I I Information Is disclosed under the Access to information Act renulgnemanb sent dlvulgu?s an vartu da la Lni'sur race}: a ?i Charm-ml ma . Olr?adfm?a i 12113;; Ggmg?: i (1, Policy Haircut: mai?wmmr Canada ?zscma'oai 2:52;: 2030 Canada in a Chanqinq Global Enerqq Landscape DRAFT for discussion March 5, 2016 Disclaimer Policy Horizons Canada (Horizons) is a strategic foresight organization within the Public Service ofCanada with a mandate to help anticipate emerging policy challenges and opportunities, explore new ideas, and experiment with methods and technologies to support resilient policy development. The views contained in this document do not necessarily represent the views of Horizons, the Government of Canada or participating departments and agencies. 000024 I I I Information disclosed under the Access to Information Act Lu renulgnom-nts sons divulguis In vertu de la Lalsur f'acds 0 f'informatfon Table of Contents Executive Summary .. 1 Insights ..2 The primary energy supply of the globe is shifting to 2 Renewable-based electricity is becoming cheaper than generation by fossil fuels .. 3 Externalitv costing will accelerate the shift to renewables 3 Renewables can reduce distribution infrastructure costs. .. 3 Storage solutions are emerging and evolving faster than 4 Electricity's flexibility allows it to cross energy silos and substitute for fossil 5 Data management will become a key element of the electrical energy 5 Heat from renewables could reduce demand for fossil fuels .. 5 Renewables enhance national energy security, productivity and economic stability .. 6 Transportation may electrify more rapidly than expected .. 7 Challenges and Opportunities .. 8 A new global energy ecosystem emerges rapidly .. 8 Competition for emerging energy markets based on technology rather than 8 Minerals become strategic assets .. 8 Oil demand for transportation declines more rapidly than expected .. 9 Fossil fuels could lose their commodity status leading to splintering of the oil market 10 Scenarios .. 11 implications for Canada .. 13 Conclusion .. 18 Annex A: Assumptions .. 19 References . . 21 000020 I . I Information Is disclond under the Access to Information Act Ln renaelgnamanh son! divulgu?s an vertu de la loiaur l'accia a l'fnforma?nn Executive Summaru The world's energy landscape is transforming rapidly as the cost of renewable-based electricity,? particularly from wind and solar, declines to become competitive with or lower than the price of electricity generated by fossil fuel and nuclear power plants. Power utilities and companies are increasingly choosing to increase their generating capacity using renewable sources rather than fossil power as the perceived problems of intermittent supply from solar and wind are addressed with better supply and demand management using a combination of integrated smart grids and battery storage. The price of batteries is falling precipitously leading to their application at local and grid-level scales in the power supply system as well as facilitating significant electrification of transportation. The shift to an electricity-dominated global energy mix will be accelerated as decreasing costs combine with increasing government and private sector concerns over climate change, energy security and air pollution, particularly in developing countries where the need for additional energy capacity is greatest. In combination, these drivers could lead to renewable-sourced electricity replacing fossil fuels as the dominant form of primary energy used in the global economy for most industrial, commercial and personal activity. What is driving change? 0 Cost Reduction: many components of a renewable?based electricity system are declining in cost much faster than predicted due to advances in technology, economies of scale and accelerating learning curves as experience with these systems grows. 0 Digital Economy: digital systems run on electricity; as the global economy shifts to become increasingly digital, the relative proportion of electricity in global energy use will increase. 0 Climate Change and Air Pollution: developing countries are embracing renewable energy to meet their economic and development goals without trading off environmental quality and human health. Policu Challenges: As the insiqhts interact, whai challenges could lie ahead? - A new electricity-based industrial ecosystem could emerge at a much faster rate than expected, significantly disrupting fossil fuel markets. 0 Competition for energy markets of the future could be won by those with the best technologies for renewable energy production, storage and management, rather than by those with deposits of fossil energy. 0 Minerals and metals such as lithium and rare earths could replace oil, gas and coal as strategic resources based on their use in the batteries, electronics and photovoltaic cells of the emerging energy ecosystem. Global oil demand could peak earlier and decline further and faster than expected with significant impacts on high-cost producers. 000020 I I information Is disclosed under the Access to Information Act Lu sent divulguis on vcrtu do In leisur- Paced: l'lnformarian 0 Oil production could significantly outpace demand with resulting downward pressure on prices as producer countries compete to maintain their share of shrinking markets while oil still has value. - Oil could lose its commodity status as purchasers begin to discriminate between oil suppliers on non-intrinsic qualities such as embodied greenhouse gas emissions and/or other environmental, political or social criteria. lnsiqhts Insights describe developments taking place now that could create further, highly disruptive change in the future should they strengthen. Insights are selected for their disruptive potential and policy implications. The primoru enerqu supplu of the qlobe is shiftinq to electricitu Electricity is expected to be the world?s fastest-growing form of final energy1 and to provide an increasing share of the energy consumed across economic sectors.2 While energy demand from all sources is expected to rise by 37% from 2012-2040,3 over the same period, world electricity demand is expected to increase by almost 80% representing over half of the increase in global primary energy use.4 The emerging middle class in developing countries is expected to drive electrification as it urbanizes Figure 1: Share of Electricity in End-Use Energy Consumption Manx-max hearing 38. Cit-ens Erasmus Mun radar Jx-xb'na w. 33-. aim-vars: I I Paroles-n Ma.- ti-wr-aw muse Emails: r-ix'womsi S?s Adopt? from: grammar). Huh.assemble.Ensureqnsinthn?cn ntrto. and men-eat.qu and shifts from biomass to electric modern home appliances for cooking, light, heat and cooling. Figure 1 is drawn from a roadmap study by China, the world?s largest economy, demonstrating that it is economically and technically feasible for electricity to comprise over 60% of its end-use energy consumption by 2050.5 The emerging digital economy and related data storage and transmission infrastructure will require increasing amounts of electricity?5 as does the growing use of additive manufacturing processes. There are also signals that suggest transportation may more quickly than expected.7 000027 I . I Information Is disclosed under the Access to information Act Lea renealgnemerlh Ion! dlvulgu?e en vertu de la Lalaur f'aocee a f'lnforma?on Renewable-based electricitu is becominq cheaper than qeneration bu fossil fuels Electricity will be increasingly produced from renewable sources rather than fossil fuels. Rapid advances in renewable energy technology and reductions in cost now permit electricity to be produced relatively inexpensively from a wide range of sources including solar photovoltaics, wind, hydro, geothermal, biomass and biofuels.8 As shown in Figure 2, most renewables can already produce electricity at a lower cost than fossil fuels.9 Renewables such as solar photovoltaics are expected to drop in price to below fossil-fuel generation prices in the next two to three years in most markets.10 Although any individual country may lack the optimal conditions for every type of renewable electricity, all countries are likely to have at least one or more options to produce electricity Figure 2: Levelized costs of electricity: tat-.5 gas a (t 24?