共查询到20条相似文献,搜索用时 15 毫秒
1.
J. Zhang S. Yan L.P. Yu X.J. Zhou T. Zhou P. Peng 《International Journal of Hydrogen Energy》2018,43(48):21864-21873
Magnesium hydride (MgH2) is a promising on-board hydrogen storage material due to its high capacity, low cost and abundant Mg resources. Nevertheless, the practical application of MgH2 is hindered by its poor dehydrogenation ability and cycling stability. Herein, the influences and mechanisms of thin pristine magnesium oxide (MgO) and transition metals (TM) dissolved Mg(TM)O layers (TM = Ti, V, Nb, Fe, Co, Ni) on hydrogen desorption and reversible cycling properties of MgH2 were investigated using first-principles calculations method. The results demonstrate that either thin pristine MgO or Mg(TM)O layer weakens the MgH bond strength, leading to the decreased structural stability and hydrogen desorption energy of MgH2. Among them, the Mg(Nb)O layer exhibits the most pronounced destabilization effect on MgH2. Moreover, the Mg(Nb)O layer presents a long-acting confinement effect on MgH2 due to the stronger interfacial bonding strength of Mg(Nb)O/MgH2 and the lower brittleness of Mg(Nb)O itself. Further analyses of electronic structures indicate that these thin oxide layers coating on MgH2 surface reduce the bonding electron number of MgH2, which essentially accounts for the weakened MgH bond strength and enhanced hydrogen desorption properties of modified MgH2 systems. These findings provide a new avenue for enhancing the hydrogen desorption and reversible cycling properties of MgH2 by designing and adding suitable MgO based oxides with high catalytic activity and low brittleness. 相似文献
2.
The influence of various halide additives milled with magnesium hydride (MgH2) on its decomposition temperature was studied. The optimum amount of halide additive and milling conditions were evaluated. 相似文献
3.
《International Journal of Hydrogen Energy》2021,46(80):40203-40216
In this study, some transitional metal carbides (Ti3C2, Ni3C, Mo2C, Cr3C2 and NbC) were prepared to enhance the hydrogen storage behaviors of magnesium-based materials. The carbides with a weight ratio of 5 wt% were introduced into magnesium hydride (MgH2) by mechanical ball milling, and the microstructure, phase composition and hydrogen storage properties of the composites were studied in detail. The phase compositions of Ni3C, Mo2C, Cr3C2 and NbC in the ball-milled composites have not changed during hydrogen absorption and desorption cycles. However, Ti3C2 decompose into multivalent Ti during hydrogenation process. All of these metal carbides can enhance the hydrogen absorption and desorption kinetics of MgH2. Among them, Ti3C2 shows the best catalytic effect on dehydrogenation kinetic properties of MgH2, followed by the Ni3C, NbC, Mo2C and Cr3C2. 相似文献
4.
Guang-lin Xia Hai-yan LengNai-xin Xu Zhi-lin LiZhu Wu Jun-lin Du Xue-bin Yu 《International Journal of Hydrogen Energy》2011,36(12):7128-7135
Though LiBH4-MgH2 system exhibits an excellent hydrogen storage property, it still presents high decomposition temperature over 350 °C and sluggish hydrogen absorption/desorption kinetics. In order to improve the hydrogen storage properties, the influence of MoCl3 as an additive on the hydrogenation and dehydrogenation properties of LiBH4-MgH2 system is investigated. The reversible hydrogen storage performance is significantly improved, which leads to a capacity of about 7 wt.% hydrogen at 300 °C. XRD analysis reveals that the metallic Mo is formed by the reaction between LiBH4 and MoCl3, which is highly dispersed in the sample and results in improved dehydrogenation and hydrogenation performance of LiBH4-MgH2 system. From Kissinger plot, the activation energy for hydrogen desorption of LiBH4-MgH2 system with additive MoCl3 is estimated to be ∼43 kJ mol−1 H2, 10 kJ mol−1 lower than that for the pure LiBH4-MgH2 system indicating that the kinetics of LiBH4-MgH2 composite is significantly improved by the introduction of Mo. 相似文献
5.
