Your search keyword '"Wei-Yin Chen"' showing total 115 results

1. Catalytic Non-Thermal MilliPulse Plasma for Methanation of CO2 without Carbon Deposition and Catalyst Deactivation

Author

Baharak Sajjadi and Wei-Yin Chen

Subjects

General Chemical Engineering, Environmental Chemistry, General Chemistry, Industrial and Manufacturing Engineering

Published

2023

2. Mechanism of Action of Xiaoyao San in Treatment of Ischemic Stroke is Related to Anti-Apoptosis and Activation of PI3K/Akt Pathway

Author

Fang Yang, Meng-yuan Huang, Wei-yin Chen, Ze-ran Chen, Yang Zhang, and Yue Xu

Subjects

0301 basic medicine, Pharmaceutical Science, Pharmacology, medicine.disease_cause, Neuroprotection, PC12 Cells, 03 medical and health sciences, Phosphatidylinositol 3-Kinases, Structure-Activity Relationship, 0302 clinical medicine, Drug Discovery, medicine, pharmacological mechanism, Animals, Protein kinase B, PI3K/AKT/mTOR pathway, biological function, Original Research, Ischemic Stroke, Drug Design, Development and Therapy, Dose-Response Relationship, Drug, Molecular Structure, Chemistry, apoptosis, In vitro, Rats, Molecular Docking Simulation, Oxidative Stress, 030104 developmental biology, Neuroprotective Agents, Mechanism of action, Apoptosis, 030220 oncology & carcinogenesis, neuroprotection, Signal transduction, medicine.symptom, Proto-Oncogene Proteins c-akt, Oxidative stress, Drugs, Chinese Herbal

Abstract

Yue Xu,1,* Weiyin Chen,1,* Zeran Chen,2 Mengyuan Huang,1 Fang Yang,1 Yang Zhang1 1Hospital of Chengdu University of Traditional Chinese Medicine, Chengdu, 610072, People’s Republic of China; 2School of Medical and Life Sciences, Chengdu University of Traditional Chinese Medicine, Chengdu Sichuan, 610041, People’s Republic of China*These authors contributed equally to this workCorrespondence: Fang YangHospital of Chengdu University of Traditional Chinese Medicine, No. 39 Shi-er-qiao Road, Chengdu, 610075, People’s Republic of ChinaTel/Fax +86 28- 87783481Email yfgreens2013@163.comYang ZhangHospital of Chengdu University of Traditional Chinese Medicine, Chengdu, 610072, People’s Republic of ChinaEmail zhangyang@cdutcm.edu.cnObjective: The traditional Chinese medicine (TCM) formulation Xiaoyao San (XYS) has a good clinical effect in treating ischemic stroke (IS). We explored the mechanism and material basis of XYS in IS treatment.Methods: Network pharmacology was used to construct a network of XYS components and IS targets. R software was used to analyze the biological process and pathway analysis of the targets of XYS in IS treatment. In vitro, a model of apoptosis of PC12 cells induced by oxygen-glucose deprivation/reperfusion (OGD/R) was established to evaluate the neuroprotective effect of XYS and its influence on the expression of apoptotic protein-related genes. The affinity between the potentially active compounds in XYS and apoptotic proteins was evaluated by molecular docking.Results: XYS was shown to have 136 chemical components that exert potential anti-IS activity by acting on 175 proteins. Bioinformatics analysis showed that apoptosis and the phosphoinositide 3-kinase/protein kinase B (PI3K-Akt) signaling pathway were the main signaling pathways of XYS. In vitro experiments showed that XYS could improve the effect of OGD/R on PC12-cell activity (EC50 = 0.43 mg/mL) and inhibit apoptosis. The main mechanisms were related to the improvement of oxidative stress and regulation of apoptosis-related gene expression. Molecular docking showed that C22, C102 and other components in XYS had a strong affinity with apoptosis-related proteins.Conclusion: Network pharmacology, in vitro experiments, and molecular docking were used, for the first time, to study the material basis and molecular mechanism of XYS in IS treatment from the perspective of multiple targets and multiple pathways. We provided a new approach for the future study of TCM formulations in the treatment of complex diseases.Keywords: apoptosis, neuroprotection, biological function, pharmacological mechanism

Published

2021

3. Pretreatment with Shenxiong Drop Pill induces AQP4- mediated neuroprotective effect on middle cerebral artery occlusion in rats

Author

Dong-dong Yang, Ji-li Deng, Wei-yin Chen, Shuo-guo Jin, Hong-hui Sun, Mei-jun Liu, Ze-ran Chen, Li Zhang, Fang Yang, and Ning-jing Ran

Subjects

business.industry, Cerebral infarction, Ischemia, Pharmaceutical Science, medicine.disease, Brain water, Neuroprotection, Cerebral edema, symbols.namesake, Anesthesia, Occlusion, Nissl body, symbols, Medicine, Pharmacology (medical), Middle cerebral artery occlusion, business

Abstract

Purpose: To investigate the neuroprotective effect of Shenxiong Drop Pill (SXDP) pretreatment on rats with middle cerebral artery occlusion (MCAO) in rats, and the mechanism involved.Methods: Ninety-nine SD rats were randomly assigned to 4 groups: control group, MCAO group, shamoperated group and SXDP group. The MCAO model was established via thread occlusion. Rats in the SXDP group was administered SXDP 7 days before induction of MCAO. Neurological deficit score (NDS) was determined using Bederson's neurological behavioral scoring method, while cerebral infarction volume was measured using TTC staining. Integrated optical density (IOD) of Nissl Body was evaluated via Nissl staining. Brain water content was measured using dry-wet method. The expression level of AQP4 in brain tissues was determined using immunocytochemistry.Results: The SXDP treatment resulted in significant reduction in NDS, marked improvement in IOD of Nissl Body, and significant reductions in cerebral infarction volume, brain water content, and expression level of AQP4, relative to control (p< 0.05).Conclusion: These results suggest that SXDP pretreatment exerts neuroprotective effect against cerebral ischemia in rats by decreasing in cerebral edema through a mechanism involving downregulation of the expression of AQP4. Keywords: Middle cerebral artery occlusion, Cerebral ischemia, Aquaporins-4, Cerebral edema, Neuroprotection

Published

2020

4. Impact of Biomass Sources on Acoustic-Based Chemical Functionalization of Biochars for Improved CO2 Adsorption

Author

Nathan I. Hammer, Vijayasankar Raman, Wei-Yin Chen, Riya Chatterjee, Daniell L. Mattern, Baharak Sajjadi, and Austin Dorris

Subjects

Chemistry, General Chemical Engineering, Energy Engineering and Power Technology, Biomass, 02 engineering and technology, 021001 nanoscience & nanotechnology, Co2 adsorption, Fuel Technology, 020401 chemical engineering, 13. Climate action, Environmental chemistry, Chemical functionalization, Biochar, 0204 chemical engineering, 0210 nano-technology

Abstract

The present study investigates the impact of biomass origin on the properties of biochar and its interaction with different treatment conditions, CO2 adsorption, and regeneration ability. The bioch...

Published

2020

5. Preadsorbed SO3 Inhibits Oxygen Atom Activity for Mercury Adsorption on Cu/Mn Doped CeO2(110) Surface

Author

Yihuan Yang, Jiawei Wang, Yongsheng Zhang, Wei-Yin Chen, Baharak Sajjadi, Wei-Ping Pan, and Tao Wang

Subjects

Surface (mathematics), Materials science, General Chemical Engineering, Inorganic chemistry, Energy Engineering and Power Technology, 02 engineering and technology, 021001 nanoscience & nanotechnology, Fuel Technology, Adsorption, Oxygen atom, 020401 chemical engineering, Mercury adsorption, Lattice oxygen, Density functional theory, Mn doped, 0204 chemical engineering, 0210 nano-technology, Adsorption energy

Abstract

The coadsorption of Hg⁰ and SO₃ on pure and Cu/Mn doped CeO₂(110) surfaces were investigated using the Density Functional Theory (DFT) method. A p (2 × 2) supercell periodic slab model with seven atomic layers was constructed to represent the CeO₂(110) surface. The results indicated that Hg⁰ physically adsorbed on the CeO₂(110) surface, while Hg⁰ chemically adsorbed on the Cu/Mn doped CeO₂(110) surface, which agree well with the experimental results that Cu and Mn doped CeO₂ greatly improved the Hg⁰ adsorption capacity of the adsorbent. The calculated results suggested that SO₃ more easily adsorbs on the above three surfaces than Hg⁰ due to the higher adsorption energy. The adsorption configurations and electronic structures indicated SO₃ reacted with O atoms of the surface to form SO₄²– species. Hence, SO₃ inhibits Hg⁰ adsorption on the CeO₂(110) surface by competing with Hg⁰ for surface lattice oxygen. In addition, SO₃ decreased the activity of the surface O atoms, which directly caused the negative effect on Hg⁰ adsorption.

Published

2020

6. Biochar from Biomass: A Strategy for Carbon Dioxide Sequestration, Soil Amendment, Power Generation, CO2 Utilization, and Removal of Perfluoroalkyl and Polyfluoroalkyl Substances (PFAS) in the Environment

Author

Wei-Yin Chen, Nosa O. Egiebor, Joel S. Hayworth, Roger L. Viticoski, Vanisree Mulabagal, Baharak Sajjadi, and David Baah

Subjects

Electricity generation, Environmental chemistry, Biochar, Amendment, Biomass, Environmental science, Carbon sequestration

Published

2022

7. Shenxiong Drop Pill exerts neuroprotective effect against focal cerebral ischemia partly via regulation of the expressions of ICAM-1 and caspase-3

Author

Ning-jing Ran, Meng-yuan Huang, Wei-yin Chen, Meng Hou, Yang Zhang, Shuo-guo Jin, Fang Yang, Xin-xia Zhang, and Ze-ran Chen

Subjects

ICAM-1, Cerebral infarction, Chemistry, Ischemia, Pharmaceutical Science, Inflammation, Caspase 3, Pharmacology, medicine.disease, Neuroprotection, Staining, symbols.namesake, Acute ischemic stroke, Neuroprotection, Inflammation, Middle cerebral artery occlusion, Caspase-3, Intercellular adhesion molecule 1, medicine, Nissl body, symbols, Pharmacology (medical), medicine.symptom

Abstract

Purpose: To investigate the effect of Shenxiong Drop Pill (SXDP) on cerebral infarction (CI) in rats, and the involvement of anti-inflammatory response in the process.Methods: Rats were sacrificed at three different time points, viz, 24, 48 and 72 h after establishment of CI model. Neurological deficit score (NDS) was determined using Bederson’s neurological behavioral scoring method, whereas triphenyltetrazolium chloride (TTC) staining was used to show brain injury. The integrated optical density (IOD) of Nissl bodies and caspase-3-positive nerve cells were measured with Nissl staining and SP kit, respectively. The mRNA expression of intercellular adhesion molecule 1(ICAM-1) was determined using reverse transcription-polymerase chain reaction (RT-PCR).Results: SXDP produced neuroprotective effect at high, medium, and low doses. The infarct volumes in the high-, medium- and low-dose SXDP, and cyclophosphamide groups were significantly reduced at each time point. Different doses of SXDP significantly reduced the mRNA expression of ICAM-1 and the IOD of caspase-3.Conclusion: These results indicate that SXDP exerts neuroprotective effects against ischemic injury by negatively regulating ICAM-1/caspase-3 downstream of inflammatory and apoptosis pathways.

