XLI2MGHN hydrides as hydrogen storage compounds

Information

  • Patent Grant
  • 8071064
  • Patent Number
    8,071,064
  • Date Filed
    Monday, October 19, 2009
    15 years ago
  • Date Issued
    Tuesday, December 6, 2011
    12 years ago
Abstract
State-of-the-art electronic structure calculations yield results consistent with the observed compound SiLi2Mg and provide likelihood of the availability of IrLi2Mg and RhLi2Mg. Similar calculations provide likelihood of the availability of YLi2MgHn, ZrLi2MgHn, NbLi2MgHn, MoLi2MgHn, TcLi2MgHn, RuLi2MgHn, RhLi2MgHn, LaLi2MgHn, Ce4+Li2MgHn, Ce3+Li2MgHn, PrLi2MgHn, NdLi2MgHn, PmLi2MgHn, SmLi2MgHn, EuLi2MgHn, GdLi2MgHn, TbLi2MgHn, DyLi2MgHn, HoLi2MgHn, ErLi2MgHn, TmLi2MgHn, YbLi2MgHn, LuLi2MgHn, HfLi2MgHn, TaLi2MgHn, ReLi2MgHn, OsLi2MgHn, and IrLi2MgHn (here n is an integer having a value in a particular compound of 4-7) as solid hydrides for the storage and release of hydrogen. Different hydrogen contents may be obtained in compounds having the same XLi2Mg crystal structures. These materials offer utility for hydrogen storage systems.
Description
TECHNICAL FIELD

This invention pertains to compounds useful for solid-state storage of hydrogen. More specifically, this invention pertains to a family of new hydride compounds, XLi2MgHn, where X may be Y, Zr, Nb, Mo, Tc, Ru, Rh, La, Ce, Pr, Nd, Pm, Sm, Eu, Gd, Tb, Dy, Ho, Er, Tm, Yb, Lu, Hf, Ta, W, Re, Os, and Ir, and n is an integer having a value of 4-7. The invention also pertains to RhLi2Mg and IrLi2Mg. These hydride compounds and two non-hydride analogs have utility for the storage of hydrogen.


BACKGROUND OF THE INVENTION

Considerable effort is currently being expended on the development of hydrogen and oxygen consuming fuel cells, and there is also interest in hydrogen burning engines. Such power systems require means for storage of hydrogen fuel which hold hydrogen in a safe form at ambient conditions and which are capable of quickly receiving and releasing hydrogen. In the case of automotive vehicles, fuel storage is required to be on-board the vehicle, and storage of hydrogen gas at high pressure is generally not preferred for such applications.


These requirements have led to the study and development of solid-state compounds for temporary storage of hydrogen, often as hydrides. For example, sodium alanate, NaAlH4, can be heated to release hydrogen gas, and a mixture of lithium amide, LiNH2, and lithium hydride, LiH, can be heated and reacted with the same effect. Despite such progress, however, no known solid-state system currently satisfies targets for on-board vehicular hydrogen storage.


SUMMARY OF THE INVENTION

This invention involves the use of state-of-the-art density functional theory to examine the possible formation of XLi2Mg materials and their hydrides with X being any of the elements Y, Zr, Nb, Mo, Tc, Ru, Rh, La, Ce, Pr, Nd, Pm, Sm, Eu, Gd, Tb, Dy, Ho, Er, Tm, Yb, Lu, Hf, Ta, W, Re, Os, and Ir (listed in order of increasing atomic number). These elements include certain 4d group elements, 5d group elements, and elements of the rare earth group. The results indicate that XLi2Mg compounds are thermodynamically stable with X═Rh and Ir and that previously unknown XLi2MgHn hydrides may form for all elements X considered with the exception of W.


This discovery provides a basis for hydrogen storage systems. In the example of rhodium and iridium, the combination of a non-hydrogen-containing base compound and its hydride, its hydrogen-containing analog, provides a basis for a rechargeable storage system. And with each selection of X, hydrogen may be released from the XLi2Mg hydride to one or more compounds of the base elements into which hydrogen may again be stored. Hydrogen is released from the hydride by application of heat or the like.


