Basic Research Needs for Solar Energy Utilization - Office of ...

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BASIC SCIENCE CHALLENGES, OPPORTUNITIES, AND RESEARCH NEEDS IN SOLAR FUELS PRODUCTION Biomass-derived Fuels Photosynthetic light-driven biological processes have enormous capacity for sustainable, carbonneutral, solar-powered replacement of fossil fuels by fixing more than 100 Gtons of carbon annually, which is roughly equivalent to 100 TW of energy. However, this fixation rate is currently in balance with respiration and other facets of the global carbon cycle, so adding another 10 TW of fixation would require enormous land areas at present. Primary products of photosynthesis include cell wall components such as cellulose and lignin, as well as storage molecules, starch, sugars, lipids, etc. There are also many intermediate metabolites that could lead to a wide range of other potentially useful organic molecules. These in turn, can be bioconverted to a wide range of fuels and value-added chemicals. Through understanding and discovery, it is possible to increase solar-energy-dependent biofuels production by plants and microbes. Challenges associated with achieving this goal include the following: (1) mining biological diversity to discover improved catalysts for biofuels production; (2) capturing the high efficiency of the early steps of photosynthesis to produce high-value chemicals and fuels; (3) understanding and modifying the bioprocesses that constrain biofuels production due to photosynthetic sink limitations, inefficient reductant use, and environmental factors; (4) elucidating plant cell wall structure and understanding how it can be modified and efficiently deconstructed by protein assemblies; (5) extending nitrogen fixation to biofuel crops to reduce dependence on fossil fuel nitrogen fertilizer; and (6) developing an overall deeper understanding of the biological processes needed to improve plants and microbes to increase solar-energydependent biofuels production. Natural Photosynthetic Systems Natural photosynthesis has achieved the ideal of solar-initiated water splitting coupled to chemical energy storage using abundant, renewable, self-assembling, “soft” matter. The resolution of fundamental structural design principles in natural photosynthesis provides a means to accelerate the discovery of synthetic architectures that embody mechanistic principles used in biology. These principles can be used to realize robust, scalable supramolecular architectures amenable to global energy applications. Two important challenges are (1) the discovery of design principles to maximize the efficiencies of solar energy capture, conversion, and storage; and (2) realization of these enabling principles in advanced biomimetic assemblies where both the supramolecular structures and surrounding supramolecular scaffolds exploit biological designs for function. Meeting these challenges will require the following: (1) understanding and controlling the weak intermolecular forces governing molecular assembly in natural photosynthesis; (2) understanding the biological machinery for cofactor insertion into proteins and protein subunit assemblies; (3) adapting combinatorial, directed-evolution, and high-throughput screening methods to enhance natural photosynthetic systems to increase the efficiency of solar fuels production; (4) characterizing the structural and mechanistic features of new, natural photosynthetic complexes to identify desirable design motifs for artificial photosynthetic systems; and 48
(5) determining the physical and chemical rules that underlie the biological mechanisms for repair and photoprotection. The resolution of structural dynamics across the entire time scale of solar energy conversion is central to the discovery of fundamental design principles for solar energy conversion. Just as ground-state optical absorption spectra cannot reveal the complexity of excited-state reaction dynamics for complex molecular ensembles, static molecular structures cannot reveal the fundamental mechanisms underlying solar energy conversion. Efficient solar energy conversion requires the discovery of mechanisms that control both the ground- and excited-state structural landscapes of complex molecular assemblies — ranging from the attosecond electron dynamics associated with nascent photon absorption and charge separation, to the minutes-and-longer control of atomic motions during the catalytic production of solar fuels. Making these discoveries will require new characterization tools (ultrafast optical, electron paramagnetic resonance, advanced x-ray, neutron scattering, and imaging) to determine structure/function relationships in photosynthetic proteins. Integration of experimental measurements of structural and electronic dynamics with multi-scale theoretical approaches is essential for (1) achieving fundamental breakthroughs in system design paradigms for solar energy capture and conversion by supramolecular structures, and (2) mapping out and predicting optimized ground- and excited-state structural and energy landscapes for efficient solar energy conversion. Catalytic power and specificity, which are key attributes of enzyme-mediated catalysis, have their origins in the active environment provided by the protein. The same is true in the primary solar energy conversion reactions of photosynthesis. The proteins involved in the lightharvesting complexes and the RCs are not just