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When ηopt < 1, Equation (2) becomes ηrec = 1 - σ(TR,H 4 - TL 4 )/ICηopt . (6) This is the receiver efficiency when conduction and convection losses are negligible. The engine efficiency must account for actual losses in its various components and the generator efficiency. Equation (3) therefore becomes where ηeng = (1 - TL/TE,H)(1 - Leng)ηgen , (7) Leng = combined fraction of all the component and parasitic losses ηgen = generator efficiency. Note that in a real system, the effective receiver reradiation temperature TR,H and the upper engine temperature TE,H are usually not the same. An expression for real system efficiency is obtained by introducing Equations 5, 6, and 7 into Equation 4. Typically, as the engine size increases, ηeng also increases, and its specific cost (dollars per kilowatt) is reduced. On the other hand, the high concentration required to maintain high power conversion efficiency during operation at high temperatures (Figure 73 and Equations 1, 2, and 3) is more difficult to attain in large systems, and it is associated with optical efficiency reduction. This difficulty is compounded by the continuous change of the sun’s location, which causes the annual-average components and system efficiencies to be significantly lower than the respective design point efficiencies. Innovations that could alleviate or resolve the apparent mismatch between the optimum size and configuration of the optical and power conversion components in a solar thermal system are vital in achieving the cost reduction required for competitiveness. The traditional approach of the solar community has been that large-volume production is the key to cost reduction. Although this might be true, the development and utilization of lower-cost materials, implementation of more efficient methods, and improvement of key components can also lead to significant cost reduction. Three optical configurations developed for concentrated solar thermal systems are as follows: line focus systems, central receiver systems, and on-axis tracking systems. Line Focus Systems. In line focus systems, sunlight is “folded” in one direction — from a plane to a line. In most cases, the optical configuration is that of a trough tracking the sun from east to west and a target that rotates accordingly (see Figure 74); recently, linear Fresnel reflectors with stationary target have also been used (Mills et al. 2004). The heat transfer fluid is heated in the tubular receiver. It then provides thermal energy to drive a Rankine cycle and 216
Direct Sunlight Tubular Receiver 217 Linear Collector Concentrated Sunlight Rotational Axis Figure 74 Trough (line focus) system configuration generate electricity. The main inherent advantage of the system is its compatibility with large engines (i.e., steam turbines of hundreds of megawatts). The main inherent disadvantage is the low operating temperature, limited to less than 750K by the relatively low concentration and long tubular receiver configuration. About 350 MW of capacity, generated by trough systems, was installed in California in the 1980s and early 1990s and has been continuously improved (Price et al. 2002). Recent developments have focused on means to increase operating temperature and/or reduce components and electricity cost. These include optical improvements with new concepts (Mills et al. 2004) and new designs to reduce optical losses in trough systems (Herrmann et al. 2004). Receiver efficiency can be enhanced by developing selective coatings capable of reaching higher temperature and by introducing smaller and more durable glass-to-metal seals and connections between receiver pipes (Benz and Kuckelkorn 2004). Working fluids and heat transfer means can be improved by direct steam generation in the trough (Almanza et al. 2002) or through the use of molten salt as working fluid. Thermal storage can be introduced by using solid materials (Laing et al. 2004) or high-heat-capacity fluids and phase-change materials (Tamme et al. 2004). Central Receiver Systems. Central receiver systems are fundamentally Fresnel reflector arrays where the reflectors (heliostats) have two axes of rotation and their common focus is stationary, at the top of a tower (see Figure 75). The two-axis tracking enables higher concentration ratios and higher operating temperatures than those of the line focus configuration, but as the system size increases, the optical efficiency declines and this advantage is diminished. The power conversion unit of large central receivers (20–200 MW) is likely to be a steam Rankine turbine, while smaller central receivers can accommodate Brayton and combined cycles operating at higher temperatures. Increasing the temperature generally leads to higher power conversion efficiency but lower optical efficiency; thus, system optimization is required.
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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
Page 180 and 181: 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 232 and 233: Receiver & Power Conversion Unit So
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 272 and 273: 258
Page 274 and 275: microscopy, 81, 85, 101, 155-157, 1
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