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1. Current laboratory performance of starlight suppression systems, and potential pathways to desired Habitable Worlds Observatory exoplanet science capabilities

Author

Mennesson, Bertrand, Belikov, Ruslan, Por, Emiel, Serabyn, Eugene, Ruane, Garreth, Riggs, A. J. Eldorado, Sirbu, Dan, Pueyo, Laurent, Soummer, Remi, Kasdin, Jeremy, Shaklan, Stuart, Seo, Byoung-Joon, Stark, Christopher, Cady, Eric, Chen, Pin, Crill, Brendan, Fogarty, Kevin, Greenbaum, Alexandra, Guyon, Olivier, Juanola-Parramon, Roser, Kern, Brian, Krist, John, Macintosh, Bruce, Marx, David, Mawet, Dimitri, Prada, Camilo Mejia, Morgan, Rhonda, Nemati, Bijan, Pogorelyuk, Leonid, Redmond, Susan, Seager, Sara, Siegler, Nicholas, Stapelfeldt, Karl, Steiger, Sarah, Trauger, John, Ygouf, a James K. Wallace Marie, and Zimmerman, Neil

Subjects
Astrophysics - Instrumentation and Methods for Astrophysics
Abstract

We summarize the current best polychromatic (10 to 20 % bandwidth) contrast performance demonstrated in the laboratory by different starlight suppression approaches and systems designed to directly characterize exoplanets around nearby stars. We present results obtained by internal coronagraph and external starshade experimental testbeds using entrance apertures equivalent to off-axis or on-axis telescopes, either monolithic or segmented. For a given angular separation and spectral bandwidth, the performance of each starlight suppression system is characterized by the values of raw contrast (before image processing), off-axis (exoplanet) core throughput, and post-calibration contrast (the final 1 sigma detection limit of off-axis point sources, after image processing). To place the current laboratory results in the perspective of the future Habitable Worlds Observatory (HWO) mission, we simulate visible observations of a fiducial Earth/Sun twin system at 12 pc, assuming a 6m (inscribed diameter) collecting aperture and a realistic end-to-end optical throughput. The exposure times required for broadband exoearth detection (20% bandwidth around a wavelength of 0.55 microns) and visible spectroscopic observations (R=70) are then computed assuming various levels of starlight suppression performance, including the values currently demonstrated in the laboratory. Using spectroscopic exposure time as a simple metric, our results point to key starlight suppression system design performance improvements and trades to be conducted in support of HWO exoplanet science capabilities. These trades may be explored via numerical studies, lab experiments, as well as high contrast space-based observations and demonstrations., Comment: 63 pages, 28 pages, submitted to JATIS

Published
2024

2. Flight mask designs of the Roman Space Telescope Coronagraph Instrument

Author

Riggs, A J Eldorado, Moody, Dwight, Gersh-Range, Jessica, Sirbu, Dan, Belikov, Ruslan, Bendek, Eduardo, Bailey, Vanessa P., Balasubramanian, Kunjithapatham, Wilson, Daniel W., Basinger, Scott A., Debes, John, Groff, Tyler D., Kasdin, N. Jeremy, Mennesson, Bertrand, Moore, Douglas M., Ruane, Garreth, Sidick, Erkin, Siegler, Nicholas, Trauger, John, and Zimmerman, Neil T.

Subjects
Astrophysics - Instrumentation and Methods for Astrophysics
Abstract

Over the past two decades, thousands of confirmed exoplanets have been detected; the next major challenge is to characterize these other worlds and their stellar systems. Much information on the composition and formation of exoplanets and circumstellar debris disks can only be achieved via direct imaging. Direct imaging is challenging because of the small angular separations ($<1$ arcsec) and high star-to-planet flux ratios (${\sim}10^{9}$ for a Jupiter analog or ${\sim}10^{10}$ for an Earth analog in the visible). Atmospheric turbulence prohibits reaching such high flux ratios on the ground, so observations must be made above the Earth's atmosphere. The Nancy Grace Roman Space Telescope (Roman), set to launch in the mid-2020s, will be the first space-based observatory to demonstrate high-contrast imaging with active wavefront control using its Coronagraph Instrument. The instrument's main purpose is to mature the various technologies needed for a future flagship mission to image and characterize Earth-like exoplanets. These technologies include two high-actuator-count deformable mirrors, photon-counting detectors, two complementary wavefront sensing and control loops, and two different coronagraph types. In this paper, we describe the complete set of flight coronagraph mask designs and their intended combinations in the Roman Coronagraph Instrument. There are three types of mask configurations included: a primary one designed to meet the instrument's top-level requirement, three that are supported on a best-effort basis, and several unsupported ones contributed by the NASA Exoplanet Exploration Program. The unsupported mask configurations could be commissioned and used if the instrument is approved for operations after its initial technology demonstration phase., Comment: 23 pages, 13 figures, 7 tables, conference

Published
2021
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3. A Decade of NASA Strategic Astrophysics Technology Investments: Technology Maturation, Infusion, and Other Benefits

Author

Pham, Thai, Ganel, Opher, Valinia, Azita, Siegler, Nicholas, Crill, Brendan, and Perez, Mario R.

Subjects
Astrophysics - Instrumentation and Methods for Astrophysics
Abstract

NASA Astrophysics Division funds development of cutting-edge technology to enable its missions to achieve ambitious and groundbreaking science goals. These technology development efforts are managed by the Physics of the Cosmos, Cosmic Origins, and Exoplanet Exploration Programs. The NASA Strategic Astrophysics Technology Program (SAT) was established in 2009 as a new technology maturation program to fill the gap in the Technology Readiness Level range from 3 to 6. Since program inception, 100 SAT grants have been openly competed and awarded, along with dozens of direct-funded projects, leading to a host of technologies advancing their Technology Readiness Levels and/or being infused into space and suborbital missions and ground-based projects. We present the portfolio distribution in terms of specific technology areas addressed, including optics, detectors, coatings, corona graphs, star shades, lasers, electronics, and cooling subsystems. We show an analysis of the rate of Technology Readiness Level advances, infusion success stories, and other benefits such as training the future astrophysics workforce, including students and postdoctoral fellows hired by projects. Finally, we present the Astrophysics Division current strategic technology maturation priorities for investment, enabling a range of future strategic astrophysics missions., Comment: 17 pages, 7 tables, 5 figures

Published
2021
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4. Wavefront sensing and control in space-based coronagraph instruments using Zernike's phase-contrast method

Author

Ruane, Garreth, Wallace, J. Kent, Steeves, John, Prada, Camilo Mejia, Seo, Byoung-Joon, Bendek, Eduardo, Coker, Carl, Chen, Pin, Crill, Brendan, Jewell, Jeff, Kern, Brian, Marx, David, Poon, Phillip K., Redding, David, Riggs, A J Eldorado, Siegler, Nicholas, and Zimmer, Robert

Subjects
Astrophysics - Instrumentation and Methods for Astrophysics, Physics - Optics
Abstract

Future space telescopes with coronagraph instruments will use a wavefront sensor (WFS) to measure and correct for phase errors and stabilize the stellar intensity in high-contrast images. The HabEx and LUVOIR mission concepts baseline a Zernike wavefront sensor (ZWFS), which uses Zernike's phase contrast method to convert phase in the pupil into intensity at the WFS detector. In preparation for these potential future missions, we experimentally demonstrate a ZWFS in a coronagraph instrument on the Decadal Survey Testbed in the High Contrast Imaging Testbed facility at NASA's Jet Propulsion Laboratory. We validate that the ZWFS can measure low- and mid-spatial frequency aberrations up to the control limit of the deformable mirror, with surface height sensitivity as small as 1 pm, using a configuration similar to the HabEx and LUVOIR concepts. Furthermore, we demonstrate closed-loop control, resolving an individual DM actuator, with residuals consistent with theoretical models. In addition, we predict the expected performance of a ZWFS on future space telescopes using natural starlight from a variety of spectral types. The most challenging scenarios require ~1 hr of integration time to achieve picometer sensitivity. This timescale may be drastically reduced by using internal or external laser sources for sensing purposes. The experimental results and theoretical predictions presented here advance the WFS technology in the context of the next generation of space telescopes with coronagraph instruments., Comment: Accepted for publication in JATIS

Published
2020
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5. High-Contrast Testbeds for Future Space-Based Direct Imaging Exoplanet Missions