- - 20? may?; cosh-m 2:5: war-r- . - .. a. 5. rr- Solar and wind include estimated costs to integrate 40% su pply of intermittent power into electricity grids. Fossil fuel power range includes health and environmental costs. is: ice/?lax er 1 Jag.? Data Source: i from renewables that will be cost comparative or cheaper than generation by fossil fuels.11 Externalitu costinq will accelerate the shift to renewables Electricity from renewable sources has significantly lower environmental impacts than from fossil fuels, most obviously on greenhouse gas emissions12 but on other variables as well such as air pollution and water use.13 Environmental externalities of fossil fuels are increasingly likely to be factored into the cost of their use 1? and could lead to renewables becoming the technology of choice for almost all new capacity. Deployment rates for renewables are already very high in countries with an electricity shortage but could accelerate. 15 Rapidly declining costs for storage16 and advances in demand and supply management17 could permit renewables to replace significant portions of the existing fossil-fueled electrical generation as power plants reach their end of useful life and are retired - both in emerging and developed economies.18 Renewables can reduce distribution infrastructure costs. Wind and photovoltaic power systems are highly scalable ?9 and distributable. They can provide power from the individual level through to utility scale and can be completely autonomous or fully integrated into electrical grids at local through to transnational scale. While grid- connected renewables will likely prevail in developed countries with existing grid infrastructure, the highly distributable nature of these renewables, combined with effective storage or load shifting, may permit countries with underdeveloped infrastructure to reduce costs of Information disclosed under the Access to Information Act Lu renuignam-nu diuulgu?s an vurtu do la Loi sur i'acd: 0 f'infarmotion electrification by bypassing the traditional electrification pattern of extending grids from central power plants.20 Storaqe solutions are emerqinq and evolvinq faster than anticipated An electricity-based ecosystem that . . . . .. . . a .. incorporates significant solar and wind Grid-scale batterv storage power will require storage to smooth the 5 intermittent supply from these sources. This can be met by proven technologies like pumped hydro storage where conditions permit. While experience with renewables supply and demand management using integrated smart grids is growing, it is expected that energy-dense, low-cost batteries will be required for renewable-based electricity to dominate the global energy mix. Technologies in this area are emerging and evolving rapidly as researchers and companies work to meet the emerging demand for a wide range of battery applications, particularly in the power and transportation sectors.21 Simultaneously, costs are declining faster than forecasted.22 Tesla Motors is reported to be producing lithium ion batteries for the automotive and home energy23 markets at its Gigafactory24 for around per - a price point that the International Energy Agency (IEA) predicted would not be reached until 2020. 25 Battery manufacturers in Asia are building battery factories at similar scales to Tesla?s Gigaiactory that will triple battery production by 2020.?5 These economies of scale are expected to further reduce the cost of batteries to per by 2020.27 At this price point, electric vehicles will become fully competitive with those powered by internal combustion engines. There is significant attention on lithium-ion technology and expanding the capacity and configurations of batteries using this chemistry. Research is also being conducted on other types of batteries such as sodium-ion or aluminum-air with the potential to substantially reduce the cost per of manufacturing" while A I secret-entdemsnd Tesla Powerwall launch event improving energy density", recharge performance and storage on April 30. 2015. capacity. Further application of batteries is expected in a range ?757 m'm?ml i of transportation modes including trains?, trucks31 and even I I aircraft.32 Batteries are also likely to be widely deployed in stand-alone33 or grid-integrated photovoltaic and wind energy units to permit continuous power supply.34 Utility-scale energy storage technologies are available now and may be a cheaper alternative to peaking power plants as well as new transmission lines?5 by allowing public utilities to position battery plants near high 000020 Information I1 disclosed under the Access to information Act he sent dlvulgu?s In vertu de la lafsur Peed: l'Infarrnarion demand areas like large cities and industries and improve load-balancing while reducing GHG emissions. Battery manufacturers are developing different sizes of stationary battery units that store enough energy to power a single home or a factory and could be used by utilities.? There is also potential to convert used lithium?ion batteries from electric vehicles into non- automotive applications like stationary storage units?? as the batteries still have significant energy storage capacity. Electricitu's flexibilitu allows it to cross enerqu silos and substitute for fossil fuels Electricity is a versatile energy form which can be used efficiently for a variety of applications. Integrated energy production, storage and use systems are expected to develop in which electrical energy flow between uses will become more seamless and fluid-f"8 Systems thinking that focuses on shifting stored electrical energy between services as they are required mobility, heat, light, computing) could allow electricity to become a fungible energy source across platforms that have traditionally been tied to a particular energy source mobility using gasoline, building heat by natural gas, light and computing by electricity). Home owners may choose to charge their electric vehicles in off-peak hours and then connect the vehicle batteries into the home power systema?9 to act as a power source during peak demand hours. This type of multipurpose storage could dramatically increase efficiency of the overall energy system by shaving peak requirements and smoothing demand thereby accelerating the shift to intermittent renewables integrated with storage. Data management will become a keg element of the electrical enerqu sustem The distributed and intermittent supply from some renewable power sources like wind and solar could add significant complexity to balancing supply and demand in electrical energy- systems."0 Different business models will likely arise for integrating renewables into electrical systems depending on the degree to which a country already has an existing centralized power generation and distribution system. However, in all cases, intelligent energy management systems are expected to become more pervasive as increasing numbers of energy consumption and storage devices become connected in the Internet of Things.?11 This could give rise to large integrated energy/data management companies that rival or replace government central utilities as the key actors in electrical energy systems.?2 Heat from renewables could reduce demand for fossil fuels Advances in technology could permit renewable sources to replace fossil fuels"3 for much of the energy used for heating. Solar thermal can provide industrial hot water and steam in a temperature range of up to - warm enough to meet the demand from the textile, chemical, plastic, food and beverages and pulp and paper industries.? Concentrated solar power can go higher."5 China leads the world in solar water heating capacity with 180.4 and plans to increase its solar water heating capacity to 560 by 2020."Solar heating 000000 I I Information Is disclosed under the Acme to Information Act Lu renulgnemenh sent dluulgu?e en vertu de la Loleur f'accee f?lnformarlon technologies could be applied to supply hot water and space heating in the buildings sector thereby reducing the carbon footprint of the residential, commercial, and institutional sectors.48 Investments in transportation and distribution infrastructure for fossil fuel could be reduced or avoided if distributed solar thermal systems are widely adopted for space heating and processing heat.?9 In addition, growth in demand for space heating (or cooling) may be lower than projected if robotics, remote control and automation remove humans from large parts of manufacturing and processing facilities or from mines to reduce the capital and operational costs of heating, cooling or ventilating. 