• Account for and discuss the main challenges involved in the transition to a sustainable energy system, including definitions of what is meant by “sustainable”.
• Account for the systemic nature of energy innovations and the sources of uncertainty and controversy this gives rise to.
• Account for the economics of energy production, distribution and consumption.
• Account for the principles underlying regulation and deregulation of power markets.
• Account for and critically discuss the theories and conceptual frameworks in the course.
• Demonstrate how these frameworks can be adapted or combined and applied to a concrete innovation strategy case (a company, technology or product) in the form of a short project (miniproject).

Energy is essential for the functioning of modern economies, yet at the same time, CO2 emissions from energy production are by far the largest contributor to global warming.  In a Danish context, carbon-reducing energy technologies such as wind turbines, district heating, and insulation, account for a significant proportion of our exports (over 60 BDKK, or 7% of exports in 2017) and employs about 75.000 persons.  To ensure a sustainable future, the entire system of energy production and consumption will have to be transformed in the decades ahead from fossil fuels to renewable energy sources.  Transportation systems will have to be electrified to substitute renewable energy for fossil-based fuels.  The electrical grid will have to be re-designed to accommodate for intermittent sources of power from wind, solar, and marine sources.  Energy generation will increasingly become distributed among many suppliers, from large centralized power plants to individual “prosumers”.  These changes represent both a huge challenge for society and an opportunity for private enterprise, which will play a key role in the transition.

The purpose of this course is to give you a deep insight into the energy industry from a business perspective.  You will be introduced to the physical realities that shape the functioning of energy markets, the development of the industry, and its unique characteristics.  You will learn how both social and physical processes shape the energy system and how market institutions are crucial for allowing the future development of the system.

We take the point of view of the individual company with an emphasis on innovation and business strategy.  We will focus in particular on frameworks to analyze “systemic innovation”, where the value of a product, process, or technology is fundamentally dependent upon its interaction with other parts of the energy system.  We will apply frameworks from business strategy, innovation, microeconomics, the economics and politics of regulation, and consumer behavior, as they apply to concrete issues in the energy industry. 

Throughout the course, we will involve guest lectures and arrange field visits to Danish energy companies and other organizations involved in the industry.

Outline of topics covered (both substantive areas and theory frameworks):

• Introduction:  Fundamentals of energy technology and sustainable energy.  The Danish energy system in an international context – challenges and opportunities.
• Smart grids and the economics of intermittent supply, energy storage, flexible demand, and grid and load defection. 
• Innovation dynamics (S-curves, first-mover advantage/disadvantage, technology lifecycles)
• Path dependence, technological trajectories, technology transitions in socio-technical systems.
• Energy consumer behavior.  Energy conservation in households and industry. 
• Energy policy at the local, national and international level.  Climate abatement policy.
• The economics of regulation and deregulation.
• Disruptive energy innovations.  Business model innovations.
• Innovations in the transportation sector:  Electric and hydrogen vehicles, car sharing, city logistics.
• Market institutions for flexible energy systems.
• Life cycle analysis.

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• Christensen, J.F.; Truffer, B.; Hekkert, M. (2018) Enterprise Strategies for Sustainable Innovation – Linking economic, organizational and institutional perspectives.  EIS radar paper (draft).  50 pp.
• Climate Interactive (2016) World Climate: A Computer-Simulation-Based Role-Playing Exercise.  https:/​/​www.climateinteractive.org/​programs/​world-climate/​
• Covert, T.; Greenstone, M.; Knittel, C.R. (2016) Will we ever stop using fossil fuels?  Journal of Economic Perspectives, 30(1): 117-138.
• Danish Energy Agency (2012) Energy policy in Denmark.   http:/​/​www.ens.dk/​en/​info/​publications. 30 pp.
• Danish Energy Agency (2014) An energy system without fossil fuels is technically possible.  Energy scenario report.  www.ens.dk.  28 pp.
• DTU (2015) Chapter 3: Synthesis, in Larsen, H. H.; Sønderberg Petersen, L. (eds.), DTU International Energy Report 2015: Energy systems integration for the transition to non-fossil energy systems, pp. 10-14.
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• Ghosh and Nanda (2010) Venture Capital Investment in the Clean Energy Sector, Working paper 11-020, Harvard Business School, 22 pp.
• Goldstein, N., R. Cialdini, et al. (2008) A Room with a Viewpoint: Using Social Norms to Motivate Environmental Conservation in Hotels.  Journal of Consumer Research 35(3):  472–82.
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• Perloff (2012) Exhaustible resources, Section 16.3 in Microeconomics, 6^th edition, Pearson, p. 580-586.
• Porter and Kramer (2006) “Strategy & Society - The Link Between Competitive Advantage and Corporate Social Responsibility”. Harvard Business Review.  13 pp.
• Poulsen, R.; Johnsen, H. (2016) The logic of business vs. the logic of energy management practice: understanding the choices and effects of energy consumption monitoring systems in shipping companies, Journal of Cleaner Production 112: 3785-3797.
• Reinhardt, F.L. (1999) "Bringing the Environment Down to Earth." Harvard Business Review.  9 pp.
• RMI (2015) The economics of battery energy storage (executive summary), Rocky Mountain Institute report.  6 pp.
• RMI (2015) The economics of demand flexibility (executive summary), Rocky Mountain Institute report.  9 pp.
• RMI (2015) The economics of grid defection (executive summary), Rocky Mountain Institute report.  4 pp.
• RMI (2015) The economics of load defection (executive summary), Rocky Mountain Institute report.  13 pp.
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