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Describe how you joined the energy research efforts at NREL and RASEI

Before the National Renewable Energy Laboratory (NREL) was officially designated as one of the 17 U.S. Department of Energy’s National Laboratories by President George H. W. Bush in 1990, it was initially designated as the Solar Energy Research Institute (SERI) and was created under the administration of President Jimmy Carter in March 1977. This was done in response to the global energy crisis created by the OPEC oil embargos of 1973 and 1978. The initial motivation for SERI’s formation was energy security (the U.S. was importing >50% of its petroleum needs in the years after the 1973 oil crisis, and the U.S. natural gas supply was predicted (erroneously) to be depleted by the mid-1980s). SERI grew from zero staff in 1977 to 1200 by 1979 (I joined in Oct, 1978).

During the late 1970s after SERI was established, there was a lot of skepticism in Congress and in the public more generally, that renewable energy, especially solar energy, was a viable energy option. For example, the cost of photovoltaic (PV) electricity in 1974 was $6-8/kWh (today it is less than $0.06 – $0.08/kWh). In addition, there was a strong push-back on the political front from conservative senators and representatives, and their fossil fuel industry supporters, who didn’t like the idea of replacing fossil fuels with renewable energy; this resulted in many senators and representatives taking a look at the newly established SERI and holding congressional hearings (I participated in a few). The general feeling was that it was a haven for hippies of the 1960s, running around in Birkenstock sandals (I did wear a pair), not serious scientists. At universities, including CU, there was skepticism and aloofness about the new, unknown, and unproven group of scientists working at SERI. The skepticism gradually diminished, and in 1999 I became the first Professor Adjoint from NREL appointed to the Chemistry Faculty at CU.

But the early SERI research staff were good, dedicated, and innovative young scientists and began to make important advances in the science and engineering of renewable energy to bring its cost down along a Moore’s Law type of Learning Curve, resulting in renewable wind and PV energy costs being driven down to about ½ of that from fossil and nuclear power plants by 2020.  Furthermore, new funding from DOE’s Office of Basic Energy Sciences (BES) was obtained in 1980 to support a new SERI research Branch called the Solar Photoconversion Branch, focused on solar fuels and artificial photosynthesis, particularly hydrogen production through solar water splitting; I was the Branch Chief from 1980 to 1985, followed by my appointment in 1985 as one of the two initial NREL Senior Research Fellows in NREL’s new Fellows Program (there were a total of 3 initial Fellows appointed in 1985).

However, Ronald Reagan campaigned for President in 1980 on the promise to close the Dept of Energy because “they never produced a barrel of oil”; Reagan’s campaign, together with the Iranian revolution in 1979 that removed the Shah of Iran plus the taking of hostages from the U.S. Embassy in Iran, led to the election of Ronald Reagan and the defeat of President Carter in the 1980 election. The situation at SERI after Reagan became President was tumultuous:  although President Reagan never did close the DOE, the then Secretary of Energy James Edwards came to SERI in 1981 to consider closing it down, but he was persuaded by Golden Elder Joe Coors to not do so (that’s another story for another time). But 2/3 of the SERI staff was terminated, reducing it from 1200 to 400), and SERI funding was also reduced by two-thirds.  But since significant renewable energy utilization was considered a very distant prospect, the basic science programs at SERI funded by BES survived, and flourishes today at greatly enhanced levels of staff and DOE funding, as well as excellent scientific and technological progress, reflected in part by its partnership with RASEI.

Beginning in the 1990s, advances in extraction technology for fossil resources, has led to general agreement that the planet has >100 years of fossil fuel in the ground. But the vast majority of climate scientists have also concluded that the present usage rate of fossil fuel cannot continue without drastic harmful consequences for the environmental health of the earth because of the associated emission of CO₂ greenhouse gas into the atmosphere. Thus, in more recent years, climate change and the need for viable renewable energy alternatives to fossil energy to help sufficiently ameliorate climate change to avoid its worst consequences has become a critical mission for NREL. However, the climate change projections have engendered a strong political backlash, primarily to resist abandonment of the enormous fossil fuel supply and infrastructure at a huge near-term financial cost to the fossil fuel industry and its stakeholders. This has created a very strong political element in the support and funding of NREL’s renewable energy programs by Congress and since 1980 has led to large and unpredictable periodic swings in NREL’s annual budgets depending on the political philosophy of the elected Government Administration and Members of Congress. These are still the political and funding challenges and realities of NREL.