Computational methods in chemistry, coupled with advances in affordable computing power, are now able to compute, with reasonable precision, the electronic total energies of elements and compounds. In turn, these electronic total energies may be combined to derive the enthalpy of formation of compounds from their constituent elements. Hence the feasibility of forming previously-unknown compounds, such as those with potential for controlled uptake and release of hydrogen, may be investigated computationally.


The Vienna ab initio simulation package (VASP), a state-of-the-art method implementing density functional theory, was employed with projector-augmented wave potentials constructed using the generalized gradient approximation for the exchange-correlation energy functional. Given a crystal structure, VASP computes the electronic structure, including the total electronic energy Eel.


Three template structures, custom character1, custom character2 and custom character3 (custom character designating parent) were selected for the XLi2Mg compounds. custom character1 is described by the CuHg2Ti-type structure (fcc F 43m space group No. 216) with X, Li, and Mg atoms occupying the 4a, (4b, 4c), and 4d sites, respectively. custom character2 is the BiF3-type structure (fcc Fm 3m; No. 225) structure with X, Li, and Mg atoms on 4b, 8c, and 4a sites, respectively, and custom character3 is described by the primitive cubic space group P 43m (No. 215) with X, Li, and Mg atoms occupying 4e, (1b, 3c, 4e), and (1a, 3d) sites, respectively.


Eight XLi2MgHn templates custom characteri (custom character designating hydride) were constructed from two known hydride structures. Seven of these were derived from the disordered tetragonal (P4/mmm; No. 123) PdSr2LiH5 structure. Enthalpies of formation ΔH were obtained for each template structure from differences of electronic total energies:

ΔH(XLi2Mg)=Eel(XLi2Mg)−Eel(X)−2Eel(Li)−Eel(Mg)  (1)

for the parent compounds, and

ΔH(XLi2MgHn)=(2/n)[Eel(XLi2MgHn)−Eel(X)−2Eel(Li)−Eel(Mg)−(n/2)Eel(H2)]  (2)

for the hydrides, where n is the number of H atoms in a given configuration. Each ΔH, specified per XLi2Mg formula unit (f. u.) in Eq. (1) and per H2 molecule in Eq. (2), is the standard enthalpy of formation at zero temperature in the absence of zero point energy contributions. A negative ΔH indicates stability of the material relative to its elemental metal and molecular H2 constituents.


Thus, a group of new hydrides are provided as compounds capable of releasing hydrogen for a hydrogen-consuming device. These new compounds are XLi2MgHn, where X will typically be any one of the elements Y, Zr, Nb, Mo, Tc, Ru, Rh, La, Ce, Pr, Nd, Pm, Sm, Eu, Gd, Tb, Dy, Ho, Er, Tm, Yb, Lu, Hf, Ta, Re, Os, and Ir, and n is an integer having a value of 4-7. Moreover, two new non-hydride compounds, RhLi2Mg and IrLi2Mg have been predicted by the calculations.


In addition to demonstrating the credible likelihood of the formation of the above identified hydrides and non-hydrides by calculations, IrLi2Mg has been prepared and its crystal structure determined.


In preferred hydrogen storage systems, these new hydrides, typically stored as a body of particles, release their hydrogen upon heating to yield one or more solid de-hydrogenated compounds to which hydrogen may subsequently be restored. The original hydride may be restored by contacting the base compounds with hydrogen under suitable pressure and temperature conditions.


Other objects and advantages of the invention will be apparent from the following description of preferred embodiments.





BRIEF DESCRIPTION OF THE DRAWINGS


FIG. 1 shows proposed compound, IrLi2Mg, in the face-centered cubic F 43m structure corresponding to the custom character1 template.



FIG. 2 shows proposed compound, IrLi2Mg, in the primitive cubic P 43m structure corresponding to the custom character3 template.



FIG. 3 shows the proposed IrLi2MgH7 compound in the hexagonal P63/mmc structure corresponding to the custom character8 template.





DESCRIPTION OF PREFERRED EMBODIMENTS

State-of-the-art computational electronic structure methods implementing density functional theory (DFT) have been employed with substantial success to model hydride properties, including the crucial enthalpies of formation. That success encourages the development of strategies for harnessing these calculational tools to guide the discovery of novel hydrides. The approach in this case is to choose a related compound having a known crystal structure and calculate enthalpies of formation for isostructural, hypothetical compounds constructed by elemental replacement. In a further step, a parallel process is followed for a hypothetical hydride derived from the hypothetical compound through the addition of hydrogen to the original lattice.


