Battery Storage for Data Centers & Commercial Industry 2026-2036

TABLE OF CONTENTS

1 EXECUTIVE SUMMARY

• 1.1 The C&I BESS market in 2026: why this decade is different
• 1.2 Ten things to know: analyst headline findings
• 1.3 The C&I BESS application universe: scope and definitions
• 1.4 From niche to mainstream: the ~5x growth case for C&I BESS 2026-2036
• 1.5 Technology landscape at a glance: who wins which application
• 1.6 The data center opportunity: AI, power constraints, and the battery response
• 1.7 The US domestic supply chain imperative: OBBBA, 45X, tariffs, and FEOC
• 1.8 Who competes and how: the C&I BESS player landscape
• 1.9 Key risks and uncertainties through 2036

2 THE DATA CENTER POWER CRISIS AND THE BESS RESPONSE

• 2.1 The Scale of the Problem
  • 2.1.1 AI, cloud, and hyperscale: the forces behind unprecedented power demand
  • 2.1.2 The interconnection queue bottleneck: why grid access, not capital, is the constraint
  • 2.1.3 Data center tier classifications and their implications for storage duration and redundancy
  • 2.1.4 The cost of downtime: financial, operational, and contractual exposure
• 2.2 How Battery Storage Answers the Problem
  • 2.2.1 Four distinct roles for BESS at data centers: UPS, load buffering, interconnection enablement, and grid flexibility
  • 2.2.2 Behind-the-meter vs front-of-meter deployments: which model suits which operator
  • 2.2.3 The BESS-as-interconnection-tool model: Aligned Data Centers and Calibrant Energy (31 MW/62 MWh, Oregon)
  • 2.2.4 Managing volatile AI compute loads: charge/discharge strategy and power smoothing
  • 2.2.5 Revenue stacking at a single data center BESS asset: UPS + peak shaving + demand response
  • 2.2.6 Cost-benefit framework and payback modelling for data center BESS
• 2.3 UPS in Depth
  • 2.3.1 UPS system topologies: offline, line-interactive, and double-conversion online - and when each applies
  • 2.3.2 The diesel generator inheritance: why lead-acid VRLA has dominated and why that is changing
  • 2.3.3 Hybrid BESS + diesel generator architectures: transitional configurations in practice
  • 2.3.4 Long-duration UPS (LDUPS): the emerging requirement for multi-hour runtime
  • 2.3.5 Case study: Riello UPS and Itility - Li-ion UPS deployment and operational learnings
  • 2.3.6 Case study: Eaton Corporation - UPS technology portfolio and key hyperscale projects
• 2.4 Alternative and Emerging Battery Technologies for Data Centers
  • 2.4.1 Why Li-ion alone may not be sufficient: thermal risk, degradation under high cycling, and FEOC exposure
  • 2.4.2 Redox flow batteries for high-cycle load buffering and LDUPS: technical case and commercial status
  • 2.4.3 Sodium-ion batteries for data center UPS
  • 2.4.4 Second-life EV batteries for data center applications
  • 2.4.5 Nickel-zinc for data center UPS
  • 2.4.6 Long-duration technologies at the data center frontier
  • 2.4.7 Technology adoption trajectory for data center BESS: 2026, 2030, and 2036 snapshots
• 2.5 Key Projects, Deals, and Market Developments (2024-2026)

