Nanostructured Materials for Room-Temperature Reversible ... · Key Results from Metal Doping...
Transcript of Nanostructured Materials for Room-Temperature Reversible ... · Key Results from Metal Doping...
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Nanostructured Materials for Room-Temperature Reversible
Hydrogen Storage: A First-Principles Study
Shengbai Zhang, Y. Zhao, Y.-H. Kim, A. Williamson, A. C. Dillon, & M. J. Heben
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Chemical hydrides> 100 kJ/mol
“spillover”Enhanced physisorption
M
M
2.00 2.40
0.99
0.97
“Kubas” binding
Carbon based materials:10 - 50 kJ/mol
Metal hydrides & Kubas molecules 50 - 100 kJ/mol
Methane(~ 400 kJ/mol)
H Binding Energy in Various Storage Hosts
Graphite-H2physisorption
4 kJ/mol
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A large binding energy will lead to energy penalties during charge & discharge, prohibit on-board recharging, and reduce the system capacities (space for heat exchangers)
1 MW
H
Binding Energy Impacts System Design
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Objective: Establishing the theoretical underpinning for molecular H2 adsorption in the 10-50 kJ/mol energy range.
Enhanced H2 binding in boron-doped fullerenesPhys. Rev. Lett. 96, 016102 (2006)
Kubas complex of (transition metal-H2) in organo-metallic molecules Phys. Rev. Lett. 94, 155504 (2005)
TimCn nanocrystals: embedded metal atoms to avoid clustering Chem. Phys. Lett. 425, 273 (2006)
Outline
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A Few Words about First-Principles Methods
We used a combination of the density functional theory within LDA or GGA approximation and the quantum Monte Carlo method
The only input is the atomic numbers and the approximate atomic geometries from which the energy minimum is searched by a force minimization
We develop models only to interpret the results, never to dictate the calculations by any adjustable parameters.
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Why Molecular Hydrogen?
No noticeable barrier for adsorptionNo additional barrier for desorption other than theadsorption energyMaintain the integrity of H2 in the entire process
→ superb adsorption/desorption kinetics.
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N: 0.056 eV B: 0.390 eV
Li: 0.068 eV F: 0.043 eV
Weak molecular binding to fullerenes regardless of the curvatureEndohedral doping does not help, whereas substitutionalmay, but need to find out which impurity and why.
H2 Binding to Light Element-Doped C36
Bare C36: 0.065 eV(1 eV ≅ 100 kJ/mol)
2.51 Å
0.77 Å
Perhaps the largest curvature existing
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H2 Binding Mechanism: Electronic PictureChemical BindingThrough Hybridization:
isolated H2
pz state of the dopant
hybridized states
By electronically mixing the occupied H2 state with the emptypz state of the dopant, the system gains electronic energy.
Boron Beryllium
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H2 Binding Mechanism: Bond PictureC35B
C35Be
Charge-density change due to H2 adsorption can tell if bond forms between the H2 and dopantsolid contour = accumulation; dashed contour = depletion
More charge transfer from H2 to C35B, but the transfer from H2 to C35Beis much more localized in the “bond” region
H2 binding energy = 0.39 eV for B & 0.65 eV for Be.
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Multi B (Be) Sites on C60 & Their H2 Binding
(Multi) boron-doped C60 has been experimentally demonstrated, and hence it can be used to test our theory
Binding energy is nearly a constant for Be, but drops a lot for B at higher H concentration due to less localized pz orbital
Recent NMR and inelastic neutron scattering studies of B-doped nanotubes indicate the existence of boron enhancement.
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Key Results from Metal Doping
light-metal doping can in principle enhance the binding energy of H2, but it requires the following conditions to be simultaneously satisfied:
Phys. Rev. Lett. 96, 016102 (2006)
(a)Presence of nonbonding orbital like the pz state to accommodate the H2 molecule (site availability)
(b)The state needs to be empty with adequate energy level position with respect to that of the σ level of H2(enabling energy gain by hybridization)
(c) Highly localized charge transfer (maximizing bond charge)
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Can We Generalize the Key Findings ?
Is there any other dopant, beyond just the light-metal atoms, that can provide, on a per atom basis, more abundant nonbonding and localized orbitals ?
→ Yes, transition metal (TM) atoms
At least in their nanocluster form, a significant number of the d-orbitals may have not been used up for the chemical bonding.
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The Kubas ComplexesIn 1984, Kubas
experimentally discovered the molecular complexes, in which transition metal atom binds molecular hydrogen through a three center-two electron interaction
A backdonation of electrons from metal d orbital to empty H2 σ* orbital was implicated for the observation.