Author

Mazoyer, Johan, Baudoz, Pierre, Belikov, Ruslan, Crill, Brendan, Fogarty, Kevin, Galicher, Raphael, Groff, Tyler, Guyon, Olivier, Juanola-Parramon, Roser, Kasdin, Jeremy, Leboulleux, Lucie, Sayson, Jorge Llop, Mawet, Dimitri, Prada, Camilo Mejia, Mennesson, Bertrand, N'Diaye, Mamadou, Perrin, Marshall, Pueyo, Laurent, Roberge, Aki, Ruane, Garreth, Serabyn, Eugene, Shaklan, Stuart, Siegler, Nicholas, Sirbu, Dan, Soummer, Remi, Stark, Chris, Trauger, John, and Zimmerman, Neil

Subjects
Astrophysics - Instrumentation and Methods for Astrophysics, Astrophysics - Earth and Planetary Astrophysics
Abstract

Instrumentation techniques in the field of direct imaging of exoplanets have greatly advanced over the last two decades. Two of the four NASA-commissioned large concept studies involve a high-contrast instrument for the imaging and spectral characterization of exo-Earths from space: LUVOIR and HabEx. This whitepaper describes the status of 8 optical testbeds in the US and France currently in operation to experimentally validate the necessary technologies to image exo-Earths from space. They explore two complementary axes of research: (i) coronagraph designs and manufacturing and (ii) active wavefront correction methods and technologies. Several instrument architectures are currently being analyzed in parallel to provide more degrees of freedom for designing the future coronagraphic instruments. The necessary level of performance has already been demonstrated in-laboratory for clear off-axis telescopes (HabEx-like) and important efforts are currently in development to reproduce this accomplishment on segmented and/or on-axis telescopes (LUVOIR-like) over the next two years., Comment: Astro2020 Decadal Survey call for Activities, Projects, or State of the Profession Consideration - APC White Paper. To be published in the Bulletin of the American Astronomical Society (BAAS). 16 pages, 5 figures

Published
2019

6. Technology Needs for Detecting Life Beyond the Solar System: A White Paper in Support of the Astrobiology Science Strategy

Author

Siegler, Nicholas, Bolcar, Matthew, Crill, Brendan P, Domagal-Goldman, Shawn, Mamajek, Eric, and Stapelfeldt, Karl

Subjects
Astrophysics - Instrumentation and Methods for Astrophysics
Abstract

In support of the Astrobiology Science Strategy, this whitepaper outlines some key technology challenges pertaining to the remote search for life in exoplanetary systems. Finding evidence for life on rocky planets outside of our solar system requires new technical capabilities for the key measurements of spectral signatures of biosignature gases, and of planetary mass measurement. Spectra of Earth-like planets can be directly measured in reflected stellar light in the visible band or near-infrared using a factor 1e-10 starlight suppression with occulters, either internal (coronagraph) or external (starshade). Absorption and emission (reflected and thermal) spectra can be obtained in the mid-infrared of rocky planets transiting M-dwarfs via spectroscopy of the transit and secondary eclipse, respectively. Mass can be measured from the star's reflex motion, the reflex motion of a star, via either precision radial velocity methods or astrometry. Several technology gaps must be closed to provide astronomers the necessary capabilities to obtain these key measurements for small planets orbiting within the predicted temperate zones around nearby stars. These involved performance improvements, in some cases, 1-2 orders of magnitude from state-of-the-art or involve performances never demonstrated. The technologies advancing to close these gaps have been identified through the NASA Exoplanet Exploration Program's annual Technology Selection and Prioritization Process in collaboration with the larger exoplanet science and technology community

Published
2018

7. Space Technology for Directly Imaging and Characterizing Exo-Earths

Author

Crill, Brendan and Siegler, Nicholas

Subjects
Astrophysics - Instrumentation and Methods for Astrophysics
Abstract

The detection of Earth-like exoplanets in the habitable zone of their stars, and their spectroscopic characterization in a search for biosignatures, requires starlight suppression that exceeds the current best ground-based performance by orders of magnitude. The required planet/star brightness ratio of order 1e-10 at visible wavelengths can be obtained by blocking stellar photons with an occulter, either externally (a starshade) or internally (a coronagraph) to the telescope system, and managing diffracted starlight, so as to directly image the exoplanet in reected starlight. Coronagraph instruments require advancement in telescope aperture (either monolithic or segmented), aperture obscurations (obscured by secondary mirror and its support struts), and wavefront error sensitivity (e.g. line-of-sight jitter, telescope vibration, polarization). The starshade, which has never been used in a science application, benefits a mission by being decoupled from the telescope, allowing a loosening of telescope stability requirements. In doing so, it transfers the difficult technology from the telescope system to a large deployable structure (tens of meters to greater than 100 m in diameter) that must be positioned precisely at a distance of tens of thousands of kilometers from the telescope. We describe in this paper a roadmap to achieving the technological capability to search for biosignatures on an Earth-like exoplanet from a future space telescope. Two of these studies, HabEx and LUVOIR, include the direct imaging of Earth-sized habitable exoplanets as a central science theme.

Published
2017
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8. Exoplanet Biosignatures: Understanding Oxygen as a Biosignature in the Context of Its Environment

Author

Meadows, Victoria S., Reinhard, Christopher T., Arney, Giada N., Parenteau, Mary N., Schwieterman, Edward W., Domagal-Goldman, Shawn D., Lincowski, Andrew P., Stapelfeldt, Karl R., Rauer, Heike, DasSarma, Shiladitya, Hegde, Siddharth, Narita, Norio, Deitrick, Russell, Lyons, Timothy W., Siegler, Nicholas, and Lustig-Yaeger, Jacob

Subjects
Astrophysics - Earth and Planetary Astrophysics
Abstract

Here we review how environmental context can be used to interpret whether O2 is a biosignature in extrasolar planetary observations. This paper builds on the overview of current biosignature research discussed in Schwieterman et al. (2017), and provides an in-depth, interdisciplinary example of biosignature identification and observation that serves as a basis for the development of the general framework for biosignature assessment described in Catling et al., (2017). O2 is a potentially strong biosignature that was originally thought to be an unambiguous indicator for life at high-abundance. We describe the coevolution of life with the early Earth's environment, and how the interplay of sources and sinks in the planetary environment may have resulted in suppression of O2 release into the atmosphere for several billion years, a false negative for biologically generated O2. False positives may also be possible, with recent research showing potential mechanisms in exoplanet environments that may generate relatively high abundances of atmospheric O2 without a biosphere being present. These studies suggest that planetary characteristics that may enhance false negatives should be considered when selecting targets for biosignature searches. Similarly our ability to interpret O2 observed in an exoplanetary atmosphere is also crucially dependent on environmental context to rule out false positive mechanisms. We describe future photometric, spectroscopic and time-dependent observations of O2 and the planetary environment that could increase our confidence that any observed O2 is a biosignature, and help discriminate it from potential false positives. By observing and understanding O2 in its planetary context we can increase our confidence in the remote detection of life, and provide a model for biosignature development for other proposed biosignatures., Comment: 55 pages. The paper is the second in a series of 5 review manuscripts of the NExSS Exoplanet Biosignatures Workshop. Community commenting is solicited at https://nexss.info/groups/ebwww

Published
2017
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9. Exoplanet Biosignatures: Observational Prospects

Author

Fujii, Yuka, Angerhausen, Daniel, Deitrick, Russell, Domagal-Goldman, Shawn, Grenfell, John Lee, Hori, Yasunori, Kane, Stephen R., Palle, Enric, Rauer, Heike, Siegler, Nicholas, Stapelfeldt, Karl, and Stevenson, Kevin B.