The goal is to identify compounds which may take up and release hydrogen in a reversible manner. Thus in pursuing computational approaches using isostructural templates to guide the calculation, at least one template, for the compound itself, is required. This represents the simplest outcome and physically corresponds to a situation where the template structure of the compound is sufficiently open to accommodate hydrogen without distorting the structure. If this situation does not arise, then one template structure will be required for the compound and another for the hydride.


In practice of this invention it has been found that even this situation is inadequate to fully capture the complexities of the reaction. First, more than one compound template is desirable and these will be designated as custom character1, custom character2 and custom character3 and then eight template structures, designated as custom character1-custom character8, are utilized for the hydride. Details are provided in subsequent sections but it should be emphasized that the structural choices are not arbitrary but are guided and informed by the known behavior of either representative examples of the family of compounds or by knowledge of analogous compounds.


For the compounds, XLi2Mg, three template structures are considered, all cubic, with templates custom character1 and custom character2 being face-centered cubic and custom character3 being a primitive cubic. The choice of custom character1 and custom character2 is based on crystallographic information available for known XLi2Mg ternary compounds. Many of these structures are disordered but ordered compounds form in a limited number of cases. The disordered structures possess 4 Li and 4 Mg, or 4 X and 4 Mg atoms on an 8-fold site in the conventional cell of either the BiF3-type (Fm 3m; No. 225) or NaTl-type (Fd 3m; No. 227) space group. To circumvent the necessity of constructing large supercells which would significantly increase the computational demand, these structures were analyzed using four ordered analogous structures. These were constructed by enforcing the placement of either one Li and one Mg atom, or of one X and one Mg atom, on either of the two sites in the primitive cell.


These four ordered structures can all be described by the fcc F 43m space group (No. 216) with X, Li, and Mg atoms occupying the 4a, (4b, 4c), and 4d sites, respectively. This was chosen as template custom character1 whose structure is shown in FIG. 1, for the proposed compound IrLi2Mg.


Another representative ordered structure represented is the BiF3-type (Fm 3m; No. 225) with X, Li, and Mg atoms on 4b, 8c, and 4a sites, respectively. This structure was selected as the second parent template, custom character2, for the proposed compound IrLi2Mg.


To further explore the implications of the choice of the template structure, but mindful of the cubic symmetry of templates custom character1 and custom character2a third cubic structure P 43m (No. 215) was chosen as template custom character3. This structure, having X, Li, and Mg atoms on 4e, (1b, 3c, 4e), and (1a, 3d) sites, respectively, has been established experimentally here for IrLi2Mg; it has also been determined recently as the correct structure for SiLi2Mg. This structure was selected for the third parent template, custom character3, and is shown in FIG. 2.


There are multiple available sites in the custom character1 template structure for incorporation of hydrogen atoms. To identify a structural template for the hydride, preliminary computations were performed to assess the stability of hydrides based on the structure of AgLi2Mg. Various numbers of hydrogen atoms were inserted at various locations in the custom character1 lattice and the stability of the resulting hydrides AgLi2MgHn evaluated. The results indicated that stable hydrides would not form and thus that this structure is not a suitable template for the hydride.


Consideration was then given to structures of lower symmetry. Eight XLi2MgHn templates custom characteri (custom character designating hydride) were constructed from two known hydride structures having lower lattice symmetries. Seven of these were derived from the disordered tetragonal (P4/mmm; No. 123) PdSr2LiH5 structure and satisfied the cases when n, the number of hydrogen atoms, was 4, 5 or 6. For the case where the case of 7 hydrogen atoms the template structure was derived from the ordered hexagonal (P63/mmc; No. 194) RuMg2LiH7 structure.