Published

2021

8. A comprehensive review on physical activation of biochar for energy and environmental applications

Author

Baharak Sajjadi, Nosa O. Egiebor, and Wei-Yin Chen

Subjects

business.industry, Process (engineering), 020209 energy, General Chemical Engineering, Plasma activation, Industrial chemistry, 02 engineering and technology, 010501 environmental sciences, 01 natural sciences, Biochar, 0202 electrical engineering, electronic engineering, information engineering, Environmental science, Process engineering, business, Energy (signal processing), 0105 earth and related environmental sciences

Abstract

Biochar is a solid by-product of thermochemical conversion of biomass to bio-oil and syngas. It has a carbonaceous skeleton, a small amount of heteroatom functional groups, mineral matter, and water. Biochar’s unique physicochemical structures lead to many valuable properties of important technological applications, including its sorption capacity. Indeed, biochar’s wide range of applications include carbon sequestration, reduction in greenhouse gas emissions, waste management, renewable energy generation, soil amendment, and environmental remediation. Aside from these applications, new scientific insights and technological concepts have continued to emerge in the last decade. Consequently, a systematic update of current knowledge regarding the complex nature of biochar, the scientific and technological impacts, and operational costs of different activation strategies are highly desirable for transforming biochar applications into industrial scales. This communication presents a comprehensive review of physical activation/modification strategies and their effects on the physicochemical properties of biochar and its applications in environment-related fields. Physical activation applied to the activation of biochar is discussed under three different categories: I) gaseous modification by steam, carbon dioxide, air, or ozone; II) thermal modification by conventional heating and microwave irradiation; and III) recently developed modification methods using ultrasound waves, plasma, and electrochemical methods. The activation results are discussed in terms of different physicochemical properties of biochar, such as surface area; micropore, mesopore, and total pore volume; surface functionality; burn-off; ash content; organic compound content; polarity; and aromaticity index. Due to the rapid increase in the application of biochar as adsorbents, the synergistic and antagonistic effects of activation processes on the desired application are also covered.

Published

2019

9. Ultrasound-assisted amine functionalized graphene oxide for enhanced CO2 adsorption

Author

Riya Chatterjee, Baharak Sajjadi, Wei-Yin Chen, and Yamin Liu

Subjects

Materials science, Graphene, 020209 energy, General Chemical Engineering, Organic Chemistry, Oxide, Energy Engineering and Power Technology, 02 engineering and technology, Partial pressure, law.invention, chemistry.chemical_compound, Fuel Technology, Adsorption, 020401 chemical engineering, chemistry, Chemical engineering, law, 0202 electrical engineering, electronic engineering, information engineering, Surface modification, Amine gas treating, Thermal stability, 0204 chemical engineering, Amination

Abstract

The present study discusses a novel ultrasound promoted amination technique to functionalize graphene oxide (GO) for CO2 adsorption. Graphene oxide was synthesized following the modified Hummer’s method. The developed functionalization technique integrates the advantages of low-frequency ultrasonic physical activation with the chemical functionalization using tetraethylenepentamine (TEPA). Acoustic treatment exfoliates the clusters of graphene oxide and enhances the surface area for the subsequent amine functionalization and CO2 adsorption. Changes in textural properties, surface functionalities, thermal stability, and elemental compositions were examined before and after activation of graphene oxide. The characterization results revealed substantial increment of N content, from 0.08 in pristine to 4.84% in functionalized GO and the subsequent reduction in surface area from 289 to 198 m2/g in the functionalized GO, indicating attachment of TEPA to GO structure. CO2 adsorption experiments were conducted under diluted CO2 with the partial pressure of 0.10 atm. at 338 K and the results revealed that ultrasonic-TEPA activated GO possessed enhanced adsorption capacity of 1.2 mmol g−1 over pristine GO. While pristine GO could only achieve the maximum adsorption capacity of 0.3 mmol g−1 at 303 K. Besides, the sonochemically modified adsorbent showed stable cyclic adsorption-regeneration performance with only 1% reduction in adsorption capacity after 10 cycles. Finally, the effectiveness of the developed physicochemical activation technique was determined by comparing its adsorption capacity with the adsorbents found from literature.

Published

2019

10. Low frequency ultrasonic‐assisted Fenton oxidation of textile wastewater: process optimization and electrical energy evaluation

Author

Naveed Ramzan, Maham Maqsood, Bade ul Jamal, Baharak Sajjadi, Wei-Yin Chen, and Anam Asghar

Subjects

Environmental Engineering, Materials science, Textile, business.industry, Electric potential energy, Advanced oxidation process, Management, Monitoring, Policy and Law, Pollution, Fenton oxidation, chemistry.chemical_compound, Wastewater, Chemical engineering, chemistry, Ultrasonic assisted, Process optimization, Hydroxyl radical, business, Water Science and Technology

Published

2019

11. Acoustic Treatment of a Coal Gasification Residue for Extraction of Selenium

Author

Wei-Yin Chen, Baharak Sajjadi, and Riya Chatterjee

Subjects

Residue (chemistry), Fuel Technology, Chemistry, General Chemical Engineering, Energy Engineering and Power Technology, chemistry.chemical_element, Coal gasification, Pulp and paper industry, Selenium

Published

2019

12. Urea functionalization of ultrasound-treated biochar: A feasible strategy for enhancing heavy metal adsorption capacity

Author

James William Broome, Nathan I. Hammer, Cameron Smith, Nosa O. Egiebor, Daniell L. Mattern, Wei-Yin Chen, and Baharak Sajjadi

Subjects

Acoustics and Ultrasonics, Oxide, chemistry.chemical_element, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Corrosion, Inorganic Chemistry, chemistry.chemical_compound, Adsorption, Nickel, Biochar, Urea, Chemical Engineering (miscellaneous), Environmental Chemistry, Phosphoric Acids, Radiology, Nuclear Medicine and imaging, Phosphoric acid, Organic Chemistry, 021001 nanoscience & nanotechnology, Nitrogen, 0104 chemical sciences, Ultrasonic Waves, chemistry, Chemical engineering, Charcoal, Surface modification, Environmental Pollutants, Graphite, 0210 nano-technology

Abstract

The main objective of a series of our researches is to develop a novel acoustic-based method for activation of biochar. This study investigates the capability of biochar in adsorbing Ni(II) as a hazardous contaminant and aims at enhancing its adsorption capacity by the addition of extra nitrogen and most probably phosphorous and oxygen containing sites using an ultrasono-chemical modification mechanism. To reach this objective, biochar physically modified by low-frequency ultrasound waves (USB) was chemically treated by phosphoric acid (H3PO4) and then functionalized by urea (CO(NH2)2). Cavitation induced by ultrasound waves exfoliates and breaks apart the regular shape of graphitic oxide layers of biochar, cleans smooth surfaces, and increases the porosity and permeability of biochar’s carbonaceous structure. These phenomena synergistically combined with urea functionalization to attach the amine groups onto the biochar surface and remarkably increased the adsorption of Ni(II). It was found that the modified biochar could remove > 99% of 100 mg Ni(II)/L in only six hours, while the raw biochar removed only 73.5% of Ni(II) in twelve hours. It should be noted that physical treatment of biochar with ultrasound energy, which can be applied at room temperature for a very short duration, followed by chemical functionalization is an economical and efficient method of biochar modification compared with traditional methods, which are usually applied in a very severe temperature (>873 K) for a long duration. Such modified biochars can help protect human health from metal-ion corrosion of degrading piping in cities with aging infrastructure.

Published

2019

13. Biomass densification: Effect of cow dung on the physicochemical properties of wheat straw and rice husk based biomass pellets

Author

Maira Iftikhar, Anam Asghar, Baharak Sajjadi, Wei-Yin Chen, and Naveed Ramzan

Subjects

Renewable Energy, Sustainability and the Environment, Chemistry, 020209 energy, Pellets, Biomass, Forestry, 02 engineering and technology, Straw, Pulp and paper industry, Manure, Husk, Bulk density, Pellet, 0202 electrical engineering, electronic engineering, information engineering, Waste Management and Disposal, Agronomy and Crop Science, Cow dung

Abstract

This study investigates the potential of cow dung, an animal manure, as a binder to enhance the physicochemical properties of the base pellet (a mixture of wheat straw and rice husk). In the first step, preliminary experiments were performed to select the best composition of wheat straw and rice husk for the base pellet. The selection was based on calorific value. Subsequently, the effect of operating parameters such as varying compositions of cow dung (0–100%), molasses concentration (0–100%) and drying time (12–48 h) was investigated. Thus, Central Composite Design using Response Surface Methodology was used to investigate the proximate analysis, calorific value, bulk density and durability of biomass pellets. The experimental results suggested that the addition of cow dung into the base pellet resulted in the increase of volatile matter, ash content, bulk density and durability of the base pellet. As a result, the maximum calorific value of 14.98 MJ/kg, moisture content of 3.37%, volatile matter of 45.49%, ash content of 31.38%, bulk density of 108990 kg/m3 and durability of 95% were obtained. However, optimization of operating parameters was performed to optimize the ash percentage. With the pellet composition of 8.5% (base pellet composition of 90% wheat straw and 10% rice husk), molasses concentration of 50% and drying time of 12 h, 52% reduction in ash content and 2.3% increase in calorific value were obtained at the cost of 38% reduction in the bulk density and insignificant reduction in durability of the produced pellet. Therefore, the use of waste material like cow dung as a binder can be considered as a sustainable approach to improve the physicochemical properties especially durability of biomass pellets. Thus, it can effectively be used to fulfill the energy and heating requirement of rural areas.