Subjects
Astrophysics - Earth and Planetary Astrophysics
Abstract

Exoplanet hunting efforts have revealed the prevalence of exotic worlds with diverse properties, including Earth-sized bodies, which has fueled our endeavor to search for life beyond the Solar System. Accumulating experiences in astrophysical, chemical, and climatological characterization of uninhabitable planets are paving the way to characterization of potentially habitable planets. In this paper, we review our possibilities and limitations in characterizing temperate terrestrial planets with future observational capabilities through 2030s and beyond, as a basis of a broad range of discussions on how to advance "astrobiology" with exoplanets. We discuss the observability of not only the proposed biosignature candidates themselves, but also of more general planetary properties that provide circumstantial evidence, since the evaluation of any biosignature candidate relies on their context. Characterization of temperate Earth-size planets in the coming years will focus on those around nearby late-type stars. JWST and later 30 meter-class ground-based telescopes will empower their chemical investigations. Spectroscopic studies of potentially habitable planets around solar-type stars will likely require a designated spacecraft mission for direct imaging, leveraging technologies that are already being developed and tested as part of the WFIRST mission. Successful initial characterization of a few nearby targets will be an important touchstone toward a more detailed scrutiny and a larger survey that are envisioned beyond 2030. The broad outlook this paper presents may help develop new observational techniques to detect relevant features as well as frameworks to diagnose planets based on the observables., Comment: part of a series of 5 review manuscripts of the NExSS Exoplanet Biosgnatures Workshop

Published
2017
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10. Exoplanet Biosignatures: Observational Prospects

Author

Fujii, Yuka, Angerhausen, Daniel, Deitrick, Russell, Domagal-Goldman, Shawn, Grenfell, John Lee, Hori, Yasunori, Kane, Stephen R, Pallé, Enric, Rauer, Heike, Siegler, Nicholas, Stapelfeldt, Karl, and Stevenson, Kevin B

Subjects
Space Sciences, Astronomical Sciences, Physical Sciences, Exobiology, Extraterrestrial Environment, Gases, Models, Theoretical, Planets, Exoplanets, Biosignatures, Characterization, Planetary atmospheres, Planetary surfaces, Astronomical and Space Sciences, Geochemistry, Geology, Astronomy & Astrophysics, Astronomical sciences
Abstract

Exoplanet hunting efforts have revealed the prevalence of exotic worlds with diverse properties, including Earth-sized bodies, which has fueled our endeavor to search for life beyond the Solar System. Accumulating experiences in astrophysical, chemical, and climatological characterization of uninhabitable planets are paving the way to characterization of potentially habitable planets. In this paper, we review our possibilities and limitations in characterizing temperate terrestrial planets with future observational capabilities through the 2030s and beyond, as a basis of a broad range of discussions on how to advance "astrobiology" with exoplanets. We discuss the observability of not only the proposed biosignature candidates themselves but also of more general planetary properties that provide circumstantial evidence, since the evaluation of any biosignature candidate relies on its context. Characterization of temperate Earth-sized planets in the coming years will focus on those around nearby late-type stars. The James Webb Space Telescope (JWST) and later 30-meter-class ground-based telescopes will empower their chemical investigations. Spectroscopic studies of potentially habitable planets around solar-type stars will likely require a designated spacecraft mission for direct imaging, leveraging technologies that are already being developed and tested as part of the Wide Field InfraRed Survey Telescope (WFIRST) mission. Successful initial characterization of a few nearby targets will be an important touchstone toward a more detailed scrutiny and a larger survey that are envisioned beyond 2030. The broad outlook this paper presents may help develop new observational techniques to detect relevant features as well as frameworks to diagnose planets based on the observables. Key Words: Exoplanets-Biosignatures-Characterization-Planetary atmospheres-Planetary surfaces. Astrobiology 18, 739-778.

Published
2018

11. Exoplanet Biosignatures: Understanding Oxygen as a Biosignature in the Context of Its Environment.

Author

Meadows, Victoria S, Reinhard, Christopher T, Arney, Giada N, Parenteau, Mary N, Schwieterman, Edward W, Domagal-Goldman, Shawn D, Lincowski, Andrew P, Stapelfeldt, Karl R, Rauer, Heike, DasSarma, Shiladitya, Hegde, Siddharth, Narita, Norio, Deitrick, Russell, Lustig-Yaeger, Jacob, Lyons, Timothy W, Siegler, Nicholas, and Grenfell, J Lee

Subjects
Oxygen, Exobiology, Extraterrestrial Environment, Photosynthesis, Planets, Origin of Life, Astronomical and Space Sciences, Geochemistry, Geology, Astronomy & Astrophysics
Abstract

We describe how environmental context can help determine whether oxygen (O2) detected in extrasolar planetary observations is more likely to have a biological source. Here we provide an in-depth, interdisciplinary example of O2 biosignature identification and observation, which serves as the prototype for the development of a general framework for biosignature assessment. Photosynthetically generated O2 is a potentially strong biosignature, and at high abundance, it was originally thought to be an unambiguous indicator for life. However, as a biosignature, O2 faces two major challenges: (1) it was only present at high abundance for a relatively short period of Earth's history and (2) we now know of several potential planetary mechanisms that can generate abundant O2 without life being present. Consequently, our ability to interpret both the presence and absence of O2 in an exoplanetary spectrum relies on understanding the environmental context. Here we examine the coevolution of life with the early Earth's environment to identify how the interplay of sources and sinks may have suppressed O2 release into the atmosphere for several billion years, producing a false negative for biologically generated O2. These studies suggest that planetary characteristics that may enhance false negatives should be considered when selecting targets for biosignature searches. We review the most recent knowledge of false positives for O2, planetary processes that may generate abundant atmospheric O2 without a biosphere. We provide examples of how future photometric, spectroscopic, and time-dependent observations of O2 and other aspects of the planetary environment can be used to rule out false positives and thereby increase our confidence that any observed O2 is indeed a biosignature. These insights will guide and inform the development of future exoplanet characterization missions. Key Words: Biosignatures-Oxygenic photosynthesis-Exoplanets-Planetary atmospheres. Astrobiology 18, 630-662.

Published
2018

12. Exoplanet Biosignatures: Understanding Oxygen as a Biosignature in the Context of Its Environment

Author

Meadows, Victoria S, Reinhard, Christopher T, Arney, Giada N, Parenteau, Mary N, Schwieterman, Edward W, Domagal-Goldman, Shawn D, Lincowski, Andrew P, Stapelfeldt, Karl R, Rauer, Heike, DasSarma, Shiladitya, Hegde, Siddharth, Narita, Norio, Deitrick, Russell, Lyons, Timothy W, Siegler, Nicholas, and Lustig-Yaeger, Jacob

Subjects
astro-ph.EP
Abstract

Here we review how environmental context can be used to interpret whether O2is a biosignature in extrasolar planetary observations. This paper builds onthe overview of current biosignature research discussed in Schwieterman et al.(2017), and provides an in-depth, interdisciplinary example of biosignatureidentification and observation that serves as a basis for the development ofthe general framework for biosignature assessment described in Catling et al.,(2017). O2 is a potentially strong biosignature that was originally thought tobe an unambiguous indicator for life at high-abundance. We describe thecoevolution of life with the early Earth's environment, and how the interplayof sources and sinks in the planetary environment may have resulted insuppression of O2 release into the atmosphere for several billion years, afalse negative for biologically generated O2. False positives may also bepossible, with recent research showing potential mechanisms in exoplanetenvironments that may generate relatively high abundances of atmospheric O2without a biosphere being present. These studies suggest that planetarycharacteristics that may enhance false negatives should be considered whenselecting targets for biosignature searches. Similarly our ability to interpretO2 observed in an exoplanetary atmosphere is also crucially dependent onenvironmental context to rule out false positive mechanisms. We describe futurephotometric, spectroscopic and time-dependent observations of O2 and theplanetary environment that could increase our confidence that any observed O2is a biosignature, and help discriminate it from potential false positives. Byobserving and understanding O2 in its planetary context we can increase ourconfidence in the remote detection of life, and provide a model forbiosignature development for other proposed biosignatures.

Published
2017

15. Flight mask designs of the Roman Space Telescope Coronagraph Instrument

Author

Zimmerman, Neil T, Trauger, John, Siegler, Nicholas, Sidick, Erkin, Ruane, Garreth, Moore, Douglas M, Mennesson, Bertrand, Kasdin, Jeremy N, Groff, Tyler D, Debes, John, Basinger, Scott A, Wilson, Daniel W, Balasubramanian, Kunjithapatham, Baileya, Vanessa P, Bendeka, Eduardo, Belikovc, Ruslan, Sirbu, Dan, Gersh-Rangeb, Jessica, Moodya, Dwight, and Riggs, A.J. Eldorado

Abstract

Over the past two decades, thousands of con?rmed exoplanets have been detected; the next major challenge is to characterize these other worlds and their stellar systems. Much information on the composition and formation of exoplanets and circumstellar debris disks can only be achieved via direct imaging. Direct imaging is challenging because of the small angular separations (< 1 arcsec) and high star-to-planet ux ratios (?109 for a Jupiter analog or ?1010 for an Earth analog in the visible). Atmospheric turbulence prohibits reaching such high ux ratios on the ground, so observations must be made above the Earth's atmosphere. The Nancy Grace Roman Space Telescope (Roman), set to launch in the mid-2020s, will be the ?rst space-based observatory to demonstrate high-contrast imaging with active wavefront control using its Coronagraph Instrument. The instrument's main purpose is to mature the various technologies needed for a future agship mission to image and characterize Earth-like exoplanets. These technologies include two high-actuator-count deformable mirrors, photon-counting detectors, two complementary wavefront sensing and control loops, and two di?erent coronagraph types. In this paper, we describe the complete set of ight coronagraph mask designs and their intended combinations in the Roman Coronagraph Instrument. There are three types of mask con?gurations included: a primary one designed to meet the instrument's top-level requirement, three that are supported on a best-e?ort basis, and several unsupported ones contributed by the NASA Exoplanet Exploration Program. The unsupported mask con?gurations could be commissioned and used if the instrument is approved for operations after its initial technology demonstration phase.

