update on electrolyte modeling with emphasis on low ......salt molality 0.0 0.5 1.0 1.5 2.0 2.5 n e...
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![Page 1: Update on Electrolyte Modeling with Emphasis on Low ......Salt Molality 0.0 0.5 1.0 1.5 2.0 2.5 N e t Li thium D e o lv ati on Ener g y, k J /mol e 500 550 600 650 700 750 800 30 oC](https://reader033.vdocuments.us/reader033/viewer/2022041507/5e25d267d4f9d17c7a6157e9/html5/thumbnails/1.jpg)
Kevin L Gering, PhD
DOE-OVT Merit Review MeetingFebruary 26, 2008 (Bethesda, MD)
This presentation does not contain proprietary or confidential information
Update on Electrolyte Modelingwith Emphasis on
Low Temperature Performance
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ScopeScope
Barriers
Li-ion batteries generally undergo a marked decrease in performance at low temperatures, and the root causes have been difficult to pinpoint using conventional methods. This performance limitation prevents this technology from being fully deployed in HEV/PHEV applications for cold climate scenarios.
Approach
This work is based on the capabilities of the Advanced Electrolyte Model (AEM), developed under the DOE-ATD program. Foundations of the AEM include molecular-scale chemical physics, ion solvation, and accurate thermodynamics. The AEM delivers state-of-the-art predictions of numerous key properties useful for electrolyte characterization, screening, optimization, and transport modeling.
Purpose
To gain further understanding of how performance of Li-ion batteries depends on molecular-scale behavior of electrolytes at cycling conditions, particularly at low temperatures. This is done to identify failure mechanisms related to the battery electrolyte.
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Summary of AEM CapabilitiesSummary of AEM Capabilities
In concert, these elements provide a sound basis for electrolytecharacterization, screening and optimization for numerous applications.
Chemical Physics and Molecular
Scale Properties (e.g., ion solvation)
Derived Parameters Custom Designed for Specific Studies(e.g., low-temperature performance)
Large Scale Simulations for
Electrolyte Optimization
Thermodynamic Properties
(osmotic and activity coefficients, partial molar
properties, etc.)
Transport Properties(viscosity, conductivity, diffusivity, etc.)
Chemical and Physical Quantities
INL Advanced Electrolyte
Model
Key properties are generally predicted to within 5-10 % of experimental values over wide ranges of T and composition.
Many predictions reach agreement to within 5 percent or less.
New in 2007: used inTransport Modeling
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Technical Milestones in 2007Technical Milestones in 2007
1. Developed self-consistent method for determination of net and ligand-wise lithium ion desolvation time and energy
2. Developed framework for modeling binary salt systems
3. Modeled electrolytes having a fluorinated solvent (mFEC)
4. Developed infrastructure for applying the AEM to cell-level transport modeling (e.g., double layer (DL) and separator regions)
5. Developed the theoretical framework for predicting how pulse conditions alter the effective transport properties of electrolyte species (ionic conductance, transference number, etc.)
6. Investigated how separator porosity affects colligative properties of the electrolyte during a pulse.
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Lithium DesolvationLithium Desolvation-- general process general process --
Lithium desolvation involves the breaking of successive solvent-Li+ligands, resulting in ligand-specific binding energies and desolvation times.
??
Lithium Anion Solvent
BE4Δt4
BE3Δt3
BE2Δt2
BE1Δt1
Is Li+ more susceptible to forming ion pairs as it becomes desolvated? Yes, if counter-transport of the anion is hampered by poor mass transport conditions (e.g., low temperature). This could further impact performance.
Net Energy Barrier = ΣBEi , where BE4 < BE3 < BE2 < BE1
Net Desolation Time = ΣΔti , where Δt4 < Δt3 < Δt2 < Δt1
For a starting Li+solvation number of four:
∴ There are kinetic and thermodynamic costs to lithium desolvation.
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Lithium Desolvation Lithium Desolvation -- sample results from AEM sample results from AEM --
Li+ desolvation time and energy show similar trends over temperature and salt concentration, although they are obtained independently. These results indicate that step-wise lithium desolvation becomes more problematic at low temperatures and lower salt concentrations.
Net Time Required for Step-wise Lithium DesolvationGen2 Electrolyte EC:EMC (3:7) + 1.2M LiPF6
(Chemical Kinetics Basis = 1st Order)
Salt Molality
0.0 0.5 1.0 1.5 2.0 2.5
Net
Lith
ium
Des
olva
tion
Tim
e, n
s
2.0
2.5
3.0
3.5
4.0
4.5
5.0
30 oC
0 oC
-30 oC
60 oC
Net Energy Required for Step-wise Lithium DesolvationGen2 Electrolyte EC:EMC (3:7) + 1.2M LiPF6
Salt Molality
0.0 0.5 1.0 1.5 2.0 2.5
Net
Lith
ium
Des
olva
tion
Ene
rgy,
kJ/
mol
e
500
550
600
650
700
750
800
30 oC
0 oC
-30 oC
60 oC
Note: a given net energy value would be spread over the span of net desolvation time.