Published

2019

14. Effects of pH on Biochar's heating value during acoustic treatment

Author

Baharak Sajjadi, Wei-Yin Chen, and Daniell L. Mattern

Subjects

Renewable Energy, Sustainability and the Environment, Forestry, Waste Management and Disposal, Agronomy and Crop Science

Published

2022

15. Introduction to Climate Change Mitigation and Adaptation

Author

Wei-Yin Chen, Maximilian Lackner, and Bahar Sajjadi

Subjects

Climate change mitigation, Geography, business.industry, Environmental resource management, business, Adaptation (computer science)

Published

2021

16. Effect of Pyrolysis Temperature on PhysicoChemical Properties and Acoustic-Based Amination of Biochar for Efficient CO2 Adsorption

Author

Daniell L. Mattern, Nathan I. Hammer, Baharak Sajjadi, Riya Chatterjee, Austin Dorris, Vijayasankar Raman, and Wei-Yin Chen

Subjects

Economics and Econometrics, tetraethylenepentamine, 020209 energy, Energy Engineering and Power Technology, lcsh:A, 02 engineering and technology, Raw material, Adsorption, Biochar, 0202 electrical engineering, electronic engineering, information engineering, biochar, Char, various pyrolysis temperature, biology, Renewable Energy, Sustainability and the Environment, Chemistry, ultrasound, Miscanthus, 021001 nanoscience & nanotechnology, biology.organism_classification, Fuel Technology, Corn stover, lcsh:General Works, 0210 nano-technology, Bagasse, CO2 adsorption, Pyrolysis, Nuclear chemistry

Abstract

The present study examined the effect of pyrolysis temperature on the physicochemical properties of biochar, activation process and carbon capture. Two different categories of biochars were synthesized from herbaceous (miscanthus and switchgrass) or agro-industrial (corn stover and sugarcane bagasse) feedstock under four different pyrolysis temperatures- 500, 600, 700 and 800 oC. The synthesized biochars underwent sono-amination activation comprising low-frequency acoustic treatment followed by amine functionalization to prepare adsorbents for CO2 capture. As per the elemental analysis, the elevated pyrolysis temperature resulted in increased %C and %ash contents and reduced %N contents of biochar. The textural analysis exhibited almost 3-times enhancement of micro surface area and pore volume upon increasing the pyrolysis temperature from 500 to 700 oC, though further increase to 800 oC reduced the micro-porosity and the surface area. The intermediate temperatures of 600 and 700 oC revealed the highest interactions with ultrasound-amination, which significantly intensified CO2 adsorption. Accordingly, the CO2 capture capacity of sono-aminated biochars synthesized at 600 and 700 oC were almost 200% greater than that of raw biochars. There were 127-159% and 115-151% increases in adsorption capacity of biochars synthesized at 800 and 500 oC upon ultrasono-amine functionalization. Miscanthus biochar synthesized at 700 oC and treated sono-chemically demonstrated the highest adsorption ability of 2.89 mmol/g at 70 oC and 0.10 atm partial pressure, which is 211% higher than its pristine condition. The superior adsorption capacity of miscanthus (at 700 oC) can be attributed to its large surface area (324.35 m2/g), high carbon content (84%), and low ash content (4.9%), as well as its %N content after sono-amination that was twice that of raw char.

Published

2020

17. Low Frequency Ultrasound Enhanced Dual Amination of Biochar: A Nitrogen-Enriched Sorbent for CO2 Capture

Author

Vijayasankar Raman, Nosa O. Egiebor, Wei-Yin Chen, Daniell L. Mattern, Baharak Sajjadi, Riya Chatterjee, and Nathan I. Hammer

Subjects

Sorbent, Chemistry, General Chemical Engineering, Activation technique, Energy Engineering and Power Technology, chemistry.chemical_element, 02 engineering and technology, 021001 nanoscience & nanotechnology, Nitrogen, Low frequency ultrasound, Fuel Technology, 020401 chemical engineering, Chemical engineering, Chemical functionalization, Biochar, 0204 chemical engineering, 0210 nano-technology, Amination

Abstract

The present study discusses a novel biochar activation technique consisting of physical modification using low frequency ultrasound and chemical functionalization with individual amines and their b...

Published

2019

18. Variables governing the initial stages of the synergisms of ultrasonic treatment of biochar in water with dissolved CO2

Author

Daniell L. Mattern, Chin-Pao Huang, Ruimei Fan, Adedapo Adeniyi, Baharak Sajjadi, Wei-Yin Chen, and Joel Mobley

Subjects

Aqueous solution, Hydrogen, biology, Chemistry, Formic acid, 020209 energy, General Chemical Engineering, Organic Chemistry, Energy Engineering and Power Technology, chemistry.chemical_element, 02 engineering and technology, Miscanthus, biology.organism_classification, Sonochemistry, chemistry.chemical_compound, Fuel Technology, 020401 chemical engineering, Environmental chemistry, Mass transfer, Biochar, 0202 electrical engineering, electronic engineering, information engineering, Heat of combustion, 0204 chemical engineering

Abstract

The objectives of a series of our researches are to determine the feasibility of applying ultrasonic pretreatment prior to biochar gasification. As per the initial results, the heating value (HV) of biochar significantly increased after acoustic treatment in water with dissolved CO2 (AIChE Journal, 2014;60:1054–1065). Accordingly, emphasis of the current work is placed on the parameters governing the HV of biochar in the early stage of the treatment. Switchgrass and miscanthus biochars were treated under different conditions. The reactant ratio, biochar:water:CO2, exhibited profound impacts on the synergism. The highest (but not yet systematically optimized) ratio of HV increase (or HV Gain, HG) to ultrasound energy supplied (ES) takes place when biochar-to-water ratio, or BC:W, equals 0.06 g/ml. The observed HG/ES is about 10, suggesting that the energy consumption is only a fraction of the acoustic energy supplied. Miscanthus biochar’s HV increases by up to 4.6% after treatment at 5% amplitude for 135 s (HG = 33 cal/g). For the same run, miscanthus biochar's H content increased by 42.7%. Changes in HV can be mediated by mineral leaching, C or H fixation, or O content loss. Mineral leaching is influenced by pH and CO2 concentration. CO2 and water are the sole contributors to C and H gains, respectively. CO2 concentration in the solution during the treatment is also affected by mass transfer limitations, ultrasound power, and design of the three-phase reactor. Increasing the BC:W ratio initially enhances the cavitation nuclei on the fluid/solid surface, and therefore sonolysis. The subsequent decrease in HV with increasing BC:W may be due to the limitation in ultrasound penetration and H supply from water. Carbon and hydrogen fixation may be connected to the formation of H2, CO, formic acid, formaldehyde, and associated radicals during sonolysis of aqueous CO2.

Published

2019

19. Enhanced degradation of organic contaminants using catalytic activity of carbonaceous structures: A strategy for the reuse of exhausted sorbents

Author

Daniell L. Mattern, Wendong Tao, Nosa O. Egiebor, Wei-Yin Chen, Baharak Sajjadi, and Kalyani Mer

Subjects

Environmental Engineering, Metal ions in aqueous solution, chemistry.chemical_element, 02 engineering and technology, 010501 environmental sciences, 01 natural sciences, Catalysis, Metal, chemistry.chemical_compound, Adsorption, Metals, Heavy, Biochar, Environmental Chemistry, Phenol, 0105 earth and related environmental sciences, General Environmental Science, Advanced oxidation process, General Medicine, Hydrogen Peroxide, 021001 nanoscience & nanotechnology, Carbon, chemistry, Chemical engineering, visual_art, Charcoal, visual_art.visual_art_medium, 0210 nano-technology, Oxidation-Reduction

Abstract

Generation of hydroxyl radicals (⋅OH) is the basis of advanced oxidation process (AOP). This study investigates the catalytic activity of microporous carbonaceous structure for in-situ generation of ⋅OH radicals. Biochar (BC) was selected as a representative of carbon materials with a graphitic structure. The work aims at assessing the impact of BC structure on the activation of H2O2, the reinforcement of the persistent free radicals (PFRs) in BC using heavy metal complexes, and the subsequent AOP. Accordingly, three different biochars (raw, chemically- and physiochemically-activated BCs) were used for adsorption of two metal ions (nickel and lead) and the degradation of phenol (100 mg/L) through AOP. The results demonstrated four outcomes: (1) The structure of carbon material, the identity and the quantity of the metal complexes in the structure play the key roles in the AOP process. (2) the quantity of PFRs on BC significantly increased (by 200%) with structural activation and metal loading. (3) Though the Pb-loaded BC contained a larger quantity of PFRs, Ni-loaded BC exhibited a higher catalytic activity. (4) The degradation efficiency values for phenol by modified biochar in the presence of H2O2 was 80.3%, while the removal efficiency was found to be 17% and 22% in the two control tests, with H2O2 (no BC) and with BC (no H2O2), respectively. Overall, the work proposes a new approach for dual applications of carbonaceous structures; adsorption of metal ions and treatment of organic contaminants through in-situ chemical oxidation (ISCO).

Published

2020

20. Microalgae lipid and biomass for biofuel production: A comprehensive review on lipid enhancement strategies and their effects on fatty acid composition

Author

Shaliza Ibrahim, Wei-Yin Chen, Abdul Aziz Abdul Raman, and Baharak Sajjadi

Subjects

Renewable Energy, Sustainability and the Environment, Chemistry, business.industry, 020209 energy, Phosphorus, chemistry.chemical_element, Biomass, 02 engineering and technology, Environmentally friendly, Renewable energy, Productivity (ecology), Biofuel, 0202 electrical engineering, electronic engineering, information engineering, Production (economics), lipids (amino acids, peptides, and proteins), Food science, Fatty acid composition, business

Abstract

Renewable energy sources e.g. biofuels, are the focus of this century. Economically and environmental friendly production of such energies are the challenges that limit their usages. Microalgae is one of the most promising renewable feedstocks. However, economical production of microalgae lipid in large scales is conditioned by increasing the lipid content of potential strains without losing their growth rate or by enhancing both simultaneously. Major effort and advances in this area can be made through the environmental stresses. However, such stresses not only affect the lipid content and species growth (biomass productivity) but also lipid composition. This study provides a comprehensive review on lipid enhancement strategies through environmental stresses and the synergistic or antagonistic effects of those parameters on biomass productivity and the lipid composition. This study contains two main parts. In the first part, the cellular structure, taxonomic groups, lipid accumulation and lipid compositions of the most potential species for lipid production are investigated. In the second part, the effects of nitrogen deprivation, phosphorus deprivation, salinity stress, carbon source, metal ions, pH, temperature as the most important and applicable environmental parameters on lipid content, biomass productivity/growth rate and lipid composition are investigated.

