ORAU
Characterization of exoplanets via direct-imaging spectroscopy
ORAU, Pasadena, California, United States, 91122
Characterization of exoplanets via direct-imaging spectroscopy
Organization:
National Aeronautics and Space Administration (NASA)
Reference Code:
0272-NPP-MAR26-JPL-Astrophys
Application Deadline:
3/1/2026 6:00:59 PM Eastern Time Zone
Description The NASA Postdoctoral Program (NPP) offers unique research opportunities to highly‑talented scientists to engage in ongoing NASA research projects at a NASA Center, NASA Headquarters, or NASA‑affiliated research institute. These one‑to‑three‑year fellowships are competitive and are designed to advance NASA’s missions in space science, Earth science, aeronautics, space operations, exploration systems, and astrobiology.
To characterize the atmosphere, climate, and potential habitability of small rocky exoplanets with spectroscopy is a significant endeavor that underpins the exploration of the universe. While the small exoplanets that orbit M dwarf stars may be within the reach of the
JWST , to characterize the small exoplanets that orbit Sun‑like stars will require direct imaging from space. Within the next decade, it is expected that the Nancy Grace Roman Space Telescope will demonstrate the coronagraph technology in space, as one of the technologies to suppress the starlight and enable direct imaging of planets in orbit. Envisioning a large space telescope that couples with starlight suppression technologies to find small exoplanets in the habitable zones of nearby stars and study their atmospheres, the Astro2020 decadal survey recommends development toward a potential flagship mission to search for Earth‑like habitable exoplanets through direct imaging.
To anticipate the types of planets that will be discovered by future direct‑imaging space missions and develop the methods to characterize them, a multidisciplinary approach that combines astrophysics, planetary science, and statistics is required. The overarching science questions include: how to distinguish a rocky planet from a volatile rich one, when they have similar radii? How to determine whether the rocky planet has a liquid‑water ocean? How to distinguish an Earth‑like planet from a Venus‑like one? And for volatile‑rich planets, what can we learn about them to better understand the evolution of planets and their atmospheres? The postdoc fellow will combine numerical simulations, Bayesian retrievals, and experiences of solar‑system exploration to address some of these broadly defined questions. The fellow will also apply what we learn about the exoplanet formation and evolution through current observations to simulate the planets to be discovered and characterized by future direct‑imaging missions.
Field of Science:
Astrophysics
Advisor:
Renyu Hu (renyu.hu@jpl.nasa.gov)
Responsibilities
Conduct numerical simulations of exoplanetary atmospheres.
Apply Bayesian retrieval techniques to interpret spectroscopic data.
Integrate solar‑system exploration experiences to model future exoplanets.
Develop methodologies to distinguish rocky from volatile‑rich planets.
Analyze potential habitability signatures such as liquid‑water oceans.
Eligibility Applications with citizens from Designated Countries will not be accepted at this time, unless they are Legal Permanent Residents of the United States.
Eligibility is currently open to:
U.S. Citizens;
U.S. Lawful Permanent Residents (LPR);
Foreign Nationals eligible for an Exchange Visitor J-1 visa status;
Applicants for LPR, asylees, or refugees in the U.S. at the time of application with 1) a valid EAD card and 2) I-485 or I-589 forms in pending status.
Application Process All applications must be submitted in
Zintellect . For detailed instructions, please visit the NASA Postdoctoral Program website (How to Apply | NASA Postdoctoral Program).
A complete application to the NASA Postdoctoral Program includes:
A research proposal.
Three letters of recommendation.
Official doctoral transcript documents.
Contact Questions about this opportunity? Please email npp@orau.org.
Point of Contact:
Mikeala.
#J-18808-Ljbffr
National Aeronautics and Space Administration (NASA)
Reference Code:
0272-NPP-MAR26-JPL-Astrophys
Application Deadline:
3/1/2026 6:00:59 PM Eastern Time Zone
Description The NASA Postdoctoral Program (NPP) offers unique research opportunities to highly‑talented scientists to engage in ongoing NASA research projects at a NASA Center, NASA Headquarters, or NASA‑affiliated research institute. These one‑to‑three‑year fellowships are competitive and are designed to advance NASA’s missions in space science, Earth science, aeronautics, space operations, exploration systems, and astrobiology.
To characterize the atmosphere, climate, and potential habitability of small rocky exoplanets with spectroscopy is a significant endeavor that underpins the exploration of the universe. While the small exoplanets that orbit M dwarf stars may be within the reach of the
JWST , to characterize the small exoplanets that orbit Sun‑like stars will require direct imaging from space. Within the next decade, it is expected that the Nancy Grace Roman Space Telescope will demonstrate the coronagraph technology in space, as one of the technologies to suppress the starlight and enable direct imaging of planets in orbit. Envisioning a large space telescope that couples with starlight suppression technologies to find small exoplanets in the habitable zones of nearby stars and study their atmospheres, the Astro2020 decadal survey recommends development toward a potential flagship mission to search for Earth‑like habitable exoplanets through direct imaging.
To anticipate the types of planets that will be discovered by future direct‑imaging space missions and develop the methods to characterize them, a multidisciplinary approach that combines astrophysics, planetary science, and statistics is required. The overarching science questions include: how to distinguish a rocky planet from a volatile rich one, when they have similar radii? How to determine whether the rocky planet has a liquid‑water ocean? How to distinguish an Earth‑like planet from a Venus‑like one? And for volatile‑rich planets, what can we learn about them to better understand the evolution of planets and their atmospheres? The postdoc fellow will combine numerical simulations, Bayesian retrievals, and experiences of solar‑system exploration to address some of these broadly defined questions. The fellow will also apply what we learn about the exoplanet formation and evolution through current observations to simulate the planets to be discovered and characterized by future direct‑imaging missions.
Field of Science:
Astrophysics
Advisor:
Renyu Hu (renyu.hu@jpl.nasa.gov)
Responsibilities
Conduct numerical simulations of exoplanetary atmospheres.
Apply Bayesian retrieval techniques to interpret spectroscopic data.
Integrate solar‑system exploration experiences to model future exoplanets.
Develop methodologies to distinguish rocky from volatile‑rich planets.
Analyze potential habitability signatures such as liquid‑water oceans.
Eligibility Applications with citizens from Designated Countries will not be accepted at this time, unless they are Legal Permanent Residents of the United States.
Eligibility is currently open to:
U.S. Citizens;
U.S. Lawful Permanent Residents (LPR);
Foreign Nationals eligible for an Exchange Visitor J-1 visa status;
Applicants for LPR, asylees, or refugees in the U.S. at the time of application with 1) a valid EAD card and 2) I-485 or I-589 forms in pending status.
Application Process All applications must be submitted in
Zintellect . For detailed instructions, please visit the NASA Postdoctoral Program website (How to Apply | NASA Postdoctoral Program).
A complete application to the NASA Postdoctoral Program includes:
A research proposal.
Three letters of recommendation.
Official doctoral transcript documents.
Contact Questions about this opportunity? Please email npp@orau.org.
Point of Contact:
Mikeala.
#J-18808-Ljbffr