5? Renewables enhance notional enerqu securitu, productiviiu and economic slobilitu Countries that do not have domestic supplies of a fossil fuel can increase their energy security and productivity while reducing economic risk by shifting their economies to renewable- generated electricity and heat. Most renewables can produce electricity and heat at lower cost than fossil fuels which makes economies that invest in renewables more competitive. Reducing the need for foreign supplies of coal, oil or gas reduces the requirements for political, military or economic geostrategic investments in fossil fuel rich regions as well as lowering the risks of price shocks if the flow of resources is interrupted.51 Some forms of distributed renewable energy like solar lead to greater overall employment and more locally-based employment than centralized power plants.52 By providing inexpensive and reliable electricity close to the end use, decentralized renewables could create a feedback loop in which local economic activity evolves to take advantage of electricity, which will stimulate additional demand for electricity that will be met by additional supply by renewables.53 The increasing recognition of the multiple benefits of renewables compared to fossil fuel generation is reflected in Figure 3 which shows the global shift in the technologies being chosen to add electricity generating capacity. While significant investments in renewables are being made by national and state utilities and private utilities, many non-energy private sector companies also are directly investing in i renewables as costs 1 decrease and customers expect Figure 3: Power generation capacity additions I Tiff. . Tiff, M, them to act on climate 5 change. In search of I gm ~55 energy self-suf?ciency, H: I EQ has announced .lt'fz; mm - 3 anlnvestment of - I in g, 500M euros II f: Eff: - energyand 100M I 3 euros In solar energy 1?10") R?tl?ft?t .Ll?lu )P'h ?int Th; Source: Bloombem New Energy flnence 000031 I . I Inform-lien le dlecloud under the Access to information Act Les renselgnemenh sent dlvulgu?e en vertu de ll Lolsur I'aodu 0 [information years.54 Apple has announced a investment to build a 280 megawatt solar farm in California.55 Many companies listed in the Fortune 100 have adopted corporate renewable energy programs that scale up their use of on-site solar and wind power systems.56 To overcome some barriers with on-site power systems and meet their energy goals, 19 big brands representing a combined demand of more than 10 million megawatt hours per year or enough power to run 1 million homes for a year have signed last year the Corporate Energy Pledge, asking public utilities to make it simpler for them to buy power generated through solar, wind, fuel cells and other alternatives sources that are less subject to price fluctuations than fossil fuel.57 One of the objectives of the concerned companies is to have access to longer-term, fixed-price energy and renewables. Transportation mou electrifu more ropidlu than expected A number of factors could converge to shift a significant percentage of transportation to electricity over the next 15 years. The growth in electric vehicle sales shown in Figure 4 could accelerate, particularly in markets in which vehicle sales are expected to grow. Many of the countries making the greatest investment in adding renewables to the energy mix are the same ones facing the greatest regulatory pressures to reduce air pollution and greenhouse gas emissions as well as the highest projected demand for vehicles.??8 Restrictions on vehicle purchases59 and incentives to purchase electric vehicles60 could accelerate their adoption in emerging markets. Potential declines in electric vehicle cost61 and increases in supply62 coupled with potentially lower than expected overall demand for personal vehicles due to emerging trends like car-sharing63 and telework64 could lead to a proportion of the global vehicle fleet that is more electrified than expected in many projections.65 66 A turnover of the vehicle fleet could occur much faster than historical averages if consumers and governments embrace autonomous vehicles for their enhanced safety and convenience.?57 It is likely that those with the highest imported oil supply will shift to electrification of Figure 4: Number of electric car sales by year and country transport at the 000.000 - highest rate to reduce i 1 703.000 - '5 0 SUPP I Unltudsum disruption or price . .513] 0mm Kingdom volatility.? 500.000 .. Netherlands -lt10000 .Iepen 1'7 Frence 4-: . 500.000 - - Chine 200 000 Germe ny Reetofthe World 100.000 0 .2. nm'imaumz 2009 IOIO 201! 2013 20? 2011 Source: Zentrum flir Sonnenenergle- und Welterlto?-Forechun: Baden-women?th 000032 I I Information II disclosed under the Arm: to Information Act Lu rennin-manta son! dlv'ulguis an wart-u dc Ia Loiaur Foods 4} l'lnfurmarlon Challenges and Opportunities A new global enerqu ecosustem emerqu rapidlu As electricity becomes more abundant, it may challenge fossil fuels in unexpected areas of transportation, processing, manufacturing and metallurgy which could previously only be performed technologically and affordany using fossil fuels.69 While the technical ability to generate renewable energy from wind and solar has been possible for decades, advances in technology and reductions in cost are permitting the globe to "discover" renewable-sourced electricity as a new energy source. Just as coal and then oil stimulated the development of technologies that used these energy sources, the emergence of cheap, reliable, abundant and non-polluting electricity combined with affordable energy-dense battery storage could accelerate the evolution of an electricity-based technological and industrial ecosystem that could out-compete and largely replace the current- fossil-fuel based system. Competition for emerging enerqu markets based on technoloqu rather than resources The assumption that regions such as Latin America or Africa will follow similar development paths to the West or even Asia and hence will be the next market for fossil fuels may be questionable. In an electricity-driven industrial and commercial ecosystem, emerging economies may leap-frog directly to renewable-generated electricity as the primary energy for their economic growth and development. Competition for these energy markets may be based on providing the best renewable energy technology and integrated energy efficiency/management systems rather than providing natural resources like fossil fuels. Those who develop the best technology would be the energy superpowers rather than those with the best oil, gas or coal deposits. - Minerals become stratequ assets Key minerals such as those required for batteries, photovoltaic cells and electric motors may replace petroleum as strategic energy-related assets. Latin America (Bolivia, Argentina and Chile) holds the largest lithium reserves in the world70 while China and Brazil have nearly 60% of the world?s reserves of rare earth metals.? As storage and mobility become larger components of the electricity-powered ecosystem, there is potential for the creation of cartels or coordinated market manipulation for key minerals." This potential threat may spur countries to explore alternate battery chemistries that could further accelerate and expand the conversion to electricity by lowering cost and expanding options across sectors." 