Published

2018

21. Increasing the chlorine active sites in the micropores of biochar for improved mercury adsorption

Author

Yongsheng Zhang, Zifeng Sui, Huicong Zhang, Wei-Ping Pan, Tao Wang, Pauline Norris, Jiawen Wu, Wei-Yin Chen, and Jun Liu

Subjects

General Chemical Engineering, Organic Chemistry, Energy Engineering and Power Technology, chemistry.chemical_element, Hydrochloric acid, 02 engineering and technology, 010501 environmental sciences, Straw, 021001 nanoscience & nanotechnology, 01 natural sciences, Metal, chemistry.chemical_compound, Fuel Technology, Adsorption, chemistry, Mercury adsorption, visual_art, Biochar, Chlorine, visual_art.visual_art_medium, 0210 nano-technology, Mesoporous material, 0105 earth and related environmental sciences, Nuclear chemistry

Abstract

A series of biochars were prepared from rice(RI), tobacco(TO), corn(CO), wheat(WH), millet(MI), and black bean straw(BB). These biochars were used to study the mechanism of elemental mercury(Hg0) adsorption by hydrochloric acid modified biochars. The biochars were modified by 1 M hydrochloric acid (HCl) and then used in a fixed-bed Hg0 adsorption experiment. As would be expected, the results indicated that HCl modification increased the Hg0 adsorption performance of the six biochars. After modification, the Hg0 adsorption efficiency of tobacco biochar increased from 8.2% to 100.0%, and the average Hg0 adsorption capacity of the biochars increased by 61 times. The acid modification dissolved the metal compounds in the biochar, reducing the metal content and increasing the average surface area of the biochar. The average surface area of the raw biochars increased from 29.9 to 110.1 m2/g after HCl modification. The extra surface area was mostly created in the micropores, leading to a significant increase in the amount of micropores. These micropores effectively adsorbed the Cl atoms, which acted as active sites for Hg0. In the adsorption process, Hg0 diffused into the interior of modified biochars via mesopores, and finally the adsorbed Cl in the micropores reacted with Hg0 to form HgCl2.

Published

2018

22. Chemical activation of biochar for energy and environmental applications: a comprehensive review

Author

Wei-Yin Chen, Tetiana Zubatiuk, Jerzy Leszczynski, Danuta Leszczynska, and Baharak Sajjadi

Subjects

business.industry, Chemistry, Process (engineering), General Chemical Engineering, Industrial chemistry, 02 engineering and technology, 010501 environmental sciences, 021001 nanoscience & nanotechnology, 01 natural sciences, Biochar, 0210 nano-technology, Process engineering, business, Energy (signal processing), Amination, 0105 earth and related environmental sciences

Abstract

Biochar (BC) generated from thermal and hydrothermal cracking of biomass is a carbon-rich product with the microporous structure. The graphene-like structure of BC contains different chemical functional groups (e.g. phenolic, carboxylic, carbonylic, etc.), making it a very attractive tool for wastewater treatment, CO2 capture, toxic gas adsorption, soil amendment, supercapacitors, catalytic applications, etc. However, the carbonaceous and mineral structure of BC has a potential to accept more favorable functional groups and discard undesirable groups through different chemical processes. The current review aims at providing a comprehensive overview on different chemical modification mechanisms and exploring their effects on BC physicochemical properties, functionalities, and applications. To reach these objectives, the processes of oxidation (using either acidic or alkaline oxidizing agents), amination, sulfonation, metal oxide impregnation, and magnetization are investigated and compared. The nature of precursor materials, modification preparatory/conditions, and post-modification processes as the key factors which influence the final product properties are considered in detail; however, the focus is dedicated to the most common methods and those with technological importance.

Published

2018

23. Ultrasound cavitation intensified amine functionalization: A feasible strategy for enhancing CO2 capture capacity of biochar

Author

Riya Chatterjee, Nosa O. Egiebor, Daniell L. Mattern, Nathan I. Hammer, Jerzy Leszczynski, Wei-Yin Chen, Baharak Sajjadi, Danuta Leszczynska, and Tetiana Zubatiuk

Subjects

Graphene, Chemistry, General Chemical Engineering, Sonication, Organic Chemistry, Oxide, Energy Engineering and Power Technology, chemistry.chemical_element, 02 engineering and technology, 010501 environmental sciences, 021001 nanoscience & nanotechnology, 01 natural sciences, law.invention, chemistry.chemical_compound, Fuel Technology, Adsorption, Chemical engineering, law, Desorption, Biochar, Surface modification, 0210 nano-technology, Carbon, 0105 earth and related environmental sciences

Abstract

This paper describes a two-stage biochar activation process for CO2 capture, which includes acoustic treatment and amination. Contrarily to traditional carbon activation at temperatures above 700 °C, both stages of the current process are conducted at or near room temperature. It is known that CO2 can be fixed on the edge carbons of polycyclic aromatics hydrocarbons (PAHs) through thermal and reductive photo-carboxylation. Our previous work on biochar suggested that carbon of CO2 could be chemically fixed on biochar through acoustic or photochemical treatment of biochar in water/CO2 systems under ambient conditions. Separately, the graphene oxide (GO) literature reveals that carboxylic acids, epoxy and hydroxyl groups on biochar surface often serve as the active sites for converting GO to a new family of chemicals; amines are commonly grafted on these groups in the functionalization. Biochar has graphite and graphitic oxide clusters that consist of the oxygen functional groups mentioned above. These oxygen functionalities can be utilized for CO2 adsorption when functionalized with amine. Thus, the present study focuses on maximizing the CO2 capture capacity by manipulating the physicochemical structure of a pinewood-derived biochar. In this two-stage process, 30 s sonication at ambient temperature was applied to physically activate biochar prior to functionalization. Low-frequency ultrasound irradiation exfoliates and breaks apart the irregular graphitic layers of biochar, and creates new/opens the blocked microspores, thus enhancing the biochar’s porosity and permeability that are the keys in functionalization and subsequent CO2 capture. The sono-modified biochar was then functionalized with tetraethylenepentamine (TEPA) in the presence of two activating agents. The changes in surface characteristics, functional groups, graphene-like structure, and functionalization using activating agents were examined in detail and the capacity of the final products in CO2 removal was tested. The experimental results revealed that CO2 capture capacity, from a flow containing 10 and 15 vol% CO2, was almost 7 and 9 times higher, respectively, for ultrasound-treated amine-activated biochar, compared to raw biochar. The optimum capacity was 2.79 mmol/g at 70 °C and 0.15 atm CO2 partial pressure. Cyclic adsorption and desorption tests revealed that the CO2 capture capacity decreased 44% after 15 cycles.

Published

2018

24. Use of a non-thermal plasma technique to increase the number of chlorine active sites on biochar for improved mercury removal

Author

Tao Wang, Yongsheng Zhang, Pauline Norris, Wei-Ping Pan, Wei-Yin Chen, Jun Liu, and Huicong Zhang

Subjects

chemistry.chemical_classification, Sulfide, Chemistry, General Chemical Engineering, Inorganic chemistry, food and beverages, chemistry.chemical_element, 02 engineering and technology, General Chemistry, 010501 environmental sciences, Straw, Nonthermal plasma, 021001 nanoscience & nanotechnology, 01 natural sciences, Sulfur, Industrial and Manufacturing Engineering, Adsorption, Biochar, Chlorine, Environmental Chemistry, 0210 nano-technology, Pyrolysis, 0105 earth and related environmental sciences

Abstract

Biochar, known as a byproduct of biomass pyrolysis, was prepared from rice straw (R6), tobacco straw (T6), corn straw (C6), wheat straw (W6), millet straw (M6), and black bean straw (B6) in high purity nitrogen at 600 °C. Chlorine (Cl) non-thermal plasma was used to increase Cl active sites on biochar to promote the mercury removal efficiency. The physio-chemical properties of biochar were characterized by proximate analysis, ultimate analysis, BET, SEM, TGA, FTIR, and XPS. Modification by chlorine plasma increased the Hg0 removal efficiency of the biochar from around 8.0% to 80.0%. The Hg0 adsorption capacity of T6 was 36 times higher after Cl2 plasma modification. Plasma caused the biochar surface to become porous and promoted the thermal stability of the biochar. Sulfur (S) content remained in the range of 0.5–0.7%, elemental/organic sulfur and sulfide were converted to sulfate during plasma treatment. The relative intensity of the oxygen functional groups (C O, C O and C(O) O C) were enhanced, while the content of oxygen (O) in biochar decreased. The main reason for the improved mercury removal efficiency by modified biochars was attributed to the increased number of C Cl groups on the surface of the biochars induced by Cl2 plasma. The C Cl groups functioned as activated sites and promoted the Hg0 removal efficiency.

