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Long Duration Energy Storage LDES Reality: Materials, Equipment Markets in 35 Lines, Technology Roadmaps, Manufacturers, Winners, Losers, Alternatives 2024-2044

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    Report

  • 492 Pages
  • December 2023
  • Region: Global
  • Zhar Research
  • ID: 5670740

LDES Market Insights: Winners, Losers, and a $10 Billion Business Blueprint for Investors and Industry Players

At last, a report estimating what will happen with LDES not what special interest groups want to happen. A report that estimates winners and losers when research groups and trade associations must back their members. Such independent information is essential to those seeking to invest in LDES, supply materials, devices or otherwise participate in the LDES supply chain. Yes, this report even takes a close look at your value-added materials opportunities. Uniquely, it surfaces alternatives and impediments to LDES and all on the 20-year timescale necessary to really understand where we are headed. Alternatives include less-intermittent forms of solar and wave power, arriving tidal stream and other green generation with no long duration intermittency and grids spanning weather and time zones but there is more. This data-driven analysis still comes up with a large figure for the LDES market. It has the detail and information to correctly position your creation of a $10 billion LDES business, avoiding the traps, knowing the lessons of past failures. The author has already created several successful businesses and he has a Physics PhD in the subject.

The Executive summary and conclusions at 40 pages is sufficient in itself, giving definitions, background, success so far, infograms, technology and market roadmaps and 35 forecasts 2024-2044. Absorb lessons from recent investment in the LDES companies, technology toolkit, different needs for grid vs beyond-grid, gaps in the market, even projected technology and company winners and losers on current evidence.

The introduction, at 49 pages, gives the background including the solar and beyond-grid megatrends, many LDES alternatives that will limit, not eliminate the opportunity. Indeed, learn why these realistic LDES forecasts will make stationary storage become a larger value market that mobile storage. Understand Levelised Cost of Storage LCOS and many time-related parameters for storage. Here are the LDES alternatives in detail with appraisal.

The 18 pages of Chapter 2 “LDES design principles, parameter comparisons, trends and materials” open with the very different needs of grid and beyond grid LDES then it presents graphics describing how the technology options compare in appropriate graphed parameters. For example, the first three graphics present 12 LDES technology choices compared in 7 columns, nine primary LDES technology families, vs 17 other criteria then detailed progress competing for increasing LDES duration by technology. It ends with graphics analysing membrane materials and needs for many forms of LDES such as advanced conventional construction and redox flow batteries plus hydrogen fuel cells and electrolysers.

The rest of the report consists of drill-down chapters with many SWOT appraisals on each LDES technology in alphabetical order starting with 133 pages of Chapter 4, “Batteries for LDES: Redox flow batteries RFB”. Technologies of the different chemistries and structures are explained with pros and cons including regular vs hybrid and the different chemistries. 56 RFB companies are compared in 8 columns: name, brand, technology, tech. readiness, beyond grid focus, LDES focus, comment the see profiles of 48 RFB manufacturers and putative manufacturers followed by research pipeline analysis.

The 51 pages of Chapter 5, “Batteries for LDES: Advanced conventional construction batteries ACCB”

use many graphics to present such things as a parameter appraisal of ACCB for LDES then seven ACCB manufacturers compared in 8 columns: name, brand, technology, tech. readiness, focus, LDES focus, comment. Subsections dive into iron-air: Form Energy USA with SWOT appraisal, molten calcium antimony: Ambri USA with SWOT appraisal, nickel hydrogen: EnerVenue USA with SWOT, sodium-ion with limited LDES potential, Sodium sulfur: NGK/ BASF Japan/ Germany and others with SWOT, zinc-air: eZinc Canada with SWOT, zinc halide EOS Energy Enterprises USA with SWOT.

Chapter 6. “Compressed air CAES” (51 pages) covers the basics, including physics, the global situation, activities of 13 key players, analysis of the research pipeline and ending with a SWOT. Then Chapter 7. “Chemical intermediary hydrogen, ammonia, methane LDES” (28 pages) explains this world of massive inefficiency but massive potential storage capacity under-ground. Hydrogen is compared to methane and ammonia for LDES delayed electricity and proposed hydrogen economy is compared to pure electrification. The sweet spot for chemical intermediary LDES is estimated but you are warned about calculating success based on dubious assumptions. Learn how mining giants prudently back many options but, for buildings, all chemical options are unimpressive. See technologies for hydrogen storage, hydrogen interconnectors for electrical energy transmission and storage and a review of 15 projects that use hydrogen for energy storage in a power system. The chapter ends with a parameter appraisal of hydrogen storage for LDES and SWOT appraisal of hydrogen, methane, ammonia for LDES.