Published
2021

16. Flight mask designs of the Roman Space Telescope Coronagraph Instrument

Author

Riggs, A.J. Eldorado, Moodya, Dwight, Gersh-Rangeb, Jessica, Sirbu, Dan, Belikovc, Ruslan, Bendeka, Eduardo, Baileya, Vanessa P, Balasubramanian, Kunjithapatham, Wilson, Daniel W, Basinger, Scott A, Debes, John, Groff, Tyler D, Kasdin, Jeremy N, Mennesson, Bertrand, Moore, Douglas M, Ruane, Garreth, Sidick, Erkin, Siegler, Nicholas, Trauger, John, and Zimmerman, Neil T

Published
2021

23. Design description and commissioning performance of a stable coronagraph technology development testbed for direct imaging of Earth-like exoplanets

Author

Patterson, Keith D, Seo, Byoung-Joon, Balasubramanian, Kunjithapatham, Chui, Talso, Crill, Brendan, Gill, John, Kern, Brian, Lam, Ray, Marx, David, Moody, Dwight, Mejia Prada, Camilo, Ruane, Garreth, Rupp, Jordan, Shaw, John, Shi, Fang, Siegler, Nicholas, Tang, Hong, Trauger, John, White, Victor, Wilson, Daniel, Yee, Karl, and Zimmer, Robert

Published
2019

24. Design description and commissioning performance of a stable coronagraph technology development testbed for direct imaging of Earth-like exoplanets

Author

Zimmer, Robert, Yee, Karl, Wilson, Daniel, White, Victor, Trauger, John, Tang, Hong, Siegler, Nicholas, Shi, Fang, Shaw, John, Rupp, Jordan, Ruane, Garreth, Mejia Prada, Camilo, Moody, Dwight, Marx, David, Lam, Ray, Kern, Brian, Gill, John, Crill, Brendan, Chui, Talso, Balasubramanian, Kunjithapatham, Seo, Byoung-Joon, and Patterson, Keith D

Abstract

UNKNOWN

Published
2019

25. In Space Assembled Telescope (ISAT) Study Preliminary Findings

Author

Mukherjee, Rudranarayan, Siegler, Nicholas, Thronson, Harley, Greenhouse, Matthew, Peterson, Bradley, Grunsfeld, John, Bowman, Lynn, Polidon, Ronald, and MacEwen, Howard

Subjects
Astrophysics
Abstract

“When is it advantageous to assemble telescopes in space rather than deploying them from launch vehicle fairings”? This question forms the crux of the objectives of a NASA study we have been conducting in collaboration with colleagues from different NASA centers, industry and academia. In this study, we have engaged a broad cross section of experts from the various fields of optics engineering, that is, telescope design and instrument design, structure and thermal engineering, robotics, launch system engineering, orbital mechanics, integration and testing, astrophysics, and NASA programmatics among others. Initial efforts began with a quick review of the current state of art of the component technologies that contribute towards an in-space assembled telescope. Then, leveraging the collective expertise of the diverse group of experts, we formulated a reference telescope design and attempted to develop a baseline approach to modularize the telescope into components amenable for robotic assembly. The group identified different trades associated with modularization and also developed a set of criteria to discern between the different options as revealed by the trades. Based on the modularization of the telescope, we will assess the impact of various launch vehicles, orbits for assembly and operation, robotic systems and operational approaches, and other related variables. From this, a concept to assemble the reference telescope in space from modular components will be developed. Based on this concept, and definition of the modules, we will develop a mission lifecycle plan for an assembled telescope over different phases of preliminary design, detailed design, assembly-test-and-integration, and in space operations. The mission lifecycle plan will be used to evaluate cost and risk implications of in-space assembly toward answering our fundamental question of the advantages, if any, of assembling a telescope in space as compared to self-deployment. In this paper, we summarize the objectives of the study, a review of the status of the underlying component technologies, a description of the methodology, including three different multi-day technical interchange meetings (TIMs), summary of findings from the TIMs and other related activities. In addition, a detailed description of the various factors that impact in-space assembly, their interplay and criteria for discerning among them, a preliminary description of the life cycle plan, including the test and integration plan, and initial observations on cost and risk implications will be included in the paper.

Published
2019

36. Flight mask designs of the Roman Space Telescope coronagraph instrument

Author

Riggs, A.J. Eldorado, primary, Bailey, Vanessa, additional, Moody, Dwight C., additional, Sidick, Erkin, additional, Balasubramanian, Kunjithapatham, additional, Moore, Douglas M., additional, Wilson, Daniel W., additional, Ruane, Garreth, additional, Sirbu, Dan, additional, Gersh-Range, Jessica, additional, Trauger, John, additional, Mennesson, Bertrand, additional, Siegler, Nicholas, additional, Bendek, Eduardo, additional, Groff, Tyler D., additional, Zimmerman, Neil T., additional, Debes, John, additional, Basinger, Scott A., additional, and Kasdin, N. Jeremy, additional

Published
2021
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37. Design of the vacuum high contrast imaging testbed for CDEEP, the Coronagraphic Debris and Exoplanet Exploring Pioneer

Author

Lystrup, Makenzie, Perrin, Marshall D., Batalha, Natalie, Siegler, Nicholas, Tong, Edward C., Maier, Erin R., Douglas, Ewan S., Kim, Dae Wook, Su, Kate, Ashcraft, Jaren N., Breckinridge, James B., Choi, Heejoo, Choquet, Élodie, Connors, Thomas E., Durney, Olivier, Gonzales, Kerry L., Guthery, Charlotte E., Haughwout, Christian A., Heath, James C., Hyatt, Justin, Lumbres, Jennifer, Males, Jared R., Matthews, Elisabeth C., Milani, Kian, Montoya, Oscar M., N'Diaye, Mamadou, Noenickx, Jamison, Pogorelyuk, Leonid, Ruane, Garreth, Schneider, Glenn, Smith, George A., Stark, Christopher C., Lystrup, Makenzie, Perrin, Marshall D., Batalha, Natalie, Siegler, Nicholas, Tong, Edward C., Maier, Erin R., Douglas, Ewan S., Kim, Dae Wook, Su, Kate, Ashcraft, Jaren N., Breckinridge, James B., Choi, Heejoo, Choquet, Élodie, Connors, Thomas E., Durney, Olivier, Gonzales, Kerry L., Guthery, Charlotte E., Haughwout, Christian A., Heath, James C., Hyatt, Justin, Lumbres, Jennifer, Males, Jared R., Matthews, Elisabeth C., Milani, Kian, Montoya, Oscar M., N'Diaye, Mamadou, Noenickx, Jamison, Pogorelyuk, Leonid, Ruane, Garreth, Schneider, Glenn, Smith, George A., and Stark, Christopher C.

Abstract

The Coronagraphic Debris Exoplanet Exploring Payload (CDEEP) is a Small-Sat mission concept for high contrast imaging of circumstellar disks. CDEEP is designed to observe disks in scattered light at visible wavelengths at a raw contrast level of 10-7 per resolution element (10-8 with post processing). This exceptional sensitivity will allow the imaging of transport dominated debris disks, quantifying the albedo, composition, and morphology of these low-surface brightness disks. CDEEP combines an off-axis telescope, microelectromechanical systems (MEMS) deformable mirror, and a vector vortex coronagraph (VVC). This system will require rigorous testing and characterization in a space environment. We report on the CDEEP mission concept, and the status of the vacuum-compatible CDEEP prototype testbed currently under development at the University of Arizona, including design development and the results of simulations to estimate performance.