3 COMMERCIAL & INDUSTRIAL BATTERY STORAGE: APPLICATIONS BEYOND DATA CENTERS

• 3.1 Telecommunications Base Stations
  • 3.1.1 Network generations and their energy signatures: from 2G macro towers to 6G dense networks
  • 3.1.2 Battery storage in telecom: the UPS baseline and the expanding value case
  • 3.1.3 US legal requirements for backup power at telecommunications infrastructure
  • 3.1.4 LFP vs NMC at base stations: temperature tolerance, cycle life, and total cost comparison
  • 3.1.5 The digital upgrade cycle: intelligent BMS and remote monitoring at telecom sites
  • 3.1.6 Sodium-ion for base station backup: Highstar's LFP vs Na-ion production positioning
  • 3.1.7 Second-life EV batteries for telecom backup: commercial viability and key deployments
  • 3.1.8 The 6G-driven demand wave in China: macro tower deployment and storage implications
• 3.2 EV Charging Infrastructure
  • 3.2.1 The DC fast charging grid bottleneck: how utility upgrade timelines strangle DCFC deployment
  • 3.2.2 How battery-buffered EV charging works: power flow, sizing logic, and cycle profile
  • 3.2.3 Infrastructure-as-a-Service (IaaS) for off-grid fast charging: business model and economics
  • 3.2.4 Megawatt charging and the next generation of BESS requirements: BYD Super-e platform
  • 3.2.5 Key projects: FEV Mobile Fast Charging, E.ON Drive Booster, Jolt MerlinOne
• 3.3 Construction, Agriculture & Mining (CAM)
  • 3.3.1 The electrification case for CAM: TCO, emissions regulation, and operational efficiency
  • 3.3.2 Electric construction vehicles: current fleet composition and battery size implications for site BESS
  • 3.3.3 Agricultural vehicle electrification: tractor, combine, and ancillary fleet - BESS at farm sites
  • 3.3.4 Mining vehicle electrification: underground vs surface fleet and implications for mine-site BESS
  • 3.3.5 Portable and modular BESS for off-grid and remote CAM operations
  • 3.3.6 Case study: C&I BESS in Indonesia's mining industry - Schneider Electric project insights
  • 3.3.7 Case study: Turntide Technologies module supply for JCB portable battery storage
• 3.4 Factories, Hospitals, Communities & Other C&I Applications
  • 3.4.1 The broader C&I BESS universe: who buys, why, and at what scale
  • 3.4.2 Microgrids: architecture, motivations, ownership models, and BESS role
  • 3.4.3 Microgrid case studies: Schneider Electric key projects
  • 3.4.4 Time-of-use (TOU) arbitrage and demand charge reduction: mechanics, economics, and limits
  • 3.4.5 Peak shaving: demand charge reduction and payback modelling for commercial facilities
  • 3.4.6 Critical facility backup: hospitals, emergency services, and disaster relief BESS

4 BATTERY STORAGE TECHNOLOGIES FOR C&I APPLICATIONS

• 4.1 Technology Landscape Overview
  • 4.1.1 The C&I technology universe: from established to emerging
  • 4.1.2 Benchmarking: methodology and weighting
  • 4.1.3 Technology demand split by chemistry 2025-2036 (%)
• 4.2 Lithium-Ion: LFP and NMC
  • 4.2.1 The LFP vs NMC decision: how application requirements drive chemistry choice
  • 4.2.2 Li-ion battery family tree: cathode chemistry variants and their C&I relevance
  • 4.2.3 C&I Li-ion BESS product benchmarking: key manufacturer system specifications compared
  • 4.2.4 C&I Li-ion BESS cost breakdown by component: 2025 baseline
  • 4.2.5 Li-ion C&I BESS cost evolution to 2036: component-level projections
  • 4.2.6 The US domestic LFP supply chain: context, urgency, and current state
  • 4.2.7 OBBBA, FEOC restrictions, and MACR thresholds: what they mean for C&I BESS buyers and suppliers
  • 4.2.8 45X Manufacturing Production Tax Credit and Section 48 ITC: quantitative analysis for C&I BESS
  • 4.2.9 LFP cost model: US domestic cell (with 45X) vs Chinese import cell (with tariffs), 2026 and beyond
• 4.3 Redox Flow Batteries
  • 4.3.1 RFB operating principle: how power and energy are decoupled and why that matters for C&I
  • 4.3.2 Vanadium RFB: performance profile, cost structure, and C&I application fit
  • 4.3.3 RFB vs Li-ion for C&I: where the economics cross over by application and duration
  • 4.3.4 RFB project database 2023-2025: C&I vs grid-scale by MWh and application
  • 4.3.5 Organic and all-iron RFBs: technical differentiation and C&I deployment examples
• 4.4 Sodium-Ion Batteries
  • 4.4.1 Na-ion fundamentals: why the chemistry is attracting C&I interest now
  • 4.4.2 Na-ion performance appraisal: honest assessment of strengths, weaknesses, and remaining gaps
  • 4.4.3 Na-ion cost trajectory vs LFP: when does it compete?
  • 4.4.4 Na-ion for stationary C&I storage: current deployments and near-term pipeline
  • 4.4.5 Key players
• 4.5 Second-Life Electric Vehicle Batteries
  • 4.5.1 The second-life value chain: from OEM return to C&I BESS deployment to end-of-life recycling
  • 4.5.2 State-of-health screening and repurposing economics: what makes a pack viable
  • 4.5.3 Key deployments and lessons
  • 4.5.4 Risks: SoH variability, warranty gaps, fire risk, and regulatory uncertainty
• 4.6 Zinc-Based and Niche Alternative Chemistries
  • 4.6.1 Nickel-zinc (Ni-Zn): non-flammable UPS credentials and data center case
  • 4.6.2 Zinc-bromine (Zn-Br): Eos Energy Z3 - technology profile, DOE loan, and C&I/industrial target markets
  • 4.6.3 Vanadium-ion batteries
  • 4.6.4 Lead-acid (VRLA): residual role, ongoing displacement, and applications where it remains relevant

