TPF-I SWG Report - Exoplanet Exploration Program - NASA

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C HAPTER 2 Beichman, C. A., Fridlund, M. , Traub, W. A., Stapelfledt, K. R., Quirrenbach, A., and Seager, S. “Comparative planetology and the search for life beyond the solar system,” Protostars and Planets V, editors Riepurth, B., et al., University of Arizona Press, Tucson, AZ, 915–928 (2006). Bordé, P. J., and Traub, W. A., “High-contrast imaging from space: Speckle nulling in a low-aberration regime,” Astrophys. J. 638, 488–498 (2006). Christensen, P. R., and Pearl, J. C., “Initial data from the Mars Global Surveyor thermal emission spectrometer experiment: Observations of the Earth,” J. Geophys. Res. 102, 10875–10880 (1997). Des Marais, D. J., Harwit, M. O., Jucks, K. W., Kasting, J. F., Lin, D. N. C., Lunine, J. I., Schneider, J., Seager, S., Traub, W. A., and Woolf, N. J., “Remote sensing of planetary properties and biosignatures of extrasolar terrestrial planets,” Astrobiology 2, 153–181 (2002). Falkowski, P. G., “Evolution: Tracing oxygen’s imprint on Earth’s metabolic evolution,” Science 311, 1724–1725 (2006). Fridlund, M., DARWIN The InfraRed Space Interferometer, ESA-SCI (2000)12, 47 European Space Agency: Noordwijk, The Netherlands (2000). Jucks K. W., Johnson D. G., Chance K. V., Traub W. A., Margitan J. J., Osterman G. B., Salawitch R. J., and Sasano, Y., “Observations of OH, HO 2 , H 2 O, and O 3 in the upper stratosphere: implications for HOx photochemistry,” Geophysical Research Letters 25, 3935–3938 (1998). Kaltenegger, L., Eiroa, C., Stankov, A., Fridlund, M., “The Darwin target star catalog,” Astron. Astrophys. submitted (2007). Kaltenegger, L., and Fridlund, M., “The Darwin mission: Search for extra-solar planets,” Advances in Space Research 36, 1114–1122 (2005). Kaltenegger, L., Traub, W. A., and Jucks, K., “Spectral evolution of an Earth-like planet,” Astrophys. J. in press (2007). Kasting, J. F., and Catling, D., “Evolution of a habitable planet,” Ann. Rev. Astron. Astrophys. 41, 429– 463 (2003). Lovelock J. E., “Thermodynamics and the recognition of alien biospheres [and discussion],” Proc. R. Soc. Lond. B 189, 167–181 (1975). Meadows, V., “Modelling the diversity of extrasolar planets,” Direct Imaging of <strong>Exoplanet</strong>s: Science and Techniques, Proc. IAU Colloquium 200, editors Aime C., and Vakili, F., Cambridge University Press, Cambridge, UK, pp. 25–34 (2006). Montanes-Rodriguez P., Pallé, E., and Goode P. R., “Globally integrated measurements of the Earth’s visible spectral albedo,” Astrophys. J. 629, 1175–1182 (2005). 34
E X O P L A N E T S CIENCE Owen, T., “The search for early forms of life in other planetary systems,” in Strategies for Search for Life in the Universe, editors Papagiannis, M. D., Springer: Dordrecht, The Netherlands, p. 177 (1980). Pavlov, A. A., Kasting, J. F., Brown, L. L., Rages, K. A., Freedman, R., “Greenhouse warming by CH4 in the atmosphere of early Earth,” J. Geophys. Res. 105, 11981–11990 (2000). Schindler, T. L., and Kasting, J. F., “Synthetic spectra of simulated terrestrial atmospheres containing possible biomarker gases,” Icarus 145, 262–271 (2000). Segura, A., Krelove, K., Kasting, J. F., Sommerlatt, D., Meadows V., Crisp D., Cohen, M., and Mlawer, E., “Ozone concentrations and ultraviolet fluxes on Earth-like planets around other stars,” Astrobiology 3, 689–708 (2003). Segura, A., Kasting, J. F., Meadows, V., Cohen, M., Scalo, J., Crisp, D., Butler, R. A. H., and Tinetti, G., “Biosignatures from Earth-like planets around M Dwarfs,” Astrobiology 5, 706–725 (2005). Selsis, F., “Physics of Planets I: Darwin and the Atmospheres of Terrestrial Planets,” Darwin and Astronomy: The Infrared Space Interferometer, ESA SP 451, European Space Agency, Noordwijk, The Netherlands, pp. 133–140 (2000). Selsis, F., Despois, D., and Parisot, J.-P., “Signature of life on exoplanets: Can Darwin produce false positive detections”Astron. Astrophys. 388, 985–1003 (2002). Tinetti, G., Meadows, V. S., Crisp, D., Kiang, N., Bosc, E., Fishbein, E., and Turnbull, M. C., “Detectability of planetary characteristics in disk-averaged spectra. I: The Earth model,” Astrobiology 6, 34–47 (2006). Tinetti, G., Meadows, V. S., Crisp, D., Kiang, N., Kahn, B. H., Bosc, E., Fishbein, E., Velusamy, T., and Turnbull, M. C., “Detectability of planetary characteristics in disk-averaged spectra. II: Synthetic spectra and light-curves of Earth,” Astrobiology 6, 881–900 (2006). Traub, W. A., and Jucks, K., “A possible aeronomy of extrasolar terrestrial planets,” Atmospheres in the Solar System: Comparative Aeronomy, AGU Monograph Series 130, editors Mendillo, M., Nagy A., and Waite J. H., American Geophysical Union: Washington, DC, 369–380 (2002). Turnbull, M. C., Traub, W. A., Jucks, K. W., Woolf, N. J., Meyer, M. R., Gorlova, N., Skrutskie, M. F., and Wilson, J. C., “Spectrum of a habitable world: Earthshine in the near-infrared,” Astrophys. J. 644, 551–559 (2006). Woolf, N. J., Smith, P. S., Traub, W. A., and Jucks, K. W., “The spectrum of Earthshine: A pale blue dot observed from the ground,” Astrophys. J. 574, 430–433 (2002). 35
Page 1 and 2: JPL Publication 07-1 Terrestrial Pl
Page 3: Abstract Over the past two years, t
Page 7 and 8: Acknowledgements Twenty-two represe
Page 9 and 10: Table of Contents 1 Introduction...