Published
2020

38. Euclid mission status after mission critical design

Author

Lystrup, Makenzie, Perrin, Marshall D., Batalha, Natalie, Siegler, Nicholas, Tong, Edward C., Laureijs, R., Racca, Giuseppe, Mellier, Y., Musi, P., Brouard, L., Boenke, Tobias, Gaspar Venancio, Luis M., Maiorano, E., Short, Alexander, Strada, Paolo, Altieri, B., Buenadicha, G., Dupac, Xavier, Gomez, Pedro, Hoar, John, Kohley, Ralf, Vavrek, Roland D., Rudolph, A., Schmidt, M., Amiaux, Jérôme, Aussel, Herve, Berthé, Michel, Cropper, Mark, Cuillandre, J. C., Dabin, C., Dinis, J., Nakajima, R., Maciaszek, Thierry, Scaramella, R., da Silva, A., Tereno, I., Williams, O., Zacchei, A., Azzollini, Ruyman, Bernardeau, F., Brinchmann, J., Brockley-Blatt, Chris, Castander, F., Cimatti, A., Conselice, C., Ealet, Anne, Fosalba, P., Gillard, William, Guzzo, L., Hoekstra, H., Hudelot, P., Jahnke, K., Kitching, T., Miller, L., Mohr, J., Percival, W., Pettorino, V., Rhodes, J., Sánchez, A., Sauvage, Marc, Serrano, S., Teyssier, R., Weller, J., Zoubian, Julien, Lystrup, Makenzie, Perrin, Marshall D., Batalha, Natalie, Siegler, Nicholas, Tong, Edward C., Laureijs, R., Racca, Giuseppe, Mellier, Y., Musi, P., Brouard, L., Boenke, Tobias, Gaspar Venancio, Luis M., Maiorano, E., Short, Alexander, Strada, Paolo, Altieri, B., Buenadicha, G., Dupac, Xavier, Gomez, Pedro, Hoar, John, Kohley, Ralf, Vavrek, Roland D., Rudolph, A., Schmidt, M., Amiaux, Jérôme, Aussel, Herve, Berthé, Michel, Cropper, Mark, Cuillandre, J. C., Dabin, C., Dinis, J., Nakajima, R., Maciaszek, Thierry, Scaramella, R., da Silva, A., Tereno, I., Williams, O., Zacchei, A., Azzollini, Ruyman, Bernardeau, F., Brinchmann, J., Brockley-Blatt, Chris, Castander, F., Cimatti, A., Conselice, C., Ealet, Anne, Fosalba, P., Gillard, William, Guzzo, L., Hoekstra, H., Hudelot, P., Jahnke, K., Kitching, T., Miller, L., Mohr, J., Percival, W., Pettorino, V., Rhodes, J., Sánchez, A., Sauvage, Marc, Serrano, S., Teyssier, R., Weller, J., and Zoubian, Julien

Abstract

Euclid, an ESA mission designed to characterise dark energy and dark matter, passed its Mission Critical Design Review in November 2018. It was demonstrated that the project is ready to start integration and test of the main systems, and that it has the ability to fulfil its top-level mission requirements. In addition, based on the performances at M-CDR, the scientific community has verified that the science requirements can be achieved for the Weak Lensing and Galaxy Clustering dark energy probes, namely a dark energy Figure of Merit of 400 and a 2% accuracy in the growth factor exponent gamma. We present the status of the main elements of the Euclid mission in the light of the demanding high optical performance which is the essential design driver is the to meet the scientific requirements. We include the space segment comprising of a service module and payload module hosting the telescope and its two scientific instruments, and the ground segment, which encompasses the operational and science ground segment. The elements for the scientific success of the mission for a timely release of the data are shortly presented: the processing and calibration of the data, and the design of the sky survey. Euclid is presently on schedule for a launch in September 2022.

Published
2020

39. The Roman exoplanet Imaging data challenge: a major community engagement effort

Author

Lystrup, Makenzie, Perrin, Marshall D., Batalha, Natalie, Siegler, Nicholas, Tong, Edward C., Girard, Julien H., Bogat, Ell, Gonzalez-Quiles, Junellie, Hildebrandt, Sergi R., Kane, Stephen R., Li, Zhexing, Turnbull, Margaret C., Stark, Christopher, Mandell, Avi, Meshkat, Tiffany, Zimmerman, Neil T., Lystrup, Makenzie, Perrin, Marshall D., Batalha, Natalie, Siegler, Nicholas, Tong, Edward C., Girard, Julien H., Bogat, Ell, Gonzalez-Quiles, Junellie, Hildebrandt, Sergi R., Kane, Stephen R., Li, Zhexing, Turnbull, Margaret C., Stark, Christopher, Mandell, Avi, Meshkat, Tiffany, and Zimmerman, Neil T.

Abstract

Organized by the Turnbull Science Investigation Team (SIT), the 2019-2020 Roman Exoplanet Imaging Data Challenge (EIDC) launched in mid October 2019 and ran for eight months. This data challenge was a unique opportunity for exoplanet scientists of all backgrounds and experience levels to get acquainted with realistic Roman CGI (coronagraphic) simulated data with a new contrast regimes at 10-8 to 10-9 enabling to unveil planets down to the Neptune-mass in reflected light. Participating teams had to recover the astrometry of an exoplanetary system combining precursor radial velocity data (also simulated across 15 years) with two to six coronagraphic imaging epochs (HLC and Star Shade). They had to perform accurate orbital fitting and determine the mass of any planet hidden in the data. It involved PSF subtraction techniques, post-processing and other astrophysics hurdles to overcome such as contamination sources (stellar, extragalactic and exozodiacal light). We organized four tutorial "hack-a-thon" events to get as many people on-board. The EIDC proved to be an excellent way to engage with the intricacies of the first mission to perform wavefront control in space, as a pathfinder to future flagship missions. It also generated a lot of positive interactions between open source package owners and a whole new set of young exoplanet scientists running them. As a community we are a few steps closer to being ready to analyze real CGI data!

Published
2020

40. Wavefront control experiments with a single mode fiber at the High-Contrast Spectroscopy Testbed for Segmented Telescopes (HCST)

Author

Lystrup, Makenzie, Perrin, Marshall D., Batalha, Natalie M., Siegler, Nicholas, Tong, Edward C., Llop-Sayson, Jorge, Jovanovic, Nemanja, Morrissey, Grady, Echeverri, Daniel, Mawet, Dimitri, Lystrup, Makenzie, Perrin, Marshall D., Batalha, Natalie M., Siegler, Nicholas, Tong, Edward C., Llop-Sayson, Jorge, Jovanovic, Nemanja, Morrissey, Grady, Echeverri, Daniel, and Mawet, Dimitri

Abstract

Achieving high levels of contrast over broad bandwidths with segmented aperture telescopes is a key requirement to maximize the scientific yield for future exoplanet imaging missions and ground-based extremely large telescopes. The High-Contrast Spectroscopy Testbed for Segmented Telescopes (HCST) in the Exoplanet Technology Laboratory (ET Lab) at Caltech is designed to proof test new technologies aimed at tackling some of the most pressing and challenging goals of exoplanet science, namely the imaging and spectroscopic characterization of small planets across a wide range of stellar host types, including temperature Earth-size planets. Here we report on the status of a key milestone: Demonstration of 20% bandwidth nulling experiments using single mode fibers wavefront control.

Published
2020

41. The Nancy Grace Roman Space Telescope Coronagraph Instrument (CGI) technology demonstration

Author

Lystrup, Makenzie, Perrin, Marshall D., Batalha, Natalie, Siegler, Nicholas, Tong, Edward C., Kasdin, N. Jeremy, Bailey, Vanessa P., Mennesson, Bertrand, Zellem, Robert T., Ygouf, Marie, Rhodes, Jason, Luchik, Thomas, Zhao, Feng, Riggs, A. J. Eldorado, Seo, Byoung-Joon, Krist, John, Kern, Brian, Tang, Hong, Nemati, Bijan, Groff, Tyler D., Zimmerman, Neil, Macintosh, Bruce, Turnbull, Margaret, Debes, John, Douglas, Ewan S., Lupu, Roxana E., Lystrup, Makenzie, Perrin, Marshall D., Batalha, Natalie, Siegler, Nicholas, Tong, Edward C., Kasdin, N. Jeremy, Bailey, Vanessa P., Mennesson, Bertrand, Zellem, Robert T., Ygouf, Marie, Rhodes, Jason, Luchik, Thomas, Zhao, Feng, Riggs, A. J. Eldorado, Seo, Byoung-Joon, Krist, John, Kern, Brian, Tang, Hong, Nemati, Bijan, Groff, Tyler D., Zimmerman, Neil, Macintosh, Bruce, Turnbull, Margaret, Debes, John, Douglas, Ewan S., and Lupu, Roxana E.