5 US MANUFACTURING, POLICY & SUPPLY CHAIN

• 5.1 The domestic manufacturing imperative: why policy is reshaping the US C&I BESS supply chain
• 5.2 The One Big Beautiful Bill Act (OBBBA): full provisions and C&I BESS implications
• 5.3 45X Manufacturing Production Tax Credit: who qualifies, at what value, and how it changes LFP economics
• 5.4 Section 48 Investment Tax Credit (ITC): eligibility, stacking with 45X, and C&I project economics
• 5.5 FEOC restrictions and MACR thresholds: which Chinese suppliers are affected and by when
• 5.6 Tariff analysis
• 5.7 US LFP cell manufacturing build-out: plant-by-plant tracker
• 5.8 European policy context: EU Battery Regulation, CBAM, and net metering updates
• 5.9 China industrial policy: local content, 6G-linked BESS stimulus, and state-owned enterprise activity

6 COMPETITIVE LANDSCAPE & PLAYER STRATEGY

• 6.1 The C&I BESS competitive structure: incumbents, integrators, and disruptors
• 6.2 How Chinese OEMs (CATL, BYD, Huawei, Gotion, Sungrow) are approaching C&I markets outside China
• 6.3 Western system integrators and UPS incumbents: Eaton, Schneider Electric, Saft, Mitsubishi - how they are adapting
• 6.4 Emerging C&I specialists: how start-ups are carving out niches in data centers, second-life, and flow batteries
• 6.5 Key strategic partnerships, JVs, and M&A activity 2024-2026
• 6.6 Business model evolution: from product sales to energy-as-a-service and outcome-based contracts

7 MARKET FORECASTS 2025-2036

• 7.1 Methodology and Assumptions
  • 7.1.1 Forecast scope: applications, geographies, metrics, and time horizon
  • 7.1.2 Bottom-up methodology: application-level demand drivers and inputs
  • 7.1.3 Scenario definitions: base case, accelerated adoption, and conservative
• 7.2 Global Demand by Application (GWh)
  • 7.2.1 Global C&I BESS demand by application, 2025-2036 (GWh)
  • 7.2.2 Data center BESS demand by region, 2025-2036 (GW and GWh)
  • 7.2.3 Telecom base station BESS demand: 5G vs 6G split, 2025-2036 (GWh)
  • 7.2.4 EV charging BESS demand, 2025-2036 (GWh)
  • 7.2.5 CAM BESS demand, 2025-2036 (GWh)
  • 7.2.6 Other C&I BESS demand, 2025-2036 (GWh)
  • 7.2.7 Application share shift: 2026, 2031, and 2036 compared
• 7.3 Global Demand by Region (GWh)
  • 7.3.1 China, 2025-2036 (GWh)
  • 7.3.2 United States, 2025-2036 (GWh)
  • 7.3.3 Europe, 2025-2036 (GWh)
  • 7.3.4 Rest of World, 2025-2036 (GWh)
• 7.4 Market Value by Application and Region (US$B)
  • 7.4.1 Global C&I BESS market value by application, 2025-2036 (US$B)
  • 7.4.2 Global C&I BESS market value by region, 2025-2036 (US$B)
• 7.5 Technology Demand Outlook (% GWh)
  • 7.5.1 C&I BESS technology mix evolution, 2025-2036

