Novel Carbon(C)-Boron(B)-Nitrogen(N)-Containing H2 Storage ... · Novel...
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Novel Carbon(C)-Boron(B)-Nitrogen(N)-!Containing H2 Storage Materials!
Shih-Yuan Liu ([email protected])Department of Chemistry, Boston College
DOE Annual Merit Review and Peer EvaluationsWashington DCJune 10, 2015
Project ID: ST104
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This presentation does not contain any confidential or otherwise restricted information
SynthesisCatalysis
Characterization!COMSOL Modeling
Theory Fuel Cell Operation
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Overview!
David Dixon
Project Team
Technical Barriers (Vehicular)A. system weight and volumeC. efficiencyD. durability/operabilityE. charging/discharging ratesJ. thermal managementR. regeneration processesS. by-product/spent material removal
TimelineProject start date: March 5, 2012Relocation UO to BC: June 2013 to September 2013Project end date: August 14, 2015
BudgetTotal funding spent (not including FFRDC funds)
: $1,437,558Total DOE Project Value: $2,526,606DOE share: $2,020,942 (includes $862,000 in FFRDC funds)cost share percentage: $505,321 (20%)
Paul OsenarJim Sisco
Tom AutreyAbhi KarkamkarMark BowdenSean WhittemoreAdrian HoughtonKriston Brooks
Shih-Yuan LiuFrank Tsung
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Outline !
• Overview of proposed molecules
• Progress since the 2014 Annual Merit ReviewInvestigate endothermic desorptionInvestigate coupled exo/endo desorptionModeling (COMSOL) exo/endo desorption
• Summary of Overall Project Accomplishments
• Future Directions
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4 Project Objectives!
1) liquid phase 2) potentially reversible 3) high capacity
NH2BH2
NH2BH2
Me
NH2BH2
Me
NH2BH2
Me
A
B
C
D
BH2
NH2
BH2
NMeH
H2BN BH2
NMeH
Me H
E
F
G
H2BH2N BH2
NH2
H2NH2B BH2
NH2
BH2
NH2
NH2H2N
BH3•
BH3•
H
I
J
K
L
Mw = 71
Mw = 85
Mw = 85
Mw = 85
Mw = 85
Mw = 99
Mw = 114
Mw = 86
Mw = 85
Mw = 88HN
H2N NH2
BH3•
BH3•BH3
•
Mw = 145
Develop novel chemical H2 storage materials that have the potential to enable non-automotive applications and meet the 2020 DOE targets for vehicular applications with focus on three classes of materials:
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4 Project Objectives!
1) liquid phase 2) potentially reversible 3) high capacity
NH2BH2
NH2BH2
Me
NH2BH2
Me
NH2BH2
Me
A
B
C
D
BH2
NH2
BH2
NMeH
H2BN BH2
NMeH
Me H
E
F
G
H2BH2N BH2
NH2
H2NH2B BH2
NH2
BH2
NH2
NH2H2N
BH3•
BH3•
H
I
J
K
L
Mw = 71
Mw = 85
Mw = 85
Mw = 85
Mw = 85
Mw = 99
Mw = 114
Mw = 86
Mw = 85
Mw = 88HN
H2N NH2
BH3•
BH3•BH3
•
Mw = 145
Develop novel chemical H2 storage materials that have the potential to enable non-automotive applications and meet the 2020 DOE targets for vehicular applications with focus on three classes of materials:
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Towards Vehicular Targets!From reverse engineering analysis (SSAWG 9/10/2014, Semelsberger)
Capacity: solutions: 9.8 – 10.6 wt%; slurries: 11.2 – 12.1 wt%Density: > 70 g / LHeat (exothermic): < |–6.4| kcal/mol Heat (endothermic): < 4.0 kcal/molEa (thermal activation): > 28 kcal/mol; Ea (desorption): <36 kcal/mol
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Towards Vehicular Targets!
