and can convert CO2 into organic compounds more efficiently. However, the utilization of microalgal biomass is heavily dependent on microalgal biomass harvesting and concentration technology. Flocculation represents a relatively low-cost and efficient approach for the harvesting of microalgal biomass at a large scale. However, in traditional flocculation, most of the chemical flocculants covalently bind to the microalgal surfaces, contaminating the final product, which significantly limits their application. This study aims to develop an efficient and convenient bioflocculation technique to harvest microalgae. Bioflocculation represents an attractive technology for harvesting microalgae with the potential additive effect of flocculants on the production of added-value chemicals. Chitosan, as a cationic polyelectrolyte, is widely used as a non-toxic, biodegradable bioflocculant for many algal species. The high cost of chitosan makes its large-scale application economically challenging, which triggered research on reducing its amount using co-flocculation with other components. In our study, chitosan alone at a concentration 10 mg/L showed up to an 89% flocculation efficiency for Chlorella vulgaris. Walnut protein extract (WPE) alone showed a modest level (up to 40%) of flocculation efficiency. The presence of WPE increased chitosan's flocculation efficiency up to 98% at a reduced concentration of chitosan (6 mg/L). Assessment of co-flocculation efficiency at a broad region of pH showed the maximum harvesting efficiency at a neutral pH. Fourier transform infrared spectroscopy, floc size analysis, and microscopy suggested that the dual flocculation with chitosan and walnut protein is a result of the chemical interaction between the components that form a web-like structure, enhancing the bridging and sweeping ability of chitosan. Co-flocculation of chitosan with walnut protein extract, a low-value leftover from walnut oil production, represents an efficient and relatively cheap system for microalgal harvesting. [ABSTRACT FROM AUTHOR]

Published

2021

11. A novel microalgal biofilm reactor using walnut shell as substratum for microalgae biofilm cultivation and lipid accumulation.

Author

Zou, Xiaotong, Xu, Kaiwei, Chang, Wenjuan, Qu, Yanhui, and Li, Yanpeng

Subjects

*SCENEDESMUS obliquus, *WALNUT, *BIOFILMS, *MICROALGAE, *CHLORELLA vulgaris, *CARBON dioxide, *LIGHT intensity, *BIOMASS production

Abstract

Microalgae are a potential candidate for biofuels, but the high cost and low biomass yield hinder the scale-up application of microalgae. In this study, a novel walnut shell based self-permeating biofilm reactor (WSPBR) was proposed for cultivation of Chlorella vulgaris (C. vulgaris) and Scenedesmus obliquus (S. obliquus). Major influencing factors such as walnut shell size, light intensity and CO 2 concentration were studied in detail. The results showed that CO 2 can enhance the storage of metabolic products in microalgal cells. Thermodynamics analysis indicated that C. vulgaris and S. obliquus were likely to adhere on the surface of walnut shells. S. obliquus and C. vulgaris biomass reached the maximum values of 97.43 and 70.49 g m−2, respectively, corresponding to the walnut shell size of 0.8–1.2 mm, light intensity of 150 μmol m−2 s−1 and CO 2 concentration of 2%. The lipid contents of these microalgal cells were 34.32% and 28.94%, respectively. These results indicated that WSPBR was an efficient system for microalgae cultivation as feedstock for biofuels. [Display omitted] • A self-permeating biofilm reactor based on walnut shell was proposed. • Walnut shells were used as substratum to support microalgae biofilm. • Cultivation in this novel reactor enhanced biomass production and lipid content. • Thermodynamics analysis was applied to evaluate the biofilm attachment process. [ABSTRACT FROM AUTHOR]

Published

2021