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Application of Argon Plasma Jet for Methane Hydrate Decomposition by Radio Frequency Irradiation

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@article{IJASEIT2638,
   author = {Ismail Rahim and Shinfuku Nomura and Shinobu Mukasa and Hiromichi Toyota and Muhammad Agung and Novriany Amaliyah},
   title = {Application of Argon Plasma Jet  for Methane Hydrate Decomposition by Radio Frequency Irradiation},
   journal = {International Journal on Advanced Science, Engineering and Information Technology},
   volume = {7},
   number = {6},
   year = {2017},
   pages = {2092--2099},
   keywords = {argon plasma jet; methane hydrate; hydrogen production; radio frequency; emission spectroscopy.},
   abstract = {

In this study, decomposition of methane hydrate using argon plasma jet was investigated in the pressure range of 0.1MPa to 2.0MPa. The plasma was successfully generated under high-pressure condition, which is difficult to achieve when using radio frequency (RF) plasma in liquid method. Using emission spectrometer analysis, the excitation temperature is found to increase as the gas pressure increases, whereas, it decreases as the argon flow rate increases. During the process of plasma irradiation, the required basic reactions for methane hydrate decomposition i.e. methane hydrate dissociation (MHD), steam methane reforming (SMR), and methane cracking reaction (MCR) were not completely satisfied due to an insignificant amount of methane. The gas chromatograph analysis confirmed that the methane cracking reaction (MCR) was only occurred to generate hydrogen and the C(s), due to the absence of C2H2 and C2H4 as the byproducts. In comparison with the other basic reactions of methane hydrate decomposition, steam methane reforming reaction became dominant in converting methane into hydrogen. Although the hydrogen production efficiency is less than that of radio frequency plasma in liquid, the reduction of CO2 by the thermal decomposition of Teflon from CO making it possible to be considered as an advanced promising technique in the future.

},    issn = {2088-5334},    publisher = {INSIGHT - Indonesian Society for Knowledge and Human Development},    url = {http://ijaseit.insightsociety.org/index.php?option=com_content&view=article&id=9&Itemid=1&article_id=2638},    doi = {10.18517/ijaseit.7.6.2638} }

EndNote

%A Rahim, Ismail
%A Nomura, Shinfuku
%A Mukasa, Shinobu
%A Toyota, Hiromichi
%A Agung, Muhammad
%A Amaliyah, Novriany
%D 2017
%T Application of Argon Plasma Jet  for Methane Hydrate Decomposition by Radio Frequency Irradiation
%B 2017
%9 argon plasma jet; methane hydrate; hydrogen production; radio frequency; emission spectroscopy.
%! Application of Argon Plasma Jet  for Methane Hydrate Decomposition by Radio Frequency Irradiation
%K argon plasma jet; methane hydrate; hydrogen production; radio frequency; emission spectroscopy.
%X 

In this study, decomposition of methane hydrate using argon plasma jet was investigated in the pressure range of 0.1MPa to 2.0MPa. The plasma was successfully generated under high-pressure condition, which is difficult to achieve when using radio frequency (RF) plasma in liquid method. Using emission spectrometer analysis, the excitation temperature is found to increase as the gas pressure increases, whereas, it decreases as the argon flow rate increases. During the process of plasma irradiation, the required basic reactions for methane hydrate decomposition i.e. methane hydrate dissociation (MHD), steam methane reforming (SMR), and methane cracking reaction (MCR) were not completely satisfied due to an insignificant amount of methane. The gas chromatograph analysis confirmed that the methane cracking reaction (MCR) was only occurred to generate hydrogen and the C(s), due to the absence of C2H2 and C2H4 as the byproducts. In comparison with the other basic reactions of methane hydrate decomposition, steam methane reforming reaction became dominant in converting methane into hydrogen. Although the hydrogen production efficiency is less than that of radio frequency plasma in liquid, the reduction of CO2 by the thermal decomposition of Teflon from CO making it possible to be considered as an advanced promising technique in the future.

%U http://ijaseit.insightsociety.org/index.php?option=com_content&view=article&id=9&Itemid=1&article_id=2638 %R doi:10.18517/ijaseit.7.6.2638 %J International Journal on Advanced Science, Engineering and Information Technology %V 7 %N 6 %@ 2088-5334

IEEE

Ismail Rahim,Shinfuku Nomura,Shinobu Mukasa,Hiromichi Toyota,Muhammad Agung and Novriany Amaliyah,"Application of Argon Plasma Jet  for Methane Hydrate Decomposition by Radio Frequency Irradiation," International Journal on Advanced Science, Engineering and Information Technology, vol. 7, no. 6, pp. 2092-2099, 2017. [Online]. Available: http://dx.doi.org/10.18517/ijaseit.7.6.2638.