8 COMPANY PROFILES

• 8.1 Lithium-Ion System Integrators and OEMs 131 (19 company profiles)
• 8.2 Power Management, UPS & System Integration Specialists (4 company profiles)
• 8.3 Redox Flow Battery Players 159 (30 company profiles)
• 8.4 Sodium-Ion and Alternative Chemistry Players (13 company profiles)
• 8.5 Sodium-Sulfur Batteries (1 company profile)
• 8.6 Liquid Metal Batteries (1 company profile)
• 8.7 Advanced Lead-Acid 219 (1 company profile)
• 8.8 Second-Life EV Battery Players (8 company profiles)
• 8.9 Niche Chemistries: Zinc and Nickel (4 company profiles)
• 8.10 Battery Analytics, BMS & Enabling Technology Providers (4 company profiles)
• 8.11 Specialist Deployers & Infrastructure Players (13 company profiles)

9 REFERENCES

List of Tables

• Table 1. Ten headline findings: topic, finding, and page reference
• Table 2. C&I BESS technology scorecard: application fit by chemistry (LFP, NMC, Na-ion, RFB, VRLA, second-life, Ni-Zn, Zn-Br)
• Table 3. US data center electricity demand as % of national grid load, 2020-2030 forecast
• Table 4. Average US grid interconnection wait time by load category, 2018-2025 (months)
• Table 5. Data center tier standards (I-IV): uptime requirement, storage duration, and UPS specification
• Table 6. Cost of unplanned downtime by data center type and sector (US$/hour), 2025 estimates
• Table 7. Four BESS roles at data centers: schematic showing where each sits in the facility power architecture
• Table 8. BTM vs FTM BESS at data centers: ownership, revenue streams, grid relationship, and example projects
• Table 9. Revenue stack waterfall: annualised value (US$/MWh installed) by service layer for a data center BESS asset
• Table 10. Data center BESS cost-benefit model: input assumptions, NPV, IRR, and payback period by use case
• Table 11. UPS runtime requirements by data center tier and grid reliability scenario (minutes to hours)
• Table 12. Li-ion limitations in data center contexts: issue, severity, and mitigation strategies
• Table 13. RFB vs Li-ion cycle degradation comparison: capacity retention over 10,000 cycles
• Table 14. Data center battery technology comparison: energy density, cycle life, flammability, US supply chain status, indicative cost (US$/kWh), and TRL
• Table 15. Key data center BESS projects 2024-2026: operator, technology provider, location, capacity (MW/MWh), application, and status
• Table 16. Li-ion technology comparison for telecom UPS: LFP vs NMC across key operational parameters
• Table 17. Global telecom BESS demand forecast by region and network generation, 2025-2036 (GWh)
• Table 18. 6G rollout timeline by region and estimated BESS demand per tower type (kWh)
• Table 19. IaaS vs capex-owned battery-buffered charging: cost structure, risk allocation, and payback
• Table 20. MW charging connector standards comparison: MCS, ChaoJi, and GB/T - power level, geography, and adoption timeline
• Table 21. Battery-buffered EV charging project database: operator, location, BESS capacity, technology, and status
• Table 22. Electrification drivers and barriers by CAM sector: construction vs agriculture vs mining
• Table 23. Electric construction vehicle taxonomy: machine type, battery capacity range, and BESS site charging demand
• Table 24. CAM BESS project database: location, application, BESS size (kWh/MWh), technology, and operator
• Table 25. CAM BESS demand forecast by sector, 2025-2036 (GWh)
• Table 26. C&I BESS application matrix: sector, primary value stream, typical system size, and preferred technology
• Table 27. Microgrid ownership model comparison: utility-owned vs community vs developer-owned
• Table 28. Microgrid case study database: location, scale, technology, owner, and BESS provider
• Table 29. Arbitrage ROI analysis by region: electricity price spread, BESS size, cycle frequency, and payback period
• Table 30. C&I BESS technology landscape: readiness, cost, and application coverage overview
• Table 31. C&I BESS technology demand mix, 2025-2036
• Table 32. Master C&I BESS technology benchmarking table: energy density, power density, cycle life, round-trip efficiency, safety rating, indicative 2025 cost (US$/kWh), and application fit score by segment
• Table 33. LFP vs NMC head-to-head: energy density, thermal stability, cost, cycle life, and preferred C&I application
• Table 34. C&I Li-ion BESS product benchmarking: manufacturer, system energy density (Wh/L), round-trip efficiency, cycle life warranty, cooling approach, and form factor
