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1、Hydrogen Insights A perspective on hydrogen investment,market development and cost competitivenessFebruary 2021Hydrogen Insights Report 2021 Hydrogen Council,McKinsey&CompanyPublished in January 2021 by the Hydrogen Council.Copies of this document are available upon request or can be downloaded from

2、 our website:.This report was authored by the Hydrogen Council in collaboration with McKinsey&Company.“The authors of the report confirm that:1.There are no recommendations and/or any measures and/or trajectories within the report that could be interpreted as standards or as any other form of(sugges

3、ted)coordination between the participants of the study referred to within the report that would infringe EU competition law;and2.It is not their intention that any such form of coordination will be adopted.Whilst the contents of the Report and its abstract implications for the industry generally can

4、 be discussed once they have been prepared,individual strategies remain proprietary,confidential and the responsibility of each participant.Participants are reminded that,as part of the invariable practice of the Hydrogen Council and the EU competition law obligations to which membership activities

5、are subject,such strategic and confidential information must not be shared or coordinated including as part of this Report.ContentsExecutive summary iii I.Introduction and methodology 2 Hydrogen Insights is a leading global perspective on hydrogen 2 The Hydrogen Insights report methodology 3 II.Depl

6、oyment and investment 6 Tremendous momentum exists,with over 200 H2 projects announced worldwide 6 More than USD 300 billion in H2 investments through 2030 7 Regulation and government support drive this momentum 8 III.Hydrogen supply 12 Renewable hydrogen could break even with gray H2 before 2030 in

7、 optimal regions 12 Electrolyzer capex savings can reduce costs quickly in a rapid global scale-up 15 Expected electrolyzer learning curves could be too conservative 15 IV.Hydrogen distribution and global supply chains 18 The optimal H2 transport mode will vary by distance,terrain and end-use:no uni

8、versal solution exists 18 Hydrogen pipelines 20 Hydrogen carriers 21 Hydrogen global transport can cost less than USD 2-3/kg 24 V.End applications 26 The cost competitiveness of hydrogen applications 26 Hydrogen production cost breakeven 27 A.Road transport and mining equipment 28 B.Ammonia 31 C.Ste

9、el 32 D.Sustainable shipping fuels 34 E.Aviation 37VI.Implementation:bringing it all together to capture the promise of hydrogen 42iiiHydrogen Insights Report 2021 Hydrogen Council,McKinsey&Company Executive summaryHydrogen is gathering strong momentum as a key energy transition pillar Underpinned b

10、y a global shift of regulators,investors,and consumers toward decarbonization,hydrogen(H2)is receiving unprecedented interest and investments.At the beginning of 2021,over 30 countries have released hydrogen roadmaps,the industry has announced more than 200 hydrogen projects and ambitious investment

11、 plans,and governments worldwide have committed more than USD 70 billion in public funding.This momentum exists along the entire value chain and is accelerating cost reductions for hydrogen production,transmission,distribution,retail,and end applications.Similarly,having grown from 60 to over 100 me

12、mbers since 2020,the Hydrogen Council now represents more than 6.6 trillion in market capitalization and more than 6.5 million employees globally.This report provides an overview of these developments in the hydrogen ecosystem.It tracks deployments of hydrogen solutions,associated investments and th

13、e cost competitiveness of hydrogen technologies and end applications.Developed collaboratively by the Hydrogen Council and McKinsey&Company,it offers a fact-based,holistic,quantitative perspective based on real industry data.Along with the report,the Hydrogen Council is launching Hydrogen Insights-a

14、 subscription service that provides granular insights and data about the hydrogen ecosystem and its development.Deployment and investments:Announced hydrogen investments have accelerated rapidly in response to government commitments to deep decarbonizationMore than 200 hydrogen projects now exist ac

15、ross the value chain,with 85%of global projects originating in Europe,Asia,and Australia,and activity in the Americas,the Middle East and North Africa accelerating as well.If all projects come to fruition,total investments will exceed USD 300 billion in hydrogen spending through 2030 the equivalent

16、of 1.4%of global energy funding.However,only USD 80 billion of this investment can currently be considered“mature,”meaning that the investment is either in a planning stage,has passed a final investment decision(FID),or is associated with a project under construction,already commissioned or operatio

17、nal.On a company level,members in the Hydrogen Council are planning a sixfold increase in their total hydrogen investments through 2025 and a 16-fold increase through 2030.They plan to direct most of this investment toward capital expenditures(capex),followed by spending on merger and acquisition(M&