Values decrease over salt conc. due to diminishing lithium solvation at higher conc.
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MixedMixed--Salt Electrolytes Salt Electrolytes -- new modeling capability new modeling capability --
Benefits in transport properties and SEI formation can be realized by using mixed salt electrolytes, just as mixed solvents are seen as necessary for contemporary electrolyte systems.
The AEM now has the capability to characterize and optimize mixed-salt (binary), multi-solvent electrolytes. Taking six of the salts from the AEM library:
LiBF4
LiBOB LiTFSI
Li2B12F12 LiClO4
LiPF6 ( )1 15 pair combinations( 1)2
n n =−
The approach is based on molar averaging of key molecular-scale quantities.
This new capability opens up a new frontier in electrolyte development and screening.
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MixedMixed--Salt Electrolytes Salt Electrolytes -- sample results from AEM sample results from AEM --
Conductivity Comparison
Salt molality
0.0 0.5 1.0 1.5 2.0
Con
duct
ivity
, mS/
cm
0.0
0.5
1.0
1.5
2.0
- 35 oC
Viscosity Comparison (log scale)
Salt molality
0.0 0.5 1.0 1.5 2.0
Vis
cosi
ty, c
P
10
100
LiPF60.5LiPF6 + 0.5LiBF4LiBF4
- 35 oC LiPF60.5LiPF6 + 0.5LiBF4LiBF4
Comparison of Single and Mixed-Salt Electrolytes (Solvent = GBL)
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System
Lithium Solvation Number
Solvent-Lithium Binding Energy
(kJ/mole)
Activation Energy for lithium desolvation (kJ/mole)
Net Lithium Desolvation Time (ns)*
EC + 1 M LiPF6 3.90 477.5 30.0 1.6
mFEC + 1 M LiPF6
3.43 426.0 24.5 1.0
Difference -12.0% -10.8% -18.3% -37.5% These AEM results at 30 °C clearly show an advantage using mFEC regarding lithium solvation quantities. Such advantages will impact charge transfer resistances at critical interfacial regions. In practice, mFEC would be added in small amounts (5-20%) to conventional electrolytes.
Lithium DesolvationLithium Desolvation-- monomono--fluoroEC vs EC SystemsfluoroEC vs EC Systems --
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Transport Modeling of ElectrolytesTransport Modeling of Electrolytes
The AEM accounts for:
Continuity expressions for all mobile species in a given electrolyte (single cations and anions, solvent, ion pairs, and triple ions (ABA,BAB)) over (x,t).
Diffusion of all electrolyte species,
Diffusion potential,
The effects of ion solvation on solvent co-transport, and how this changes with species velocities,
Explicit consideration of intrinsic lithium desolvation kinetics,
Electrolyte properties for conditions of non-electroneutrality,
Limiting packing fractions of electrolyte species,
Considers a fine matrix of spatial dimension in x versus pulse time,
Calculates current, resistance, net charge delivered, etc. over (x,t).
Pulse type: − constant potential or constant current− charge or discharge− duration and magnitude.
And More
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Solvation Sheath
x
At thermodynamic equilibrium Under pulse conditions
Apply voltage potential
Solvation region around ion is at maximum value, and
Solvation region diminishes under transport conditions, and
Faradaic transport of ions results in alterations to their solvation environment, which will affect key transport properties linked to battery performance.
j j
The AEM determines the shift in transport properties due to the Faradaic transport of all charged species.
oj,x j, x
os, j s, j
oj j
oj j
0v v
n n
t t
= =
=
λ = λ
=
eff oj,x j,x j,x
eff os, j s, j s, j
eff oj j j
eff oj j j
v v v
n n n
t t t
= ≠
= ≠
λ = λ ≠ λ
= ≠
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Results for Gen2 Chemistry, Electrolyte = EC:EMC (3:7) + 1.2M LiPF6
Concentration Profiles (normalized to time zero values) After 1-second Constant Current Discharge Pulse (0.1 mA/cm2)
Distance from Edge of Anode, nm0 10 20 30 40 50
Cj'
0
1
2
3
4
5
6
7
Li+
PF6-
SolventCollective Ion PairsABA+-type Triple IonsBAB--type Triple IonsEffective Conductivity
Distance from Edge of Cathode, nm
01020304050
Cj'
0.0
0.5
1.0
1.5
2.0
- 30 oC
Distance from Edge of Anode, nm0 10 20 30 40 50
Cj'
0
5
10
15
20
Distance from Edge of Cathode, nm
01020304050
Cj'
0.0
0.5
1.0
1.5
2.0
30 oC
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Li+
etc., into rest of separator
Looking at a small cross-section at one face of the separator
At rest
Under pulse conditions
Apply voltage potential
FreeElectrolyte
Only cations are shown, for clarity Pore dimensions are not to scale
Upon starting a pulse, there is an enrichment of ions along the face of the separator as the ion flux from the free electrolyte region enters the separator an encounters a restricted volume. The result is a funneling or bottleneck effect that increases the local concentration of ions, which will have a profound effect on local properties such as viscosity and conductivity.