To progress from the known PdSr2LiH5 to the desired XLi2MgHn structure the following atom substitutions are first made to transform the parent PdSr2Li atom placement into an atom placement for the desired parent XLi2Mg. X is substituted for Pd; Li is substituted for Sr; and Mg is substituted for Li. This locates X, Li, and Mg on the 1a, 2h, and 1b sites in P4/mmm, respectively. To progress from the known RuMg2Li atom placement to the desired XLi2Mg atom placement, X is substituted for Ru; Mg is substituted for Li; and Li is substituted for Mg.


In the hydride PdSr2LiH5 the H atoms occupy the 2e, 2g, and one of the 2f sites. Seven XLi2MgHn templates with n=4, 5, and 6 were generated by various fillings of these, with the eighth template based on RuMg2LiH7. The templates are:



custom character1-XLi2MgH4 with four H atoms on the 2e and 2f sites. The P4/mmm space group symmetry (of PdSr2LiH5) is preserved.



custom character2-XLi2MgH4 with four H atoms on the 2e and 2g sites. The P4/mmm space group symmetry (of PdSr2LiH5) is maintained.



custom character3-XLi2MgH4 with four H atoms on the 2f and 2g sites. The structure remains P4/mmm.



custom character4-XLi2MgH5 with five H atoms occupying one of the 2e and all 2f, 2g sites. This structure is equivalent to an ordered orthorhombic Pmmm (No. 47) lattice with X (1a), Li (2l), Mg (1b), and H (1c, 1e, 1f, and 2i) sites.



custom character5-XLi2MgH5 with five H atoms occupying one of the 2f and all 2e, 2g sites. This structure can also be described as ordered orthorhombic Pmmm with X (1a), Li (2l), Mg (1b), and H (1c, 1d, 1f, and 2i) sites.



custom character6-XLi2MgH5 with five H atoms occupying one of the 2g and all 2e, 2f sites. This structure is equivalent to an ordered tetragonal P4m (No. 99) structure with X (1a1), Li (1b1, 1b2), Mg (1a2), and H (1a3, 2c1, and 2c2) sites.



custom character7-XLi2MgH6 with six H atoms on the 2e, 2f, and 2g sites. The space group symmetry is again P4/mmm.



custom character8-XLi2MgH7 ordered hexagonal (P63/mmc; No. 194). The populated sites are X (2a), Li (4f), Mg (2b), and H (2c, 12k). This is the structure shown in FIG. 3 for the proposed compound IrLi2MgH7.


Since the purpose of the calculations is to identify previously unknown compounds and hydrides, there can be no foreknowledge of which compounds or hydrides are stable, and if stable, what structure they will adopt. Hence calculations must be made for various parent and hydride structures.


As detailed at some length above the choice of templates is informed by the behavior of compounds comprising elemental species believed to behave in comparable manner to those under consideration. However, it is well known to those skilled in the art that apparently minor differences in valence or atomic size between chemical species will promote their adoption of different crystal structures. Thus, there can be no guarantee that the structural choices described comprise all possible crystal structures that might be adopted by the chemical compounds under consideration.


However, in the absence of any kinetic barrier, compounds will adopt their lowest energy configuration. Thus, any compound identified as stable under the artificial constraint that it adopts the crystal structure of one of the designated templates must be stable if it crystallizes in another structure since the occurrence of another structure, by definition, means that it has the lowest energy. Stated differently, the calculations provide an upper bound on the energies of the proposed compounds and, as such, lead to reliable predictions of stability even if they cannot be used as predictors of crystal structure.


Electronic total energies Eel were calculated with the Vienna ab initio simulation package (VASP), which implements DFT using a plane wave basis set. Projector-augmented wave potentials were employed for the elemental constituents, and the generalized gradient approximation (GGA) of Perdew and Wang was used for the exchange-correlation energy functional μxc. Results for X═Ce were computed for both Ce3+ (one 4f electron in the fixed core) and Ce4+. Although Sm, Eu, Tm and Yb often exhibit two valence states with different 4f occupancy as well, the calculations reported here were done for Sm3+, Eu2+, Tm3+ and Yb2+ since PAW (Projector Augmented Wave) potentials were only available for those most common configurations. Non-magnetic calculations were performed for all materials. In all cases a 900 eV plane wave cutoff energy was imposed. The number of points in the irreducible Brillouin zone for the k-space meshes utilized was at least 120 (custom character1), 165 (custom character2), 220 (custom character3), 125 (custom character4, custom character5) 126 (custom character1, custom character2, custom character3, custom character6, custom character7), and 133 (custom character8). At least two simultaneous relaxations of the lattice constants and nuclear coordinates not fixed by the space group were carried out. The electronic total energies and forces were converged to 10−6 eV/cell and 10−3 eV/Å, respectively. Calculations for the H2 molecule and the elemental metals were performed with the same computational machinery to the same levels of precision.