18、A)and research and development(R&D)activities.The global shift toward decarbonization backed by government financial support and regulation is supporting this momentum.For instance,75 countries representing over half the worlds GDP have net zero carbon ambitions and more than 30 have hydrogen-specif

19、ic strategies.Governments have already pledged more than USD 70 billion and included new capacity targets and sector level regulation to support these hydrogen initiatives.For example,the EU has announced a 40-gigawatt(GW)electrolyzer capacity target for 2030(up from less than 0.1 GW today)and more

20、than 20 countries have announced sales bans on internal combustion engine(ICE)vehicles before 2035.In the US,where federal emission standards for new vehicles have lagged behind those in the EU,state-level initiatives in California and 15 other states have set ambitious targets to transition not onl

21、y passenger cars but also trucks to zero-emission status by 2035.In China,the 2021-24 fuel cell support program will see the equivalent of USD 5 billion spent on fuel cell vehicle deployment,with a strong emphasis on the development of local supply chains.ivHydrogen Insights Report 2021 Hydrogen Cou

22、ncil,McKinsey&CompanySupply:If scaled up with the right regulatory framework,clean hydrogen costs can fall faster than expected1 These costs reflect pure production costs and assume a dedicated renewable and electrolysis system for renewable hydrogen.They do not include costs required for baseload s

23、upply of hydrogen(e.g.,storage and buffers),costs for redundancies,services and margins;they also do not include any cost for hydrogen transportation and distribution.With the advent of hydrogen giga-scale projects,hydrogen production costs can continue to fall.For renewable hydrogen,the biggest dri

24、ver is a quicker decline in renewables costs than previously expected,driven by at-scale deployment and low financing costs.2030 renewable costs could be as much as 15%lower than estimated just a year ago.The strongest reductions are expected in locations with optimal resources such as Australia,Chi

25、le,North Africa and the Middle East.But lower renewable costs are not enough:for low-cost clean hydrogen production,value chains for electrolysis and carbon management need to be scaled up.This will not happen on its own:a further step-up of public support is required to bridge the cost gap,develop

26、low-cost renewable capacities and scale-up carbon transportation and storage sites.For the cost projections in this report,we assume an ambitious development of the use of hydrogen in line with the Hydrogen Council vision.For electrolysis,for example,we assume 90 GW deployment by 2030.Such a scale-u

27、p will lead to a rapid industrialization of the electrolyzer value chain.The industry has already announced electrolyzer capacity increases to over approximately 3 GW per year,and will need to scale rapidly beyond that.This scaling can translate into system costs falling faster than previously estim

28、ated,hitting USD 480-620 per kilowatt(kW)by 2025 and USD 230-380 per KW by 2030.System costs include stack and balance of plant but exclude transportation,installation and assembly,costs of building and any indirect costs.At-scale deployment of renewable hydrogen will require the development of giga

29、-scale hydrogen production projects.Such projects with purpose-built renewables can boost utilization by merging multiple renewable sources,such as a combined supply from onshore wind and solar photovoltaics(PV),and by overbuilding renewables supply versus electrolyzer capacity.In combination,projec

30、tions show that renewable hydrogen production costs could decline to USD 1.4 to 2.3 per kilogram(kg)by 2030(the range results from differences between optimal and average regions).1 This means new renewable and gray hydrogen supply could hit cost parity in the best regions by 2028,and between 2032 a

31、nd 2034 in average regions.In parallel to renewable hydrogen production,low-carbon hydrogen production from natural gas has continued to evolve technologically.With higher CO2 capture rates and lower capex requirements,low-carbon hydrogen production is a strong complementary production pathway.If ca

32、rbon transportation and storage sites are developed at scale,low-carbon hydrogen could break even with gray hydrogen by the end of the decade at a cost of about USD 35-50 per ton(t)of carbon dioxide equivalent(CO2e)1.Distribution:Cost-efficient transmission and distribution required to unlock hydrog

33、en applications With hydrogen production costs falling,transmission and distribution costs are the next frontier when it comes to reducing delivered hydrogen costs.Longer-term,a hydrogen pipeline network offers the most cost-efficient means of distribution.For example,pipelines can transmit 10 times

34、 the energy at one-eighth the costs associated with electricity transmission lines and have capex costs similar to those for natural gas.The industry can partially reuse existing gas infrastructure,but even newly constructed pipelines would not be cost prohibitive(assuming leakage and other safety r