overall potential:9.4 wt.%; 94 g H2/L,potential liquid phase starting material at operating T
Overall (–6 H2)!H(gas) = –83.1!H(liquid) = –59.6!G(gas) = –107.3
Per mol H2:!G(gas) = –17.8!H(liquid) = –10.0!G(THF) = –13.6
Energies in kcal/mol @ 298K Gas Phase: G3MP2 Liquid Phase: G3MP2 (gas) + BP*0.025 (Trouton’s rule)
Overall (–6 H2)!H(gas) = +102.3!H(liquid) = +102.8!G(gas) = +49.4
Per mol H2:!G(gas) = –4.8!H(liquid) = +4.0!G(THF) = –3.6
From reverse engineering analysis (SSAWG 9/10/2014, Semelsberger)
Capacity: solutions: 9.8 – 10.6 wt%; slurries: 11.2 – 12.1 wt%Density: > 70 g / LHeat (exothermic): < |–6.4| kcal/mol Heat (endothermic): < 4.0 kcal/molEa (thermal activation): > 28 kcal/mol; Ea (desorption): <36 kcal/mol
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Towards Vehicular Targets!
overall potential:9.4 wt.%; 94 g H2/L,potential liquid phase starting material at operating T
Overall (–6 H2)!H(gas) = –83.1!H(liquid) = –59.6!G(gas) = –107.3
Per mol H2:!G(gas) = –17.8!H(liquid) = –10.0!G(THF) = –13.6
Energies in kcal/mol @ 298K Gas Phase: G3MP2 Liquid Phase: G3MP2 (gas) + BP*0.025 (Trouton’s rule)
Overall (–6 H2)!H(gas) = +102.3!H(liquid) = +102.8!G(gas) = +49.4
Per mol H2:!G(gas) = –4.8!H(liquid) = +4.0!G(THF) = –3.6
Need to develop H2 desorption from CC!
From reverse engineering analysis (SSAWG 9/10/2014, Semelsberger)
Capacity: solutions: 9.8 – 10.6 wt%; slurries: 11.2 – 12.1 wt%Density: > 70 g / LHeat (exothermic): < |–6.4| kcal/mol Heat (endothermic): < 4.0 kcal/molEa (thermal activation): > 28 kcal/mol; Ea (desorption): <36 kcal/mol
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CC Dehydrogenation Catalyst Screen!
Catalyst Hydrogen Evolution
BN heterocycle Cyclohexane
Pt/Al2O3 (0.5 wt%) No Yes
Pt/C (10 wt%) No Yes
Pd/Al2O3 (5 wt%) No Yes
Pd/C (10 wt%) Yes Yes
Pd/SiO2 (5 wt%) No Yes
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Synthesis of Compound X: A Model Compound for Endothermic Desorption!
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BFNMe
1) TMSCl (2 eq.) THF, RT, 20 min
BF3K
2) NHMeEt3N
Grubbs 1st generation catalyst (1.2 mol%)
CH2Cl2, RT, 3hBFNMe
48% over 2 steps
MeMgBr40%
BN
Me
MeH2 (45 psi)
10 wt.% Pd/C (1 mol%)
RT, 18hBN
Me
Me
X 54%
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Synthesis of Compound X: A Model Compound for Endothermic Desorption!
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BFNMe
1) TMSCl (2 eq.) THF, RT, 20 min
BF3K
2) NHMeEt3N
Grubbs 1st generation catalyst (1.2 mol%)
CH2Cl2, RT, 3hBFNMe
48% over 2 steps
MeMgBr40%
BN
Me
MeH2 (45 psi)
10 wt.% Pd/C (1 mol%)
RT, 18hBN
Me
Me
X 54%
capacity bp, mp (charged fuel)
bp,mp(spent fuel)
!H(kcal/mol)
3.6 %
bp: ~170 °Cmp: < –35 °C
bp: ~170 °Cmp: < 0 °C
(30)[31]
(): experimental values for the N-tBu derivative (at 333K, solution phase)[]: predicted value at G3(MP2) level (298K, gas phase)
BN
Me
BN
Me–2 H2
Me MeX
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Continuous CC Dehydrogenation"from Compound X!
Catalyst loading optimization allows for continuous dehydrogenation
H2 m
ass
sign
al in
tens
ity
Time (min)
Injection start
8
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CC Dehydrogenation Temperature Screen!