• Table 35. Li-ion C&I BESS cost breakdown (US$/kWh): cells, BMS, PCS, thermal management, fire protection, housing - 2025, high power (0.5 h) vs high energy (4 h)
• Table 36. US LFP cell manufacturing capacity: installed and announced capacity by year (GWh/year), 2024-2030
• Table 37. US LFP cell manufacturing plants for ESS: company, location, planned capacity (GWh/year), investment, status, and target market
• Table 38. OBBBA and FEOC rules: provision, eligibility threshold, effective date, and impact on LFP sourcing decisions
• Table 39. 45X credit value (US$/kWh) at different US LFP cell production cost levels
• Table 40. LFP cost model detail: Opex, Capex, tariff rate, 45X credit, and net delivered cost - opportunity window analysis
• Table 41. VRFB strengths and weaknesses: energy density, cycle life, temperature range, scalability, cost, and supply chain risk
• Table 42. RFB vs Li-ion LCOS (US$/MWh) crossover by storage duration (2h, 4h, 8h, 12h): 2025 and 2030
• Table 43. RFB project database 2023-2025: location, capacity (MWh), chemistry variant, application, developer, and status
• Table 44. RFB chemistry variant comparison: vanadium, iron-iron, organic, zinc-bromine - cost target, maturity, and C&I suitability
• Table 45. Na-ion performance appraisal: parameter, current status vs LFP, expected improvement by 2030
• Table 46. Second-life BESS economics: SoH threshold, repurposing cost, installed cost (US$/kWh) vs new LFP - 2025 and 2030 estimates
• Table 47. Second-life BESS deployment database: company, location, capacity (kWh/MWh), source battery chemistry, application, and year commissioned
• Table 48. Ni-Zn vs LFP for data center UPS: energy density, cycle life, safety, cost, and footprint
• Table 49. Alternative and niche chemistry summary: Ni-Zn, Zn-Br, V-ion, VRLA - technology specs, TRL, key player, and C&I applications
• Table 50. OBBBA provisions relevant to C&I BESS: rule, description, effective date, and practical impact
• Table 51. FEOC-restricted entity list implications for C&I BESS procurement: affected cells, modules, timeline
• Table 52. LFP cost model: detailed OpEx/CapEx breakdown under five tariff and tax credit scenarios - opportunity window analysis
• Table 53. US LFP cell manufacturing facilities for ESS: company, location, nameplate capacity (GWh/year), investment, status, expected first production, and 45X eligibility
• Table 54. US LFP ESS manufacturing capacity build-out: cumulative GWh/year by year, 2024-2030
• Table 55. Chinese BESS OEM C&I strategy comparison: target geographies, product lines, channel approach, and differentiators
• Table 56. Start-up and scale-up landscape: technology vs. maturity vs. funding raised (bubble chart)
• Table 57. Notable C&I BESS partnerships, acquisitions, and JVs: parties, rationale, date, and strategic significance
• Table 58. Forecast methodology summary: driver variable, data source, and bottom-up logic by application
• Table 59. Scenario assumptions: key variable, base case value, upside assumption, downside assumption
• Table 60. Global C&I BESS demand by application: 2025-2036 (GWh)
• Table 61. Forecast data table: global C&I BESS demand by application, 2025-2036 (GWh, annual)
• Table 62. Forecast data table: data center BESS demand by region, 2025-2036 (GW and GWh, annual)
• Table 63. Telecom BESS demand: 5G vs 6G technology split, 2025-2036 (GWh)
• Table 64. Forecast data table: telecom BESS demand by network generation, 2025-2036 (GWh)
• Table 65. EV charging BESS demand forecast, 2025-2036 (GWh)
• Table 66. Forecast data table: EV charging BESS demand by region, 2025-2036 (GWh)
• Table 67. CAM BESS demand forecast by sector, 2025-2036 (GWh)
• Table 68. China C&I BESS demand by application, 2025-2036 (GWh)
• Table 69. Forecast data table: US C&I BESS demand by application, 2025-2036 (GWh)
• Table 70. Forecast data table: Europe C&I BESS demand by application, 2025-2036 (GWh)
• Table 71. Forecast data table: RoW C&I BESS demand by application, 2025-2036 (GWh)
• Table 72. Forecast data table: global C&I BESS market value by application, 2025-2036 (US$B)
• Table 73. Forecast data table: global C&I BESS market value by region, 2025-2036 (US$B)
• Table 74. Forecast data table: C&I BESS technology demand split by application and year (GWh and %)
• Table 75. HiNa Battery sodium-ion battery characteristics.

