Steam reforming of formaldehyde on Cu (100) surface : a density functional study
As concerns about rising fossil fuel prices, energy security, and climate change increase, alternative source of energy can play a key role in producing local, clean, and inexhaustible energy. A more viable alternative source of energy would be the employment of hydrogen. However, hydrogen cannot...
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| Format: | Final Year Project |
| Language: | English |
| Published: |
2010
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| Online Access: | http://hdl.handle.net/10356/39613 |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | As concerns about rising fossil fuel prices, energy security, and climate change
increase, alternative source of energy can play a key role in producing local, clean, and
inexhaustible energy. A more viable alternative source of energy would be the employment
of hydrogen. However, hydrogen cannot be stored easily. This led to the investigation of
fuel cells that can produce hydrogen on board. Fuel cell, which is an electrochemical
energy conversion device, has become a more environmentally friendly and realistic
alternative to combustion engines. A hydrogen cell uses hydrogen as fuel and oxygen as
oxidant, producing water as product, which does not harm environment. However,
difficulties of transportation and danger of handling have been caused by hydrogen’s low
density and large volume. Therefore, liquid fuel is preferred over gas fuel as they are more
convenient and less dangerous to handle. Strong efforts have been made by researchers to
achieve an efficient in situ conversion of liquid fuel to hydrogen.
In this project, the main objective is to understand the reaction mechanism of
formaldehyde steam reforming reactions on Cu (100) surface. A typical process for this
purpose is methanol steam reforming (MSR) on Cu-based catalysts. On the catalyst, the
formation of CO2 is thought to be via the route of formaldehyde reacting with water related
species (i.e. OH and O) via a formate type intermediate on the Cu surface; instead of the
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decomposition of formaldehyde to CO followed by formation of CO2 via the water-gasshift
reaction. A detailed understanding of the mechanism of formaldehyde steam
reforming is necessary to provide indispensable guiding information for designing and
producing new, more efficient steam reforming catalyst. Thus in this current works, we
studied the kinetics and mechanism of formaldehyde steam reforming on the Cu (100)
surface. |
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