Catalytic activity observed at temperatures ~ 180 °C.H2:product ratio approximately 2:1 at all screened temperatures.
! X ! H2 ! Spent fuel
Temperature (°C)
!"#
$%&'
(()*
*+,
(-./
( *%0
./1(
2+*
3+40
5(6(
()71(
Spent Fuel Activity (mmol g-1 min-1)
y = 2.2122x - 0.1001 R" = 0.9838
H2 A
ctiv
ity
(mm
ol g
-1 m
in-1
)
9
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Ea and !H‡ for compound X dehydrogenation are higher than either cyclohexene or cyclohexane.
Entropic parameters are similar to those of cyclohexene.
These activation parameters have been used for the modeling studies performed by the PNNL team.
Dehydrogenation Activation Parameters!10
Substrate Ea (kcal mol-1) log10 A ΔH‡ (kcal mol-1) ΔS‡ (cal mol-1 K-1)
6.0±0.2 +18.3±0.7 –34±1
–40±1
Compound X +19.2±0.7cyclohexenea +10.2±0.4cyclohexanea +9.5±0.8
4.7±0.2 +9.4±0.4
1.5±0.5 +8.6±0.8 –55±2a Values determined experimentally using same reactor system as compound X
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XH2 is a solid at room temperature (RT). On the other hand, the mixture of XH2 and X is a liquid phase material at RT and thus amenable to kinetic studies. Further more, the XH2+X mixture features higher storage capacities.
Kinetic Coupling of Exothermic and Endothermic Reaction!
11
!H = +24.6 kcal/mol; +8.2 kcal/mol H2!G = –2.2 kcal/mol
BN
Me
BN
Me–2 H2
Me MeX
3.6 wt%29.9 g H2/L
BN
Me
BN
Me–3 H2
Me Me
XH2
H
H
5.4 wt%solid material atroom temperature
BN
Me
BN
Me–n H2
Me Me
XH2
H
HBN
Me
Me
X
+
1.0 : 2.5
4.9 wt%liquid phase at room temperature41.2 g H2/L
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The observed decrease in Ea for the exo/endo mixture is consistent with kinetic coupling.
Preliminary Kinetic Studies!12
Ea (kcal/mol)
log10(A)
BN
Me
BN
Me–2 H2
Me MeX
19.2±0.7
BN
Me
BN
Me–n H2
– m D2Me Me
XD2
D
DBN
Me
Me
X
+
1.0 : 2.5
6.0±0.2
BN
Me
BN
Me
– 1 D2Me Me
XD2
D
D
7.3 0.1
BN
Me
BN
Me–2 H2
Me MeX
15.6 4.8
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Coupled Exothermic/Endothermic Reactions!
•# Rationale –# Increase hydrogen capacity of CBN materials
•# Removal of H2 from carbon backbone increases hydrogen capacity from 4.7 wt% to 9.4 wt%
–# Reduce energy required during endothermic dehydrogenation •# RH2B-NH2R’ ! RHB=NHR’ + H2 Exothermic •# RH2C-CH2R’ ! RHC=CHR’ + H2 Endothermic
–# Reduce maximum temperature associated with exotherm
17
Thermodynamic coupling can be beneficial to hydrogen capacity, on-board efficiency, and reactor design
13
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•# Parity between exothermic and endothermic reaction enthalpies •# Parity between exothermic and endothermic reaction rates •# Acceptable thermodynamic limitations on reaction equilibrium
!G = –RT ln(Keq) = !H –T!S Constraint on endothermic reaction only (< 50 kJ/mol)
•# Reasonable energy requirements for regeneration Primarily a constraint on the exothermic reaction
Constraints for Effective Thermodynamic Coupling!
To Be Effective Thermodynamic Coupling Requires Appropriate Thermodynamics and Kinetics
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Approach to Modeling!•# Automotive Application
–# HSECoE assumes 43 kWe is required for 80 kWe auto •# Ballast tank compensates for large transients
–# COMSOL Model Includes: •# Reaction Enthalpy, Reaction Rate, Thermodynamic Equilibrium •# Plug Flow Reactor with Axial/Radial Conduction •# Heat Losses to Environment
–# Does not include H2 production increasing velocity
A C + 4H2
43 kWe Power
Insulation
Heat Loss
Qendo Qexo
Model includes real reactor properties (e.g. heat and mass transfer) permitting first semi-
quantitative evaluation of thermodynamic coupling
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Modeling Results—Generic Reaction Parameters !