Enthalpies of formation ΔH were obtained from differences of electronic total energies:

ΔH(XLi2Mg)=Eel(XLi2Mg)−Eel(X)−2Eel(Li)−Eel(Mg)

for the parent compounds, and

ΔH(XLi2MgHn)=(2/n)[Eel(XLi2MgHn)−Eel(X)−2Eel(Li)−Eel(Mg)−(n/2)Eel(H2)]

for the hydrides, where Eel(Y) is the electronic total energy of constituent Y and n is the number of H atoms in a given configuration. Each ΔH, specified per XLi2Mg formula unit (f. u.) in Eq. (1) and per H2 molecule in Eq. (2), is the standard enthalpy of formation at zero temperature in the absence of zero point energy contributions.










TABLE I








ΔH (XLi2Mg) (kJ/mole f. u.)












Compound

custom character 1


custom character 2


custom character 3


















SiLi
2
Mg



−98


−74


−101




YLi2Mg
41
18
39



ZrLi2Mg
111
86
110



NbLi2Mg
212
192
208



MoLi2Mg
258
250
255



TcLi2Mg
189
194
188



RuLi2Mg
67
85
65





RhLi
2
Mg



−103


−73


−104




LaLi2Mg
30
11
28



Ce4+Li2Mg
93
72
93



Ce3+Li2Mg
24
5
23



PrLi2Mg
28
9
27



NdLi2Mg
31
12
30



PmLi2Mg
35
15
33



SmLi2Mg
38
17
36



EuLi2Mg
19
4
19



GdLi2Mg
43
21
41



TbLi2Mg
46
24
44



DyLi2Mg
49
27
47



HoLi2Mg
52
30
50



ErLi2Mg
55
32
52



TmLi2Mg
57
33
54



YbLi2Mg
22
3
21



LuLi2Mg
61
37
58



HfLi2Mg
152
124
148



TaLi2Mg
263
239
255



WLi2Mg
337
323
330



ReLi2Mg
271
270
267



OsLi2Mg
143
158
140





IrLi
2
Mg



−76


−50


−79










A negative ΔH indicates stability of the material relative to its elemental metal and molecular H2 constituents. Table I lists ΔH(XLi2Mg) calculated according to Eq. (1) for all XLi2Mg compounds with X═Y, Zr, Nb, Mo, Tc, Ru, Rh, La, Ce, Pr, Nd, Pm, Sm, Eu, Gd, Tb, Dy, Ho, Er, Tm, Yb, Lu, Hf, Ta, W, Re, Os, and Ir with structures based on the custom character1, custom character2 and custom character3 templates. For purposes of validation, a similar calculation was performed for SiLi2Mg. In qualitative agreement with experimental evidence for its existence, ΔH is negative for SiLi2Mg (shown in underlined bold in Table I) using all three templates. For the group of compounds not previously reported, ΔH is positive for XLi2Mg with X═Y, Zr, Nb, Mo, Tc, Ru, La, Ce, Pr, Nd, Pm, Sm, Eu, Gd, Tb, Dy, Ho, Er, Tm, Yb, Lu, Hf, Ta, W, Re and Os indicating that the compounds likely do not exist. Of the remainder, Ce3+Li2Mg, EuLi2Mg and YbLi2Mg show only small positive ΔH values for structures corresponding to the custom character2 template leaving open to question whether or not they might be marginally stable in view of the upper bound nature of the calculations. The other three compounds, shown in bold underline, SiLi2Mg, RhLi2Mg and IrLi2Mg, show large negative ΔH values for all three templates and are therefore predicted to be stable. As noted, SiLi2Mg is known to exist but RhLi2Mg and IrLi2Mg, are previously-unreported compounds. In all cases the custom character1 and custom character3 templates yield nearly identical and appreciably lower values of ΔH than the custom character2 template, suggesting that the custom character2 structure would not be observed. This is again consistent with the known properties of SiLi2Mg which adopts the crystal structure of the custom character3 template. Thus, the credible likelihood of the formability of a pair of novel three element compounds comprising Li and Mg is established: RhLi2Mg and IrLi2Mg.