Chapter 8. “Liquefied gas energy storage: Liquid air LAES or CO2” (23 pages) explains these intriguing options for grid storage without the massive earthworks of hydro, compressed air or hydrogen. Understand their higher energy density but often higher LCOS than CAES, hybrid LAES, parameter appraisal of LAES for LDES and scope for increasing the LAES storage time and discharge duration. Six company activities assessed, the research pipeline and two SWOT appraisals end this chapter.

Chapter 9. “Pumped hydro: conventional PHES and advanced APHES” (38 pages) is the world where about 95% of grid storage is of this type and maybe 99% of the electricity stored. Although some meets an LDES specification, it has been rarely used for this but now things change. Environmental objections and other siting limitations drive the need for advanced forms, mainly out of sight and not needing mountains, so more widely deployable. Learn conventional pumped hydro PHES with projects and intentions across the world, the economics, parameter appraisal and see a SWOT appraisal of PHES but more detailed is the analysis of advanced pumped hydro APHES. That means pressurised underground by Quidnet Energy USA, sea floor StEnSea Germany and Ocean Grazer Netherlands compared to other underwater LDES, brine in salt caverns Cavern Energy USA, mine storage Sweden, liquid heavier than concrete invisibly-pumped up mere hills by RheEnergise UK. There is a SWOT appraisal of APHES.

The 25 pages of Chapter 10. “Solid gravity energy storage SGES” cover the one with no self-leakage even for seasonal storage but many moving parts. See the overview and the IIASA, Austria proposal in 2023, the parameter appraisal of SGES for LDES, activity of four companies then SWOT appraisal. Much space is given to leaders Energy Vault with giant partners and huge units proceeding in China initially for short-term storage and Gravitricity, using mines in partnership with ABB and others.

The report closes by assessing the technology that has suffered the most exits. Deserving only 14 pages, Chapter 11. “Thermal energy storage for delayed electricity ETES” contrasts the great success of delayed heat with the inefficiency and limited parameters of thermally-delayed electricity. There is a parameter appraisal of ETES for LDES, the successful special case of molten salt storage for concentrated solar and the lessons of failure of Azelio Sweden, Siemens Gamesa Germany and Stiesdal Denmark. Learn why Antora USA and Malta Inc Germany hope to succeed by using different approaches and see a SWOT appraisal of ETES for LDES.

Report Data

  • 17-parameter technology appraisals: 6
  • Chapters: 11
  • SWOT appraisals: 20 
  • Key conclusions: 22
  • Forecast lines 2024-2044: 35
  • Companies: 104
  • New infograms: 143

Table of Contents

1. Executive Summary and Conclusions
1.1 Purpose and scope of this report
1.2 Methodology of this analysis
1.3 Definition and need
1.4 The very different needs for grid vs beyond-grid LDES 2024-2044
1.5 Basic technology choices for LDES
1.6 Duration being achieved by technology and location
1.7 Lesson from relative investment by technology and location
1.8 Key conclusions: markets
1.9 Key conclusions: technology
1.10 Probable winner for beyond grid LDES: RFB success and gaps in its markets
1.11 Long Duration Energy Storage LDES roadmap 2023-2044
1.12 Market forecasts 2024-2044 in 35 lines
1.12.1 Total LDES market 8 hours and above in 11 technology categories $ billion 2023-2044 table, graphs
1.12.2 Regional share of LDES value market in four regions 2024-2044
1.12.3 Global market split by duration 2024 and 2044
1.12.4 Possible LDES global scenario TWh cumulative 2024-2044
1.12.5 Possible LDES global scenario average duration 2024-2044
1.12.6 Possible LDES global scenario TW cumulative 2024-2044
1.12.7 Beyond-grid LDES market in 8 categories $ billion 2023-2044: table and line graphs
1.12.8 RFB global value market grid vs beyond-grid 2023-2044 table, graph, explanation
1.12.9 RFB global value market short term and LDES 2023-2044 table, graph, explanation
1.12.10 Vanadium vs iron vs other RFB market % 2024-2044 table, graph, explanation
1.12.11 Regular vs hybrid RFB % value sales 2024-2044

2. Introduction
2.1 Overview: energy storage and its mitigation
2.1.1 What is energy storage?
2.1.2 Why stationary electricity storage will overtake mobile storage
2.1.3 Long Duration Energy Storage definition, need for new technology and alternatives
2.1.4 Capacity factor of wind, solar and options that need little or no LDES
2.1.5 Anatomy of LDES and why it is still needed
2.2 Going electric and the place of hydrogen and nine harvesting options
2.3 The solar megatrend
2.4 Growth of wind and solar energy sources across the world
2.5 The beyond-grid megatrend
2.6 Overview, definition and usefulness of Levelised Cost of Storage LCOS
2.7 Many different time parameters for storage
2.8 Progress to advanced photovoltaics and storage implications
2.8.1 Progress so far
2.8.2 Advanced photovoltaics
2.9 Advanced wind power to reduce need for LDES
2.9.1 Taller turbines
2.9.2 Airborne Wind Energy AWE vs ocean power to reduce need for LDES
2.10 Conventional hydropower