Typical Results Endothermic Reaction Conversion
Reaction enthalpy ratio has larger impact on conversion than kinetic ratio
Coupled reactions significantly improve endothermic reaction
conversion
16
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Impact of Reactor Configuration!
21
Reaction Enthalpy Ratio = -2
Simple Single Pass Reactor Provides Highest Conversion
17
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Reaction Parameters Based on Actual CBN Material Experiments!
Exothermic Reaction Endothermic Reaction
Thermodynamic Coupling Performed with Properties of Actual CBN Materials
89:;0(<(.=/>=(?@A*+,(9B 89:;0(<(CB>D(?@A*+,(9B
BN
Me
BN
Me–2 H2
Me MeX
BH2
NH23
J
–6H2
4.7 wt% H247 g H2/L
BN
NBN
B
18
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Modeling Results of Thermodynamically Coupled Reactions !
•# Large reduction in endothermic conversion without exothermic reaction
•# High maximum temperature without endothermic reaction
Test Case! Active Reactions!
Exothermic Conversion!
Endothermic Conversion!
Maximum Reactor Temperature!
1!Exothermic and Endothermic(
100%( 46%( 356°C(
2! Exothermic Only( 100%( N/A( 508°C(
3! Endothermic Only ( N/A( 3.2%( 160°C(
Temperature (°C) Exothermic & Endothermic Conversion
19
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NH2BH2
NH2BH2
Me
NH2BH2
Me
NH2BH2
Me
A
B
C
D
BH2
NH2
BH2
NMeH
H2BN BH2
NMeH
Me H
E
F
G
H2BH2N BH2
NH2
H2NH2B BH2
NH2
BH2
NH2
NH2H2N
BH3•
BH3•
H
I
J
K
L
5.6 wt% H252 g H2/Ld: 0.92 g/mLmp: 36-37 °C
4.7 wt% H242 g H2/Ld: 0.89 g/mLviscosity: 25 cPmp: –16 to –18 °C!H(exp) = –9.1 kcal / mol monomer
11.6 wt% (5 H2)mp: >150 °Cthermally stable
9.4 wt% (4 H2)94 g H2/Ld: 1.00 g/mLmp: 75 °C
~10 wt%mp: 130 °Cdecomp.d: 0.82 g/mL!H1(exp): –2.4!H2(exp): –0.9
2.0 wt% (1 H2)17.4 g H2/Ld: 0.87 g/mLmp: 72-73 °C
4.7 wt% H242 g H2/Ld: 0.89 g/mLmp: 50 °C
4.7 wt% H2mp: 25-27 °C
5.3 wt% (3 H2)mp: 65 °Cbp: 125 °C
Mw = 71
Mw = 85
Mw = 85
Mw = 85
Mw = 85
Mw = 99
Mw = 114
Mw = 86
Mw = 85
HN
H2N NH2
BH3•
BH3•BH3
•
20 Summary!1) liquid phase 2) potentially reversible 3) high capacity
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NH2BH2
NH2BH2
Me
NH2BH2
Me
NH2BH2
Me
A
B
C
D
BH2
NH2
BH2
NMeH
H2BN BH2
NMeH
Me H
E
F
G
H2BH2N BH2
NH2
H2NH2B BH2
NH2
BH2
NH2
NH2H2N
BH3•
BH3•
H
I
J
K
L
5.6 wt% H252 g H2/Ld: 0.92 g/mLmp: 36-37 °C
4.7 wt% H242 g H2/Ld: 0.89 g/mLviscosity: 25 cPmp: –16 to –18 °C!H(exp) = –9.1 kcal / mol monomer