Abstract

The Coronagraph Instrument (CGI) on the Nancy Grace Roman Space Telescope will demonstrate the highcontrast technology necessary for visible-light exoplanet imaging and spectroscopy from space via direct imaging of Jupiter-size planets and debris disks. This in-space experience is a critical step toward future, larger missions targeted at direct imaging of Earth-like planets in the habitable zones of nearby stars. This paper presents an overview of the current instrument design and requirements, highlighting the critical hardware, algorithms, and operations being demonstrated. We also describe several exoplanet and circumstellar disk science cases enabled by these capabilities. A competitively selected Community Participation Program team will be an integral part of the technology demonstration and could perform additional CGI observations beyond the initial tech demo if the instrument performance warrants it.

Published
2020

42. SPHEREx: NASA's near-infrared spectrophotometric all-sky survey

Author

Lystrup, Makenzie, Perrin, Marshall D., Batalha, Natalie, Siegler, Nicholas, Tong, Edward C., Crill, Brendan P., Werner, Michael, Akeson, Rachel, Ashby, Matthew, Bleem, Lindsey, Bock, James J., Bryan, Sean, Burnham, Jill, Byunh, Joyce, Chang, Tzu-Ching, Chiang, Yi-Kuan, Cook, Walter, Cooray, Asantha, Davis, Andrew, Doré, Olivier, Dowell, C. Darren, Dubois-Felsmann, Gregory P., Eifler, Tim, Faisst, Andreas, Habib, Salman, Heinrich, Chen, Heitmann, Katrin, Heaton, Grigory, Hirata, Christopher, Hristov, Viktor, Hui, Howard, Jeong, Woong-Seob, Kang, Jae Hwan, Kecman, Branislav, Kirkpatrick, J. Davy, Korngut, Phillip M., Krause, Elisabeth, Lee, Bomee, Lisse, Carey, Masters, Daniel, Mauskopf, Philip, Melnick, Gary, Miyasaka, Hiromasa, Nayyeri, Hooshang, Nguyen, Hien, Öberg, Karin, Padin, Steve, Paladini, Roberta, Pourrahmani, Milad, Pyo, Jeonghyun, Smith, Roger, Song, Yong-Seong, Symons, Teresa, Teplitz, Harry, Tolls, Volker, Unwin, Stephen, Windhorst, Rogier, Yang, Yujin, Zemcov, Michael, Lystrup, Makenzie, Perrin, Marshall D., Batalha, Natalie, Siegler, Nicholas, Tong, Edward C., Crill, Brendan P., Werner, Michael, Akeson, Rachel, Ashby, Matthew, Bleem, Lindsey, Bock, James J., Bryan, Sean, Burnham, Jill, Byunh, Joyce, Chang, Tzu-Ching, Chiang, Yi-Kuan, Cook, Walter, Cooray, Asantha, Davis, Andrew, Doré, Olivier, Dowell, C. Darren, Dubois-Felsmann, Gregory P., Eifler, Tim, Faisst, Andreas, Habib, Salman, Heinrich, Chen, Heitmann, Katrin, Heaton, Grigory, Hirata, Christopher, Hristov, Viktor, Hui, Howard, Jeong, Woong-Seob, Kang, Jae Hwan, Kecman, Branislav, Kirkpatrick, J. Davy, Korngut, Phillip M., Krause, Elisabeth, Lee, Bomee, Lisse, Carey, Masters, Daniel, Mauskopf, Philip, Melnick, Gary, Miyasaka, Hiromasa, Nayyeri, Hooshang, Nguyen, Hien, Öberg, Karin, Padin, Steve, Paladini, Roberta, Pourrahmani, Milad, Pyo, Jeonghyun, Smith, Roger, Song, Yong-Seong, Symons, Teresa, Teplitz, Harry, Tolls, Volker, Unwin, Stephen, Windhorst, Rogier, Yang, Yujin, and Zemcov, Michael

Abstract

SPHEREx, the Spectro-Photometer for the History of the Universe, Epoch of Reionization, and ices Explorer, is a NASA MIDEX mission planned for launch in 2024. SPHEREx will carry out the first all-sky spectral survey at wavelengths between 0.75µm and 5µm with spectral resolving power ~40 between 0.75 and 3.8µm and ~120 between 3.8 and 5µm At the end of its two-year mission, SPHEREx will provide 0.75-to-5µm spectra of each 6.”2 x 6.”2 pixel on the sky - 14 billion spectra in all. This paper updates an earlier description of SPHEREx presenting changes made during the mission's Preliminary Design Phase, including a discussion of instrument integration and test ow and a summary of the data processing, analysis, and distribution plans.

Published
2020

43. Data processing for high-contrast imaging with the James Webb Space Telescope

Author

Lystrup, Makenzie, Perrin, Marshall D., Batalha, Natalie, Siegler, Nicholas, Tong, Edward C., Ygouf, Marie, Rocha, Graça, Beichman, Charles, Greenbaum, Alexandra, Leisenring, Jarron, De Furio, Matthew, Meyer, Michael, Girard, Julien, Pueyo, Laurent A., Perrin, Marshall, Uyama, Taichi, Green, Joseph J., Jewell, Jeffrey B., Lystrup, Makenzie, Perrin, Marshall D., Batalha, Natalie, Siegler, Nicholas, Tong, Edward C., Ygouf, Marie, Rocha, Graça, Beichman, Charles, Greenbaum, Alexandra, Leisenring, Jarron, De Furio, Matthew, Meyer, Michael, Girard, Julien, Pueyo, Laurent A., Perrin, Marshall, Uyama, Taichi, Green, Joseph J., and Jewell, Jeffrey B.

Abstract

The JamesWebb Space Telescope (JWST) will probe circumstellar environments at an unprecedented sensitivity. However, the performance of high-contrast imaging instruments is limited by the residual light from the star at close separations (<2-3"), where the incidence of exoplanets increases rapidly. There is currently no solution to get rid of the residual starlight down to the photon noise level at those separations, which may prevent some crucial discoveries. JWST's launch is planned for October 2021 with a planned baseline science mission lifetime of only five years. Thus, it is crucial to start developing a solution to this problem before its launch. We are investigating an innovative approach of post-processing built on a Bayesian framework that provides a more robust determination of faint astrophysical structures around a bright source. This approach uses a model of high-contrast imaging instrument that takes advantage of prior information, such as data from wavefront sensing (WFS) operations on JWST, to estimate simultaneously instrumental aberrations and the circumstellar environment. With this approach, our goal is to further improve the contrast gain over the contrast that can be achieved with JWST instruments, starting with NIRCam direct imaging and coronagraphic imaging. This work will pave the way for the future space-based high-contrast imaging instruments such as the Nancy Grace Roman Space Telescope_ Coronagraph Instrument (Roman CGI). This technique will be crucial to make the best use of the telemetry data that will be collected during the CGI operations.

Published
2020

45. Wavefront sensing and control in space-based coronagraph instruments using Zernike’s phase-contrast method

Author

Ruane, Garreth, primary, Wallace, J. Kent, additional, Steeves, John, additional, Prada, Camilo Mejia, additional, Seo, Byoung-Joon, additional, Bendek, Eduardo, additional, Coker, Carl, additional, Chen, Pin, additional, Crill, Brendan, additional, Jewell, Jeff, additional, Kern, Brian, additional, Marx, David, additional, Poon, Phillip K., additional, Redding, David, additional, Riggs, A. J. Eldorado, additional, Siegler, Nicholas, additional, and Zimmer, Robert, additional

Published
2020
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46. Status of Space-based Segmented-Aperture Coronagraphs for Characterizing Exo-Earths Around Sun-Like Stars

Author

Shaklan, Stuart, Crill, Brendan, Belikov, Ruslan, Bryson, Stephen, Bendek, Eduardo, Bolcar, Matt, Fogarty, Kevin, Krist, John, Mawet, Dimitri, Mejia Prada, Camilo, Mazoyer, Johan, N'diaye, Mamadou, Noss, James, Juanola-Parramon, Roser, Por, Emiel, Riggs, A. J. Eldorado, Ruane, Garreth, Siegler, Nicholas, Sirbu, Dan, Sivaramakrishnan, Anand, Soummer, Rémi, St. Laurent, Kathryn, Stark, Christopher, Zimmerman, Neil, Joseph Louis LAGRANGE (LAGRANGE), Université Côte d'Azur (UCA)-Université Nice Sophia Antipolis (... - 2019) (UNS), COMUE Université Côte d'Azur (2015-2019) (COMUE UCA)-COMUE Université Côte d'Azur (2015-2019) (COMUE UCA)-Observatoire de la Côte d'Azur, COMUE Université Côte d'Azur (2015-2019) (COMUE UCA)-Université Côte d'Azur (UCA)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National de la Recherche Scientifique (CNRS), Centre National de la Recherche Scientifique (CNRS), Observatoire de la Côte d'Azur (OCA), and Institut national des sciences de l'Univers (INSU - CNRS)-Centre National de la Recherche Scientifique (CNRS)

Subjects
[PHYS]Physics [physics], [SDU]Sciences of the Universe [physics]
Abstract

We aim to inform Astro2020 of the status of coronagraph technology for use with a space-based segmented and/or partially obscured primary mirror. Our design and modeling study has determined that multiple coronagraph architectures can achieve the necessary performance. Some preliminary observatory requirements appear challenging but achievable.

