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

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Receiver & Power Conversion Unit Solar Tower Structure 218 Heliostat Field Figure 75 Central receiver (solar power tower) system configuration Reflected Light Beams Heliostats Several power conversion methods have been developed for solar central receivers. A 10-MW system using molten salt as heat transfer fluid and storage medium, combined with a steam Rankine turbine at up to about 850K was demonstrated in the DOE Solar II project. Other methods are (a) steam generation and superheating in the receiver, (b) heating of atmospheric air to about 950K in the receiver and then using it to superheat steam, and (c) heating of compressed air in the receiver to over 1,100K and using it in a solar/fuel hybrid gas-turbine. On-axis Tracking Systems. On-axis systems, such as the parabolic dish concentrators depicted in Figure 76, provide the highest optical efficiency of all the concentrating solar systems. Their main drawback is the concentrator size, which is limited by practical structural considerations; dishes with reflective area of 15–400 m 2 have been built and tested. Much of the development of on-axis systems involved the use of solarized Stirling engines for power conversion. Recent progress in small Brayton engine development provides the option of using a dish/Brayton system as an alternative to the dish/Stirling system. Recent advancements related to central receivers and on-axis tracking systems focus on improving performance and reducing the cost of the concentrator (heliostat or dish) by increasing the reflector size and working with low-cost structures, better optics, and high-accuracy tracking. Optical efficiency has been increased by means of nonimaging secondary concentration (Welford and Winston 1989; Ries et al. 1997a), improved tracking methods, and better optical system design software. New “directly irradiated” or “volumetric” receivers have been found
Receiver & Power Conversion Unit 219 Concentrated Sunlight Parabolic Dish Concentrator Figure 76 On-axis (parabolic dish concentrator) system configuration that can operate efficiently at high solar fluxes and in temperature and pressure ranges compatible with those of advanced heat engines (Bertocchi et al. 2004; Karni et al. 1997). Enhanced radiation and convection heat transfer have been obtained by developing hightemperature ceramic absorbers for the solar receiver (Karni et al. 1998; Fend et al. 2004). Many estimates indicate that present technologies of the three high-temperature solar systems — linear focus, central receiver, and on-axis concentrators — could produce electricity at a cost that is two to three times larger than that of coal or natural gas plants. The development areas suggested in the Priority Research Directions document should lead to the cost reductions required to make this technology competitive with conventional electricity production within five to ten years, assuming fossil fuels remain at present prices. Concentrated Solar Thermochemical Processes Solar thermochemical processes can be used to generate a primary fuel source. The concentrating component of these systems is identical to that of concentrated solar thermal processes for power generation, but the energy conversion is a thermochemical process converting radiation to heat to chemical potential. These systems provide an effective means for long-term storage and transportation of solar energy in the form of fuel and for its utilization in motor vehicles and industrial applications. The basic concept is shown in Figure 77.
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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
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thin films, organic semiconductors,
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genetic sequencing, protein product
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INTRODUCTION The supply and demand
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showing promise to overcome them. T
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GLOBAL ENERGY RESOURCES 7
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energy can be exploited on the need
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BASIC RESEARCH CHALLENGES FOR SOLAR
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CONVERSION OF SUNLIGHT INTO ELECTRI
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PHYSICS OF PHOTOVOLTAIC CELLS Inorg
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Figure 4 Learning curve for PV prod
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Needs of Direct-gap, Thin-film Phot
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Figure 6 Current record efficiencie
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devices. The molecules and material
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Figure 8 Structure for high-efficie
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One critical property of the photoa
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PHOTOELECTROCHEMICAL STORAGE CELLS
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BASIC RESEARCH CHALLENGES FOR SOLAR
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information about the proteins that
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convert it into H2 and liquid fuels
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charge separation ensures highly ef
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Efficient Photo-initiated Charge Se
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artificial RCs, have proven to be i
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CATALYSTS FOR CO2 REDUCTION Photo-d
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Upon photoexcitation, the electron
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(5) determining the physical and ch
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following challenges must be met: (
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A.F. Heyduk and D.G. Nocera, “Hyd
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J. Seth, V. Palaniappan, R.W. Wagne
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THREE TYPES OF CONCENTRATED SOLAR
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Solar Thermal to Electric Energy Co
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Tm = mean temperature Z = measure o
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control and further diode developme
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An overview of solar thermochemical
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for electron and phonon band struct
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coefficient. The thermal conductivi
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J.J. Greffet, R. Carminati, K. Joul
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CROSS-CUTTING RESEARCH CHALLENGES B
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ange of time and length scales span
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Research Issues Advances in the syn
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Advances across several science fro
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Figure 19 Transparent conductive el
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Carrier generation, relaxation, and
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E. Hutter and J.H. Fendler, “Expl
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PRIORITY RESEARCH DIRECTIONS Revolu
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RESEARCH DIRECTIONS Several paths e
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Multiple Energy Level Solar Cells I
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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
Page 182 and 183: Solar Concentrators and Hot Water H
Page 184 and 185: G. Chen, M.S. Dresselhaus, J.-P. Fl
Page 186 and 187: Materials and Processing Methods to
Page 188 and 189: materials and fabrication approache
Page 190 and 191: multi-electron H2O and CO2 activati
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Page 196 and 197: and quantum dots. Quantum dots are
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Page 202 and 203: Flux (mA/eV.cm2 Flux (mA/eV.cm ) 2
Page 204 and 205: Table 1 Worldwide PV Module Product
Page 206 and 207: Amorphous Silicon. From its discove
Page 208 and 209: Table 2 Are There Enough Materials
Page 210 and 211: passivating window and back-surface
Page 212 and 213: R.R. King, C.M. Fetzer, K.M. Edmond
Page 214 and 215: currently accounting for only a sma
Page 216 and 217: Anaerobic Digestion One gasificatio
Page 218 and 219: Electrolysis is the process for bre
Page 220 and 221: alkaline electrolyzers require a mi
Page 222 and 223: maintenance costs of the small prod
Page 224 and 225: P. Courty, P. Chaumette, and C. Rai
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Page 228 and 229: periods and extend the system opera
Page 230 and 231: When ηopt < 1, Equation (2) become
Page 234 and 235: Figure 77 General concept of solar-
Page 236 and 237: Other areas whose development could
Page 238 and 239: THERMOPHOTOVOLTAICS Thermophotovolt
Page 240 and 241: N. Benz and Th. Kuckelkorn, “A Ne
Page 242 and 243: R.A. Sherif, H.L. Cotal, R.R. King,
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Page 246 and 247: Sub-panelists Edmond Amouyal, Centr
Page 248 and 249: Terry Tritt, Clemson University Joh
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Page 252 and 253: Plenary Closing Session — Wednesd
Page 254 and 255: Panel 1C (Photoelectrochemistry)
Page 256 and 257: Agenda for Solar Fuels Breakout Ses
Page 258 and 259: Tuesday, April 19, 2005, 8:00 a.m.
Page 260 and 261: Wednesday, April 20, 2005, 8:00 a.m
Page 262 and 263: Wednesday, April 20, 2005, 8:00 a.m
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Page 266 and 267: R. Corkish, S. Kettemann, and J. Ne
Page 268 and 269: T. Polivka and V. Sundstrom, “Ult
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Page 274 and 275: microscopy, 81, 85, 101, 155-157, 1
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