Turning now to the hydrides, enthalpies of formation relative to the elemental metals and H2 for the XLi2MgHn hydrides in the eight custom characteri template structures are presented in Table II. At least one, and in most cases several, negative ΔH values are obtained for every X except W, raising the possibility of hydride formation in the cases of Y, Zr, Nb, Mo, Tc, Ru, Rh, La, Ce (in both the +4 and +3 oxidation states), Pr, Nd, Pm, Sm, Eu, Gd, Tb, Dy, Ho, Er, Tm, Yb, Lu, Hf, Ta, Re, Os, and Ir. For each X the lowest ΔH value is shown in bold underline and Table III summarizes the minimum ΔH results from Table II and includes the hydrogen mass percentage for each hydride.









TABLE II







ΔH(XLi2MgHn) (kJ/mole H2)















X

custom character 1 (4)


custom character 2 (4)


custom character 3 (4)


custom character 4 (5)


custom character 5 (5)


custom character 6 (5)


custom character 7 (6)


custom character 8 (7)



















Y
−7
−43
−25
−33
−35
−89
−51
 4


Zr
8
−11
−19
−27
−28
−57
−45
 5


Nb
41
35
 5
−5
−1
−15





22


21


Mo
52
69
 12
3
23
 4





10


30


Tc
18
61
−25
−25
8
−20





29


−3


Ru
−33
29





73


−59
−24
−47
−60
−49 


Rh
−96
−46





112

−85
−77
−85
−90
−102 


La
25
−46
 10
−2
−26





77


−20
20


Ce4+
40
−25
 20
7
−15





80


−13
13


Ce3+
29
−45
 17
4
−23





77


−16
26


Pr
23
−44
 11
−1
−25





79


−21
24


Nd
18
−43
 6
−6
−26





80


−26
22


Pm
13
−43
 0
−12
−27





82


−31
20


Sm
10
−42
 −4
−15
−28





83


−34
18


Eu
25
−43
 8
−6
−20





70


−24
44


Gd
1
−42
−15
−24
−30





86


−42
13


Tb
−1
−41
−18
−27
−30





86


−45
11


Dy
−3
−40
−21
−30
−31





86


−48
 9


Ho
−4
−39
−24
−32
−31





86


−50
 7


Er
−5
−38
−26
−34
−32





89


−51
 5


Tm
−6
−37
−28
−36
−32





89


−53
 3


Yb
8
−43
−11
−23
−21





72


−41
44


Lu
−7
−34
−32
−38
−33





88


−55
 0


Hf
20
4
−17
−23
−22





45


−43
 4


Ta
59
47
 15
7
8
 −7





16


22


W
87
90
 41
30
42
 27
7
33


Re
57
87
 10
5
30
 11
−9
 0


Os
10
60
−37
−29
1
−16
−40


−48



Ir
−74
−28
−96
−73
−66
−62
−84


−116




















TABLE III





XLi2MgHn
ΔH(XLi2MgHn)
ΔH * (XLi2MgHn)