Published
2019

47. Heterodyn receiver for the Origins Space Telescope concept 2

Author

Belitsky, Victor, Desmaris, Vincent, Di Giorgio, Anna Maria, Goldstein, Christophe, Ellison, Brian, Gallego, Juan-Daniel, Herpin, Fabrice, Huet, Jean-Michel, Krieg, Jean-Michel, Laporte, Philippe, Quertier-Dagorn, Benjamin, Plume, René, Risacher, Christophe, De Beck, Elvire, Goldsmith, Paul, Hogerheijde, Michiel, Hunt, Leslie, Lis, Darek, Aalto, Susanne, Viti, Serena, Wyrowski, Friedrich, Neufeld, David, Melnick, Gary, Bergin, Edwin, Battersby, Cara, Milam, Stefanie, Borgo, Bruno, Carter, Ruth, Cooray, Asantha, Corsetti, James, Delorme, Yan, Dipirro, Michael, Eggens, Martin, Hills, Richard, Keizer, Geert, Kroes, Gabby, Leisawitz, David, Meixner, Margaret, Nguyen Tuong, Napoléon, Pontoppidan, Klaus, Staguhn, Johannes, Martins, Gregory, Wiedner, Martina, Baryshev, Andrey, Laurens, André, Gerin, Maryvonne, Helmich, Frank, Jellema, Willem, Mehdi, Imran, Amatucci, Edward, MacEwen, Howard, Lystrup, Makenzie, Fazio, Giovanni, Batalha, Natalie, Tong, Edward, Siegler, Nicholas, FORMATION STELLAIRE 2018, Laboratoire d'Astrophysique de Bordeaux [Pessac] (LAB), Université de Bordeaux (UB)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National de la Recherche Scientifique (CNRS)-Université de Bordeaux (UB)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National de la Recherche Scientifique (CNRS), Laboratoire d'Etude du Rayonnement et de la Matière en Astrophysique (LERMA), École normale supérieure - Paris (ENS Paris), Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Université Pierre et Marie Curie - Paris 6 (UPMC)-Institut national des sciences de l'Univers (INSU - CNRS)-Observatoire de Paris, Université Paris sciences et lettres (PSL)-Université de Cergy Pontoise (UCP), Université Paris-Seine-Université Paris-Seine-Centre National de la Recherche Scientifique (CNRS), Department of Physics and Astronomy [Calgary], University of Calgary, Jet Propulsion Laboratory (JPL), NASA-California Institute of Technology (CALTECH), Max-Planck-Institut für Radioastronomie (MPIFR), Harvard-Smithsonian Center for Astrophysics (CfA), Smithsonian Institution-Harvard University [Cambridge], Institut d'astrophysique spatiale (IAS), Université Paris-Sud - Paris 11 (UP11)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National de la Recherche Scientifique (CNRS), California Institute of Technology (CALTECH), Observatoire de Paris, Université Paris sciences et lettres (PSL), and Astronomy

Subjects
Heterodyne, Pixel, Computer science, Astronomy, 7. Clean energy, 01 natural sciences, Focal Plane Arrays, Spitzer Space Telescope, Planet, 0103 physical sciences, HERO, Satellite, [SDU.ASTR.GA]Sciences of the Universe [physics]/Astrophysics [astro-ph]/Galactic Astrophysics [astro-ph.GA], 010306 general physics, 010303 astronomy & astrophysics, ComputingMilieux_MISCELLANEOUS
Abstract

The Origins Space Telescope (OST) is a NASA study for a large satellite mission to be submitted to the 2020 Decadal Review. The proposed satellite has a fleet of instruments including the HEterodyne Receivers for OST (HERO). HERO is designed around the quest to follow the trail of water from the ISM to disks around protostars and planets. HERO will perform high-spectral resolution measurements with 2x9 pixel focal plane arrays at any frequency between 468GHz to 2,700GHz (617 to 111 μm). HERO builds on the successful Herschel/HIFI heritage, as well as recent technological innovations, allowing it to surpass any prior heterodyne instrument in terms of sensitivity and spectral coverage.