3. LDES Design Principles, Parameter Comparisons, Trends and Materials
3.1 Overview: definition, different design requirements for grid vs beyond-grid LDES
3.2 The 12 LDES technology choices compared in 7 columns
3.3 Nine primary LDES technology families, vs 17 other criteria
3.4 Progress competing for increasing LDES duration by technology
3.5 Equivalent efficiency vs storage hours for RFB and other options
3.6 Available sites vs space-efficiency for LDES technologies
3.7 LCOS $/kWh trend vs storage and discharge time
3.8 LDES power GW trend vs storage and discharge time
3.9 Days storage vs rated power return MW for LDES technologies
3.10 Days storage vs capacity MWh for LDES technologies
3.11 Potential by technology to supply LDES at peak power after various delays
3.12 Added value metals, compounds and membranes for LDES
3.12.1 Overview
3.12.2 Membrane difficulty levels and materials used and proposed
3.12.3 RFB membrane difficulty levels and materials used and proposed

4. Batteries for LDES: Redox Flow Batteries RFB
4.1 Overview
4.2 RFB technologies
4.2.1 Regular or hybrid and their chemistries with two SWOT appraisals
4.2.2 Specific designs by material: vanadium, iron and variants, other metal ligand, HBr, organic, manganese
4.3 SWOT appraisal of RFB for stationary storage
4.4 SWOT appraisal of RFB energy storage for LDES
4.5 Parameter appraisal of RFB for LDES
4.6 56 RFB companies compared in 8 columns: name, brand, technology, tech. readiness, beyond grid focus, LDES focus, comment
4.7 Profiles of 48 RFB manufacturers and putative manufacturers
4.8 Research analysis

5. Batteries for LDES: Advanced Conventional Construction Batteries ACCB
5.1 Overview
5.2 SWOT appraisal of ACCB for LDES
5.3 Parameter appraisal of ACCB for LDES
5.4 Seven ACCB manufacturers compared: 8 columns: name, brand, technology, tech. readiness, beyond-grid focus, LDES focus, comment
5.5 Iron-air: Form Energy USA with SWOT appraisal
5.6 Molten calcium antimony: Ambri USA with SWOT appraisal
5.7 Nickel hydrogen: EnerVenue USA with SWOT
5.8 Sodium-ion many companies but limited beyond-grid LDES potential
5.9 Sodium sulfur: NGK/BASF Japan/Germany and others with SWOT
5.10 Zinc-air: eZinc Canada with SWOT
5.11 Zinc halide EOS Energy Enterprises USA with SWOT

6. Compressed Air CAES for LDES
6.1 Overview
6.2 Undersupply attracts clones
6.3 Market positioning of CAES
6.4 Parameter appraisal of CAES vs LAES
6.5 CAES technology options
6.5.1 Thermodynamic
6.5.2 Isochoric or isobaric storage
6.5.3 Adiabatic choice of cooling
6.6 CAES manufacturers, projects, research
6.6.1 Overview
6.6.2 Siemens Energy Germany
6.6.3 MAN Energy Solutions Germany
6.6.4 Increasing the CAES storage time and discharge duration
6.6.5 Research in UK and European Union
6.7 CAES profiles and appraisal of system designers and suppliers
6.7.1 ALCAES Switzerland
6.7.2 APEX CAES USA
6.7.3 Augwind Energy Israel
6.7.4 Cheesecake Energy UK
6.7.5 Corre Energy Netherlands
6.7.6 Gaelectric failure Ireland - lessons
6.7.7 Huaneng Group China
6.7.8 Hydrostor Canada
6.7.9 LiGE Pty South Africa
6.7.10 Storelectric UK
6.7.11 Terrastor Energy Corporation USA
6.8 SWOT appraisal of CAES for LDES

7. Chemical Intermediary Hydrogen, Ammonia, Methane LDES
7.1 Overview
7.2 Hydrogen compared to methane and ammonia for LDES
7.3 Beware vested interests
7.4 The hydrogen economy vs electricity
7.5 Sweet spot for chemical intermediary LDES
7.6 Calculating success based on dubious assumptions
7.7 Mining giants prudently back many options
7.8 For buildings, all options together would be too expensive
7.9 Technologies for hydrogen storage
7.9.1 Overview
7.9.2 Choices of underground storage for hydrogen
7.9.3 Hydrogen interconnectors for electrical energy transmission and storage
7.9.4 Review of 15 projects that use hydrogen for energy storage in a power system
7.10 Parameter appraisal of hydrogen storage for LDES
7.11 SWOT appraisal of hydrogen, methane, ammonia for LDES