6.
《International Journal of Hydrogen Energy》2022,47(15):9346-9356
Herein, a novel flower-like Ni MOF with good thermostability is introduced into MgH2 for the first time, and which demonstrates excellent catalytic activity on improving hydrogen storage performance of MgH2. The peak dehydrogenation temperature of MgH2-5 wt.% Ni MOF is 78 °C lower than that of pure MgH2. Besides, MgH2-5 wt.% Ni MOF shows faster de/hydrogenation kinetics, releasing 6.4 wt% hydrogen at 300 °C within 600 s and restoring about 5.7 wt% hydrogen at 150 °C after dehydrogenation. The apparent activation energy for de/hydrogenation reactions are calculated to be 107.8 and 42.8 kJ/mol H2 respectively, which are much lower than that of MgH2 doped with other MOFs. In addition, the catalytic mechanism of flower-like Ni MOF is investigated in depth, through XRD, XPS and TEM methods. The high catalytic activity of flower-like Ni MOF can be attributed to the combining effect of in-situ generated Mg2Ni/Mg2NiH4, MgO nanoparticles, amorphous C and remaining layered Ni MOF. This research extends the knowledge of elaborating efficient catalysts via MOFs in hydrogen storage materials. 相似文献
7.
P. Moretto C. Zlotea F. Dolci A. Amieiro J.-L. Bobet A. Borgschulte D. Chandra H. Enoki P. De Rango D. Fruchart J. Jepsen M. Latroche I. Llamas Jansa D. Moser S. Sartori S.M. Wang J.A. Zan 《International Journal of Hydrogen Energy》2013
A Round Robin Test exercise on magnesium hydride (MgH2) was performed by 14 laboratories with the aim to compare experimental isothermal data such PCI curves, kinetics curves and formation enthalpies together with a basic statistical evaluation of the results. 相似文献
8.
《International Journal of Hydrogen Energy》2022,47(6):3918-3926
MgH2 is considered as a promising hydrogen storage material for on-board applications. In order to improve hydrogen storage properties of MgH2, the amorphous TiMgVNi3-doped MgH2 is prepared by ball milling under hydrogen atmosphere. It is found that the catalytic (Ti,V)H2 and Mg2NiH4 nanoparticles are in situ formed after activation. As a result, the amorphous TiMgVNi3-doped MgH2 exhibits enhanced dehydrogenation kinetics (the activation energy for hydrogen desorption is 94.4 kJ mol?1 H2) and superior cycle durability (the capacity retention rate is up to 92% after 50 cycles). These results demonstrate that the in situ formation of highly dispersed catalytic nanoparticles from an amorphous phase is an effective pathway to enhance hydrogen storage properties of MgH2. 相似文献
9.
《International Journal of Hydrogen Energy》2021,46(66):33186-33196
Additive doping is one of the effective methods to overcome the shortcomings of MgH2 on the aspect of relatively high operating temperatures and slow desorption kinetics. In this paper, hollow g-C3N4 (TCN) tubes with a diameter of 2 μm are synthesized through the hydrothermal and high-temperature pyrolysis methods, and then nickel is chemically reduced onto TCN to form Ni/TCN composite at 278 K. Ni/TCN is then introduced into the MgH2/Mg system by means of hydriding combustion and ball milling. The MgH2–Ni/TCN composite starts to release hydrogen at 535 K, which is 116 K lower than the as-milled MgH2 (651 K). The MgH2–Ni/TCN composite absorbs 5.24 wt% H2 within 3500 s at 423 K, and takes up 3.56 wt% H2 within 3500 s, even at a temperature as low as 373 K. The apparent activation energy (Ea) of the MgH2 decreases from 161.1 to 82.6 kJ/mol by the addition of Ni/TCN. Moreover, the MgH2–Ni/TCN sample shows excellent cycle stability, with a dehydrogenation capacity retention rate of 98.0% after 10 cycles. The carbon material enhances sorption kinetics by dispersing and stabilizating MgH2. Otherwise, the phase transformation between Mg2NiH4 and Mg2NiH0.3 accelerates the re/dehydrogenation reaction of the composite. 相似文献
10.