Published
2018

48. The ARIEL space mission

Author

Beaulieu, Jean-Philippe, Bowles, Neil, Coudé Du Foresto, Vincent, Coustenis, Athena, Decin, Leen, Drossart, Pierre, Eccleston, Paul, Encrenaz, Therese, Forget, François, Griffin, Matt, Pascale, Enzo, Barstow, Joanna, Güdel, Manuel, Hartogh, Paul, Heske, Astrid, Lagage, Pierre-Olivier, Leconte, J., Malaguti, Pino, Micela, Giusi, Middleton, Kevin, Min, Michiel, Moneti, Andrea, Morales, Juan Carlos, Ollivier, Marc, Pace, Emanuele, Pilbratt, Goran, Puig, Ludovic, Rataj, Miroslaw, Ray, Tom, Ribas, Ignasi, Rocchetto, Marco, Sarkar, Subhajit, Selsis, Franck, Taylor, William, Tennyson, Jonathan, Tinetti, Giovanna, Turrini, Diego, Vandenbussche, Bart, Venot, Olivia, Waldmann, Ingo, Wolkenberg, Paulina, Wright, Gillian, Zapatero Osorio, Maria-Rosa, Zingales, Tiziano, Bezawada, Naidu, Papageorgiou, Andreas, Mugnai, Lorenzo, MacEwen, Howard, Lystrup, Makenzie, Fazio, Giovanni, Batalha, Natalie, Tong, Edward, Siegler, Nicholas, Institut d'Astrophysique de Paris (IAP), Université Pierre et Marie Curie - Paris 6 (UPMC)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National de la Recherche Scientifique (CNRS), Department of Atmospheric, Oceanic and Planetary Physics [Oxford] (AOPP), University of Oxford [Oxford], Laboratoire d'études spatiales et d'instrumentation en astrophysique (LESIA), Centre National de la Recherche Scientifique (CNRS)-Université Paris Diderot - Paris 7 (UPD7)-Observatoire de Paris, PSL Research University (PSL)-PSL Research University (PSL)-Institut national des sciences de l'Univers (INSU - CNRS)-Université Pierre et Marie Curie - Paris 6 (UPMC), Institute of Astronomy [Leuven], Catholic University of Leuven - Katholieke Universiteit Leuven (KU Leuven), Institut Pierre-Simon-Laplace (IPSL), École normale supérieure - Paris (ENS Paris)-Université de Versailles Saint-Quentin-en-Yvelines (UVSQ)-Université Pierre et Marie Curie - Paris 6 (UPMC)-Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Centre National d'Études Spatiales [Toulouse] (CNES)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National de la Recherche Scientifique (CNRS)-École polytechnique (X), University College of London [London] (UCL), Paul Scherrer Institute (PSI), Max-Planck-Institut für Sonnensystemforschung (MPS), Max-Planck-Gesellschaft, Astrophysique Interprétation Modélisation (AIM (UMR_7158 / UMR_E_9005 / UM_112)), Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Institut national des sciences de l'Univers (INSU - CNRS)-Université Paris Diderot - Paris 7 (UPD7)-Centre National de la Recherche Scientifique (CNRS), ECLIPSE 2018, Laboratoire d'Astrophysique de Bordeaux [Pessac] (LAB), Université de Bordeaux (UB)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National de la Recherche Scientifique (CNRS)-Université de Bordeaux (UB)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National de la Recherche Scientifique (CNRS), INAF - Osservatorio Astronomico di Palermo (OAPa), Istituto Nazionale di Astrofisica (INAF), Instituto de Investigaciones Químicas, CSIC, Institut de Génomique Fonctionnelle de Lyon (IGFL), École normale supérieure - Lyon (ENS Lyon)-Institut National de la Recherche Agronomique (INRA)-Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Université de Lyon-Centre National de la Recherche Scientifique (CNRS), University of Valencia, Consejo Superior de Investigaciones Científicas [Spain] (CSIC), Dipartimento di Informatica [Verona], Università degli Studi di Verona, Cardiff University, Chemistry, Istituto di Fisica dello Spazio Interplanetario (IFSI), Consiglio Nazionale delle Ricerche (CNR), Laboratoire Interuniversitaire des Systèmes Atmosphériques (LISA (UMR_7583)), Centre National de la Recherche Scientifique (CNRS)-Université Paris Diderot - Paris 7 (UPD7)-Université Paris-Est Créteil Val-de-Marne - Paris 12 (UPEC UP12)-Institut national des sciences de l'Univers (INSU - CNRS), Space Research Centre of Polish Academy of Sciences (CBK), Polska Akademia Nauk (PAN), Laboratoire de Météorologie Dynamique (UMR 8539) (LMD), Université Pierre et Marie Curie - Paris 6 (UPMC)-Institut national des sciences de l'Univers (INSU - CNRS)-École polytechnique (X)-École des Ponts ParisTech (ENPC)-Centre National de la Recherche Scientifique (CNRS)-Département des Géosciences - ENS Paris, École normale supérieure - Paris (ENS Paris)-École normale supérieure - Paris (ENS Paris), Max Planck Institute for Solar System Research (MPS), Département d'Astrophysique (ex SAP) (DAP), Institut de Recherches sur les lois Fondamentales de l'Univers (IRFU), Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Université Paris-Saclay-Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Université Paris-Saclay, Université de Bordeaux (UB)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National de la Recherche Scientifique (CNRS), Institut d'astrophysique spatiale (IAS), Université Paris-Sud - Paris 11 (UP11)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National de la Recherche Scientifique (CNRS), ECLIPSE 2017, Université Paris-Est Créteil Val-de-Marne - Paris 12 (UPEC UP12)-Institut national des sciences de l'Univers (INSU - CNRS)-Université Paris Diderot - Paris 7 (UPD7)-Centre National de la Recherche Scientifique (CNRS), Istituto di Astrofisica e Planetologia Spaziali - INAF (IAPS), Université Pierre et Marie Curie - Paris 6 (UPMC)-Institut national des sciences de l'Univers (INSU - CNRS)-Observatoire de Paris, Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Université Paris Diderot - Paris 7 (UPD7)-Centre National de la Recherche Scientifique (CNRS), École normale supérieure - Paris (ENS Paris), Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-École normale supérieure - Paris (ENS Paris), Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL), Consejo Superior de Investigaciones Científicas [Madrid] (CSIC), Institut national des sciences de l'Univers (INSU - CNRS)-Université Paris Diderot - Paris 7 (UPD7)-Université Paris-Est Créteil Val-de-Marne - Paris 12 (UPEC UP12)-Centre National de la Recherche Scientifique (CNRS), University of Oxford, École normale supérieure - Paris (ENS-PSL), Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Université de Versailles Saint-Quentin-en-Yvelines (UVSQ)-Université Pierre et Marie Curie - Paris 6 (UPMC)-Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Institut national des sciences de l'Univers (INSU - CNRS)-École polytechnique (X)-Centre National d'Études Spatiales [Toulouse] (CNES)-Centre National de la Recherche Scientifique (CNRS), Max-Planck-Institut für Sonnensystemforschung = Max Planck Institute for Solar System Research (MPS), Astrophysique Interprétation Modélisation (AIM (UMR7158 / UMR_E_9005 / UM_112)), École normale supérieure de Lyon (ENS de Lyon)-Institut National de la Recherche Agronomique (INRA)-Université Claude Bernard Lyon 1 (UCBL), Department of Computer Science [Verona] (UNIVR | DI), Università degli studi di Verona = University of Verona (UNIVR), National Research Council of Italy | Consiglio Nazionale delle Ricerche (CNR), Polska Akademia Nauk = Polish Academy of Sciences (PAN), Centre National de la Recherche Scientifique (CNRS)-Institut national des sciences de l'Univers (INSU - CNRS)-Université Pierre et Marie Curie - Paris 6 (UPMC), Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Université de Versailles Saint-Quentin-en-Yvelines (UVSQ)-Université Pierre et Marie Curie - Paris 6 (UPMC)-Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Centre National d'Études Spatiales [Toulouse] (CNES)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National de la Recherche Scientifique (CNRS)-École polytechnique (X), Centre National de la Recherche Scientifique (CNRS)-Institut national des sciences de l'Univers (INSU - CNRS)-Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Université Paris Diderot - Paris 7 (UPD7), Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Université de Lyon-Centre National de la Recherche Scientifique (CNRS)-Institut National de la Recherche Agronomique (INRA)-École normale supérieure - Lyon (ENS Lyon), and University of Verona (UNIVR)

Subjects
Astronomy, [SDU.ASTR.EP]Sciences of the Universe [physics]/Astrophysics [astro-ph]/Earth and Planetary Astrophysics [astro-ph.EP], Space, Astrophysics::Cosmology and Extragalactic Astrophysics, Atmospheric model, Space (commercial competition), 7. Clean energy, 01 natural sciences, law.invention, 010309 optics, Telescope, law, Planet, 0103 physical sciences, Astrophysics::Solar and Stellar Astrophysics, Transit (astronomy), 010303 astronomy & astrophysics, Instrumentation, Astrophysics::Galaxy Astrophysics, Spectroscopy, ComputingMilieux_MISCELLANEOUS, [SDU.ASTR]Sciences of the Universe [physics]/Astrophysics [astro-ph], Atmosphere, Atmospheric wave, Exoplanets, Exoplanet, Stars, 13. Climate action, Transit, Astrophysics::Earth and Planetary Astrophysics, Geology
Abstract

The Atmospheric Remote-Sensing Infrared Exoplanet Large-survey, ARIEL, has been selected to be the next M4 space mission in the ESA Cosmic Vision programme. From launch in 2028, and during the following 4 years of operation, ARIEL will perform precise spectroscopy of the atmospheres of about 1000 known transiting exoplanets using its metre-class telescope, a three-band photometer and three spectrometers that will cover the 0.5 μm to 7.8 μm region of the electromagnetic spectrum. The payload is designed to perform primary and secondary transit spectroscopy, and to measure spectrally resolved phase curves with a stability of < 100 ppm (goal 10 ppm). Observing from an L2 orbit, ARIEL will provide the first statistically significant spectroscopic survey of hot and warm planets. These are an ideal laboratory in which to study the chemistry, the formation and the evolution processes of exoplanets, to constrain the thermodynamics, composition and structure of their atmospheres, and to investigate the properties of the clouds.

Published
2018

49. Design description and commissioning performance of a stable coronagraph technology development testbed for direct imaging of Earth-like exoplanets

Author

Patterson, Keith, primary, Seo, Byoung-Joon, additional, Balasubramanian, Kunjithapatham, additional, Chui, Talso, additional, Crill, Brendan, additional, Gill, John, additional, Kern, Brian D., additional, Lam, Ray, additional, Marx, David, additional, Moody, Dwight, additional, Mejia Prada, Camilo, additional, Ruane, Garreth, additional, Rupp, Jordan, additional, Shaw, John, additional, Shi, Fang, additional, Siegler, Nicholas, additional, Tang, Hong, additional, Trauger, John, additional, White, Victor, additional, Wilson, Daniel W., additional, Yee, Karl, additional, and Zimmer, Robert, additional

Published
2019
Full Text
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50. Testbed demonstration of high-contrast coronagraph imaging in search for Earth-like exoplanets

Author

Seo, Byoung-Joon, primary, Patterson, Keith, additional, Balasubramanian, Kunjithapatham, additional, Crill, Brendan, additional, Chui, Talso, additional, Echeverri, Daniel, additional, Kern, Brian D., additional, Marx, David, additional, Moody, Dwight, additional, Mejia Prada, Camilo, additional, Ruane, Garreth, additional, Shi, Fang, additional, Shaw, John, additional, Siegler, Nicholas, additional, Tang, Hong, additional, Trauger, John, additional, Wilson, Daniel W., additional, and Zimmer, Robert, additional

Published
2019
Full Text
View/download PDF

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