inert scaffolds. They provide much more than just a means of optimally positioning the chromophores and the electron transfer cofactors. The medium provided by the protein actively promotes, enhances, and indeed controls the lightharvesting and electron-transfer reactions both within the protein and across interfacial protein boundaries. This is a key feature of the natural system that allows it to operate so efficiently. Furthermore, proteins can be readily engineered, via genetic modification, to explore a diversity of structure/function scenarios. Because of major limitations imposed by covalent synthesis of large assemblies, construction of the next generation of bio-inspired solar-energy conversion devices will require placing the chromophores into a “smart matrix” to control their key electronic properties by using weak interactions and self-assembly. Achieving efficient integrated solar energy conversion systems using smart matrices will require the following: (1) learning how natural protein matrices control and optimize energy and charge transport both within a single protein and between proteins; (2) engineering proteins, polymers, membranes, gels, and other ordered molecules to provide tailored active environments (i.e. smart matrices); (3) incorporating bio-inspired cofactors within the designed matrix; (4) integrating multiple cofactor-matrix assemblies to perform the overall function; (5) characterizing the coupling between the cofactors and the matrix in natural and bio-inspired systems by using advanced techniques; and (6) developing smart matrices that compartmentalize incompatible products (e.g., O2 and H2). 49
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On the Cover: One route to harvesti
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Revisions, September 2005 p ix, par
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CONTENTS (CONT.) Appendix 4: Additi
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OEC oxygen-evolving complex PCET pr
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viii
Page 12 and 13: thin films, organic semiconductors,
Page 14 and 15: genetic sequencing, protein product
Page 17 and 18: INTRODUCTION The supply and demand
Page 19 and 20: showing promise to overcome them. T
Page 21: GLOBAL ENERGY RESOURCES 7
Page 24 and 25: energy can be exploited on the need
Page 27 and 28: BASIC RESEARCH CHALLENGES FOR SOLAR
Page 29 and 30: CONVERSION OF SUNLIGHT INTO ELECTRI
Page 31 and 32: PHYSICS OF PHOTOVOLTAIC CELLS Inorg
Page 33 and 34: Figure 4 Learning curve for PV prod
Page 35 and 36: Needs of Direct-gap, Thin-film Phot
Page 37 and 38: Figure 6 Current record efficiencie
Page 39 and 40: devices. The molecules and material
Page 41 and 42: Figure 8 Structure for high-efficie
Page 43 and 44: One critical property of the photoa
Page 45 and 46: PHOTOELECTROCHEMICAL STORAGE CELLS
Page 47 and 48: BASIC RESEARCH CHALLENGES FOR SOLAR
Page 49 and 50: information about the proteins that
Page 51 and 52: convert it into H2 and liquid fuels
Page 53 and 54: charge separation ensures highly ef
Page 55 and 56: Efficient Photo-initiated Charge Se
Page 57 and 58: artificial RCs, have proven to be i
Page 59 and 60: CATALYSTS FOR CO2 REDUCTION Photo-d
Page 61: Upon photoexcitation, the electron
Page 65 and 66: following challenges must be met: (
Page 67 and 68: A.F. Heyduk and D.G. Nocera, “Hyd
Page 69: J. Seth, V. Palaniappan, R.W. Wagne
Page 72 and 73: THREE TYPES OF CONCENTRATED SOLAR
Page 74 and 75: Solar Thermal to Electric Energy Co
Page 76 and 77: Tm = mean temperature Z = measure o
Page 78 and 79: control and further diode developme
Page 80 and 81: An overview of solar thermochemical
Page 82 and 83: for electron and phonon band struct
Page 84 and 85: coefficient. The thermal conductivi
Page 86 and 87: J.J. Greffet, R. Carminati, K. Joul
Page 89 and 90: CROSS-CUTTING RESEARCH CHALLENGES B
Page 91 and 92: ange of time and length scales span
Page 93 and 94: Research Issues Advances in the syn
Page 95 and 96: Advances across several science fro
Page 97 and 98: Figure 19 Transparent conductive el
Page 99 and 100: Carrier generation, relaxation, and
Page 101 and 102: E. Hutter and J.H. Fendler, “Expl
Page 103: PRIORITY RESEARCH DIRECTIONS Revolu
Page 106 and 107: RESEARCH DIRECTIONS Several paths e
Page 108 and 109: Multiple Energy Level Solar Cells I
Page 110 and 111: Strain Relaxation. Growth of layers
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the relevant elastic and inelastic
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A.J. Nozik, “Quantum Dot Solar Ce
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these new organic structures, and t
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Figure 30 Schematic diagram (right)
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carrier injection between the indiv
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108
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Figure 32 One important example of
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interface for charge separation. Fo
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• Light harvesting, • Advanced
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116
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Multicomponent structures are often
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REFERENCES A.J. Bard and M.A. Fox,
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PLANT PRODUCTIVITY AND BIOFUEL PROD
