metal hydrides npre 498 – term presentation (11/18/2011) vikhram v. swaminathan
TRANSCRIPT
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METAL HYDRIDES
NPRE 498 – TERM PRESENTATION (11/18/2011)
Vikhram V. Swaminathan
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Outline
Motivation Current status and projections Requirements and Challenges
Chemical/Reversible Metal hydrides Magnesium Hydride
Transportation and Regeneration Getting the better of AB5
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Motivation
Hydrogen has the highest energy per unit of weight of any chemical fuel
Convenient, pollution free energy carrier, route to electrical power
Clean, only product is water—no greenhouse gases/air pollution Anode: 2H2 4H+ + 4e-
E° = 1.23 VIn practice, Ecell
≈ 1 V
Cathode: O2 + 4H+ + 4e- 2H2O
Can we beat Carnot limits?PEM Fuel cell efficiencies up to 70%System efficiencies of 50-55%!!
e-
PEM
Catalyst
Catalyst
H+
H+ H+
H+
H2O
H2O
H2H2
H2
H2
H2 source
O2 O2
O2
O2 from air
However, Hydrogen needs to be stored and carried appropriately!
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Motivation
Well.. er.. we like to avoid this!
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Motivation
DOE’s famous hydrogen roadmap
We aren’t yet there w.r.t to both volumetric and gravimetric requirements for vehicular applications!
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Motivation
Some challenges to address among all methods: Weight and Volume.
Materials needed for compact, lightweight, hydrogen storage systems Sorbent media such a MOFs, CNTs etc are not quite effective yet!
Efficiency. A challenge for all approaches, especially reversible solid-state materials. Huge energy associated with compression/liquefaction and cooling for
compressed and cryogenic hydrogen technologies. Durability.
We need hydrogen storage systems with a lifetime of 1500 cycles. Refueling/Regeneration Time.
Too long! Need systems with refueling times of a few minutes over lifetime.
Cost, ultimately. Low-cost, high-volume processing, and cheap transport for effective
scaling
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0
50
100
150
0 5 10 15 20 25 30
Hydrogen mass density (%)
Hy
dro
ge
n v
olu
me
de
ns
ity
(k
g H
2/m
3 )
100
TiH2
CaH2
NaH
AlH3
MgH2
KBH4
NaAlH4
NaBH4
LiAlH4 LiH
LiBH4
NH3BH3
CH3OH
C2H5OH C8H18
C4H10
NH3
C3H8
C2H6 CH4
Liquid hydrogen
700 bar
350 bar
2010 system targets 45 kg H2/m
3, 6% wt
2015 system targets 81 kg H2/m
3, 9% wt
100
Motivation
Where do some sources fit in?
Metallic hydrides may be preferred over liquid hydrocarbon sources Me-OH/HCOOH : need dilution, low Open circuit voltage, CO-
poisoning However we have to address the uptake/release and handling
issues
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Chemical Metal Hydride Sources Theoretical capacities of chemical metal hydrides (0.6 V
fuel cell operation) Hydrogen is spontaneously generated by hydrolysis:
MHx + xH2O M(OH)x + xH2
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Chemical Metal Hydride Sources Do we get these capacities, in reality?
CaH2/Ca(OH)2 LiH/LiOH LiBH4 NaBH4
Hydrogen yield and reaction kinetics determined by by-product
hydroxide porosity & expansion affect water vapor partial pressure!
What about recharging the sources?
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Metal Hydride Alloys
Combinations of exothermic metal A (Ti, Zr, La, Mm) and endothermic metal B (Ni, Fe, Co, Mn) without affinity to hydrogen
Typical forms: AB5, AB2, AB, or A2B
La-Ni alloy- LaNi4.7Al0.3
Ergenics (Solid State Hydrogen Energy Solutions
LaNi5:Gravimetric density of 1.3 wt% HVolumetric density of 0.1 kg/L
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Metal Hydride Alloys
Hydrogen absorption/desorption isotherms Applications
Modular Hydrogen storage battery technology for heavy equipment
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Magnesium Hydride
Abundantly available- most representative group 2 hydride Inexpensive Medium sorption temperatures 300-325°C Slow kinetics!
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Magnesium Hydride
Can we improve the kinetics? Nano-Cr2O3 particles, ball milling synthesis
5x improved sorption rates Hydrogen uptake/release Capacity caps at ~6%
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Metal Hydride Slurries..
Create a slurry of the Hydride to transport in pipelines
-Safe Hydrogen, LLC
What about safety?
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Metal Hydride Slurries..
How is the metal hydride regenerated?
Upto 11% wt capacity with MgH2
Can this combine with a project like DESERTEC?
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Metal Hydride Slurries..
Cost-effectivenessContaminants
Might work if production >104 ton H2/hr
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Novel Mixed Alloy Hydrides
Can we get better than AB5?
MmNi4.16Mn0.24Co0.5Al0.1 perhaps, holds the answer! An unexpected source:
Key aspects: 3-7 bar operating pressure for sorption cycles 15/80°C absorption-desorption temperatures—PEMFCs peak
performance at 80°C! Over 1000 cyles of regeneration capacity
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MmNi4.16Mn0.24Co0.5Al0.1
May be we could engineer a way to run a fuel cell, than pump seawater..
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MmNi4.16Mn0.24Co0.5Al0.1
Hydrogen storage/release
between 15 and 80°C
Some performance metrics..
Regeneration capacity
>93% after 1000 cycles
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QUESTIONS?
Thank You!!