Science, Technology, and Public Policy

The Belfer Center began researching energy technology issues in the late 1990s. Its mission was “to determine and promote the adoption of effective strategies for developing and deploying cleaner and more efficient energy technologies that can reduce greenhouse gas emissions, reduce dependence on fossil fuels and stress on water resources, and improve economic development.”

In this issue, we look at the history and influence of the Center’s energy innovation efforts in the past two decades by focusing primarily on ETIP’s work in the U.S. and China.

This document contains March 2016 updates to our database on U.S. government investments in energy research, development, demonstration, and deployment (ERD3) through the Department of Energy. The database, in Microsoft Excel format, tracks DOE appropriations from FY 1978–2016 and the 2017 budget request and includes funding for ERD3 from the American Recovery and Reinvestment Act of 2009. It also includes several charts.

A new study co-authored by researchers at Harvard Kennedy School's Belfer Center for Science and International Affairs, Duke University’s Nicholas Institute for Environmental Policy Solutions, and the University of Calgary provides the first comprehensive representation of changing water consumption patterns associated with fuel extraction and power generation.

Understanding the long-term patterns of innovation in energy technologies is crucial for technology forecasting and public policy planning in the context of climate change. This paper analyzes which of two common models of innovation over the technology life-cycle — the product-process innovation shift observed for mass-produced goods or the system-component shift observed for complex products and systems — best describes the pattern of innovation in energy technologies.

The Federal Government has many tools at its disposal to advance energy technology innovation. It can signal markets, for example, through energy tax and regulatory policy ("market pull"), and it can advance research, development, and deployment of energy technologies ("technology push"). Both of these kinds of tools can be effective, but the most effective policy portfolio balances a combination of these policies.

This document contains September 2015 updates to our database on U.S. government investments in energy research, development, demonstration, and deployment (ERD3) through the Department of Energy. The database, in Microsoft Excel format, tracks DOE appropriations from FY 1978–2015 and the 2016 budget request and includes funding for ERD3 from the American Recovery and Reinvestment Act of 2009. It also includes several charts.

The Science, Technology, and Public Policy (STPP) Programis seeking a new colleague to manage, coordinate, and conduct research for a major research project. The project examines a wide range of issues focusing on innovations, climate mitigation, and sustainable energy alternatives in China, the United States, and the European Union.

Characterizing the future performance of energy technologies can improve the development of energy policies that have net benefits under a broad set of future conditions. In particular, decisions about public investments in research, development, and demonstration (RD&D) that promote technological change can benefit from (1) an explicit consideration of the uncertainty inherent in the innovation process and (2) a systematic evaluation of the tradeoffs in investment allocations across different technologies. To shed light on these questions, over the past five years several groups in the United States and Europe have conducted expert elicitations and modeled the resulting societal benefits. In this paper, the authors discuss the lessons learned from the design and implementation of these initiatives.

How much should the U.S. government invest on energy R&D, and where should those investments be focused? How can the government work with the private sector to accelerate energy innovation? This book addresses these and other important questions to meet the energy challenge with new analytical methods and data.

Energy technology innovation is the key to driving the technological changes that are necessary to meet the challenge of mitigating energy-related greenhouse gas emissions to avoid 'dangerous climate change.' Success in innovation requires the enhancement of public investment in the innovation process, the creation of markets for low-carbon technologies through stronger climate policies, and a continued focus on energy access and equity.