000033 I . I Inform?lon In under tho Access to Information Arr Les "Milan-menu sent dlvulgu?a on warm de la La] :ur f'accis I'I?nforma?on Oil demand for transportation declines more rapidlu than expected A growing number of weak signals suggest a potential shortage of demand for fossil fuels rather than a shortage of supply. As electricity increases its proportion of the world's primary energy supply and that energy is increasingly met with low-polluting, cost-competitive renewable generation, transportation could shift towards electrical power. Coupled with other factors that could reduce transportation demand (see Figure 5), demand for oil could peak sooner and decline faster than expected. Figure 5: Future of Asian oil demand . .. 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Watt-'9? task-haw; mu and semi, AlwImillK one! entertainan 1m: tics ms mm for Mums?m'r am tt?sum. (?mow L?umrmud (um {la-man's Er: smirk-29:. 6.3 $5 per {mimi- - Limo? and :eutm-i-l :u traumas-9 demiw Ma: misc-.4 use emu swung? allwimws mum-wink: mt Additive Howlutuririq Mam get-m produced rectum; lane: mun-tr- momma. sum to ?ail =9 ur? new" gnu [maple by man speedulvuurJait Imam: .. nucleus, unto me and smut. MUI flights. . I '1 murmur! Ma mi Sim-Mr. ?mink: mo. :1 ?mgr-MN in "mm all mum and loan-2M1: new - may mum-i wit to Mullah-,1: anu Nudirm! humble mimic [mme -- CUM temptat?l'?w at :mr-rr-wd am?! view. ?we now-Inn? rmnulrr curbs i, ms 2350 Based on 2013 projections from BP, Exxon, Shetland IEA. 000034 I I Information II dlsdoud under the Mm: to Information Act LII unsalgnamenh son! dlvulgu?s an v-rtu do In tnfsur l'acds l'lnformari?on Fossil fuels could lose their commoditu status leading to splinterinq of the oil market The assumption that fossil fuels such as oil are essential to drive economies may begin to be eroded as the availability of cost?competitive renewable-based energy increases and industrial and economic ecosystems embrace and evolve to use it. Grades of oil, natural gas and coal are largely considered uniform commodity products once they enter global markets. However, their sources vary significantly as can the geopolitical, environmental or social impacts of their extraction, production and transportation. If demand outstrips supply, discrimination between oil, coal or gas on the basis of these impacts may be limited, but if supply exceeds demand, pressure could mount to provide quantitative and qualitative information related to the source of the fossil fuel being sold. In this plausible future, the concept that coal, oil or gas is a globally uniform product could fail leading them to lose their commodity status. If this were to occur, the global market for a fossil energy like oil could splinter into three broad tiers - the bottom (price only), middle (best mix of price but with floors on key criteria) and premium/high end (the purchaser will pay a premium to ensure all criteria are met). Embodied carbon in the production of the fossil fuel will likely be the first discriminator to be widely adopted. Others may follow such as associated environmental degradation; water consumption; air pollution; human rights record; indigenous inclusion; democratic freedom; inclusion of women; political and economic stability; lack of conflict; etc. If this were to come about, some fuels may have to sell at a steep discount to offset aspects of their production that are considered negatives by potential buyers. Rather than being price-takers from suppliers, consumer countries could become price-makers on different sources of oil as suppliers adjust pricing to maintain share of a diminishing and more discriminating market place. Although oil is generally not segregated in the supply chain currently, increased data from sensors, big-data analytics and the Internet of Things could provide the information needed by purchasers at all points in the supply chain to more effectively track and discriminate between fossil fuel products from different sources. A system for open, transparent and verifiable tracking of oil from different sources and the products derived from them could be built using a Blockchain process. Similar programs are currently being developed to track the provenance of foods or other products fromprimary sources to end products." Alternately, fuel suppliers could emerge that only source their oil from suppliers meeting top tier criteria. Although the actual oil received by a purchaser may come from a pool of oil from all suppliers, the purchasers contracting from those suppliers would receive confirmation that top tier oil offset bottom tier oil in the pool and that the payment was directed to the producer of the top tier oil. This system would shift revenues from low tier producers to upper tier producers without disrupting a pooled oil handling system. This system would be similar to that used currently for "green power" from a provincial electricity grid.75 Delivered price could become only one of several characteristics used by purchasers of energy. It could be difficult to challenge these purchase decisions in the current multilateral trade regime as they would be made by individuals rather than at country level. 10 000035 I Information II disclosed under the Access to information Act Lu sent dlvulgu?s In vortu do la Lolsur l'acds A l'inforrnarian Scenarios Scenarios are used to visualize how the future could evolve under different drivers and conditions. Scenarios are not attempts to predict the future, but rather to explore how the future might emerge, in order to test current assumptions and potential policy approaches against a range of alternatives. reserves. It continues to invest economic, social and political capital in expanding and maintaining production from the oil sands as a driver of employment, economic growth and tax/royalty revenues. I Canada dismisses or actively resists domestic and international initiatives to encourage divestment in fossil fuels or to differentiate oil in international markets based on non- intrinsic qualitative measures. - By defending the World Trade Organization rules that prevent discrimination of oil or petroleum based products based on their origin, and not taking steps to categorize oil based on non-intrinsic criteria, Canada is increasingly at risk of missing the expanding ?premium? oil market and becoming a price taker. Needing to sell to the bottom of the market is further eroding investment in petroleum resources with impacts on tax and royalty revenues and employment. its traditional market, the U.S., requires steep discounts on Canadian bitumen-derived oil as it needs to compensate purchasers for the costs of emissions credits or carbon taxes that are imposed in the U.S., to permit it to meet the significant GHG reductions targets it accepted in negotiations with China. Negative perceptions on its climate/energy stance are spilling into non-energy related matters. Canada?s international "brand" is being significantly damaged and a wide range of Canadian products and services are considered "dirty" in the international market placef"6 Soft power and influence continue to wane across a spectrum of issues. 0 Significant financing costs for investments in fossil fuel infrastructure may need to be written off by the private sector or absorbed into government budgets at the taxpayer?s expense. I - Canada recognizes the growing importance of low-carbon energy as a key discriminator in a carbon-constrained global economy. It is expanding its already high electrification from sources. Promoting its clean electricity story internationally is leading to its products and services being recognized and sought out for their low-carbon content. 