Page 11 and 12: 4.8.3 Post-Nulling Calibration.....
Page 13 and 14: 6.4.5 Double Fourier Interferometry
Page 15 and 16: I NTRODUCTION 1 Introduction Over 2
Page 17 and 18: I NTRODUCTION et al. 2004), and res
Page 19 and 20: I NTRODUCTION Standard Interferomet
Page 21: I NTRODUCTION 1.4 References Angel,
Page 24 and 25: C HAPTER 2 0.7 to 1.5 AU scaled by
Page 26 and 27: C HAPTER 2 Table 2-2. Illustrative
Page 28 and 29: C HAPTER 2 Classical interferometry
Page 30 and 31: C HAPTER 2 trivial in the absence o
Page 32 and 33: C HAPTER 2 Figure 2-3. Simulated mi
Page 34 and 35: C HAPTER 2 would be in atmospheres
Page 36 and 37: C HAPTER 2 Figure 2-6. The mid-infr
Page 38 and 39: C HAPTER 2 Lines of constant stella
Page 40 and 41: C HAPTER 2 presence of zodiacal clo
Page 42 and 43: C HAPTER 2 S EZ 2π ∫ θ max ∫
Page 44 and 45: C HAPTER 2 Figure 2-11. Observation
Page 46 and 47: C HAPTER 2 Figure 2-12. Models of t
Page 50 and 51: C HAPTER 2 2.7.4 Suitable Targets E
Page 52 and 53: C HAPTER 2 Reach, W. T., Franz, B.
Page 54 and 55: C HAPTER 3 3.1.1 Darwin/TPF-I Prope
Page 56 and 57: C HAPTER 3 clouds or an OB associat
Page 58 and 59: C HAPTER 3 Figure 3-3. Three possib
Page 60 and 61: C HAPTER 3 the circumstellar disk,
Page 62 and 63: C HAPTER 3 Figure 3-6. (Left panel)
Page 64 and 65: C HAPTER 3 Continuum interferometry
Page 66 and 67: C HAPTER 3 Figure 3-9: Simulated im
Page 68 and 69: C HAPTER 3 3.3 Conclusions Darwin/T
Page 70 and 71: C HAPTER 3 Nguyen, H. T., Kallivaya
Page 73 and 74: D ESIGN AND A R C H I T E C T U R E
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D ESIGN AND A R C H I T E C T U R E
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C HAPTER 5 Heavy launch vehicle. Th
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C HAPTER 5 5.3.2 Combiner Spacecraf
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C HAPTER 5 5.3.5 Beam Transfer betw
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C HAPTER 5 Figure 5-8. Control sche
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C HAPTER 5 Figure 5-9. First sectio
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C HAPTER 5 Figure 5-9 shows the fir
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C HAPTER 5 5.4.4 Shear Metrology Sh
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C HAPTER 5 Figure 5-15. TPF-I Fligh
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C HAPTER 5 secondary mirror along t
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C HAPTER 5 a) c) b) d) IWA = 43 mas
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C HAPTER 5 planets found. Figure 5-
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C HAPTER 5 30 25 5 M earth 3 M eart
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C HAPTER 5 5.8.4 Angular Resolution
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C HAPTER 5 Table 5-3. Angular Resol
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C HAPTER 5 The optimization works b
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T E C H N O L O G Y R OADMAP FOR TP
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F UTURE D EVELOPMENTS 7 Preparatory
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F UTURE D EVELOPMENTS • To comple
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F UTURE D EVELOPMENTS Table 7-1. Pr
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D ISCUSSION AND C ONCLUSION 8 Discu
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Appendices 167
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T E C H N O L O G Y A DVISORY C O M
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F L I G H T S YSTEM C ONFIGURATION
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F L I G H T S YSTEM C ONFIGURATION
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A PPENDIX C 2. Identical FACS fligh
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A PPENDIX C 2. Recall that the coef
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A PPENDIX C Once the formation has
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A PPENDIX C Figure C-3. Example of
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A PPENDIX C Figure C-4. FAST Flight
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A PPENDIX C The “true” time of
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A PPENDIX C References Cohen, S., a
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A PPENDIX D DC DCB DM DM DOCS DOD D
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A PPENDIX D NaCl NAR NASA NASTRAN N
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A PPENDIX E Appendix E TPF-I Review
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A PPENDIX F Alice Quillen, Universi
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A PPENDIX F Figure 3-1 - Original f
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