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Organometallic Molecule with Carbon Ring
H-H
M
Kubas, J. Organometallic Chem. 635, 37 (2001)
Ligand 1: H-H
Fisc
her a
nd J
ira,
J. O
rgan
omet
allic
Che
m.
637,
7 (2
001)
.
Ligand 2: C-C
cyclopentadienyl(Cp) ring
H2 loaded metal atoms on a Cp ring
C--C
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Scandium & Cp Ring: The Binding MechanismThe Binding Mechanism
CpSc
2H
Cp[ScH2]HScCp + H2
coupling between two nearly degenerate states
1.30 eV
Cp[ScH2]H2
Cp[ScH2(H2)]
ScCpH2 + H2
coupling between two states energetically distant
0.29 eV
Binding EnergiesConfigurationsCpSc
CpSc
Sc
CH
Sc + Cp
one electron transfer -> Coulombic
3.76 eVs+d orbitals
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Consecutive H2 Loading to a Removable 6.7 wt%6.7 wt%
Cp[ScH2]
Cp[ScH2(H2)]0.29 eV
Cp[ScH2(H2)2]0.28 eV
Cp[ScH2(H2)3]0.46 eV
Consecutive binding of H2
Cp[ScH2(H2)4]0.23 eV
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H-H Bond Lengths (A)
Sc 4x0.80
Ti 4x0.85
V 3x0.9
Cr 3x0.96
Mn 3x0.94
Fe 2x0.95
Co 2x1.10
Ni 1x0.94
0.0
0.4
0.8
1.2
1.6
Sc Fe Co NiTi V Cr Mn3d14s2 3d24s2 3d34s2 3d54s2 3d64s2 3d74s2 3d84s23d54s1
Bin
ding
Ene
rgy
(eV
/H2)
Consecutive H2 Binding to 3d Metal-Cp Complex
1st H22st H2
3st H2
4st H2
5st H2
Full width open bar for dihydride (2H)Half width open bar for monohydride (H)Solid bars for dihydrogen (H2)
0.1-0.6 eV
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The 18-Electron Rule for H Sorption on TM
Sc Ti V Cr Mn Fe Co Ni
nvNH
310
49
58
67
76
85
94
103
In all cases, we have nv + NH + 5 = 18wherenv: number of s + d electrons of the TM atomNH : number of the H atoms a TM can bind5: number of the π electrons in the Cp ring
Phys. Rev. Lett. 94 (April), 155504 (2005)
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A Problem: Polymerization of CpTM Complexes
Cp[ScH2]
Cp[ScH2] chain
Polymerization of ionic molecules
After the removal of H2, the CpTMcomplexes are likely to form polymerized chains due to their mutual Coulomb attraction, thereby loosing the ability to retake molecular hydrogen
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One can assemble the organometallicmolecules into more stable forms
(1) TM-coated buckyball or nanotubes;(2) TM-decorated polymers;(3) TM-decorated metalorganic frameworks;(4) organometallic supra molecules;(5) metal carbide nanocrystals;(6) or whatever that may work.
What Can One Do?
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From Cp-TM Complex to TM-Coated Buckyball
Organizing the CpOrganizing the Cp--TMTM--H clusters into a H clusters into a buckyballbuckyballcan help to eliminate dipolecan help to eliminate dipole--induced polymerizationinduced polymerization
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12-ScH2 Loaded C60: 7.0 wt% H7.0 wt% H22
Very similar binding energies to those of a Cp ring for the hydrides and the H2 molecules
C60[ScH2(H2)4]12C60[ScH2]12
48H2
Sc
H
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C48B12[ScH(H2)5]12C48B12[ScH]12
60H2
One more electron is transferred from each Sc to the corresponding pentagon, which enhances both the Sc-C60 binding and the hydrogen storage capacity.
12-ScH Loaded C48B12: 8.8 wt% H8.8 wt% H22
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[ScH3]3 [ScH3 ] 3Sc[H3(H2)6]
ScH3(H
2)6
Will the TM Coated Fullerenes Disintegrate?
-0.16-0.18 -0.14 -0.12 µH (eV)
C48B12[ScH]12
0
1
2
3
Form
atio
n E
nerg
y (e
V/S
c)
0.86 4. 07 19.3 PH2 (atm)0.18
C60[ScH2]12
There exists barriers against disintegration of the coated fullerenes.
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See no sign of disintegration of the coated fullerenes, nor TM clustering.
