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Comparison of the LCOP distributions for HDPE <span class="search-highlight">production</span> ( He <em>et al</em>...
Published: March 2023
FIG. 1.6 Comparison of the LCOP distributions for HDPE production ( He et al., 2018 ). (AP region: M = 0 , N † = 30 , N + = 500 , N Θ = 15 000 ; GC region: M = 0 , N † = 116 , N + = 500 , N Θ = 58 000 ). More about this image found in Comparison of the LCOP distributions for HDPE production ( He et al...
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Comparison of the GWP distributions for the HDPE <span class="search-highlight">production</span> ( He <em>et</em>...
Published: March 2023
FIG. 1.7 Comparison of the GWP distributions for the HDPE production ( He et al., 2018 ). (AP region: M = 0 , N † = 30 , N + = 500 , N Θ = 15 000 ; GC region: M = 0 , N † = 116 , N + = 500 , N Θ = 58 000 ). More about this image found in Comparison of the GWP distributions for the HDPE production ( He et...
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Views about knowledge-<span class="search-highlight">production</span> are affected by both domain (Mathematics a...
Published: March 2023
FIG. 11.1 Views about knowledge-production are affected by both domain (Mathematics and Physics), and time of immersion in a field (below or above 8 years) from Sperandeo-Mineo (2012) . More about this image found in Views about knowledge-production are affected by both domain (Mathematics a...
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Dual-Range Force Sensor (left picture) (see:  https://www.vernier.com/produ...
Published: March 2023
FIG. 6.3 Dual-Range Force Sensor (left picture) (see: https://www.vernier.com/product/dual-range-force-sensor/ ) and Go Direct Force and Acceleration Sensor (right picture) [available at https://www.vernier.com/product/go-direct-force-and-acceleration-sensor/ ). More about this image found in Dual-Range Force Sensor (left picture) (see: https://www.vernier.com/produ...
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Characterization life cycle impacts comparison between TEG and [EMIM][Tf...
Published: March 2023
FIG. 3.13 Characterization life cycle impacts comparison between TEG and [EMIM][Tf2N]. (a) TEG and [EMIM][Tf2N] production stage (functional unit: production of 1 kg TEG and [EMIM][Tf2N]); (b) the NG dehydration process including the dehydrant production and use stages (functional unit: removal of 1 g water vapor); (c) use stage in NG dehydration process (functional unit: removal of 1 g water vapor). Reprinted with permission from Wu et al., ACS Sustain. Chem. Eng. 7 (23), 19194–19201 (2019). Copyright 2019 American Chemical Society. More about this image found in Characterization life cycle impacts comparison between TEG and [EMIM][Tf...
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Characterization life cycle impacts comparison between TEG and [EMIM][Tf...
Published: March 2023
FIG. 3.13 Characterization life cycle impacts comparison between TEG and [EMIM][Tf2N]. (a) TEG and [EMIM][Tf2N] production stage (functional unit: production of 1 kg TEG and [EMIM][Tf2N]); (b) the NG dehydration process including the dehydrant production and use stages (functional unit: removal of 1 g water vapor); (c) use stage in NG dehydration process (functional unit: removal of 1 g water vapor). Reprinted with permission from Wu et al., ACS Sustain. Chem. Eng. 7 (23), 19194–19201 (2019). Copyright 2019 American Chemical Society. More about this image found in Characterization life cycle impacts comparison between TEG and [EMIM][Tf...
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(a) Predicted melt-grown β-Ga<sub>2</sub>O<sub>3</sub> substrate <span class="search-highlight">production</span>...
Published: February 2023
FIG. 1.9 (a) Predicted melt-grown β-Ga2O3 substrate production cost compared to SiC ( Reese et al., 2019 ), and β-Ga2O3 substrate growth by (b) EFG ( Kuramata et al., 2016 ) and (c) CZ ( Ahmadi and Oshima, 2019 ). More about this image found in (a) Predicted melt-grown β-Ga2O3 substrate production...
Book Chapter
Series: AIPP Books, Methods
Published: March 2023
EISBN: 978-0-7354-2574-3
ISBN: 978-0-7354-2572-9
...References References Chen , B. , Liao , Z. , Wang , J. , Yu , H. , and Yang , Y. , “ Exergy analysis of hydrogen production by steam reforming of hydrocarbons and its carbon emission evaluation ,” Shiyou Xuebao, Shiyou Jiagong/Acta Pet Sin (Petroleum Process Sect.)   28...
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Influence of the volume flow rate <em>V</em><sub>IL</sub> (a) and t...
Published: March 2023
FIG. 3.10 Influence of the volume flow rate VIL (a) and the water content (mass fraction) w H 2 O , IL in the inlet IL (b) on the water content (mole fraction) y1 in the outlet gas product. Reprinted with permission from Yu et al., Energy Fuels 31 (2), 1429–1439 (2017). Copyright 2017 American Chemical Society. More about this image found in Influence of the volume flow rate VIL (a) and t...
Book Chapter
Series: AIPP Books, Methods
Published: March 2023
10.1063/9780735425743_001
EISBN: 978-0-7354-2574-3
ISBN: 978-0-7354-2572-9
... that technological advancements including the combined application of hydraulic fracturing and horizontal drilling have recently led to a shale revolution that stimulated tremendous production of shale gas worldwide ( Gao and You, 2017 ). According to the assessment of the Energy Information Administration...
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Influence of mass flow rate <em>m</em><sub>IL</sub>, a number of th...
Published: March 2023
FIG. 3.12 Influence of mass flow rate mIL, a number of theoretical stages Nt (a), absorber temperature T1 (b), flash drum temperature T2 (c), and flash drum pressure P2 (d) on the water content y1 in the gas product. Reprinted with permission from Yu et al., Energy Fuels 31 (2), 1429–1439 (2017). Copyright 2017 American Chemical Society. More about this image found in Influence of mass flow rate mIL, a number of th...
Book Chapter
Series: AIPP Books, Methods
Published: March 2023
10.1063/9780735425743_frontmatter
EISBN: 978-0-7354-2574-3
ISBN: 978-0-7354-2572-9
... of technical challenges by using state-of-the-art systematic methods. It covers a broad range of energy topics, including traditional fossil fuels, renewable energy, clean energy production and storage, emerging non-traditional energy sources such as oil sands, shale gas, and natural gas hydrates, and energy...