Published

2018

25. A techno-economic analysis of solar catalytic chemical looping biomass refinery for sustainable production of high purity hydrogen

Author

Asif Hasan Rony, Jerzy Leszczynski, Maohong Fan, Tara Kathleen Righetti, Jennie Perey Saxe, Wei-Yin Chen, and Baharak Sajjadi

Subjects

Waste management, Power station, Renewable Energy, Sustainability and the Environment, business.industry, 020209 energy, Energy Engineering and Power Technology, Biomass, 02 engineering and technology, Raw material, Claus process, Refinery, Renewable energy, Fuel Technology, 020401 chemical engineering, Nuclear Energy and Engineering, 0202 electrical engineering, electronic engineering, information engineering, Environmental science, 0204 chemical engineering, business, Rectisol, Chemical looping combustion

Abstract

Compared to traditional biomass and coal-fired power plants, a process that includes integrated pyrolysis and subsequent gasification is a promising technology to deliver a larger electrical output through the production of high-purity hydrogen with a low carbon footprint. Chemical looping can further enhance the biomass contribution to the global renewable energy demand while fulfilling the stringent CO2 emission cuts needed in the energy sector. This study aims at investigating the feasibility of developing a solar catalytic chemical looping biomass refinery (SCCLBR) power plant for sustainable production of energy using a comprehensive plant modeling and techno-economic assessment. The plant is composed of 7 sequential units: i) biomass preparation (drying, transferring, and grinding), ii) reacting unit (SCCLBR), iii) water gas shift unit and heat recovery, iv) CO2 and H2S separation (Rectisol Process), v) sulfur removal (Claus Process), vi) air separation and vii) catalyst regeneration. The simulation was performed for 1–6 tonne/hour of biomass as input. The effect of key variables (feedstock load, water injection, and temperature) on the economic performance of the plant were analyzed. The simulated results of the chemical looping reactor were validated against the experimental results, while the results of Rectisol and air separation units were validated against the thermodynamic simulation. The results demonstrated that the CCLBR (without solar integration) and integrated SCCLBR can reach the efficiency of 34% and 41% respectively, yet the results have not been optimized. The sensitivity analysis indicated that water injection rate is the most influential parameter, which can even suppress the impact of biomass loading rate. A separate thermodynamic simulation was also performed to investigate the reaction equilibrium of oxygen carrier regeneration (Ca2Fe2O5) using CO2. The results demonstrated that a temperature above 730 °C is required to avoid carbonation (Fe2O3 and CaCO3 production). The maximum greenhouse gas emission in SCCLBR is 10.70, which is significantly lower than traditional coal-to-hydrogen and biomass-to-hydrogen power plants. It has also been found that across varying feedstock input rates, greenhouse gas emissions average 12.8% lower when solar PV supplements refinery power needs; optimization of the steam/biomass ratio may reduce emissions even further.

Published

2021

26. Investigating the effect of flue gas temperature and excess air coefficient on the size distribution of condensable particulate matters

Author

Yongsheng Zhang, Wei-Ping Pan, Baharak Sajjadi, Wei-Yin Chen, Nan Shi, Yue Peng, Jiawei Wang, and Tao Wang

Subjects

Flue gas, Range (particle radiation), Chemistry, 020209 energy, General Chemical Engineering, Organic Chemistry, Condensation, Analytical chemistry, Energy Engineering and Power Technology, 02 engineering and technology, 010501 environmental sciences, Particulates, Combustion, 01 natural sciences, Fuel Technology, Particle-size distribution, 0202 electrical engineering, electronic engineering, information engineering, Mass fraction, NOx, 0105 earth and related environmental sciences

Abstract

Primary particles emitted from fuel combustion mainly involve filterable particulate matter (FPM) and condensable particulate matter (CPM). Particularly, CPM has emerged as a subject for further emission control. This study investigated the effects of the sampling temperature and excess air coefficient (EAC) on the total mass, chemical speciation, and particle size distribution of CPM by integrating Electrical Low-Pressure Impactor+ (ELPI+) sampling devices with the EPA Method 202 (dry impinger method). The total mass of CPM increased with the sampling temperature and EAC. Specifically, the total concentration of CPM was 10.51–39.93 mg/m3, in which the mass fraction of organic species varied between 8.74 and 49.80%, and the organic components in CPM followed the ranking order of alkanes/alkenes (62.6–78.6%), oxygen-containing volatile organic compounds (OVOCs) (19.7–35.4%), and aromatics (5.6%). Compared with other inorganic species such as HCl and NOX, SO3 had a higher migration tendency from the flue gas to CPM. The particle size distribution suggested that heterogeneous condensation was responsible for the whole size range of particles in CPM, whereas the homogeneous condensation led to the increase of finer particles (smaller than 0.2 µm). Accordingly, adjusting the emission temperature and EAC could help to control the emission of CPM.

Published

2021

27. Modeling radical edge-site reactions of biochar in CO2/water solution under ultrasonic treatment

Author

Baharak Sajjadi, Jerzy Leszczynski, Danuta Leszczynska, Wei-Yin Chen, Glake Hill, and Tetiana Zubatiuk

Subjects

Aqueous solution, Inorganic chemistry, General Physics and Astronomy, chemistry.chemical_element, 02 engineering and technology, Edge (geometry), 010402 general chemistry, 021001 nanoscience & nanotechnology, Ring (chemistry), Photochemistry, 01 natural sciences, Oxygen, 0104 chemical sciences, Electron transfer, chemistry, Biochar, Density functional theory, Irradiation, Physical and Theoretical Chemistry, 0210 nano-technology

Abstract

We report results of theoretical evaluation of the mechanisms of possible radical reactions on the edge-site of biochar with CO 2 · - , OH , and H in irradiated aqueous solution. The computational studies were performed for model poly aromatic systems. Obtained mechanisms reflect one of the routes of the oxygen loss accompanied by increase of hydrogen content, as observed in photochemical experiment. The reaction of CO 2 · - with the edge site of biochar mainly leads to reduced rather than oxidized products. The mechanism of CO2 capturing is mapped by different routes of one-electron reduction and radical addition to the aromatic ring.

Published

2017

28. Double-layer magnetized/functionalized biochar composite: Role of microporous structure for heavy metal removals

Author

Austin Dorris, Ronish M. Shrestha, Nathan I. Hammer, Daniell L. Mattern, Baharak Sajjadi, Vijayasankar Raman, and Wei-Yin Chen

Subjects

Materials science, Process Chemistry and Technology, Metal ions in aqueous solution, Nanoparticle, 02 engineering and technology, Microporous material, 010501 environmental sciences, 01 natural sciences, chemistry.chemical_compound, Adsorption, 020401 chemical engineering, chemistry, Chemical engineering, Biochar, Magnetic nanoparticles, Surface modification, 0204 chemical engineering, Safety, Risk, Reliability and Quality, Waste Management and Disposal, 0105 earth and related environmental sciences, Biotechnology, Magnetite

Abstract

Magnetization facilitates the separation and reuse of adsorbents, but significantly reduces the adsorption capacity. In this study, a double layer magnetized/functionalized biochar composite was synthesized through a hybrid post-pyrolysis magnetization which sustained and even significantly increased the adsorption capacity of microporous carbonaceous biochar (BC). The developed process included i) structural modification of biochar under ultrasound waves, ii) magnetization with magnetite (Fe3O4) nanoparticles, and iii) functionalization with 3-aminopropyltriethoxysilane (TES). Ultrasound irradiation exfoliates and breaks apart the irregular graphite layers of biochar, and creates new, or opens blocked, micropores, thus enhancing the BC’s porosity. For its part, TES stabilizes the magnetic nanoparticles on the biochar surface, while it participates in water decontamination through the strong chelation ability of its amino groups toward metal ions. Scanning electron microscopy demonstrated the stable and uniform distribution of Fe3O4 nanoparticles on the surface of microporous biochar, and Fourier-transform infrared spectroscopy indicated effective surface functionalization. In addition, although magnetization usually reduces the porosity of carbonaceous adsorbents, the ultraviolet–visible spectroscopic analysis showed that double layer magnetic biochar composite exhibited a much greater ability to remove Ni(II) and Pb(II), with 139 % and 38 % higher adsorptions than raw biochar. Almost complete removal of Pb (91 %) was observed by magnetic-BC and the adsorbent could easily be separated using a neodymium magnet. This high performance can be attributed to the synergistic effect of ultrasound activation on increasing the porosity and surface area of biochar along with enhanced chelation imparted by amine functionalization. The developed technique can be used for synthesizing advanced adsorbents for removal of nuclear waste-related metal ions from aqueous environments.

Published

2021

29. Derivation of oxygen-containing functional groups on biochar under non-oxygen plasma for mercury removal

Author

Tao Wang, Yongsheng Zhang, Baomin Sun, Wei-Ping Pan, Huicong Zhang, and Wei-Yin Chen

Subjects

020209 energy, General Chemical Engineering, Radical, Organic Chemistry, Inorganic chemistry, Energy Engineering and Power Technology, chemistry.chemical_element, 02 engineering and technology, Oxygen, Mercury (element), Fuel Technology, Adsorption, 020401 chemical engineering, chemistry, Desorption, Biochar, Oxygen plasma, Correlation analysis, 0202 electrical engineering, electronic engineering, information engineering, 0204 chemical engineering

Abstract

Biochar was subjected to N2-plasma treatment after adsorbing water or oxygen. The mercury removal efficiency of the obtained samples was tested. The results of H2O-thermogravimetric and O2-temperature programmed desorption show that biochar had adsorption capacity for both water and oxygen during storage. The adsorbed water exhibited an inhibitory effect on mercury removal. However, after plasma treatment, water decomposed into oxygen-containing active radicals and combined with biochar to form oxygen-containing functional groups. The generated functional groups compensated for the inhibition of mercury capture. After the biochar adsorbed oxygen, the biochar was easily sintered under plasma, thereby reducing the mercury removal performance. The oxygen-containing functional groups formed by plasma treatment of oxygen adsorbed biochar also improved the mercury removal efficiency. Hg-temperature programmed desorption revealed that Hg0 could be oxidised by the generated oxygen-containing functional group to form HgO. Correlation analysis showed that the oxygen adsorbed by the biochar from air during storage was the main source of oxygen-containing functional groups generated under a non-oxygen plasma environment. The correlation coefficient was up to 0.999. During normal storage, the oxygen adsorbed by the adsorbent from the air can be converted into oxygen-containing functional groups during the plasma modification process, thereby oxidising Hg0.