《International Journal of Hydrogen Energy》2020,45(22):12408-12418
This study aims to better understand the Fe role in the hydrogen sorption kinetics of Mg–Fe composites. Mg-8 mol% Fe nanocomposites produced by high energy reactive milling (RM) for 10 h resulted in MgH2 mixed with free Fe and a low fraction of Mg2FeH6. Increasing milling time to 24 h allowed formation of a high fraction of Mg2FeH6 mixed with MgH2. The hydrogen absorption/desorption behavior of the nanocomposites reactive milled for 10 and 24 h was investigated by in-situ synchrotron X-ray diffraction, thermal analyses and kinetics measurements in Sieverts-type apparatus. It was found that both 10 and 24 h milled nanocomposites presents extremely fast hydrogen absorption/desorption kinetics in relatively mild conditions, i.e., 300–350 °C under 10 bar H2 for absorption and 0.13 bar H2 for desorption. Nanocomposites with MgH2, low Fe fraction and no Mg2FeH6 are suggested to be the most appropriate solution for hydrogen storage under the mild conditions studied. 相似文献
11.
R. Floriano S. Deledda B.C. Hauback D.R. Leiva W.J. Botta 《International Journal of Hydrogen Energy》2017,42(10):6810-6819
In this study, powder mixtures of MgH2 + 2 mol.% X, with X = Nb, Nb2O5, NbF5, Fe, Fe2O3, FeF3, were processed by mechanical milling at liquid nitrogen temperature (cryomilling). The effect of additives on crystalline structure, thermal properties and hydrogen storage properties of the mixtures were investigated. Morphological investigations indicated a heterogeneous particle size distribution of the powder mixtures and a fine dispersion of additive particles (FeF3) in the MgH2 matrix. High resolution synchrotron radiation X-ray diffraction (SR-XRD) data followed by Rietveld refinements showed a significant reduction on crystallite size for the samples containing fluorides (11 nm) in comparison with the pure MgH2 sample (29 nm). This was related to the mechanical behavior of fluorides during milling with MgH2, which act as a lubricant, dispersing and/or cracking agent during milling, and thus helping to further reduce MgH2 particle size. DSC analysis revealed that fluorides (NbF5, FeF3) are much more effective than oxides (Nb2O5, Fe2O3) and the transition metals (Nb and Fe), respectively, in reduction the desorption temperature. Furthermore, Nb2O5 is more efficient than Fe2O3. Finally, the best results for desorption kinetics were observed for the fluorides: NbF5 and FeF3 (equivalent effect and consistent to the DSC analysis) followed by the oxides: Nb2O5, Fe2O3 and Nb. The addition of Fe was not efficient in comparison with the pure cryomilled sample. 相似文献
12.
This work performs the simulation of hydrogen desorption processes with Mg2Ni hydrogen storage alloy to investigate the canister designs. Reaction rates and equilibrium pressures of Mg2Ni alloy were calculated by fitting experimental data in literature using least squares regression. The obtained reaction kinetics was used to model the thermalfluid behavior of hydrogen desorption. Since the alloy powders will expand and shrink during the absorption and desorption cycle, the canisters considered are comprised of expansion volume atop the metal bed. In order to enhance the heat transfer performance of the canister, an air pipe is equipped at the canister centre line with/without internal fins. Detailed equations that describe the force convection of the heat exchange pipe and the natural convection at the reactor wall are carefully incorporated in the model. Simulation results show that the bare cylindrical canister can not complete the desorption process in 2.8 h, while the canister equipped with the concentric heat exchanger pipe and fins can complete desorption within 1.7 h.Results also demonstrate that the reaction rates can be further increased by increasing the pipe flow velocity and/or increasing the fin volume. 相似文献
13.