35、isks are properly addressed).For example,we estimate the cost to transport hydrogen from North Africa vHydrogen Insights Report 2021 Hydrogen Council,McKinsey&Companyto central Germany via pipeline could amount to about USD 0.5 per kg of H2 less than the cost difference of domestic renewable hydroge

36、n production in these two regions.In the short-to medium-term,the most competitive setup for large-scale clean hydrogen applications involves co-locating hydrogen production on-or near-site.The industry can then use this scaled production to supply the fuel to other hydrogen users in the vicinity,su

37、ch as refueling stations for trucks and trains,and smaller industrial users.Trucking the fuel to such users typically offers the most competitive form of distribution,with costs below USD 1 per kg of H2.For longer-distance transport by ship,hydrogen needs to be converted to increase its energy densi

38、ty.While several potential hydrogen carrier approaches exist,three carbon-neutral carriers liquid hydrogen(LH2),liquid organic hydrogen carriers(LOHC)and ammonia(NH3)are gaining most traction.2 The cost-optimal solution depends on the targeted end-use,with deciding factors including central versus d

39、istributed fueling,the need for reconversion,and purity requirements.At-scale,international distribution could arrive by 2030 at total costs of USD 2-3/kg(excluding cost of production),with the lions share of costs needed for conversion and reconversion.For example,if the targeted end application is

40、 ammonia,shipping costs add only USD 0.3-0.5/kg to the total cost.If the targeted end application is for liquid hydrogen or hydrogen with a high purity requirement,shipping as liquid hydrogen might add only USD 1.0-1.2/kg,with additional benefits for further distribution from port.These cost levels

41、would enable global trade in hydrogen,connecting future major demand centers such as Japan,South Korea,and the EU to regions of abundant low-cost hydrogen production means like the Middle East and North Africa(MENA),South America or Australia.Like hydrogen production,carriers need substantial initia

42、l investments,and the right regulatory framework to bridge the cost delta in the first decade.End applications:Falling clean hydrogen costs and application-specific cost drivers improve the cost competitiveness of hydrogen applications From a total cost of ownership(TCO)perspective(including hydroge

43、n production,distribution and retail costs)hydrogen can be the most competitive low-carbon solution for 22 end applications,including long haul trucking,shipping and steel.However,pure TCO is not the only driver of application adoption:future expectations on environmental regulations,demands from cu

44、stomers and associated“green premiums,”as well as the lower cost of capital for ESG-compliant investments will all influence investment and purchase decisions.In industry,lower hydrogen production and distribution costs are particularly important for cost competitiveness as they represent a large sh

45、are of total costs.Refining is expected to switch to low-carbon hydrogen over the next decade.For fertilizer production,green ammonia produced with optimized renewables should be cost competitive by 2030 against gray ammonia produced in Europe at a cost of less than USD 50 per ton of CO2e.Steel,one

46、of the largest industrial CO2 emitters,could become one of the least-cost decarbonization applications.With an optimized setup using scrap and hydrogen-based direct reduced iron(DRI),green steel could cost as little as USD 515 ton of crude steel,or a premium of USD 45 per ton of CO2e by 2030.In tran

47、sport,lower hydrogen supply costs will make most road transportation segments competitive with conventional options by 2030 without a carbon cost.While battery technology has advanced rapidly,fuel cell electric vehicles(FCEVs)are emerging as a complementary solution,in particular for heavy-duty truc

48、ks and long-range segments.In heavy-duty long-haul transport,the FCEV option can achieve breakeven with diesel in 2028 if hydrogen can be made available for USD 4.5 per kg at the 2 Synthetic methane produced from biogenic or air-captured CO2 represents a potential fourth candidate to be studied furt

49、her.viHydrogen Insights Report 2021 Hydrogen Council,McKinsey&Companypump(including hydrogen production,distribution and refueling station costs).Furthermore,hydrogen combustion(H2 ICE)offers a viable alternative in segments with very high power and uptime requirements,including heavy mining trucks.

50、Hydrogen is likewise advancing in trains,shipping,and aviation.Clean ammonia as a shipping fuel will be the most cost-efficient way to decarbonize container shipping by 2030,breaking even with heavy fuel oil(HFO)at a cost of about USD 85 per ton of CO2e.3 Aviation can achieve competitive decarboniza

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