Published

2020

30. Low-temperature acoustic-based activation of biochar for enhanced removal of heavy metals

Author

Baharak Sajjadi, Wei-Yin Chen, Daniell L. Mattern, Nathan I. Hammer, and Austin Dorris

Subjects

Diethanolamine, Process Chemistry and Technology, Sonication, chemistry.chemical_element, 02 engineering and technology, 010501 environmental sciences, 01 natural sciences, Nickel, chemistry.chemical_compound, Adsorption, 020401 chemical engineering, chemistry, Biochar, Surface modification, Leaching (metallurgy), 0204 chemical engineering, Safety, Risk, Reliability and Quality, Porosity, Waste Management and Disposal, 0105 earth and related environmental sciences, Biotechnology, Nuclear chemistry

Abstract

Conventional carbon activation requires heating carbon at a temperature greater than 700 °C for over 3 h, consuming 18,600 kcal/kg of activated biochar. In contrast, the ultrasound treatment method is conducted at ambient condition for a very short duration (∼30 s, which requires about 1135 kcal/kg of activated BC produced. The advanced low-temperature acoustic-based surface modification method not only increases the porosity and surface functionality of raw biochar, but also is economically feasible and environmentally friendly. As a sequel of our previous works, this study aims to investigate the interaction between ultrasonic-structural modification with four different pre-treatments including i) control with no pretreatment, ii) EDC/HBOt, iii) alkali using KOH, iv) acid using HNO3 or H3PO4. The process was then followed by amine functionalization with DEA (diethanolamine) for nickel removal. The results demonstrated that all acoustic-based amine-functionalized biochar samples, without any exception, had more amine- and oxygen-containing functional groups as well as micro porosity, compared to those aminated without acoustic-activation, particularly in samples pretreated with HNO3 and H3PO4. Despite an increase in porosity by ultrasonication, metal leaching from US-only samples and those activated with EDC/HOBt was observed during longer adsorption durations. However, the synergism created by the combined effect of ultrasound and KOH and H3PO4, not only enhanced the adsorption capacity of biochar but also significantly reduced the adsorption duration from 8 to 3 h. The highest nickel adsorptions were observed for ultrasonic-amine samples activated with H3PO4 > HNO3 ∼ KOH, which were far higher (60 %, 49 %, and 46 % more adsorption, without any leaching) than raw or US-biochar, or biochar aminated with EDC/HOBt or without pretreatment.

Published

2020

31. Photochemical and acoustic interactions of biochar with CO2and H2O: Applications in power generation and CO2capture

Author

Daniell L. Mattern, Alec A. Mattei, Wei-Yin Chen, James Corbett Senter, Connor W. Redwine, and Eneruvie Okinedo

Subjects

Environmental Engineering, Electricity generation, Adsorption, Hydrogen, chemistry, General Chemical Engineering, Biochar, chemistry.chemical_element, Heat of combustion, Combustion, Photochemistry, Biotechnology

Abstract

A critical literature review suggests that carbonaceous compounds react with (CO2 +H2O) mixture through thermal, photochemical, and sonochemical/sonophysical routes. A biochar was selected for studying these effects at 60°C and 1 atm for its potential benefits on power generation and CO2 capture. All treatments remove sizable minerals (K, Na, and Si) detrimental in power generation, and introduce carbon (up to 16% of original carbon in biochar) into the biochar matrix. Most treatments show increased hydrogen (up to 24%). Treatments lead to notable increased heating value of biochar (up to 50%). Treated biochars show increase (up to 19 fold) in internal surface area. The ultrasound energy output is a fraction of the increased heating value. Thus, pretreatment is potentially attractive for increasing the energy efficiency in combustion and gasification. Moreover, better understandings of the salient reactions of these processes will be advantageous for the development of advanced adsorbents for CO2 capture. © 2014 American Institute of Chemical Engineers AIChE J, 60: 1054–1065, 2014

Published

2014

32. Fuel Efficiency in Transportation Systems

Author

John Seiner, Wei-Yin Chen, and Maximilian Lackner

Subjects

Waste management, Fuel efficiency, Environmental science

Published

2016

33. Effect of Additive Agents on the Simultaneous Absorption of NO2 and SO2 in the Calcium Sulfite Slurry

Author

Junhu Zhou, Xiang Zhang, Zhihua Wang, Zhijun Zhou, Kefa Cen, and Wei-Yin Chen

Subjects

Ammonium sulfate, Flue gas, Chemistry, General Chemical Engineering, Inorganic chemistry, Energy Engineering and Power Technology, Ferrous, Flue-gas desulfurization, chemistry.chemical_compound, Fuel Technology, Sulfite, Calcium sulfite, Slurry, Absorption (chemistry)

Abstract

It is known that NO in the flue gas can be effectively converted to NO2 by O3. The objective of this work is to investigate the feasibility of simultaneously abating NO2 and SO2 from flue gas by liquid-phase conversion. A suite of cost-effective additives for enhancing NO2 absorption through enriching the concentration of sulfite ion, SIV, in the liquid phase has been evaluated under pH similar to traditional flue-gas desulfurization (FGD). Experiments were conducted in a lab-scale washing tower with CaSO3 slurry, including metal and non-metal additives: FeSO4, FeCl2, Fe2(SO4)3, MnSO4, MnCl2, MgSO4, MgCl2, (NH4)2SO4, and NH4Cl. All of these additives enhance the absorption efficiency of NO2. Ferrous sulfate, FeSO4, is the most effective additive, with absorption efficiency reaching 95%, but the loss of additive is high because of the oxidation of FeII into FeIII. Ammonium sulfate, (NH4)2SO4, has similar absorption efficiency but shows lower loss during absorption. Its absorption efficiency improves with a...

Published

2012

34. Kinetics of post-combustion nitric oxide reduction by waste biomass fly ash

Author

Benson Gathitu and Wei-Yin Chen

Subjects

Order of reaction, Reducing agent, General Chemical Engineering, Inorganic chemistry, Energy Engineering and Power Technology, chemistry.chemical_element, Mineralogy, Oxygen, Reaction rate, Fuel Technology, Reaction rate constant, Adsorption, chemistry, Char, BET theory

Abstract

This work demonstrates that biomass fly ash, a carbon-containing by-product of a commercial pine-bark fired grate boilers, is a more viable and effective NO reducing agent than lignite char in a gasstream containing NO, O 2 and He in a tubular reactor at 300 to 600 °C that simulates the post-combustion zones. It requires no chemical or physical activation. It seems to follow the reburning mechanisms reported earlier. CO is a pivotal reaction intermediate. Alkali and alkaline earth metals catalyze both carbon oxidation leading to CO formation, and oxygen tranfer leading to CO scavenging of surfaceoxides formed after adsorption of NO. Empirical rate expressions for carbon oxidation and NO reduction are developed. The following rate model is used to recover the rate constants of carbon oxidation in the simulated flue gas. d X d t = k ( 1 − X ) ( P oxygen ) m A exp( − k c h a r d e a c t i v a t i o n t ) where X , t , k , P oxygen , m , A and k char deactivation denote carbon conversion, reaction time, rate constant based on per unit surface area, partial pressure of O 2 at the inlet, reaction order, N 2 BET surface area per unit weight of the sample, and rate of carbon deactivation, respectively. A first-order rate expression is adopted for recovering the rate constants of NO reduction.

Published

2011

35. Efficient and cost effective reburning using common wastes as fuel and additives

Author

Wei-Yin Chen, Benson Gathitu, and Yaxin Su

Subjects

Waste management, Reducing agent, Chemistry, business.industry, General Chemical Engineering, Organic Chemistry, Energy Engineering and Power Technology, Mineralogy, Scrap, Raw material, Industrial waste, Fuel Technology, Natural gas, Fly ash, By-product, Char, business

Abstract

Potential substitutes of natural gas and lignite fly ash as NO and HCN reducing agents, respectively, for heterogeneous reburning were examined in a bench-scale apparatus equipped with a simulated reburning and a burnout furnace. Selection of NO reducing agent is based on fuel volatility and nitrogen functionality. HCN reducing agent selection is based on literature data. A wide range of waste materials and industrial by-products show overall NO reduction efficiency up to 88% at reburning stoichiometric ratio 0.90 or 0.95. Mixed fuel containing scrap tire and Fe 2 O 3 is particularly effective. Though its cost is constrained by the energy-intensive operation of grinding the tire, the estimated raw-material cost is better than that of natural gas reburning and highly competitive against SCR. A first-level approximation study of the selectivities of nitrogen species to form NO in burnout zone reveals the importance of HCN and char nitrogen reaction mechanisms.

Published

2010

36. Video encoder design for high-definition 3D video communication systems

Author

Li-Fu Ding, Liang-Gee Chen, Wei-Yin Chen, Pei-Kuei Tsung, Yu-Han Chen, Pai-Heng Hsiao, Chuang Tzu-Der, and Shao-Yi Chien

Subjects

Computer Networks and Communications, business.industry, Computer science, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, Memory bandwidth, Communications system, Computer Science Applications, High-definition video, Cache, Electrical and Electronic Engineering, Multiview Video Coding, business, Encoder, Context-adaptive binary arithmetic coding, Computer hardware, Data compression

Abstract

VLSI realization of video compression is the key to real-time high-definition 3D communication systems. The newly established multiview video coding standard, as an extension profile of H.264/AVC, draws more and more attention for its high compression ratio and free-viewpoint support. Besides providing the 3D experience, multiview video can also give users complete scene perception. However, the multiple-viewpoint throughput requirement of MVC increase the complexity and hardware cost dramatically. The system memory bandwidth, on-chip memory size, and processing data throughput of each module all need to be optimized in an MVC encoder. Therefore, efficient hardware solutions for MVC architecture design are needed. In this article an overview of 3D video coding standards developments and design challenges of an MVC encoder are discussed. Then the algorithm and architecture optimization schemes are proposed. For the trade-off between system memory bandwidth and on-chip memory size, a cache-based prediction engine is proposed to ease both design challenges. Moreover, the hybrid open-close loop intra prediction scheme and the frame-parallel pipeline-doubled dual CABAC solve the throughput requirement problem. At the end of this article, based on all the proposed solutions, a prototype single-chip MVC encoder design with processing ability of 4096 × 2160 single-view to 1280 × 720 seven-view is presented.