11.6 wt% (5 H2)mp: >150 °Cthermally stable
9.4 wt% (4 H2)94 g H2/Ld: 1.00 g/mLmp: 75 °C
~10 wt%mp: 130 °Cdecomp.d: 0.82 g/mL!H1(exp): –2.4!H2(exp): –0.9
2.0 wt% (1 H2)17.4 g H2/Ld: 0.87 g/mLmp: 72-73 °C
4.7 wt% H242 g H2/Ld: 0.89 g/mLmp: 50 °C
4.7 wt% H2mp: 25-27 °C
5.3 wt% (3 H2)mp: 65 °Cbp: 125 °C
Mw = 71
Mw = 85
Mw = 85
Mw = 85
Mw = 85
Mw = 99
Mw = 114
Mw = 86
Mw = 85
HN
H2N NH2
BH3•
BH3•BH3
•
20 Summary: Materials not Made!
! !
3 Compounds were not synthesized
1) liquid phase 2) potentially reversible 3) high capacity
!
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BH2
NH2
BH2
NMeH
H2BN BH2
NMeH
Me H
E
F
G
2.0 wt% (1 H2)17.4 g H2/Ld: 0.87 g/mLmp: 72-73 °C
5.3 wt% (3 H2)mp: 65 °Cbp: 125 °C
Mw = 85
Mw = 99
Mw = 114
21 Summary: Potentially On-Board Reversible Materials!
!
!
Existence of thermodynamic sinks led to the down-selection of F and G.
!
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H2BH2N BH2
NH2
H2NH2B BH2
NH2
BH2
NH2
NH2H2N
BH3•
BH3•
H
I
J
K
L
11.6 wt% (5 H2)mp: >150 °Cthermally stable
9.4 wt% (4 H2)94 g H2/Ld: 1.00 g/mLmp: 75 °C
~10 wt%mp: 130 °Cdecomp.d: 0.82 g/mL!H1(exp): –2.4!H2(exp): –0.9
Mw = 86
Mw = 85
HN
H2N NH2
BH3•
BH3•BH3
•
22
!
Summary: High-Capacity Materials!
!
!
• Compound H is a remarkably thermally stable ! material, yet it can be activated to release 4.7 wt% ! H2 in the presence of a catalyst• Investigation of H led to a better understanding of ! factors improving thermal stability, i.e., reduce the ! hydridic character of the B–H. • Coupling of exothermic and endothermic reaction ! processes can lead to increased storage capacity ! and energy efficiency• Compound J has the potential to meet the 2020 ! DOE system targets for vehicular applications
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NH2BH2
NH2BH2
Me
NH2BH2
Me
NH2BH2
Me
A
B
C
D
5.6 wt% H252 g H2/Ld: 0.92 g/mLmp: 36-37 °C
4.7 wt% H242 g H2/Ld: 0.89 g/mLviscosity: 25 cPmp: –16 to –18 °C!H(exp) = –9.1 kcal / mol monomer
4.7 wt% H242 g H2/Ld: 0.89 g/mLmp: 50 °C
4.7 wt% H2mp: 25-27 °C
Mw = 71
Mw = 85
Mw = 85
Mw = 85
23 Summary: Liquid Phase Materials!
• discovered a single-component liquid phase material• demonstrated clean H2 desorption both under ! thermal conditions and in the presence of a catalyst• demonstrated use of compound B in the context of ! fuel cells in collaboration with Protonex, Inc. • demonstrated that fuel blends of B with ammonia ! borane or J increase fuel capacity, decrease release ! of volatile detrimental impurities, and decreases the ! melting point of the mixture• demonstrated that blends are conducive to tractable ! regeneration reactions
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NH2BH2
NH2BH2
Me
NH2BH2
Me
NH2BH2
Me
A
B
C
D
5.6 wt% H252 g H2/Ld: 0.92 g/mLmp: 36-37 °C
4.7 wt% H242 g H2/Ld: 0.89 g/mLviscosity: 25 cPmp: –16 to –18 °C!H(exp) = –9.1 kcal / mol monomer
4.7 wt% H242 g H2/Ld: 0.89 g/mLmp: 50 °C
4.7 wt% H2mp: 25-27 °C
Mw = 71
Mw = 85
Mw = 85
Mw = 85
23
!