0 Canada is becoming Increasingly adept at using its clean electricity by developing andfor 11 000000 I Inform-Non lI disclosed under Access to information Act Lu rennin-menu cont divul'u?s Il'l unrtu do I: lollur race}: a f?lnforma?on being an early adopter of new technologies and processes in the expanding electricity- based industrial and commercial energy ecosystem. It is becoming an increasingly dominant global player in a number of key niche areas of electrical energy use such as data farming and mineral resource extraction/refining using new electricity-based processes. By taking a progressive role in developing and codifying the emerging international information base for the de-commodification of oil, Canada is positioning itself as an important player in this subset of the climate/energy issue. Shifting the component of Canada's oil exports to premium (essentially conventional) sources is allowing it to retain and grow a share of the declining global oil market. Carbon Capture and Storage is cost effective due to advances in technology and environmental credits gained for recovering oil from existing conventional deposits. Research efforts continue on using the energy potential of the oil sands for alternate fuels through in situ biological transformation into hydrogen, ethanol and syngas which are used in transportation, chemicals, plastics and clean combustion to produce electricity for the U.S. Market. 12 000037 implications for Canada I I Information II disclosed under the Access to information Ac! Lu ranulgnamanu son! divulguis on vortu do la La! sur Pact-is f'informarion Canada would be relativelu well placed to take advantaqe of an electricitu-based industrial ecosustem Access to electricity is essentially universal in Canada"7 and approximately 66% of the electricity it produces comes from renewable hydro power and non-greenhouse gas emitting nuclear power. 78 This is in stark contrast to low electrification rates in many developing countries79 and to global electricity generation in which 75% is generated by fossil fuels. While significant parts of the world still need to add capacity and to shift to renewables, Canada has not only sufficient electricity for its domestic needs but capacity to export nearly 10% of its production.$0 Canada also has significant potential to increase its total electricity production81 and to shift its electricity production further to low-carbon sources. These factors place Canada in an enviable position to export low-carbon electricity directly to markets in the U.S. and Mexico. Both economies could be expected to see increasing electricity demand while seeking to reduce their greenhouse gas emissions. The potential for long-distance transmission to further markets could increase as technology advances.83 Canada could also export technology, software and expertise in B2 Data Centres: Economic Hubs of the Digital Economy As digital technologies enable and penetrate more sectors of the global economy, electricity demand associated with data processing. storage and transmission is increasing both in absolute terms as well as share of end-use energy. intercontinental exports of electricity are not yet cost-effective, but data can today be transferred efficiently between continents using high-speed fiber optic cables. Data centers can be located In areas with low-cost, low carbon electricity and favourabi?j?ilmaftes to reduce energy demand for cooling._tafge, fastgand reliable data centers could become innovation and economic hubs by attracting activities for whichco'mputational speed andror volume are an Increasingly digital economy, bene?ts will come to those 'Who are able to store, manipulate. transfer and apply data at the greatest speed and security ?and at the loiNest cost and environmental impact. I 1 i lcelanci proves ideal for carbon neutral data centre electrical energy production, particularly from hydro-electricity, as well as in electricity distribution, management, use and storage. Canada could become a global player in the emerging electrical industrial ecosystem in a number of ways. By hosting data centres, Canada could provide a significant share of the rapidly growing global electrical energy demand from the rising digital economy.? As the economy becomes more digitally-based and additive manufacturing expands, many areas of production could be re-shored. Electricity could be exported to support similar re-shorlng in the U.S. and Mexico. The cost competitiveness or preference for Canadian products or services produced with clean electrical energy could be increased in a carbon-constrained world. Canada could export low-carbon energy embodied in products or services? by attracting production of goods or services that require a lot of electricity but are currently being produced in other countries using relatively high percentages of electricity generated using fossil fuels. 13 000030 I Information is disclosed under the Access to Information lu rnnulgnumunt: writ divulgu?s on vnrtu do ll Lal sur l'accis 6 i?lnforma?on Canada could lead on research to switch industrial processes that are currently fossil-fueled to use electricity and/or be an early adopter of technologies developed elsewhere to produce low embodied-carbon products using electricity. Mineral processing and metallurgy are generally considered mature industrial sectors in which Canada may have a comparative advantage in developing or adopting disruptive technologies using electricity. 86 Canada mat; hold manq of the minerals and metals of an electrified digital world As a new industrial ecosystem evolves to take advantage of electricity, the materials that are used in it will shift. New technologies will require greater amounts of minerals and metals such as lithium, graphite and cobalt for batteries as well as rare earths for the permanent magnets in electric motors.? Canada?s well-developed exploration and mining expertise could place it in a relatively strong position to develop or partner with others to find and develop new sources. Opportunities to find new applications for existing materials or to develop new bio-based materials could also be explored. Canada mat; need to review the anticipated demand for its petroleum assets A significant shift to electrification of personal transport combined with the potential slowing of demand for transportation of goods and people could result in oil demand peaking sooner and declining faster than forecast.88 if these trends were to continue, Canada may find that not all of its petroleum is marketable at prevailing prices, particularly if low-cost producers keep prices low by maintaining or even increasing supplies to keep market share and maximize the sale of their oil assets while oil still has economic value. 89 Canada mau need to reconsider the of different tapes of oil reserves if global or regional markets for Canadian oil begin to differentiate oil based on non-intrinsic values such as embodied greenhouse gas emissions and splinter into tiers, Canadian producers could become either price-makers or price-takers depending on whether their reserves were rated as premium, middle ground, or low tier. It would be important for Canada to understand the criteria that are likely to emerge to define tiers and which of the deposits of fossil fuels in Canada could meet those criteria. As Figure 6 indicates, greenhouse gas emission metrics on some Canadian oil resources are lower than international reputation would suggest. Canada's greenhouse gas emissions profile could be improved by selective development of oil sources even within oil sands deposits. 14 000030 I Information In disclosed under the Access to Information Act lu sent dlvulgu?s an vertu do In Leisur- i'acds l'infarmarion The emergence of a rating system for deposits that classified them based on their tier could significantly reduce shareholder and company value if deposits are rated low or, conversely, increase shareholder value for companies with premium rated deposits. Potential spillover effects could be seen in stock markets like the TSX which are heavily weighted to resources like oil and from there into the economy as a whole. Figure 6: A comparison of greenhouse gas emissions: Canadian vs global oil fields Rim . . . . . . . . . . . . . .. . . . . . . . . .. - - i . M, 2?35, -: '1 {Sit?pqu-d. m: ll 1: ii bk". [tum-1 95: (Diana. filial undo-I?