Published

2010

37. A 212 MPixels/s 4096 $\times$ 2160p Multiview Video Encoder Chip for 3D/Quad Full HDTV Applications

Author

Ping-Chih Lin, Liang-Gee Chen, Pei-Kuei Tsung, Chia-Yu Chang, Pai-Heng Hsiao, Wei-Yin Chen, Chuang Tzu-Der, Li-Fu Ding, Tung-Chien Chen, Shao-Yi Chien, Hsu-Kuang Chiu, and Yu-Han Chen

Subjects

Hardware architecture, High-definition television, business.industry, Computer science, Embedded system, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, Macroblock, Electrical and Electronic Engineering, Multiview Video Coding, business, Encoder, Auxiliary memory, Computer hardware

Abstract

Multiview video coding (MVC) plays an important role in a 3-D video system. In addition, the resolution of HDTV is increasing to present more vivid perception for users. To realize real-time processing of dozens of TOPS, VLSI solution is necessary. However, ultra high computational complexity, a large amount of external memory bandwidth and on-chip SRAM size, and complex MVC prediction structures are three main design challenges of implementation of MVC hardware architecture. In this paper, an MVC single-chip encoder is proposed for H.264/AVC Multiview High Profile and High Profile for 3-D and quad full high definition (QFHD) TV applications, respectively. The 4096 × 2160 p multiview video encoder chip is implemented on a 11.46 mm2 die with 90 nm CMOS technology. An eight-stage macroblock pipelined architecture with proposed system scheduling and cache-based prediction core supports real-time processing from one-view 4096 × 2160 p to seven-view 720 p videos. The 212 Mpixels/s throughput is 3.4 to 7.7 times higher than previous work. The 407 Mpixels/W power efficiency is achieved, and 94% on-chip SRAM size and 79% external memory bandwidth are saved by the proposed techniques.

Published

2010

38. Effects of Pretreatment of Coal by CO2 on Nitric Oxide Emission and Unburned Carbon in Various Combustion Environments

Author

Wei-Yin Chen and Benson Gathitu

Subjects

Bituminous coal, business.industry, General Chemical Engineering, geology.rock_type, geology, chemistry.chemical_element, General Chemistry, Combustion, Coal liquefaction, Industrial and Manufacturing Engineering, Supercritical fluid, chemistry, Chemical engineering, Fly ash, Coal, business, Carbon, Staged combustion

Abstract

Polar solvents are known to swell coal, break hydrogen bonds in the macromolecular structure, and enhance coal liquefaction efficiencies. The effects of the pretreatment of coal using supercritical CO{sub 2} on its physical structure and combustion properties have been studied at the bench-scale level. Emphasis has been placed on NO reburning, NO emissions during air-fired and oxy-fired combustion, and loss on ignition (LOI). Pretreatment was found to increase porosity and to significantly alter the fuel nitrogen reaction pathways. Consequently, NO reduction during reburning using bituminous coal increased, and NO emissions during oxidation of lignite decreased. These two benefits were achieved without negative impacts on LOI.

Published

2009

39. Effects of Coal Interaction with Supercritical CO2: Physical Structure

Author

Michael McClure, Benson Gathitu, and Wei-Yin Chen

Subjects

Bituminous coal, Chemistry, business.industry, General Chemical Engineering, geology.rock_type, Maceral, geology, Mineralogy, chemistry.chemical_element, Sorption, General Chemistry, Coal liquefaction, complex mixtures, Industrial and Manufacturing Engineering, Supercritical fluid, chemistry.chemical_compound, Chemical engineering, Carbon dioxide, Coal, business, Carbon

Abstract

It is known that polar solvents swell coal, break hydrogen-bonds in the macromolecular structure, and enhance coal liquefaction efficiencies. The effects of drying, interaction with supercritical CO2 and degassing on the physical structure of coal have been studied using gas sorption technique and a scanning electron microscope (SEM). Both drying and interaction with supercritical CO2 drastically change the micropore and mesopore surface area, absolute volume, and volume distribution in both bituminous coal and lignite. Degassing removes debris in the pore space which allows for better analysis of the changes in the morphology that were induced by drying and exposure to supercritical CO2. SEM reveals that interaction of bituminous coal with supercritical CO2 results in an abundance of carbon structures similar to the maceral collinite.

Published

2009

40. Roles of Mineral Matter in the Early Stages of Coal Combustion

Author

Wei-Yin Chen, Shaolong Wan, and Guang Shi

Subjects

Bituminous coal, business.industry, Chemistry, General Chemical Engineering, geology.rock_type, technology, industry, and agriculture, geology, Energy Engineering and Power Technology, Coal combustion products, chemistry.chemical_element, Mineralogy, Combustion, complex mixtures, Oxygen, Oxygen balance, Fuel Technology, Chemical engineering, Coal, Char, business, Carbon

Abstract

In a recent study, we discovered that oxygen from the gas phase, organic portions of the coal, and minerals in the coal have profound influence on the formation and desorption of stable surface oxides in the early stages of coal combustion. In an attempt to isolate the effects of minerals, demineralized coals (DMC) are oxidized in O{sub 2} with a contact time less than 1 s, and the amount and strength of stable surface oxides are characterized by temperature-programmed desorption (TPD) up to 1650{sup o}C. Young chars derived from both demineralized lignite and bituminous coals show low and flat TPD profiles over a wide temperature range, signifying the minerals' catalytic activities in forming stable surface oxides for both coals. Indeed, the oxidation rates of chars from both bituminous coals and lignite, estimated based on the O{sub 2} concentrations entering and exiting the Al{sub 2}O{sub 3} reactor, were higher than their DMC counterparts. Moreover, graphite, containing no minerals and organically bound oxygen, has an even lower oxidation rate. Similar to those for the raw coals, the combined oxygen balance and elemental analysis of chars from DMC suggests that the oxygen in the organic portion of the lignite activates oxygen turnover andmore » carbon oxidation during its combustion; neither chars from raw nor demineralized bituminous coals possess these properties. X-ray photoelectron spectroscopy (XPS) of raw and demineralized bituminous coals and their char show peaks at around 532.0 eV in the O(1s) difference spectrum, suggesting the possible existence of intercalated stable surface oxides. 35 refs., 7 figs., 4 tabs.« less

Published

2009

41. Content-Aware Prediction Algorithm With Inter-View Mode Decision for Multiview Video Coding

Author

Li-Fu Ding, Pei-Kuei Tsung, Wei-Yin Chen, Shao-Yi Chien, and Liang-Gee Chen

Subjects

Motion compensation, Computer science, Image processing, Coding tree unit, Computer Science Applications, Rate–distortion theory, Search algorithm, Motion estimation, Signal Processing, Media Technology, Electrical and Electronic Engineering, Multiview Video Coding, Algorithm, Image compression, Block-matching algorithm, Data compression

Abstract

3-D video will become one of the most significant video technologies in the next-generation television. Due to the ultra high data bandwidth requirement for 3-D video, effective compression technology becomes an essential part in the infrastructure. Thus multiview video coding (MVC) plays a critical role. However, MVC systems require much more memory bandwidth and computational complexity relative to mono-view video coding systems. Therefore, an efficient prediction scheme is necessary for encoding. In this paper, a new fast prediction algorithm, content-aware prediction algorithm (CAPA) with inter-view mode decision, is proposed. By utilizing disparity estimation (DE) to find corresponding blocks between different views, the coding information, such as rate-distortion cost, coding modes, and motion vectors, can be effectively shared and reused from the coded view channel. Therefore, the computation for motion estimation (ME) in most view channels can be greatly reduced. Experimental results show that compared with the full search block matching algorithm (FSBMA) applied to both ME and DE, the proposed algorithm saves 98.4-99.1% computational complexity of ME in most view channels with negligible quality loss of only 0.03-0.06 dB in PSNR.

Published

2008

42. Characterization of Early-stage Coal Oxidation by Temperature-programmed Desorption

Author

Wei-Yin Chen, Guang Shi, and Shaolong Wan

Subjects

Thermal desorption spectroscopy, business.industry, General Chemical Engineering, Energy Engineering and Power Technology, chemistry.chemical_element, Oxygen, Fuel Technology, chemistry, Chemical engineering, Desorption, Organic chemistry, Coal gasification, Coal, Char, business, Pyrolysis, Carbon

Abstract

To obtain representative temperature-programmed desorption (TPD) profiles of young oxidized chars up to 1650 °C with minimal reactor wall interferences, the chemistry and physics of four ceramic materials has been critically reviewed. A two-staged experimental apparatus is then uniquely designed to produce chars in an Al2O3 flow reactor with 1−21% O2 followed by in situ TPD with a SiC tube. Comparison of TPD profiles of oxidized chars with those from pyrolyzed chars and ashes suggests early-stage char oxidation is profoundly influenced by oxygen from three sources: organics oxygen, mineral matters, and gas phase O2. Young chars oxidized at 1000 °C with less than 0.3 s residence time shows CO desorption peaks during TPD at three distinct temperatures: 730, 1280, and 1560 °C. The peaks at 730 °C are mainly caused by incomplete devolatilization. The peaks at 1280 °C mainly represent desorption of stable surface oxides and incomplete devolatilization. Increasing the gas phase oxidants notably increases the am...

Published

2008

43. Handbook of Climate Change Mitigation and Adaptation

Author

Toshio Suzuki, Maximilian Lackner, and Wei-Yin Chen

Subjects

Climate change mitigation, business.industry, Environmental resource management, Environmental science, business, Adaptation (computer science)

Published

2016

44. Stable Oxides on Chars and Impact of Reactor Materials at High Temperatures

Author

Guang Shi, Wei-Yin Chen, and Shaolong Wan

Subjects

Materials science, General Chemical Engineering, Analytical chemistry, Energy Engineering and Power Technology, chemistry.chemical_element, Mineralogy, Activation energy, Combustion, Oxygen, chemistry.chemical_compound, Fuel Technology, chemistry, Aluminium, Desorption, Carbon dioxide, Char, Carbon

Abstract

This paper reports our first study on the deactivation of young chars in flame conditions. The quantity and strength of surface oxides on young chars are monitored in situ by temperature-programmed desorption (TPD) up to 1700 °C. Young chars contain more abundant surface oxides than old chars over a wide range of temperature. Lignite chars possess more oxides than chars derived from a bituminous coal. Chars oxidized at 629 °C show desoprtion products at three distinct temperatures: 725, 1430, and 1700 °C. The TPD peaks around 725 °C correspond to activation energies in the range of 107-170 kJ/mol and have been well-documented in the literature. CO desorbed at around 1430 °C corresponds to activation energies over 300 kJ/mol, signifying the possible roles of strongly bound oxides on the basal planes of carbon. Search of the oxygen source for the huge amount of CO production at 1700 °C reveals that commonly adopted alumina tubes and support materials decompose to Al 2 O (g) and emit a notable amount of O 2 at temperatures above 1300 °C. Moreover, alumina tube and support materials react with CO and form CO 2 ; they also react with carbon and form CO and aluminum oxycarbides. SiC tube, on the other hand, is oxidized by O 2 , CO 2 , and H 2 O and forms SiO (g) , SiO 2(s) , Si-(OH) 4(g) , and CO above 650 °C. Moreover, Si can also form through a secondary reaction of SiC and SiO 2 . Thus, alumina appears suitable for the oxidation part of the experiments, where up to 120 ppm of O 2 emission is acceptable at a temperature of 1700 °C. SiC appears acceptable for TPD, though a small amount of SiC may be oxidized by the TPD product, CO 2, at temperatures above 900 °C. Oxidation of SiC prior to TPD should be avoided.