hydride (custom character i)
(kJ/mole H2)
(kJ/mole H2)
mass % H


















YLi2MgH5 (custom character 6)
−89

3.8


ZrLi2MgH5 (custom character 6)
−57

3.7


NbLi2MgH6 (custom character 7)
−22

4.4


MoLi2MgH6 (custom character 7)
−10

4.3


TcLi2MgH6 (custom character 7)
−29

4.3


RuLi2MgH4 (custom character 3)
−73

2.8


RhLi2MgH4 (custom character 3)
−112
−61
2.8


RhLi2MgH7 (custom character 8)
−102
−73
4.8


LaLi2MgH5 (custom character 6)
−77

2.8


Ce4+Li2MgH5 (custom character 6)
−80

2.7


Ce3+Li2MgH5 (custom character 6)
−77

2.7


PrLi2MgH5 (custom character 6)
−79

2.7


NdLi2MgH5 (custom character 6)
−80

2.7


PmLi2MgH5 (custom character 6)
−82

2.6


SmLi2MgH5 (custom character 6)
−83

2.6


EuLi2MgH5 (custom character 6)
−70

2.6


GdLi2MgH5 (custom character 6)
−86

2.5


TbLi2MgH5 (custom character 6)
−86

2.5


DyLi2MgH5 (custom character 6)
−86

2.4


HoLi2MgH5 (custom character 6)
−86

2.4


ErLi2MgH5 (custom character 6)
−89

2.4


TmLi2MgH5 (custom character 6)
−89

2.4


YbLi2MgH5 (custom character 6)
−72

2.3


LuLi2MgH5 (custom character 6)
−88

2.3


HfLi2MgH5 (custom character 6)
−88

2.3


TaLi2MgH6 (custom character 7)
−16

2.7


ReLi2MgH6 (custom character 7)
−9

2.6


OsLi2MgH7 (custom character 8)
−48

3.0


IrLi2MgH7 (custom character 8)
−116
−94
3.0









According to the van't Hoff relation

ln p/p0=ΔH/RT−ΔS/R,

where ΔS is the entropy of formation and R the gas constant, the configuration having the most negative ΔH is that which is stable at the lowest H2 pressure p.


For controlled and repeated hydrogen uptake and release, it is more desirable to have XLi2MgHn release hydrogen while reverting to XLi2Mg than to have XLi2MgHn revert to its constituent elements while releasing hydrogen. The preferred reversible reaction is then:

XLi2MgHncustom characterXLi2Mg+n/2H2,

and the formation enthalpy of the hydride with respect to its parent compound, ΔH*(XLi2MgHn), is given by:

ΔH*(XLi2MgHn)≡(2/n)[Eel(XLi2MgHn)−Eel(XLi2Mg) −(n/2)Eel(H2)]

Listings of ΔH*(XLi2MgHn) are also given in Table III.


For the predicted hydrides RhLi2MgH4 (custom character3 template), RhLi2MgH7 (custom character8 template) and IrLi2MgH7 (custom character8 template), ΔH*(XLi2MgHn)<0 in Table III and a stable parent (RhLi2Mg, IrLi2Mg) is predicted to exist (cf. Table I) suggesting the desirable possibility of cycling between the two according to the reaction given above.


Thus, a family of hydrides is provided as follows: YLi2MgHn, ZrLi2MgHn, NbLi2MgHn, MoLi2MgHn, TcLi2MgHn, RuLi2MgHn, RhLi2MgHn, LaLi2MgHn, Ce4+Li2MgHn, Ce3+Li2MgHn, PrLi2MgHn, NdLi2MgHn, PmLi2MgHn, SmLi2MgHn, EuLi2MgHn, GdLi2MgHn, TbLi2MgHn, DyLi2MgHn, HoLi2MgHn, ErLi2MgHn, TmLi2MgHn, YbLi2MgHn, LuLi2MgHn, HfLi2MgHn, TaLi2MgHn, ReLi2MgHn, OsLi2MgHn and IrLi2MgHn. In these hydride formulas, n is an integer having a value from 4 to 7.


Particles of one or more of these compositions may be used in a suitable, predetermined mass to release a desired quantity of hydrogen upon heating for delivery to a hydrogen-consuming device. Upon release of hydrogen they may revert to like hydrogen-depleted analogs or other useful hydrogen-storage compounds containing the base elements. Hydrogen may be reacted with the analogs or remaining compounds to restore the hydrides for re-use.


EXPERIMENTAL

Guided by the calculations, it was decided to attempt a synthesis of IrLi2Mg. Equimolar quantities of iridium and magnesium in powder form (˜325 mesh) were well mixed and added to a stoichiometric quantity of lithium. The three-component mixture was placed in a stainless steel crucible and sealed under an inert atmosphere of argon with a stainless steel closure by arc welding. This practice was followed to avoid oxidation, particularly of lithium, and to avoid loss by vaporization. The crucible was then held at a temperature of 510° C. for 4 days. Following such enclosed heating, the crucible was opened, the contents were fragmented and the resulting powder subjected to conventional powder X-ray diffraction analysis. The X-ray diffraction data confirmed that the reaction product was crystalline and present as a single phase in a cubic structure. The data was also consistent with the presence of only a single compound and showed no discernable peaks corresponding to the elemental constituents. This analysis was taken as strongly suggesting the formation of the predicted IrLi2Mg compound. Further validation was afforded by high energy ball milling the constituents in a stainless steel milling jar under an inert argon atmosphere. This process afforded similar results but indicated the presence of some impurities, mainly un-reacted iridium.


