Multiscale Modeling, Design, and Efficiency Analysis of High-Pressure Hydrogen Water-Splitting System

In recent years, we have experienced extreme climate changes due to the global warming, continuously impacting and changing our daily lives. To build a sustainable environment and society, various energy technologies have been developed and introduced. Among them, energy harvesting, converting ambient environmental energy into electrical energy, has emerged as one of the promising technologies for a variety of energy applications. In particular, a photo (electro) catalytic water splitting system, coupled with emerging energy harvesting technology, has demonstrated high device performance, demonstrating its great social impact for the development of the new water splitting system. In this review article, we introduce and discuss in detail the emerging energy-harvesting technology for photo (electro) catalytic water splitting applications. The article includes fundamentals of photocatalytic and electrocatalytic water splitting and water splitting applications coupled with the emerging energy-harvesting technologies using piezoelectric, piezo-phototronic, pyroelectric, triboelectric, and photovoltaic effects. We comprehensively deal with different mechanisms in water splitting processes with respect to the energy harvesting processes and their effect on the water splitting systems. Lastly, new opportunities in energy harvesting-assisted water splitting are introduced together with future research directions that need to be investigated for further development of new types of water splitting systems.

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Improved Endurance of HfO2-Based Metal- Ferroelectric-Insulator-Silicon Structure by High-Pressure Hydrogen Annealing

IEEE Electron Device Letters ◽

10.1109/led.2019.2914700 ◽

2019 ◽

Vol 40 (7) ◽

pp. 1092-1095 ◽

Cited By ~ 8

Author(s):

Seungyeol Oh ◽

Jeonghwan Song ◽

In Kyeong Yoo ◽

Hyunsang Hwang

Keyword(s):

High Pressure ◽

Silicon Structure ◽

Hydrogen Annealing ◽

Pressure Hydrogen

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Application of the modified Dubinin-Astakhov equation for a better understanding of high-pressure hydrogen adsorption on activated carbons

International Journal of Hydrogen Energy ◽

10.1016/j.ijhydene.2019.09.240 ◽

2020 ◽

Vol 45 (48) ◽

pp. 25912-25926 ◽

Cited By ~ 4

Author(s):

G. Sdanghi ◽

S. Schaefer ◽

G. Maranzana ◽

A. Celzard ◽

V. Fierro

Keyword(s):

High Pressure ◽

Hydrogen Adsorption ◽

Activated Carbons ◽

Pressure Hydrogen

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Effect of High Pressure Gaseous Hydrogen on the Tensile Properties of Four Types of Stainless Steels: Investigation of Materials Properties in High Pressure Gaseous Hydrogen—1

Volume 6: Materials and Fabrication ◽

10.1115/pvp2007-26462 ◽

2007 ◽

Cited By ~ 1

Author(s):

Hideki Nakagawa

Keyword(s):

High Pressure ◽

Stainless Steel ◽

Hydrogen Embrittlement ◽

Storage System ◽

Gaseous Hydrogen ◽

Fuel Cell Vehicle ◽

Ductility Loss ◽

Hydrogen Storage System ◽

Type 316L ◽

Pressure Hydrogen

Practical application of fuel cell vehicle has started in the world, and high-pressure hydrogen tanks are currently considered to be the mainstream hydrogen storage system for commercially implemented fuel cell vehicle. Application of metallic materials to the components of high-pressure hydrogen storage system: hydrogen tanks, valves, measuring instructions and so on, have been discussed. In this work, tensile properties of four types of stainless steels were evaluated in 45MPa (6527psig) and 75MPa (10878psig) high-pressure gaseous hydrogen at a slow strain rate of 3×10−6 s−1 at ambient temperature. Type 316L (UNS S31603) stainless steel hardly showed ductility loss in gaseous hydrogen, since it had stable austenitic structure. On the other hand, Type 304 (UNS S30400) metastable austenitic stainless steel showed remarkable ductility loss in gaseous hydrogen, which was caused by the hydrogen embrittlement of strain induced martensitic phase. Likewise, Type 205 (UNS S20500) nitrogen-strengthened austenitic stainless steel showed remarkable ductility loss in gaseous hydrogen, though it had stable austenitic structure in the same manner as Type 316L. The ductility loss of Type 205 was due to the hydrogen embrittlement of austenitic phase resulting from the formation of planar dislocation array. Furthermore, Type 329J4L (UNS S31260) duplex stainless steel showed extreme ductility loss in gaseous hydrogen, which was caused by the hydrogen embrittlement of ferritic phase.

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Proposal of Design Method Enabling Cr-Mo Steels to be Used in High-Pressure Hydrogen Gas Environment

Hyomen Kagaku ◽

10.1380/jsssj.36.562 ◽

2015 ◽

Vol 36 (11) ◽

pp. 562-567

Author(s):

Hisao MATSUNAGA ◽

Junichiro YAMABE ◽

Saburo MATSUOKA

Keyword(s):

High Pressure ◽

Design Method ◽

Hydrogen Gas ◽

Gas Environment ◽

Pressure Hydrogen

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Crack Growth Analysis of High-Pressure Equipment for Hydrogen Storage

Volume 1B: Codes and Standards ◽

10.1115/pvp2013-97272 ◽

2013 ◽

Author(s):

Z. Y. Li ◽

C. L. Zhou ◽

Y. Z. Zhao ◽

Z. L. Hua ◽

L. Zhang ◽

...

Keyword(s):

High Pressure ◽

Hydrogen Storage ◽

Crack Growth ◽

Growth Analysis ◽

Model Material ◽

Hydrogen Gas ◽

Cycle Life ◽

Cold Worked ◽

Type 304 ◽

Pressure Hydrogen

Crack growth analysis (CGA) was applied to estimate the cycle life of the high-pressure hydrogen equipment constructed by the practical materials of 4340 (two heats), 4137, 4130X, A286, type 316 (solution-annealed (SA) and cold-worked (CW)), and type 304 (SA and CW) in 45, 85 and 105 MPa hydrogen and air. The wall thickness was calculated following five regulations of the High Pressure Gas Safety Institute of Japan (KHK) designated equipment rule, KHKS 0220, TSG R0002, JB4732, and ASME Sec. VIII, Div. 3. We also applied CGA for four typical model materials to discuss the effect of ultimate tensile strength (UTS), pressure and hydrogen sensitivity on the cycle life of the high-pressure hydrogen equipment. Leak before burst (LBB) was confirmed in all practical materials in hydrogen and air. The minimum KIC required for LBB of the model material with UTS of even 1500 MPa was 170 MPa·m0.5 in 105 MPa. Cycle life qualified 103 cycles for all practical materials in air. In 105 MPa hydrogen, the cycle life by KIH was much shorter than that in air for two heats of 4340 and 4137 sensitive to hydrogen gas embrittlement (HGE). The cycle life of type 304 (SA) sensitive to HGE was almost above 104 cycles in hydrogen, while the cycle life of type 316 (SA and CW) was not affected by hydrogen and that of A286 in hydrogen was near to that in air. It was discussed that the cycle life increased with decreasing pressure or UTS in hydrogen. This behavior was due to that KIH increased or fatigue crack growth (FCG) decreased with decreasing pressure or UTS. The cycle life data of the model materials under the conditions of the pressure, UTS, KIH, FCG and regulations in both hydrogen and air were proposed quantitatively for materials selection for high-pressure hydrogen storage.

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