Published

2007

45. Exploratory study on the relationship between knowledge attributes and innovation behavior in SMEs in the information service industry

Author

Wei-Yin Chen, Feng-Shang Wu, and Chien-Hsin Wu

Subjects

Service (business), Knowledge management, business.industry, Qualitative interviews, media_common.quotation_subject, Manufacturing, Information system, Exploratory research, business, Tertiary sector of the economy, Autonomy, media_common

Abstract

Studies conducted in recent years have indicated that the innovation behaviors of a company is determined by its knowledge attributes. Research conducted on these topics has mainly focused on the manufacturing industry, and limited emphasis is placed on service-oriented industries such as the information service industry. Most of the companies in the information service industry are small and medium-sized enterprises (SMEs). Therefore, this study focused on information service SMEs and aimed to determine the relationship between knowledge attributes and innovation behaviors in information service companies. An exploratory study involving qualitative interviews with five software companies was performed, and the results indicated that 1) knowledge attributes influence innovation behaviors and management in software companies, and 2) R&D personnel autonomy in information service SMEs also influence innovation behaviors and management. The findings of this study have potential applicability in both the theory and practice of knowledge management.

Published

2015

46. Design of mixed fuel for heterogeneous reburning

Author

Wei-Yin Chen and Benson Gathitu

Subjects

Fuel Technology, Chemical engineering, Chemistry, General Chemical Engineering, Organic Chemistry, Carbon source, Energy Engineering and Power Technology, Mineralogy, Selective catalytic reduction, Reaction intermediate, Mixed fuel, Catalysis

Abstract

Recent study of heterogeneous reburning suggests effective NO reduction requires an adequate carbon source and a pool of catalysts that reduces not only NO, but also the reaction intermediate HCN [Chen WY and Tang L. Variables, kinetics and mechanisms of heterogeneous reburning. AIChE J 2001;47:2781-2797]. The current work demonstrates that ashes from lignite-fired power plants contain these desirable catalytic ingredients. Their reactivity is slightly lower than that of ashes produced in laboratory at lower temperatures, probably due to the formation of crystalline structure. The current work also demonstrates that for the power plants remote from lignite resources, ashes from biomass-fired grate boilers are a remarkably effective and economical substitute. About 85% of NO reduction efficiency appears achievable at a stoichiometric ratio 0.945. The raw-material cost estimates of the mixed-fuel technology suggest that it could be competitive with selective catalytic reduction (SCR).

Published

2006

47. Stochastic modeling of nonlinear epidemiology

Author

Wei-Yin Chen and Sankar Bokka

Subjects

Statistics and Probability, Mathematical optimization, Monte Carlo method, Population, Communicable Diseases, Models, Biological, General Biochemistry, Genetics and Molecular Biology, Disease Outbreaks, Master equation, Humans, Quantitative Biology::Populations and Evolution, Applied mathematics, education, Monte Carlo algorithm, Probability, Mathematics, education.field_of_study, Models, Statistical, General Immunology and Microbiology, Stochastic process, Applied Mathematics, General Medicine, Covariance, Nonlinear system, Modeling and Simulation, Disease Susceptibility, General Agricultural and Biological Sciences, Epidemic model, Monte Carlo Method, Algorithms

Abstract

The objectives of this paper to analyse, model and simulate the spread of an infectious disease by resorting to modern stochastic algorithms. The approach renders it possible to circumvent the simplifying assumption of linearity imposed in the majority of the past works on stochastic analysis of epidemic processes. Infectious diseases are often transmitted through contacts of those infected with those susceptible; hence the processes are inherently nonlinear. According to the classical model of Kermack and McKendrick, or the SIR model, three classes of populations are involved in two types of processes: conversion of susceptibles (S) to infectives (I) and conversion of infectives to removed (R). The master equations of the SIR process have been formulated through the probabilistic population balance around a particular state by considering the mutually exclusive events. The efficacy of the present methodology is mainly attributable to its ability to derive the governing equations for the means, variances and covariance of the random variables by the method of system-size expansion of the nonlinear master equations. Solving these equations simultaneously along with rates associated influenza epidemic data yields information concerning not only the means of the three populations but also the minimal uncertainties of these populations inherent in the epidemic. The stochastic pathways of the three different classes of populations during an epidemic, i.e. their means and the fluctuations around these means, have also been numerically simulated independently by the algorithm derived from the master equations, as well as by an event-driven Monte Carlo algorithm. The master equation and Monte Carlo algorithms have given rise to the identical results.

Published

2005

48. [Effects of Shenxiong pill on infarct brain volumes and NF-kappaB expression in SD rats with middle cerebral artery occlusion (MCAO)]

Author

Ping, Cao, Wei-Yin, Chen, Fang, Yang, Bi-De, Zhu, Fu-You, Liu, Wen, Xie, and Fang, Yu

Subjects

Rats, Sprague-Dawley, NF-kappa B, Animals, Brain, Infarction, Middle Cerebral Artery, Drugs, Chinese Herbal, Rats

Abstract

To investigate the effects of Shenxiong Pill on the infarct volume and expression of NF-kappaB in brains of rats with middle cerebral artery occlusion.169 SD rats were randomly divided into five groups: normal group, sham group, model group, cyclophosphamide group and Shenxiong Pill group. MCAO rat models were established by string ligation (for model, cyclophosphamide-treated and Shenxiong-treated groups). Rats in the Shenxiong Pill group was further randomly divided into sub-groups, receiving a range of high dose treatment (5 to 20 times of clinical dosage). Brains of the rats were examined 48 h or 72 h after interventions in a random order. Image processing software was used in the calculation of volume of cerebral infarction. Conventional HE staining was used for observation of brain tissue. Immunohistochemical method was used to determine NF-kappaB expression.Compared with the model group, rats treated with Shenxiong Pill and cyclophosphamide had lower infarct brain volumes (P0.05). NF-kappaB positive inflammatory cells were not found in the normal and sham groups. But the MCAO model rats had increased numbers of NF-kappaB positive inflammatory cells and higher integral optical density of NF-kappaB over time. Compared with the model group, lower numbers and expression of NF-kappaB positive inflammatory cells were found in those treated with Shenxiong Pill (P0. 05). Higher dosage of Shenxiong was associated with lower numbers and expression of NF-gB inflammatory cells (P0. 05).Shenxiong Pill can reduce pathological damage to brains as a result of cerebral ischemia, possibly through inhibiting the expression and activation of NF-kappaB.

Published

2014

49. Variables, kinetics and mechanisms of heterogeneous reburning

Author

Wei-Yin Chen and Lin Tang

Subjects

Flue gas, Environmental Engineering, Waste management, business.industry, Chemistry, Reducing agent, General Chemical Engineering, Decomposition, chemistry.chemical_compound, Adsorption, Chemical engineering, Natural gas, Nitrogen oxide, Char, business, Staged combustion, Biotechnology

Abstract

The variables, kinetics, and mechanisms of heterogeneous reburning were studied in a flow reactor with a simulated flue gas. The efficiency of heterogeneous reburning depends on the origin of the char, char preparation history and the presence of oxidants, CO2 and O2, and the reducing agent CO, in reburning. Estimated intrinsic rate constants for surface NO reduction in various gaseous environments were compared with those published. In addition to its large surface area, the effectiveness of lignite char appears to be due to its ability to promote two consecutive reactions: (1) the gasification of char by CO2 and O2 for production of CO; (2) the removal of surface oxygen complexes, including those formed after adsorption of NO, by gaseous CO, for the regeneration of reactive sites. Moreover, lignite ash also catalyzes the decomposition of HCN, a major intermediate of NO conversion during gas reburning. These observations suggest that reburning by a mixed fuel containing natural gas and lignite char can be a potentially attractive route for the in–furnance control of nitrogen oxide.

Published

2001

50. Stochastic modeling of controlled-drug release

Author

Xueyu Chen, L.T. Fan, Ahmed H. Hikal, Wei-Yin Chen, and B.C. Shen

Subjects

education.field_of_study, Environmental Engineering, Chemistry, Population, Biomedical Engineering, Pellets, Bioengineering, Standard deviation, Microsphere, Master equation, Drug release, Oral route, education, Biological system, Random variable, Biotechnology

Abstract

A drug release process by the oral route is random in nature and thus is subject to constant fluctuations. Moreover, individuals have varied tolerances to such fluctuations. The objective of this work is to characterize these fluctuations by a stochastic formalism. The system under consideration, i.e., the gastrointestinal tract consists of four consecutive compartments, i.e., stomach, duodenum, jejunum, and ileum. The master equation of the system as well as the governing equations for the means, variances, and covariances of the random variables, each representing the number of microspheres in an individual compartment, have been derived through the probabilistic population balance. These equations have been numerically solved to predict the total release fraction of drug and its internal fluctuations, and the dynamic statistics (means, variances, and covariances) of the amount of drug in each compartment at any time after administration. The dissolution-intensity functions in the model have been recovered from the available in vitro dissolution data from controlled-release pellets of isosorbide-5-nitrate (IS-5-N) by assuming that the rate of release is of the first order. The residence times and transition-intensity functions of drug in the individual compartments have been estimated from the available data generated by the gamma scintigraphies of IS-5-N pellets labeled by 111 In . Based on these parameters, the total numbers of dissolved drug microspheres and their fluctuations at any instance have been calculated. The model is in accord with the existing in vivo dissolution data of the same drug independently obtained through plasma analysis. More important, the model predicts that fluctuations in terms of the standard deviations of the numbers of particles in the duodenum, jejunum, and ileum can be of the same orders of magnitude as the corresponding mean numbers when 100 microspheres are simultaneously administered orally; in practice, such fluctuations characterized by these deviations could result in an undesirable release profile. Discussion is given of the potential direct clinical application of the results obtained as well as the plausible indirect application of these results and the model derived to the analyses of chemical and biochemical reactors.

Published

1998