Lithium amide and magnesium hydride are lightweight materials with high hydrogen-holding capacities and thus they are of interest for hydrogen storage. In the present work mixtures with initial molar compositions of (LiNH2 + MgH2) and (2LiNH2 + MgH2) were ball milled with and without the presence of 3.3 mol% potassium hydride dopant. Temperature programmed desorption, TPD, analyses of the mixtures showed that the potassium hydride doped samples had lower onset temperatures than their corresponding pristine samples. The dehydrogenation kinetics of the doped and pristine mixtures was compared at 210 °C. In each case a constant pressure thermodynamic driving force was applied in which the ratio of the plateau pressure to the applied hydrogen pressure was set at 10. Under equivalent conditions, the (LiNH2 + MgH2) mixture desorbed hydrogen about 4 times faster than the (2LiNH2 + MgH2) mixture. The addition of potassium hydride dopant was found to have a 25-fold increase on the desorption rates of the (2LiNH2 + MgH2) mixture, however it had almost no effect on the desorption rates of the (LiNH2 + MgH2) mixture. Activation energies were determined by the Kissinger method. Results showed the potassium hydride doped mixtures to have lower activation energies than the pristine mixtures. 相似文献
14.
《International Journal of Hydrogen Energy》2020,45(52):28183-28189
Mg hydride is a competitive candidates for hydrogen storage based on its high gravimetric hydrogen capacity and accessibility. In this study, a small amount of KOH and graphene were added into MgH2 by high energy ball milling. MgH2 doped with both KOH and graphene has a greatly improved hydrogen storage performance. The existence of graphene and the in-situ formed KMgH3 and MgO decreased activation energy of MgH2 to 109.89 ± 6.03 kJ/mol. The both KOH and graphene doped sample has a reversibly capacity of 5.43 wt % H2 and can released H2 as much as 6.36 times and 1.84 times faster than those of undoped sample and only KOH doped sample at 300 °C, respectively. The addition of graphene not only can provide more “H diffusion channels”, but also can disperse the catalyst. 相似文献
15.
Magnesium hydride MgH2 is an attractive hydrogen storage candidate due to its high reversible hydrogen mass capacity of 7.6 wt%, abundant resources of Mg and low cost. Unfortunately, its stubborn thermodynamic stability results in a high temperature of 573 K for hydrogen desorption, which is still far from the target for practical applications. In this article, we highlight the recent advances in stress/strain effects on the de/rehydrogenation thermodynamics of MgH2, which sheds a new light on tuning the thermodynamic properties of magnesium and other metal hydrides for hydrogen storage. 相似文献
16.
《International Journal of Hydrogen Energy》2019,44(55):29189-29195
The high dehydrogenation temperature of magnesium-based hydride (MgH2) is still a challenge as a potential hydrogen storage material in automobile applications. To improve the hydrogen desorption properties of MgH2; we selected TiFe0.8Mn0.2, graphite and Fe as additives. We prepared the Mg–graphite, Mg–TiFe0.8Mn0.2–Fe, Mg–TiFe0.8Mn0.2–graphite, Mg–Fe–graphite and Mg–TiFe0.8Mn0.2–Fe–graphite composites with high-energy ball milling under argon atmosphere. We investigated the effects of graphite and Fe addition to the desorption mechanism of TiFe0.8Mn0.2 using X-ray diffractometer (XRD), scanning electron microscope, differential scanning calorimeter and pressure-composition-temperature measurements using Sievert apparatus. We observed MgH2 in Mg–TiFe0.8Mn0.2–graphite, Mg–Fe–graphite and Mg–TiFe0.8Mn0.2–Fe–graphite with XRD analyses after hydrogenation at 200 °C under a hydrogen pressure of 2.5–2.6 MPa. As compared to pure milled MgH2 powder, we found that the dehydrogenation peak temperatures are decreased by 90, 160 and 165 °Cfor Mg–TiFe0.8Mn0.2–graphite, Mg–Fe–graphite, and Mg–TiFe0.8Mn0.2–Fe–graphite composites, respectively. The co-addition of TiFe0.8Mn0.2, graphite, and Fe exhibit the synergistic effects in improving the hydrogen desorption properties of MgH2. 相似文献
17.