- .- - . .31? .1{p.15 so? i ll . (M HIM fowl .141 - "Source adapted from: Clrn-gl- Endowment for Internationll Pun, ?Know tic-ur Oil. Creating I Global Oil-Climatl lndu", March 2015 Canada has a bulk handling system for oil, gas and coal but may have to consider source segregation, identification and certification for different tiers of oil to avoid rejection of low tier oil by a premium tier purchaser. If linked to a carbon pricing/tax scheme geared towards reducing carbon emissions, one could see a situation in which a purchaser could avoid paying carbon taxes or purchasing emissions permits by buying all which already has a lower embodied-energy of production - the emission reduction would be considered to be intrinsic to the oil. Higher embodied-energy oil would sell at a discount because it would incur higher taxes or emissions permit costs when used. Leodinq on orderlu and responsible transition to post-oil future An emerging grid of actors opposed to oil production could be potentially very disruptive to the Canadian Oil sector. The campaign to encourage investors to divest in fossil fuels"0 may gain momentum. Recognizing that oil will still be a significant component of the global energy mix, at least in the near future, but that some oil is likely to remain in the ground, an opportunity 15 000040 I . I Information 11 disclosed under the Ame: to information Act lu r-nulgnemenh son! divulgu?s on warm do II In! :ur l'acci: l'lnfarma?on may exist for Canada to demonstrate global leadership role in an orderly and responsible transition to a post-oil future. If the market can choose amongst suppliers as a means to address climate change or other goals, it is likely that the demand will be greatest for the least environmentally or socially damaging oil. Canada may have oil that meets an emerging higher bar and by being active in this space, be able to bring this oil to market. An implication of tier- ranking is that some deposits may not be marketable and will have to be written off. This may require Canada to shift its thinking about where to invest in infrastructure and the tax/royalties streams that are likely from different types of oil deposits. There are also potential issues related to decommissioning stranded existing petroleum production and transportation infrastructure. Alternately, Canada may need to research and develop alternate uses for potentially stranded petroleum deposits or means to convert them into energy in forms other than oil such as methane or hydrogen.91 Use for plastics is not likely to be an option considering that no oil is used in plastic production in major markets like the U.S.92 Rethinking Arctic Development Stratequ There are potential implications for Canada?s Arctic if global oil and gas demand does not increase as expected. Arctic oil may be less marketable in an era of global oversupply because of its high cost (including embodied energy of production) but also high perceived environmental risk. Energy companies may be less interested in securing rights to oil and gas deposits in the Arctic or in the development of existing holdings which could reduce economic and employment opportunities for the region. However, materials such as minerals and metals needed in an electricity-based energy ecosystem or natural resources such as fisheries may emerge as assets with strategic and economic value. A shift away from oil and gas as an economic driver could require shifts in development and infrastructure investment decisions. Low cost renewables could challenge Canadian power utilities? business models The potential for unsubsldized and decentralized renewables to produce electricity for the same (or lower) cost as traditional power plants may challenge Canadian utilities to provide cost-competitive electricity under the existing central utility model. In coming years, Innovation, increased mass production capacities and market expansion of Asian, European and American companies will continue to drive down the cost of renewable energy devices and could undermine the competitiveness of Canadian central utility models.? Canada mau face rnuitiple pressures to derequiate its electricitu markets to permit qreater penetration of renewable enerqu production and different business models for its distribution The rapid expansion of renewables, particularly in Asia, may lead to new business models for electricity production and distribution based on the low-cost, scalability and decentralization of renewable energy. Renewable energy technology producers could look to expand their global 16 000041 I . Information I. disclosed undor the Access to Information Act la: rennignemunt: sent divulgu?: Vlrtu do ll L01 our l'aods r} rfnlormarian share in foreign markets. Combined with the potential trade liberalization of environmental goods through the conclusion of the Environmental Goods Agreement94 within the World Trade Organization, foreign-made rooftop photovoltaic power or wind turbines and storage technology may become viable economic options for Canadian electricity consumers owning buildings in commercial, agriculture, institutional, governmental and industrial sectors. Consumers at the individual and corporate level may also drive a shift towards increased share of renewables, which may not be connected to the existing grid, based on their low cost and low carbon emissions. The cost of electricitu from central power plants mot; become more expensive? In the Canadian system in which supply from provincially-owned centralized power plants already meets demand, additions of renewable energy from other actors will offset energy production from the central power plants. Costs of electricity from provincial utilities could increase because large scale nuclear and thermal power plants are optimized for continuous operation. Varying or reducing output from them can reduce their efficiency and increase their cost of operation. Provincial utilities also have debt servicing burdens to cover as well as significant costs associated with maintenance of extensive long-distance transmission lines that may not be required by decentralized renewable-based alternatives.96 Uncertainty about the time frame in which energy from decentralized renewable systems becomes cost-competitive with central utilities? energy prices could increase the risk of public investments in state-owned power plants because the revenues from large, capital~intensive new power plants may not be sufficient to service the public debt incurred to build them. 17 000042 I lnformallon II disclosed under the Arm: to Information Art [as nnulgnumenu nan! dhrulguil on vortu do In lollur Pact-i: l'lnfarmorfon Conclusion It is increasingly plausible to foresee a future in which cheap renewable electricity becomes the world?s primary power source and fossil fuels are relegated to a minority status. This plausible future would seem to favour strategies that develop Ca nada?s own energy production and distribution systems to adopt and benefit from low cost renewable electricity. This would also provide Canada with the necessary expertise to participate in the growing global market for renewable powered electrification. By contrast, this plausible future would seem to recommend against long term investments in oil and gas production, refinement, and distribution infrastructure as these could be at high risk of becoming economically unviable as prices in renewable electricity further decline. At a minimum, this plausible future would suggest that governments ensure that the risks of further investments in oil and gas infrastructure be borne by private sector interests rather than taxpayers. Finally, while overall prospects for fossil fuel producers appear limited in this plausible future, there may be potential for some low-cost, low GHG-emitting Canadian producers to serve a niche market for green and ethical oil. Overall, the potential for significant disruptions in energy over the next 10-15 years; as illustrated in the plausible future described in this paper, would argue for caution by both governments and business to avoid long term investments that may not be viable under changing conditions. 