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een made in identifying and charact
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126
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SUMMARY OF RESEARCH DIRECTION The k
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developing multi-electron catalytic
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coupling in multi-cofactor-containi
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134
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low toxicity, and processibility. T
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8 electrons) are extremely limited.
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largely unknown are the fundamental
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nanostructure design, and developme
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ealize an efficient artificial phot
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Figure 46 Defect-tolerant solar cel
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equired 20-30 years of operation to
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H2SO4 at 1,130K, and the University
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the sequestration step, these solar
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P. von Zedtwitz and A. Steinfeld,
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The continued advances in energy- a
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for the detailed understanding and
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160
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A shortcoming of this approach is t
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of ~2.4 at 300K and quantum-dot PbT
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High-throughput Experimental Screen
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Solar Concentrators and Hot Water H
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G. Chen, M.S. Dresselhaus, J.-P. Fl
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Materials and Processing Methods to
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materials and fabrication approache
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multi-electron H2O and CO2 activati
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180
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and quantum dots. Quantum dots are
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Flux (mA/eV.cm2 Flux (mA/eV.cm ) 2
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Table 1 Worldwide PV Module Product
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Amorphous Silicon. From its discove
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Table 2 Are There Enough Materials
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passivating window and back-surface
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R.R. King, C.M. Fetzer, K.M. Edmond
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currently accounting for only a sma
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Anaerobic Digestion One gasificatio
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Electrolysis is the process for bre
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alkaline electrolyzers require a mi
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maintenance costs of the small prod
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P. Courty, P. Chaumette, and C. Rai
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212
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periods and extend the system opera
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When ηopt < 1, Equation (2) become
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Receiver & Power Conversion Unit So
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Figure 77 General concept of solar-
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Other areas whose development could
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THERMOPHOTOVOLTAICS Thermophotovolt
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N. Benz and Th. Kuckelkorn, “A Ne
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R.A. Sherif, H.L. Cotal, R.R. King,
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Sub-panelists Edmond Amouyal, Centr
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Terry Tritt, Clemson University Joh
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Plenary Closing Session — Wednesd
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Panel 1C (Photoelectrochemistry)
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Agenda for Solar Fuels Breakout Ses
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Tuesday, April 19, 2005, 8:00 a.m.
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Wednesday, April 20, 2005, 8:00 a.m
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Wednesday, April 20, 2005, 8:00 a.m
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250
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R. Corkish, S. Kettemann, and J. Ne
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T. Polivka and V. Sundstrom, “Ult
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256
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258
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microscopy, 81, 85, 101, 155-157, 1
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