What do you enjoy doing outside of work?

My devoted and loving wife, Rhoda, and I both enjoy hiking, skiing (XC and downhill), biking, and travelling to the artic regions on National Geographic Expeditions.

What made you focus your research on harvesting solar energy?

I first became interested in renewable energy, specifically both photovoltaic (PV) and solar fuels (the latter mainly solar water splitting for creating the so-called hydrogen economy), in the early 1970s. Regarding PV, in 1972, I discovered a new defect semiconductor, Cadmium Stannate, or CTO, that had the best properties as a transparent conductor (very high transparency in the solar spectral region coupled with high conductivity) when compared to other known transparent conductor (ITO, FTO), and it held promise for use in PV solar cells; support for this application was provided by the NSF’s RANN (Research Applied to National Needs) program, which existed from 1971 to 1977. In August 1977, the RANN program was terminated and essentially transferred to ERDA (Energy Research and Development Agency), which in October 1977 was incorporated into the newly formed Department of Energy (DOE); SERI was included in this reorganization and became a DOE funded facility. Also in 1972, following up on my thesis research using Mössbauer spectroscopy to study the electronic properties of Iron-based systems, I discovered that Iron 3+ adsorbed on polycrystalline titanium dioxide surfaces could be oxidized to Iron 4+ when the titanium dioxide was photoexcited with supra-band-gap light (>3 eV). Because the redox potential of the Iron 3+ / Iron 4+ couple is very positive (∼+1.6 V), it was clear that the positive holes photogenerated in titanium dioxide had very strong oxidation potentials. Then, in 1972, the famous Fujishima−Honda paper appeared in Nature, demonstrating that water could be photodecomposed to hydrogen and oxygen gas in a photoelectrolysis cell containing a near-UV-illuminated titanium dioxide photoanode. This paper was consistent with my earlier finding of the strong oxidizing power of photoexcited titanium dioxide.

The oil embargo and energy crisis of 1973−1974 produced a sudden and intense flurry and level of support for research and development for alternatives to fossil energy; this included new R&D activities in industry and at universities. I joined Allied Chemical in 1974 to pursue research on photoelectrochemical energy conversion; this led to my paper in Nature in 1975 that was the first follow-up to the 1972 Fujishima−Honda paper, which clarified some issues with the use of titanium dioxide as a photoanode in a photoelectrolysis solar fuel-producing cell. All of my early 1970s research described above and in the literature from 1975 to 1978 was carried out in the large basic corporate research laboratories of American Cyanamid and Allied Chemical. In 1978, I moved from Allied Chemical to the new DOE SERI laboratory to establish and pursue both photoelectrochemical PV and solar fuels research; I have continued this pursuit ever since at both NREL and beginning in 1999 as a Professor Adjoint and since 2012 as a Research Professor in the Department of Chemistry at CU, Boulder and since 2008 as a RASEI Fellow.

What advice would you give to a junior researcher interested in entering the field of solar energy?

My advice to young researchers to achieve success in any field is to “think outside the box” as much as possible. Maximize your creativity and learn to connect the dots of research progress in widely different fields that are outside of, or apparently tangential, to your own specialized area.  This is done by stimulating your curiosity, exploring science outside of your narrow field, and reading, talking to, and listening to presentations of other scientists to the maximum extent allowed by your personal situation. Persistence in following your instincts and ideas despite setbacks is also critical - don’t allow discouragement to prevent ultimate success.

Why is it so important that we move to using renewable energy sources, in particular solar power?

The scientific evidence is now overwhelming that the present concentration of CO₂ in the atmosphere (415 ppm and rising about 2 ppm/yr)  compared to a stable value of 280 ppm at the start of the industrial revolution 100 years ago, is causing huge negative effects of climate change around the globe, and  these effects will get progressively worse in the future unless this level of CO₂ is reduced by using renewable energy to replace fossil fuel.  Solar irradiance at the surface of the earth delivers as much energy in one hour as all the energy consumed on earth by humanity in one year (18 TW in 2020). The challenge is to implement this change from fossil energy to renewable energy at a reasonable financial cost and appropriate scale before the CO₂ level reaches 450 ppm (the point of no return when the most drastic consequences of climate change are unavoidable and irreversible;  the date of this point of no return is predicted to occur by  about 2035 at the current and expected future increasing rate of CO₂ emissions.  

We are running out of time!