18 000043 I Information In disclosed under the Acme to Information Act Lu renaalgnemanu sent dlvulgues an vartu da la Lofsur .l'acda i' information Annex A: Assumptions This foresight study challenges current assumptions about the expected future of the global energy landscape. It proposes alternative assumptions that are more likely to be robust across a range of future scenarios instead. Assumption Robust Assumption Fossil fuels will continue to dominate global Electricity will increase as a percentage of Primarv energy supply. primary energy globally and may challenge fossil fuels as the predominant form of energy consumed in many economic sectors. Renewable energy requires subsidies to be Many types of renewable-based electricity cost competitive with coal or natural gas generation are already cheaper without powered generation. subsidies than generation by fossil fuel; those that are not are likely to be so within 10 years. Environmental and social considerations will There may not be a requirement to incur remain secondary to economics in energy environmental or social tradeoffs in increasing supply and consumption decisions. energy supply. Declining costs of renewable energy technology combined with increasing internalization of environmental and health costs emissions from fossil fuels could make all forms of renewables the least expensive source of electricity within 10 years. State-based centralized electricity utilities The scalability of renewables, particularly wind and extensive grids will continue to be the and solar could lead to regional or continental dominant business model for supply. mega-grids that span multiple jurisdictions as well as to hyper-local or captive power that is not connected to a utility?s power grid. The contribution of wind and solar to Regional integration of wind and solar electricity generation will be limited by the generation combined with advanced demand high cost of storage needed to compensate management can smooth for the variability oi supply meaning that significantly; storage may not be a limiting peaking plants will always be required. factor until wind and solar'exceed 70% of supply; storage battery costs could continue to decline to be more cost effective than peaking plants; disseminated, lnternet-connected batteries in building?nd vehicles could act as 19 000044 I Information is disclosed under the Access to Information Act Lu renuignements sent divulgu?s en vertn do ll tolsur f?acds f'lnformation virtual peaking plants. Adoption rates for electric vehicles will remain low due to high upfront costs compared to internal combustion engine vehicles, short driving ranges and limited charging infrastructure. Battery costs will decline to the point at which the drive-away cost of an electric vehicle is competitive with a conventional internal combustion engine vehicle; consumer experience with electric vehicles will reduce range anxiety; fleets may change over more quickly than historical average due to changing concepts of car ownership and regulatory measures to reduce environmental and health impacts of fossil fuel use. Global demand for crude oil will substantially grow over the next 10-15 years, mainly driven by a rising vehicle market in emerging countries and growth in freight and aviation sectors. Worldwide demand for fossil fuels could peak earlier and decline faster than predicted, leading to a softening of global demand. Emerging technologies such as electric vehicles and behavioural shifts such as virtual work and the sharing economy in the mobility industry may reduce the demand for oil for transportation. Major oil producing countries will rebalance supplies to increase and stabilize prices. Low-cost oil producers may not curtail supply in order to maintain their share of a diminishing market, seeking to maximize the extraction of their reserves before all is replaced as a predominant energy source. Petroleum-based fuels and products are commodity goods. Purchasers at all points in the supply chain may be able to track products produced from different sources of oil and discriminate between those products based on intrinsic qualities of the source oil as well as non- intrinslc qualities such environmental or social impacts of extraction, transportation and production of the products. 20 000045 I I Information I. diadmd under the Acme to Information Act Lu son! divulguts en vartu de la talsur Face? 0 ?information References 1 IEA, World Enerav Outlook 2014, Executive Summary. 2 IEA, Electricity?s share in industry?s total final energy consumption almost doubled from 15 in 1973 to 27 in 2012. 3 IEA, World Energy Outlook 2014 Factsheet. IEA, World Enerqy Outlook 2014 Factsheet. 5 Energy Research Institute, National Development and Reform Commission. China 2050 High Renewable Energy Penetration Scenario and Roadmapjtucly; 2015. 6 Centre for Energy-Efficient Telecommunications, University of Melbourne, The Power of the Wireless Cloud. The CE ET models estimate the 2012 wireless cloud energy consumption at 9.2 Terawatt hours. The estimated energy consumption of the wireless cloud for 2015 Is between 32 Terawatt hours and 43 Terawatt hours - and increase of between 390% and 460% over three years. 7 Policy Horizons Canada. 2015. Energy Cluster Findings The Future of Asia: Implications for Canada. 3 REN21, Renewables 2014: Global Status Report, 2014, 21; IEA, Renewables information, 2014, Paris, OECD publications. 9 IRENA, ?enewable Power generation costs in 2014, 2015. 1? Deutsche Bank's 2015 solar outlook: accelerating investment and cost competitiveness?, January 13, 2015, mm: "Unsubsidized rooftop solar electricity costs anywhere between $0.13 and $0.23/kWh today, well below retail price of electricity In many markets globally. The economics of solar have improved significantly due to the reduction in solar panel costs, financing costs and balance of system costs. We expect solar system costs to'decrease 545% annually over the next 3+ years which could result in grid parity within "50% of the target markets. If global electricity prices were to Increase at 3% per year and cost reduction occurred at 5-15% CAG R, solar would achieve grid parity in an additional ?30% of target markets globally. We believe the cumulative incremental total available market for solar is currently around ~14OGW/year and could potentially increase to over the next 5 years as solar achieves grid parity In more markets globally and electric capacity needs increase?; Clean Technica, "Solar Pv Costs to 21 000046 . I Information Is disclosed under the Amen to information Act rennin-laments Ion! dhrulgu?s In vnrtu til I. 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This has significant implications for the assumptions used when modelling future 22 000047 I Information I: dlsdoud under the Access to information Act Lu sent Ilhrulgu?s on venu do II Lot lur 'accls a l'infarma?on energy and transport systems and permits an optimistic outlook for BEVs contributing to low- carbon transport?; Tesla, Powerwall Tesla Home Battery, 17 GE, Wind in the Cloud? How the digital Wind Farm will Make Wind Power 20% More Efficient, May 2015, 19 3006786Golwind-in?the-clou d-how-the-digita wind-farm-will IBM, Research Launches Project "Green Horizon?? to Help China Deliver on Ambitious Energy and Environment Goals, July 2014, 03.ibm.com ress us en ressrelease 44202.wg 18 Global Research, Replacing Fossil Fuel and Nuclear Power with Renewable Energy: Wind, Solar and Hydro Power, March 2014, nd-lydro-powe U53i5036; Bloombetg, Obama?s EPA Rule is Redrawing the us. Coal Mag, April 2015, .com ra hics 2015-coal- lants . 