【SCI/EI会议推荐】第四届能源、环境与材料科学国际学术会议EEMS2018

时间：2018年6月22-24日

地点：新加坡南洋理工大学

ANPO教授，于日本大阪府立大学工作了40年，曾担任研究生工程学院院长 (工程学院)，副总裁兼执行董事，植物工厂研发中心主任，以及10年的总裁顾问等。目前在中国福州大学的能源和环境光催化国家重点实验室担任国际顾问。他是研究固体表面光化学反应的先锋，包括催化剂的研究，并于1988年在Asakura-shoten出版了这一领域的第一本书“Photocatalysis”。1989年，于Elsevier出版了一本名为“Photochemistry on Solid Surfaces” 的英文书。到今天，他已经出版了110多本英文科学书籍。Anpo博士发表的原始论文超过530篇，被引用次数超过32500次。他的梦想是建立“太阳能化学”，作为一种新型的环境友好型科技。他还对人工光合作用(光催化)和自然光合作用的杂交特别感兴趣，致力于光响应型TiO2 薄膜光催化剂与人造光型（LED）植物工厂中绿色植物的自然光合作用的杂交, 使含有生物量的水高效产生 H2 , 并通过太阳能的有效利用快速生产清洁、安全的蔬菜。

Research Progress at the “Research Institute of Photocatalysis”,

Fuzhou University and Current Development of Visible Light-responsible

Graphic Carbon Nitride and Hexagonal Boron Carbon Nitride Photocatalysts

Energy depletion and environmental pollution on a global scale are the most serious and urgent issues facing mankind in recent times. It is vital to design novel energy production and conversion systems that utilize natural energy and allow sustainable development without environmental destruction or pollution. The splitting of H2O to produce H2 as well as the related reactions using visible light-responsive photocatalysts under sunlight irradiation has been intensively investigated to address these issues. In the past half century, research on various photocatalytic systems using metal oxides have been carried out.1)  However, to achieve higher efficiency in the production of H2 from H2O, more innovative breakthroughs in the development of new types of photocatalytic materials have been strongly desired.2)

To address such issues, graphitic carbon nitride (g-C3N4) and hexagonal boron carbon nitride (BCN) nanomaterials have been investigated in our laboratory as promising visible light-responsive photocatalytic materials.2,3) In this presentation, we will introduce research progress at the research institute of photocatalysis and current development of g-C3N42,4-6) and BCN7,8) photocatalytic nanomaterials, focusing on their design, construction and optimization as well as their applications to environmentally-benign solar energy conversion systems for the decomposition of H2O and organic redox reactions. Such visible light-responsive photocatalytic materials can be considered the most important research for the development of safe and clean energy production technologies for the 21st Century and beyond.

题目： Experimental and Numerical Study on the Tee Resistance Reduction in Ventilation and Air Conditioning

摘要：

Energy consumption due to duct resistance (fan energy consumption) accounts for approximately 30–50% of the total energy consumption in central air conditioning systems. The duct resistance can be reduced by optimizing the form of local ventilation components and air conditioning ducts, which are of important engineering significance for improving the utilization and conservation of energy.Three resistance reduction methods of dividing flow tees in a ventilation and air-conditioning duct is studied. A reasonable position for installing the guide vane is proposed. The form of the guide vane and the cambered surface are optimized.The resistance characteristics of the tee are analyzed. The implementation effect of optimizing a tee is verified through a full-scale experiment.The results show that the resistance reduction rate of the proposed guide vane is 18.3% to 65.1% under different resistance reduction methods.The calculated results are verified by a full-scale experiment and by previous studies, ensuring the accuracy of the present study.

题目： Title: Preparation of rare earth element modified magnetic biochars for efficient antimony (V) removal

摘要：

It is important to remove antimony from aqueous solution due to its potential toxicity and carcinogenicity towards humans [1]. Compare to Sb(III), Sb(V) is more mobile with the main species of Sb(OH)6- over a wide pH range [2]. Biochar has exhibited a great potential to adsorb Sb(V) due to its low cost. However, raw biochars may have limited ability to adsorb Sb(V) of high concentrations and is difficult to separate from solution [3]. In this work, rare earth element modified magnetic biochars were prepared by co-precipitating two common rare earth elements, Ce(III)/La(III), with Fe(II/III) and biochars. The physicochemical properties, Sb(V) adsorption performance and possible mechanisms of the modified (CeFe-BC, LaFe-BC and Fe-BC) and unmodified biochars (BC) were systematically evaluated. After modification with rare earth elements, the maximum Sb(V) adsorption capacities of CeFe-BC and LaFe-BC were 3.8 and 3.2 times higher compared to Fe-BC, and 10.0 and 8.4 times higher than BC. The TEM, XRD, FTIR, and XPS analyses confirmed that Ce and La elements were successfully loaded onto the biochars’ surfaces and were the main contribution for Sb(V) adsorption. Although the magnetic property of Fe-BC was decreased after modified with Ce and La, it is still high for separation. All the results suggested that Ce/LaFe-BC can serve as a promising adsorbent for aqueous Sb(V) removal.

1.EI论文集征稿：
EEMS 2018会议的论文将被IOP Conference Series: Earth and Environmental Science (EES)(Online ISSN: 1755-1315   Print ISSN: 1755-1307)出版，出版后提交EI检索。目前该期刊 EI 检索非常稳定。

2. SCI期刊征稿：      
【录满截止，欢迎投稿。只能通过邮箱投稿，并且投稿的时候务必备注SCI】 
（1）推荐10篇： Applied Ecology and Environmental Research(ISSN 1785 0037 (Online), ISSN 1589 1623 (Print)), IF=0.681

（2）推荐5篇：Acta Scientiarum Polonorum-Hortorum Cultus(ISSN: 1644-0692), IF= 0.523

EEMS 2017

2017年7月28-30日

新加坡

EEMS 2016

2016年7月29-31日

新加坡