Shun HiroiSou Hosokai Tomohiro Akiyama 《International Journal of Hydrogen Energy》2011,36(2):1442-1447
This paper describes the ultrasonic irradiation on the hydrolysis of magnesium hydride to enhance hydrogen generation; the effects of the ultrasonic frequency and the sample size on the hydrogen generation were mainly examined. In the experiments, three MgH2 particle and nanofiber samples were soaked in distilled water and ultrasonically irradiated at frequencies of 28, 45, and 100 kHz. Then, the amount of hydrogen generated was measured. We found that the low frequency of ultrasonic irradiation and the relatively small sample size accelerated the hydrolysis reaction MgH2 + 2H2O = Mg(OH)2 + 2H2 + 277 kJ. In particular, the MgH2 nanofibers exhibited the maximum hydrogen storage capacity of 14.4 mass% at room temperature at a frequency of 28 kHz (ultrasound irradiation). The results also experimentally validated that a combination of ultrasonic irradiation and MgH2 hydrolysis is considerably effective for efficiently generating hydrogen without heating and adding any agent. 相似文献
18.
The influence of different additives on the solid-state reaction of magnesium hydride (MgH2) with Si
The possibility of increasing the solid-state reaction rate of MgH2 with Si by modifying the mixture preparation method and adding chemical compounds or elements, such as niobium pentafluoride (NbF5), nano-titanium (IV) oxide (TiO2), nano-chromium (III) oxide Cr2O3, yttrium, and nano- and microsized nickel, was investigated. The results show that changing the milling parameters of the MgH2 and Si mixture in a planetary ball mill greatly affects the rate of direct reaction between them and allows the reaction to take place at temperatures as low as 200 °C with an equilibrium pressure over 1 bar. Moreover, all additives significantly enhanced the reaction speed. The reaction pathway was found to be different for decomposition in a hydrogen vacuum and pressures of several bars. Reactions of the powders investigated did not occur at temperatures below 150 °C. 相似文献
19.
Steven Barcelo Matthew RogersCostas P. Grigoropoulos Samuel S. Mao 《International Journal of Hydrogen Energy》2010
Hydrogen sorption property of magnesium (Mg) in the form of sandwiched Pd/Mg/Pd films is investigated. Pulsed laser deposition method was applied to deposit the samples consisting of films of nanoparticles. The enthalpy of formation of MgH2 was found to be −68 kJ/mol H2 for films with nanoparticle size on the order of 50 nm, which is smaller than the value for bulk MgH2 and may be explained by the concept of excess volume. 相似文献
20.
《International Journal of Hydrogen Energy》2023,48(56):21383-21394
Magnesium hydride (MgH2) is the most prominent carrier for storing hydrogen in solid-state mode. However, their slow kinetics and high thermodynamics become an obstacle in hydrogen storage. The present study elaborates on the catalytic effect of graphene (Gr) and vanadium disulfide (VS2) on MgH2 to enhance its hydrogen sorption kinetic. The temperature-programmed desorption study shows that the onset desorption temperature of MgH2 catalyzed by VS2 and MgH2 catalyzed by Gr is 289 °C and 300 °C, respectively. These desorption temperatures are 87 °C and 76 °C lower than the desorption temperature of pristine MgH2. The rapid rehydrogenation kinetics for the MgH2 catalyzed by VS2 have been found at a temperature of 300 °C under 15 atm H2 pressure by absorbing ∼4.04 wt% of hydrogen within 1 min, whereas the MgH2 catalyzed by Gr takes ∼3 min for absorbing the same amount of hydrogen under the similar temperature and pressure conditions. The faster release of hydrogen was also observed in MgH2 catalyzed by VS2 than MgH2 catalyzed by Gr and pristine MgH2. MgH2 catalyzed by VS2 releases ∼2.54 wt% of hydrogen within 10 min, while MgH2 catalyzed by Gr takes ∼30 min to release the same amount of hydrogen. Furthermore, MgH2 catalyzed by VS2 also persists in the excellent cyclic stability and reversibility up to 25 cycles. 相似文献