T = 727°C,t = 10 ps, ∆t = 0.4 fs(= 25,000 time steps)
First-Principles Molecular Dynamic Simulation of C48B12 [ScH]12
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Enhanced H2 Binding to Ti-Coated Carbon Nanotubes
Yildirim and Ciraci, PRL 94 (May), 175501 (2005)
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Enhanced H2 Binding to Cr AtomGagliardi and Pyykko, JACS 126,
15014 (2004)
62 kJ/mol-H2 (exothermic)
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Enhanced H2 Binding to Ni-Coated C60
Shin, Yang, Goddard III, and Kang, APL 88, 053111 (2006)
First H2 adsorption is 77.7 kJ/mol; 6.8 wt %
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2.07 eV/Ti 0.0 eV/Ti
Metal Clustering Could Be a ProblemSun, Wang, Jena, and Kawazoe, JACS
127, 14582 (2005)
Thermodynamically, a clustered phase is noticeably more stable.
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However, there are also other possibilities …
In B doped fullerene, clustering energy is substantially smaller, and Sc prefers to coat nano-surfaces evenly.
-0.07 0.0 0.86 eV/Sc
B
C
Sc
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Embedding Transition Metal
Atoms into Carbon NetworkZhao, et al., Chem. Phys. Lett. 425, 273 (2006)
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Experimental Observations: Ti: Ti88CC12 12 and Tiand Ti1414CC1313
Guo et al., Science 255, 1411(1992)
A magic cluster M8C12,M = Ti, V, Y, Zr, Hf, Mo
Pilgrim and Duncan,JACS 115, 9724 (1993)
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TiTi88CC1212: Total Hydrogen Capacity of 6.1 wt%: Total Hydrogen Capacity of 6.1 wt%
# of H atoms Eb (eV/H2) Hydrides on Ti: 2 1.43Hydrides on C: 12 0.64Dihydrogen (H2): 10 0.17-0.33
+ 16 H2 =
Ti8C12H34
H
α α
β
γ
Ti8C12H2
C
TiH
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TiTi1414CC1313: Total Hydrogen Capacity of 7.7 wt%: Total Hydrogen Capacity of 7.7 wt%
+ 19 H2 =
Ti14C13H42
Ti14C13H4
# of H atoms Eb (eV/H2) Hydrides on Ti: 4 0.89Hydrides on C: 12 1.31Dihydrogen (H2): 10 0.18-0.38
H
CTi
H
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Lee, Choi, and IhmCombinatorial Search for Enhanced H2 Binding in
PolymersPRL 97, 056104 (2006)
(a) Cis-polyacetylene, (b) and (c) Trans-polyacetylenes, (d) Polypyrrole, (e) and (f) Polyaniline; The transition metal is Ti
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Summary
B-doped fullerenes & TM coated buckyballs are among the potential systems to first try experimentally
First-principles calculations establish a unified Kubas-type mechanism for enhanced H2 binding on metal atoms on carbon hosts: Non-bonding, empty, and localized metal states
Acknowledgement: DOE Office of Energy Efficiency and Renewable Energy, Hydrogen, Fuel Cell, and Infrastructure Technologies Program.
Metal clustering is a challenge but may be avoidable by a better choice of the host systems
In any case, it is unlikely and probably unnecessary that the ultimate H2 adsorbate system is thermodynamically stable; kinetic stability is more likely and, in most applications, enough
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Methods of Calculations
First-principles density functional theory within the LDA approximation for light elementsValidated by Quantum Monte Carlo calculations
GGA approximation for 3d transition metalsValidation by comparing calculated Kubas molecule with experiment
Ultrasoft pseudopotentials and projector augmented wave method; converged results.
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How Reliable Are the C35B Results?
Linear-scaling Quantum Monte Carlo (QMC) method
QMC vs. high-level quantum chemical (QC) calculations for BH5
0.2 eV (QMC) vs. 0.39 eV (LDA) and -0.03 eV (GGA) for H2 binding to C35B
The 0.2-eV QMC energy here represents a significant increase from that of a typical vdW energy of 0.04 eV.
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Chemistry of the TiChemistry of the Ti88CC1212
Metal atoms form atetra-capped tetrahedron frame
Carbon atoms form pairs with triple bondsRohmer et al., Chem. Rev. 100, 495 (2000)
Ml
Mo
MetCar is full of TM atoms with unsaturated d states, which could be beneficial for H2 binding, while the carbon backbone serves to stabilize the structure from metal clustering.
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(5)
d
(1)
(2)
(3)(4)
(0)
6 5 4 3 2 (A)d =
-1.6
-1.2
-0.8
-0.4
(eV)
0.0
A Microscopic Model for the Spillover A Microscopic Model for the Spillover @ @ MetaCarMetaCar
H2 gas
Spilloverforming C-H
Direct dissociation
Metal assisteddissociationforming M-H
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(111)
A Diamond Lattice of the MetCars
Lattice constant: 1.77 nmCohesive energy: 6.7 eV/MetCar
(110)
(100)
1.25 nm