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Electrolyte Properties In Separator, per AEMElectrolyte Properties In Separator, per AEM
Gen2 Electrolyte Resistivity for Enrichment of Bulk Salt at Separator Edge at Start of Discharge
1/T, K-1
0.0030 0.0032 0.0034 0.0036 0.0038 0.0040 0.0042
Res
istiv
ity, (
mS
/cm
)-1
10-1
100
101 1.2 M (baseline electrolyte)Celgard 2500:2.18 M Li+and PF6
Celgard 2325:3.0 M Li+ and PF6
Inflection occurs ataround -3 oC
Ea = XXX kJ/mole
Separators Studied:
Celgard 2500 (P = 0.55)Celgard 2325 (P = 0.40)
Lower porosity separators result in higher electrolyte resistivity at their faces.
Note that electrolyte phase transitions are more likely at the higher molarities at low T.Electroneutral Case
Gen2 Electrolyte:
EC:EMC (3:7) + 1.2M LiPF6
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Summary / ConclusionsSummary / Conclusions1. Li-ion desolvation is a process whose kinetics and thermodynamics is modeled by the
AEM and utilized in transport calculations.
2. In addition to mixed solvent systems, the AEM can now model mixed salts and was extended to include fluorinated solvents, which will allow many contemporary electrolytes to be screened and characterized.
3. The AEM transport model accounts for how ionic and bulk electrolyte properties are altered due to the effective ionic migration under the pulse conditions. More severe pulse conditions will intensify this effect.
4. It appears Faradaic co-transport of solvent with ions becomes more problematic for cellperformance at low temperatures due to more stable Li+-solvent interactions, slower Li+desolvation kinetics, and lowered solvent diffusivity.
5. Modeling of electrolyte properties in lower-porosity separators confirmed that high local impedance can exist at low T, due to ionic flux limitations and non-electroneutrality that can emerge at the separator faces. Higher-porosity separators can alleviate part of such limitations.
6. Thus, the AEM provides an advantage in that it produces accurate local electrolyte properties, spanning between the electrodes, without the need for oversimplifying assumptions that can render invisible the true root causes of performance limitations tied to the electrolyte.
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Future WorkFuture Work
Continue modeling novel candidate electrolytes of interest to ATD (e.g., explore mixed-salt systems and fluorinated solvents of potential benefit to ATD).
Investigate the role of porosity and tortuosity within interfacial regions as it pertains to SEIs, double-layers, and the separator.
Provide results and conclusions from AEM transport model for relevant test chemistries.
Perform experiments that will confirm root causes of diminished cell performance at low temperatures, e.g., separator experiments.
Publish.
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OtherOther
Technology Transfer
DOE-ATD meetings provide some level of technology transfer between participants. AEM capabilities have served the private sector through the INL work-for-others program and ATD-relevant collaborations. Publication of this work will also serve as a technology transfer mechanism.
Publications / Patents / Presentations
Several peer-reviewed manuscripts are planned for this work, with some under preparation.
Presentations:K. L. Gering, Modeling the Thermodynamic and Kinetic Costs of Lithium Ion Desolvation, ECS 2007 Fall Meeting.K. L. Gering, Molecular-Based Modeling of the Thermodynamic and Kinetic Costs of Ion Desolvation (Regarding
The Commercial Application Of Lithium-Ion Batteries), AIChE 2007 Fall Meeting.
Response to Previous Review Comments
The previous merit review of this work occurred in FY 06. Relevant comments that followed the intent and scope of the work were considered and adopted as feasible (e. g., determine root causes, model transport at the interface).
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AcknowledgementsAcknowledgements
• Tien Duong and David Howell, DOE-ATD Program
• Office of Vehicle Technologies
• Dennis Dees, ANL
• Andrew Jansen, ANL
• Tim Murphy, INL
This work was performed for the
United States Department of Energy
under contract DE-AC07-05ID14517.
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Supplemental InformationSupplemental Information
This material will not be presented
For Reviewer Reference Only
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Ion Solvation Quantities
(via chemical physics equation of state)
• HS and effective transport diameters of cation and anion as f(comp., T):
, e ffH Sj jσ σ
• Solvation numbers: ns+, ns- • Solvent residence times: τ+, τ−
Transport Properties (molecular basis)
• Viscosity: η • Conductivity: κ • Diffusivity: D • Transference Number : t+
etc.
Thermodynamic Properties(Associative MSA basis)
• Activity Coefficient: γ± • Osmotic Coefficient: φm • Ion Pair Formation (CIP, SSIP) • Triple Ion Formation • Onset of solid solvates
Energy, Dielectric Quantities(Molecular, Thermodynamic bases)
• Gibbs free energy of ion solvation• Solvent-to-ion Binding Energy for
cation and anion • Relative enthalpy • Dielectric Depression
AEM Approach and OverviewAEM Approach and Overview