!
!
Summary: Liquid Phase Materials!
! Down-selected due to thermal stability issues Ea (thermal decomposition) < 28 kcal/mol
1) liquid phase
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Need to develop liquid-phase material that is thermally stable! These materials can be suitable for potential portable-power as well as H2 delivery (to the forecourt) applications.
• Exothermic H2 desorption will avoid problems with delivering the necessary ! H2 pressures at the forecourt.
How to make CBN compounds liquid phase and more stable:• Mechanistic studies are consistent with a second-order decomposition pathway ! that first involves a B–N bond dissociation. • Six-membered CBN compounds are less prone to B–N bond dissociation ! consistent with their significantly improved thermal stability.• Introduction of electron-withdrawing F substituents can reduce the hydridic ! character of the B–H, improving thermal stability.• Use of mixtures can achieve melting depression• Potential materials to be developed:
24
Liquid Phase Material Future Direction!
BH2
NH2
FBH2
NH2
F
BH2
NH2
FBH2
NH2F
BH2
NH2
F
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Acknowledgement!25
Frank Tsung Gang Chen Xuguang Liu Zachary Giustra Randy Chou
Tom Autrey Kriston Brooks Mark Bowden Abhi Karkamkar Sean Whittemore Adrian Houghton
David Dixon Tanya Mikulas Edward Garner
Paul Osenar Jim Sisco
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Technical Back-Up Slides!
26
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Compound J Exothermic Reaction!
# Compound J reaction 80-120°C, 10% Pd on C, Batch Experiment
•# Fit experimental data with two first order reactions in series
•# Compound J and J trimer are both solid at room temperature
–# J cannot be used for the endothermic reaction kinetics
E# 89:;0(<(.=/>=(?@A*+,(9B
BH2
NH23
J
–6H2
4.7 wt% H247 g H2/L
BN
NBN
B
27
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Compound X Endothermic Reaction Kinetics!
# Compound X reaction 170-190°C, 10% Pd on C, Flow-Through Experiment
•# Fit experimental data with one first order & equilibrium limited rxn
•# Compound X is a liquid at room temperature, already has B-N hydrogen removed
–# X cannot be used for the exothermic reaction kinetics
E# 89:;0(<(CB>D(?@A*+,(9B
BN
Me
BN
Me–2 H2
Me MeX
28
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Impact of Burning Hydrogen on Thermodynamic Coupling !
35
5% H2 Produced Burned No H2 Produced Burned
End
othe
rmic
Con
vers
ion
End
othe
rmic
Con
vers
ion
Max
imum
Rea
ctor
Tem
p.
Max
imum
Rea
ctor
Tem
p.
29
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30
B-N BDE = 25.2 #G(gas) = 22.0 #G(Et2O) = 25.6 #G(THF) = 29.9 Keq (gas) =6.67x10-17 Keq (Et2O) = 1.52x10-19 Keq (THF) = 1.14x10-22
1
3
2
1
2
3
H2 + BNC3H8 (ring) + BNC3H10 (chain) -11.6
43.4
8.9
-7.7
0.0 BNC3H10 (ring) + BNC3H10 (chain)
34.9 unimolecular Bond dissociation energy (BDE) for the B-N bond of A in kcal/mol. Free energies at 298 K.
Potential energy surface for the catalyzed elimination of H2 from A at 298 K in kcal/mol obtained at the B3LYP/DZVP2 level.
Bimolecular Mechanism of Thermal H2 Desorption (CBN Cyclopentanes)!
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31
Bond dissociation energy (BDE) for the B-N bond in kcal/mol. Free energies at 298 K.
Potential energy surface for the catalyzed elimination of H2 from BNC4H12 at 298 K in kcal/mol obtained at the B3LYP/DZVP2 level.
BDE = 28.6 #G(298) = 24.2 #G(Et2O) = 28.2 #G(THF) = 32.8 Keq =1.62x10-18 Keq (Et2O) = 2.14x10-21 Keq (THF) = 9.16x10-25
1
3
2
1
2
3
H2 + BNC4H10 (ring) + BNC4H12 (chain)
-11.9
46.7
10.6
-8.3
0.0
BNC4H12 (ring) + BNC4H12 (chain)
36.8 unimolecular
Bimolecular Mechanism of Thermal H2 Desorption (CBN Cyclohexanes)!