List of Figures

• Figure 1. C&I BESS application map: segments, sub-applications, and illustrative end-users
• Figure 2. Global C&I BESS demand forecast summary, 2025-2036 (GWh, by application)
• Figure 3. Global C&I BESS market value forecast summary, 2025-2036 (US$B, by application)
• Figure 4. C&I BESS competitive landscape map: player type, technology, and primary application
• Figure 5. Interconnection timeline comparison: traditional utility upgrade vs BESS-enabled grid connection (illustrative, months)
• Figure 6. AI workload power demand profile: MW-scale fluctuations and BESS buffering simulation
• Figure 7. Revenue stack waterfall: annualised value (US$/MWh) by service layer for a data center BESS asset
• Figure 8. VRLA vs Li-ion UPS 10-year total cost of ownership (US$/kW installed): capex, opex, and replacement
• Figure 9. BESS-diesel hybrid UPS architecture diagram for a hyperscale facility
• Figure 10. Second-life EV battery repurposing pipeline: from OEM return -> State-of-health screening -> BESS integration
• Figure 11. Battery technology share at data centers by GWh: 2026, 2030, 2036
• Figure 12. Energy consumption per base station by network generation: 2G through 6G (kW per site)
• Figure 13. Telecom BESS technology mix evolution: 2025 vs 2036 (stacked bar, % share)
• Figure 14. DCFC deployment constraint diagram: utility upgrade timeline vs battery-enabled fast-track (illustrative months)
• Figure 15. Battery-buffered EV charging system architecture: grid connection, BESS, charger, and vehicle
• Figure 16. MW charging BESS architecture: grid, storage, and charger integration at scale
• Figure 17. Mine-site BESS deployment model: renewable generation, storage, and electric fleet charging architecture
• Figure 18. CAM BESS demand forecast by sector, 2025-2036 (GWh)
• Figure 19. Microgrid system architecture
• Figure 20. TOU arbitrage charge/discharge schedule vs electricity price curve (illustrative)
• Figure 21. Li-ion battery chemistry family tree: from LCO to LFP, NMC, NCA, and LNMO
• Figure 22. Li-ion C&I BESS cost breakdown (US$/kWh): 2036 projection, high power vs high energy - compared against 2025 baseline
• Figure 23. Final LFP cell cost comparison: US-made vs Chinese import under tariff scenarios, 2026-2030 (US$/kWh)
• Figure 24. RFB system architecture schematic
• Figure 25. Na-ion vs LFP: key property comparison (radar chart) - energy density, cost, low-temperature performance, safety, cycle life
• Figure 26. Na-ion vs LFP cell cost (US$/kWh) forecast: 2025-2036 with projected crossover range
• Figure 27. Second-life EV battery value chain: stages, actors, and value capture points
• Figure 28. Second-life BESS installed cost range vs new Li-ion BESS, 2025 (US$/kWh): median, P10, P90
• Figure 29. VRLA market share trajectory in C&I BESS: declining % of new installations, 2020-2036
• Figure 30. US C&I BESS supply chain map: Chinese-dominated baseline vs emerging domestic alternatives
• Figure 31. 45X credit benefit (US$/kWh) by manufacturing cost scenario
• Figure 32. Net LFP cell cost (US$/kWh): Chinese import under tariff scenarios vs US-made with 45X credit, 2026-2030
• Figure 33. C&I BESS value chain: cell manufacturer -> system integrator -> EPC -> O&M -> end-user
• Figure 34. Global C&I BESS demand by application: 2025-2036 (GWh)
• Figure 35. EV charging BESS demand forecast, 2025-2036 (GWh)
• Figure 36. C&I BESS demand share by application: 2026 vs 2031 vs 2036
• Figure 37. Forecast data table: global C&I BESS market value by application, 2025-2036 (US$B)
• Figure 38. Samsung SDI's sixth-generation prismatic batteries.
• Figure 39. Rongke Power 400 MWh VRFB.
• Figure 40. Schematic of the quinone flow battery.
• Figure 41. HiNa Battery pack for EV.
• Figure 42. JAC demo EV powered by a HiNa Na-ion battery.
• Figure 43. Kite Rise's A-sample sodium-ion battery module.
• Figure 44. Peak Energy's sodium-ion storage system at SolarTAC in Colorado.
• Figure 45. Schematic diagram of liquid metal battery operation.