8. Liquefied Gas for LDES - Air LAES or Carbon Dioxide
8.1 Overview
8.2 Principle of liquid air energy storage system
8.3 Higher energy density but often higher LCOS than CAES
8.4 Hybrid LAES
8.5 Parameter appraisal of LAES for LDES
8.6 Increasing the LAES storage time and discharge duration
8.7 Highview Power UK with research appraisal
8.8 Highview Power and partners in Australia, Spain, Chile, Australia
8.9 Phelas Germany
8.10 LAES research: Mitsubishi, Hitachi, Linde, European Union, Others
8.11 SWOT appraisal of LAES for LDES
8.12 Liquid carbon dioxide energy storage: Energy Dome Italy
8.12.1 Overview and process
8.12.2 SWOT appraisal of Energy Dome liquid carbon dioxide LDES

9. Pumped Hydro: Conventional PHES and Advanced APHES
9.1 Conventional pumped hydro PHES
9.1.1 Overview: capability and available sites
9.1.2 Three basic technologies
9.1.3 Projects and intentions across the world
9.1.4 Economics
9.1.5 Parameter appraisal
9.1.6 SWOT appraisal of PHES
9.2 Advanced pumped hydro APHES does not need mountains
9.2.1 Overview
9.2.2 Pressurised underground: Quidnet Energy USA
9.2.3 Sea floor StEnSea and Ocean Grazer compared to other underwater LDES
9.2.4 Brine in salt caverns Cavern Energy USA
9.2.5 Mine storage Sweden
9.2.6 Heavy water up hills RheEnergise UK
9.2.7 SWOT appraisal of APHES

10. Solid Gravity Energy Storage SGES
10.1 Overview
10.2 Parameter appraisal of SGES for LDES
10.3 ARES USA
10.4 Energy Vault Switzerland
10.5 Gravitricity UK
10.6 SinkFloat Solutions France

11. Thermal Energy Storage for Delayed Electricity ETES
11.1 Overview
11.2 Parameter appraisal of ETES for LDES
11.3 Special case: molten salt storage for concentrated solar
11.4 Lessons from failure of Azelio Sweden, Siemens Gamesa Germany and Stiesdal Denmark
11.5 Antora USA
11.6 Malta Inc Germany
11.7 SWOT appraisal of ETES for LDES

Companies Mentioned

  • Agora Energy Technologies
  • ALACAES
  • Altris
  • Ambri
  • Antora
  • APEX CAES
  • ARES
  • Azelio
  • B9 Energy Storage
  • Baker Hughes
  • BP
  • Breeze
  • Brenmiller Energy
  • CAES
  • Cavern Energy
  • Cellcube
  • Ceres
  • Cheesecake Energy
  • Chevron
  • CNESA
  • Corre Energy
  • CPS Energy
  • Crondall Energy
  • E-zinc
  • Echogen
  • Energy Dome
  • Energy Nest
  • Energy Vault
  • Enervenue
  • Enlighten
  • EOS
  • ERCOT
  • ESS Technology
  • Faradion
  • Form Energy
  • Fortescue Metals Group
  • GE
  • Gravitricity
  • Greenco Group
  • H2 Inc
  • HBI
  • Heatrix
  • Highview Power
  • HiNa
  • Hochtief
  • HuanengHighview Power
  • Huisman
  • Hydrostor
  • IEA
  • ILI Group
  • InnoEnergy
  • Invinity Energy Systems
  • IOT Energy
  • JSC Uzbekhydroenergo 
  • Kraft Block
  • Kyoto Group
  • Largo
  • Lazard
  • Linde
  • Lockheed martin
  • Locogen
  • Magaldi
  • Magnum
  • Malta
  • MAN Energy Solutions
  • MGA Thermal
  • Mine Storage
  • Mitsubishi Hitachi
  • MSE International
  • Natron
  • Phelas
  • Primus Power
  • Quidnet Energy
  • Rcam Technologies
  • Redflow
  • Reliance Industries
  • RHEnergise
  • Rye Development
  • SaltX Tech.
  • Schmid Group
  • Sens Pumped Hydro Storage
  • Sherwood Energy
  • Siemens Energy
  • SinkFloatSolutions 
  • Sintef
  • Stiesdah
  • Storelectric
  • StorEn Technologies
  • StorTera
  • Storworks Power
  • Subsea 7
  • Sumitomo Electrical Industries
  • Swanbarton
  • Terrastor 
  • Tesla
  • Tiamat
  • Torc
  • UET
  • UniEnergy Techmologies
  • VFlowTech
  • Voith Hydro
  • Volt Storage
  • VRB Energy

Methodology

Research Inputs Include:

  • Appraisal of which targeted needs are genuine
  • Web, literature, databases, experience and patents
  • Close study of research pipeline
  • Appraisal of regional initiatives
  • Actitivies of standard bodies
  • Limitations of physics and chemistry
  • Interviews

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