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Kinetic ReactIR Experiments!32
Experiment: Compound B in tetraglyme solution (kinetic studies)
Thermal decomposition is second order with respect to the substrate determined by initial rate kinetics ! consistent with a bimolecular decomposition mechanism.
Activation parameters are also consistent with bimolecular decomposition mechanism:
Ea = 19 kcal/mol A = 2.1 x 107 M-1s-1
# !H‡ = 18 kcal/mol # !S‡ = –32 e.u.
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New “Liquid-Phase” Materials Design with Increased Thermal Stability!
Hypothesis: The formally positively charged NH2 group that is uniquely positioned in compound H is exerting an electron-withdrawing inductive effect that renders the B–H group less hydridic, thus reducing its propensity to release H2.
BH2
NH2
H2BH2N BH2
NH2
BH2
NH2Me
NH3–BH3
entry reaction !H (kcal/mol) !G (kcal/mol)
NH2–BH2– H2
– H2
– H2
– H2
1
2
3
4
BH
NHMe
BHNH
H2BH2N BH
NH
–7.3a (5.1)b
–5.9a
–7.0a
+4.6a
–16.0
–14.3
–15.8
–4.4
a G3MP2. b Feller-Peterson-Dixon composite correlated molecular orbital method.
H2BH2N BH
NH– H2
5HBHN BH
NH –5.7a –14.5
H
33
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Potential New Targets For A Single-Component, Kinetically Stable, Liquid-
Phase Material!
BH2
NH2 + H2BHNH
A
BH2
NH2
FBHNH
F
BH2
NH2
FBHNH
FF F
+ H2
+ H2
reactions !H (kcal/mol) !G (kcal/mol)
G3MP2 energies at 298K.
materials H wt%( –2 H2)
–7.0
–0.7
–1.6
–15.3
–9.0
–10.1
5.6%
4.5%
3.7%
34
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Model Compound X!
Me Me–2 H2
Me Me–3 H2
capacity bp, mp (charged fuel)
bp,mp(spent fuel)
!H(kcal/mol)
6.1 %
3.6 %
bp: +101 °Cmp: –126 °C
bp: ~170 °Cmp: < –35 °C
bp: +111 °C,mp: –95 °C
bp: ~170 °Cmp: < 0 °C
+49
(30)[31]
(): experimental values for the N-tBu derivative (at 333K, solution phase)[]: predicted value at G3(MP2) level (298K, gas phase)
BN
Me
BN
Me–2 H2
X
Me MeX
Recharging will lead to the fully saturated methylcyclohexane!
35
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Regeneration with molecular H2 needs further optimization.
Unoptimized Regeneration of !Compound X from Spent Fuel!
36
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Comparative Thermal Stability in Solution:! AB ~ B < J < H !
37
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Mas
s (%
)
Hea
t Exc
hang
e (m
W/m
g)
-0.6
-0.5
-0.4
-0.3
-0.2
-0.1
0
0.1
0 10 20 30 40 50 60 70 80 90
100
0 50 100 150 200 250
TG DSC
Temperature (oC)
a)
Thermal Stability of H as Neat Material: TGA-DSC
1H and 11B NMR indicated compound H is stable over the endothermic sublimation process.
38
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0
0.5
1
1.5
2
2.5
0 5 10 15 20 25
H2 r
elea
sed
(equ
iv.)
Time (min)
5 mol% cat., RT
0.5 mol% cat., 65 °C Inte
nsity
a) b)
0 50 100 150 200 m/z (amu)
0 50 100
Tetraglyme Compound H in tetraglyme
Rapid Pure H2 Release at Room Temperature
Compound H can be activated to release 4.7 wt% of analytically pure H2 at room temperature in 15 min in the presence of a [Ru] catalyst.
H2N
RuPR2
R2P
NH2
Cl
Cl
R = t-Bu
Cat. = + NaOtBu
39