Volume 3, Issue 2 (Suppl)

Ind Chem

ISSN: 2469-9764, ICO an open access journa

Industrial Chemistry 2017

May 22-23, 2017

Page 45

Notes:

conference

series

.com

May 22-23, 2017 Las Vegas, USA

2

nd

World Conference on

Industrial Chemistry and Water Treatment

Crystalline/amorphous low energy bandgapTiO

2

materials prepared in solution and their industrial

applications

R

ecently, surface-disordered TiO

2

, referred to as black TiO

2

, which can absorb both visible and near-infrared solar light

that has triggered an explosion of interest in many important applications. Here, we demonstrate a selective reduction

of commercialized degussa P-25 TiO

2

nanoparticles using simple room-temperature solution processing, which maintains

the unique three-phase interfaces composed of ordered white-anatase and disordered black-rutile with open structures for

easy electrolyte access. The strong reducing agent in superbase, which consists of lithium ion ethylenediamine (Li-EDA), can

disorder only the white-rutile phase of P-25. Single P-25 TiO

2

nanoparticles with this engineered surface made immediate

contact with the electrolyte. This contact is called white-black-electrolyte three-phase interfaces and can not only efficiently

internally separate electrons/holes through type-II bandgap alignment but also induce a strong hydrogen (H

2

) evolution surface

reaction. The white-black-electrolyte three-phase interfaces exhibited outstanding H

2

production rates of 13.89 mmol/h/g

using 0.5 wt.% Pt (co-catalyst) and 3.46 mmol/h/g without using any co-catalyst. These values are the highest recorded in the

world to date. In addition, our newly developed crystalline/amorphous reduced TiO

2

(rTiO

2

) that has low energy bandgap can

effectively generate reactive oxygen species (ROS) under solar light and successfully remove a bloom of algae. Only reduced

TiO

2

materials can generate ROS under solar light, which was confirmed by electron spin resonance. Among the three different

types of Li-EDA treated TiO

2

(anatase, rutile and both phased TiO

2

), the both phased rTiO

2

showed the best performance to

produce ROS. The generated ROS effectively removed the common green algae

Chlamydomonas

. This is the first report on

algae degradation under solar light, proving the feasibility of commercially available products for disinfection. Finally, we like

to introduce transition metal chalcogenide materials for the hydrogen evolution reaction and energy storage with graphene

flakes.

Biography

Hyoyoung Lee has received his PhD degree at Department of Chemistry, University of Mississippi (USA) in 1997. He did his Post-doctorate at North Carolina

State University, USA, for 2 years. He has worked at Electronics and Telecommunications Research Institute from 2000 to 2009 as a Team Leader. He moved to

Sungkyunkwan University and has served as a Full Professor at Departmet of Chemistry, lecturing Organic Chemistry. He has served as a Director of National Cre-

ative Research Initiatives (NCRI), Center of Smart Molecular Memory from 2006 to 2015. Currently, he has serving as an Associate Director of Centre for Integrated

Nanostructure Physics (CINAP), Institute of Basic Science (IBS) from November 2015. His current research area is on organic semiconducting materials including

low bandgap TiO

2

and devices including molecular/organic memory, OLED, OTFT, sensors, Energy harvesting and storage, graphene oxide, reduced graphene

oxide and 2D transition metal chalcogenide (TMC). He has written more than 120 journal articles with top-tier journals.

hyoyoung@skku.edu

Hyoyoung Lee

Sungkyunkwan University, South Korea

Hyoyoung Lee, Ind Chem 2017, 3:2 (Suppl)

http://dx.doi.org/10.4172/2469-9764-C1-004