19 Brookings, Making Renewable Power Sustainable in India, January 2015, sustainable-in-indiaz 2? RMI, "Learning from the Cell Phone Phenomenon: How Microgrids Can Help Developing Countries Leapfrog into a New Energy Paradigm?, July 2013, htthiblongiorgibloe 2013 07 29 learning from the cell phone phenomenon 21 Mueller, SC, Sandner, PG, and Welpe, IM, "Monitoring innovation in electrochemical energy storage technologies: a patent-based approach? (2014) Applied Energy, DOI: 10.1016/j.apenergy.2014.06.082 22 IEA, Global EV Outlook: Understanding the Electric Vehicle Landscape to 2020, 2013, p. 17. 23 Powerwall; Tesla Motors; 2? Tesla Glgafactory; Tesla Motors; 25 Bjorn and Mans Nilsson, Rapidly falling costs of battery packs for electric vehicles, March 2015, Nature, 'o ll i ?6 Tesla, "Planned 2020 Gigafactory Production Exceeds 2013 Global Production?, . i I i f; Reuters, "China's BYD takes aim at Tesla in battery factory race, 13"1 March 2015, [gum? if": 2 23 000048 I . I Inbrmatlon Ia duelon under the Arm to information Act Lu amalgam-nu sent dlvulguis an vortu do In Lalaur i'acdc 6 anormatlan 27 Morgan Stanley, "Solar Power and Energy Storage: Policy factors vs. Improving Economics?, July 28th 2014, p.6, stanlev energy storage blue paper 2014.pdf 28 ECN, "Design to improve material properties of sodium-ion batteries?, June 26th 2015, batteries; NextBigFUture, "Sakti could mass produce next generation solid state battery for around $100 per kwh?, March 26th 2015, 29 Fortune, "Tesla's gigafactory could be obsolete before it even opens. Here's why?, April 27 2015, fortune.com 2015 04 27 i afactor -obsolete . . . 3? The Guardian, "Low carbon battery-powered train carries first passengers?, January 13t 2015, train-carries-first-passengers 31 570News, "Tesla Motors co-founder Ian Wright wants to electrify gas-guzzling commercial trucks?, June 2 2015, 32 Economie, d?Airbus, premier avion 100% ?lectrique a traverser la Manche", Juillet 10 2015, 33 Green Mountain Power, Tesla Powerwall, 2015, reenmountain ower.com roducts-services overview owerwall 3" Mark Chediak and Dana Hall, Bloomberg, "Elon Musk says utilities shouldn't fear his battery systems?; June 8, 2015; 35 Reneweconomy, "Graph of the Day of cheap shale gas and cheap energy?, January 14th 2015, energy-77050 3? Tesla Energy, oto .c Daimler, ?Sales Launch of private energy storage plants?, June 9th 2015, 37 Charged, "Nissan, GM and Toyota repurpose used EV batteries for stationary storage?, June 17"1 2015, 24 000049 I Inform-lion ll disclosed under lha Access to Information Art Lu rennin-manta sent dlvulgu?s In vertu do la La] Iur Feed: 45 i?informarian Gizmag, "Nissan to incorporate used Leaf batteries in stationary energy storage system?, June 15th 2015, - 38 Vehicle to Home Electricity Supply System; Nissan Motor Corporation, to home.html 39 Nissan, "Leaf to Home Electricity Supply System", to home.html; Automobile propre, Smart-grid Nissan exp?riemente le leaf to home au Japon, D?cembre 2014, f-to-home?iapon[ ?0 Institute for Energy Research, Germany?s Electricity Market Out of Balance, August 2014, flexible-back-power/ Eric Martinot, How is Germany Integrating and Balancing Renewable Energy Today?, January 2015, 41 Bloomberg, ?China out-spends the US for first time in $15bn smart grid market?, February 2014, smart-grid-marketz GSMA, How China is set for global M2M Leadership, June 2014, sma.com connectedlivin haw-china-is-set-for- lobal-mZm-leadershi Poindexter, Owen. 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The-internet-ofvThin s-WilI-Thrive-On-Ener Efficiency-.htmi \loutubeI Smart Energy Systems: 100% Renewable Energy at a National Level, November 2014, YouTube, Smart Solar Energy Management with SMA, Feb 2015, 5: outube.com watch?v=eiBiB40aYOM (its not the best video but it show something quite interesting, home smart system able to accede to weather forecast could tell when is the best time to use appliances and as appliances are becoming smart well it could start the washing machine without you at the right time); Youtube, What is the Smart Grid?, iune 2013, ?2 IBM, Smart Grid, Tesla, Powerwail Tesla Home Battery, Breaking Energy, New Storage Technologies Open Doors for Wind and Solar, May 2015, salad ?3 Solar Heat technology for industrial process - potential, 2015, p. 4, "approximately 40, 96 of industrial primary energy consumption is covered by natural gas and approximately 41 25 000000 I I I Information II disclosed under the Access to infoma'lion Act lea rennin-manta Iont divulgu?s In vortu do In Lei urr i'acels a i'informarlan by petroleum?, ETSAP Tech Brief E21 Solar Heat industrial 2015.pdf 44 IRENA, Solar Heat technology for industrial process potential, 2015 ETSAP Tech Brief E21 Solar Heat Industrial 2015.pdf 45 American Institute of Chemical Engineering, "Molten Salt Gives Concentrated Solar a Unique Advantage?, 2013, solar-unigue-advantage; Low-Tech Magazine, "The bright future of solar thermal powered factories?, YouTube, "Melting steel with solar power?, 2008, embedded 46 IRENA, Solar Heat technology for industrial process potential, 2015 DocumentDownloads Publications IRENA ETSAP Tech Brief E21 Solar Heat industrial 2015.pdf 47 Solar Heat World Wide, Markets and Contribution to the Energy supply 2012, 2014, IEA, Technology roadmap: Solar Heating and Cooling, 2012, p. 26. 48Drake Landing Community, ?The Drake Landing Solar Community (DLSC) is a master planned neighbourhood in the Town of Okotoks, Alberta, Canada that has successfully integrated Canadian energy efficient technologies with a renewable, unlimited energy source - the sun. The first of its kind in North America, DLSC is heated by a district system designed to store abundant solar energy underground during the summer months and distribute the energy to each home for space heating needs during winter months. The system is unprecedented in the World, fulfilling ninety percent of each home?s space heating requirements from solar energy and resulting in less dependency on limited fossil fuels. The Government of Canada and its Canadian industry partners are proud to showcase Canadian solar thermal and energy efficient technologies In this one-of-a-kind community?. ?9 The Economist, LNG: A Liquid market, 2012, 5? RIA, Robotics and Energy Cost Reduction, 2006, "Because robots can operate unsupervised, they can produce items while people are not present. The ability to operate in the dark or in unheated environments can lead to substantial energy savings on the part of manufacturers?, 26 000061 I Information is disclosed under the Amen to information Act Lea ransalgnamlnta lent divulgu?s ll'l vertu dc Ia Laiaur l'accis a 51 Business Insider, China has crossed a major investment threshold that is going to change the entire world, February 2015, abroad-2015-2 5?2 IRENA, Renewable Energy and Jobs: Annual Review 2015, 2015, DocumentDownloads Publications IRENA RE Jobs Annual Review 201 5.9df; UKERC, Low Carbon jobs: The evidence for net job creation from policy support for energy efficiency and renewable energy, November 2014, 5'3 Kenichi Imai, "Impacts of Electrification with Renewable Energies on Local Economies: The Case of India's Rural Areas, march 2013, en.a i.or.' user04 923 226. df 5" Le Monde, lkea s?engage sur les ?nergies renouvelables, June 2015, renouve_lgbles 4646962 3234.html 55 Ecowatch, Tim Cook: New Solar Farm Will Be Apple?s 'Biggest, Boldest and MostAmbitious Project Ever?, February 2015, farm/ 55 Renewable Energy World, Big Companies, Big Renewable investments, August 2014, world.com articles 2014 08 bi -cam anies-bi -renewable- 57 WWF, Powering Businesses on Renewable Energy, ;GreenBiz, Apple, ikea, Walmart 12 leaders in on-site renewables, December 2014, reenbiz.com article A le-Goo le-Walmart-cor orate-renewables-leaders 58 Skolkovo, Emerging Markets Transforming the Global Automotive Industry, .skol ima re Issu - "By 2030, China's annual sales are expected to reach 39 million, or 28 percent of global sales. 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