RefMan/ProCite (RIS)

TY  - JOUR
AU  - Rahim, Ismail
AU  - Nomura, Shinfuku
AU  - Mukasa, Shinobu
AU  - Toyota, Hiromichi
AU  - Agung, Muhammad
AU  - Amaliyah, Novriany
PY  - 2017
TI  - Application of Argon Plasma Jet  for Methane Hydrate Decomposition by Radio Frequency Irradiation
JF  - International Journal on Advanced Science, Engineering and Information Technology; Vol. 7 (2017) No. 6
Y2  - 2017
SP  - 2092
EP  - 2099
SN  - 2088-5334
PB  - INSIGHT - Indonesian Society for Knowledge and Human Development
KW  - argon plasma jet; methane hydrate; hydrogen production; radio frequency; emission spectroscopy.
N2  - 

In this study, decomposition of methane hydrate using argon plasma jet was investigated in the pressure range of 0.1MPa to 2.0MPa. The plasma was successfully generated under high-pressure condition, which is difficult to achieve when using radio frequency (RF) plasma in liquid method. Using emission spectrometer analysis, the excitation temperature is found to increase as the gas pressure increases, whereas, it decreases as the argon flow rate increases. During the process of plasma irradiation, the required basic reactions for methane hydrate decomposition i.e. methane hydrate dissociation (MHD), steam methane reforming (SMR), and methane cracking reaction (MCR) were not completely satisfied due to an insignificant amount of methane. The gas chromatograph analysis confirmed that the methane cracking reaction (MCR) was only occurred to generate hydrogen and the C(s), due to the absence of C2H2 and C2H4 as the byproducts. In comparison with the other basic reactions of methane hydrate decomposition, steam methane reforming reaction became dominant in converting methane into hydrogen. Although the hydrogen production efficiency is less than that of radio frequency plasma in liquid, the reduction of CO2 by the thermal decomposition of Teflon from CO making it possible to be considered as an advanced promising technique in the future.

UR - http://ijaseit.insightsociety.org/index.php?option=com_content&view=article&id=9&Itemid=1&article_id=2638 DO - 10.18517/ijaseit.7.6.2638

RefWorks

RT Journal Article
ID 2638
A1 Rahim, Ismail
A1 Nomura, Shinfuku
A1 Mukasa, Shinobu
A1 Toyota, Hiromichi
A1 Agung, Muhammad
A1 Amaliyah, Novriany
T1 Application of Argon Plasma Jet  for Methane Hydrate Decomposition by Radio Frequency Irradiation
JF International Journal on Advanced Science, Engineering and Information Technology
VO 7
IS 6
YR 2017
SP 2092
OP 2099
SN 2088-5334
PB INSIGHT - Indonesian Society for Knowledge and Human Development
K1 argon plasma jet; methane hydrate; hydrogen production; radio frequency; emission spectroscopy.
AB 

In this study, decomposition of methane hydrate using argon plasma jet was investigated in the pressure range of 0.1MPa to 2.0MPa. The plasma was successfully generated under high-pressure condition, which is difficult to achieve when using radio frequency (RF) plasma in liquid method. Using emission spectrometer analysis, the excitation temperature is found to increase as the gas pressure increases, whereas, it decreases as the argon flow rate increases. During the process of plasma irradiation, the required basic reactions for methane hydrate decomposition i.e. methane hydrate dissociation (MHD), steam methane reforming (SMR), and methane cracking reaction (MCR) were not completely satisfied due to an insignificant amount of methane. The gas chromatograph analysis confirmed that the methane cracking reaction (MCR) was only occurred to generate hydrogen and the C(s), due to the absence of C2H2 and C2H4 as the byproducts. In comparison with the other basic reactions of methane hydrate decomposition, steam methane reforming reaction became dominant in converting methane into hydrogen. Although the hydrogen production efficiency is less than that of radio frequency plasma in liquid, the reduction of CO2 by the thermal decomposition of Teflon from CO making it possible to be considered as an advanced promising technique in the future.

LK http://ijaseit.insightsociety.org/index.php?option=com_content&view=article&id=9&Itemid=1&article_id=2638 DO - 10.18517/ijaseit.7.6.2638