Samples of the prepared material, considered to be IrLi2Mg, were placed in a Cahn TG-2151 high-pressure, thermogravimetric analyzer, pressurized to 82 bar of hydrogen, heated to 400° C., and held at temperature for approximately nine hours. The temperature of the contents of the analyzer was then reduced to about 25° C. It was expected that the material had adsorbed some hydrogen. The hydrogen gas atmosphere was carefully released from the analyzer and replaced with helium to a pressure of 1.3 bar. The powder in the analyzer under a helium atmosphere was then progressively heated to 450° C. and held at temperature for about an hour during which time the sample weight stabilized. A mass spectrometer analysis of the gas atmosphere confirmed the evolution of hydrogen gas substantiating that IrLi2Mg was likely hydrogenated in accord with expectations based on the calculated enthalpies.

Claims
  • 1. Any one or more of the hydrides having a compositional formula selected from the group consisting of YLi2MgHn, ZrLi2MgHn, NbLi2MgHn, MoLi2MgHn, TcLi2MgHn, RuLi2MgHn, RhLi2MgHn, LaLi2MgHn, Ce4+Li2MgHn, Ce3+Li2MgHn, PrLi2MgHn, NdLi2MgHn, PmLi2MgHn, SmLi2MgHn, EuLi2MgHn, GdLi2MgHn, TbLi2MgHn, DyLi2MgHn, HoLi2MgHn, ErLi2MgHn, TmLi2MgHn, YbLi2MgHn, LuLi2MgHn, HfLi2MgHn, TaLi2MgHn, ReLi2MgHn, OsLi2MgHn, IrLi2MgHn where n is an integer having a value of 4 to 7.
  • 2. One or more of the hydrides of claim 1 having a compositional formula selected from the group consisting of YLi2MgHn and ZrLi2MgHn.
  • 3. One or more of the hydrides of claim 1 having a compositional formula selected from the group consisting of NbLi2MgHn, MoLi2MgHn, and TcLi2MgHn.
  • 4. One or more of the hydrides of claim 1 having a compositional formula selected from the group consisting of RuLi2MgHn, RhLi2MgHn, and LaLi2MgHn.
  • 5. One or more of the hydrides of claim 1 having a compositional formula selected from the group consisting of Ce4+Li2MgHn, Ce3+Li2MgHn, and PrLi2MgHn.
  • 6. One or more of the hydrides of claim 1 having a compositional formula selected from the group consisting of NdLi2MgHn, PmLi2MgHn, and SmLi2MgHn.
  • 7. One or more of the hydrides of claim 1 having a compositional formula selected from the group consisting of EuLi2MgHn, GdLi2MgHn, and TbLi2MgHn.
  • 8. One or more of the hydrides of claim 1 having a compositional formula selected from the group consisting of DyLi2MgHn, HoLi2MgHn, and ErLi2MgHn.
  • 9. One or more of the hydrides of claim 1 having a compositional formula selected from the group consisting of TmLi2MgHn, YbLi2MgHn, LuLi2MgHn, and HfLi2MgHn.
  • 10. One or more of the hydrides of claim 1 having a compositional formula selected from the group consisting of TaLi2MgHn, ReLi2MgHn, OsLi2MgHn, and IrLi2MgHn.
  • 11. One or more of the chemical compounds having a chemical formula selected from the group consisting of IrLi2Mg and RhLi2Mg.
US Referenced Citations (3)
Number Name Date Kind
7618607 Herbst Nov 2009 B2
20080305024 Herbst Dec 2008 A1
20110038776 Herbst Feb 2011 A1
Related Publications (1)
Number Date Country
20110091368 A1 Apr 2011 US