Ravit Helled
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Israeli planetary scientist
Ravit Helled's AcademicInfluence.com Rankings
Ravit Helledphysics Degrees
Physics
#6937
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#8929
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Planetary Science
#139
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#141
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Astrophysics
#750
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#803
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Physics
Ravit Helled's Degrees
- PhD Planetary Science Tel Aviv University
- Masters Physics Tel Aviv University
- Bachelors Physics Tel Aviv University
Why Is Ravit Helled Influential?
(Suggest an Edit or Addition)According to Wikipedia, Ravit Helled is a planetary scientist and a professor in the department of astrophysics and cosmology at the University of Zürich. She studies gas giant planets in the Solar System and exoplanets. She is a member of the science team of Juno, a NASA probe to study the planet Jupiter. In 2015, she accurately calculated Saturn's rotational period together with Eli Galanti and Yohai Kaspi of the Weizmann Institute of Science. In 2015, selected among the 50 most influential women of Forbes Israel.
Ravit Helled's Published Works
Number of citations in a given year to any of this author's works
Total number of citations to an author for the works they published in a given year. This highlights publication of the most important work(s) by the author
Published Works
- The PLATO 2.0 mission (2013) (785)
- A chemical survey of exoplanets with ARIEL (2018) (198)
- Comparing Jupiter interior structure models to Juno gravity measurements and the role of a dilute core (2017) (175)
- Jupiter’s atmospheric jet streams extend thousands of kilometres deep (2018) (170)
- INTERIOR MODELS OF URANUS AND NEPTUNE (2010) (155)
- New indication for a dichotomy in the interior structure of Uranus and Neptune from the application of modified shape and rotation data (2012) (145)
- Measurement of Jupiter’s asymmetric gravity field (2018) (142)
- A suppression of differential rotation in Jupiter’s deep interior (2018) (139)
- Giant Planet Formation, Evolution, and Internal Structure (2013) (81)
- A generalized Bayesian inference method for constraining the interiors of super Earths and sub-Neptunes (2016) (77)
- Core formation in giant gaseous protoplanets (2008) (65)
- Atmospheric confinement of jet streams on Uranus and Neptune (2013) (64)
- The Fuzziness of Giant Planets’ Cores (2017) (62)
- Grain sedimentation in a giant gaseous protoplanet (2008) (61)
- The effects of metallicity and grain growth and settling on the early evolution of gaseous protoplanets (2010) (58)
- Revisited mass-radius relations for exoplanets below 120 M⊕ (2019) (58)
- INTERIOR MODELS OF SATURN: INCLUDING THE UNCERTAINTIES IN SHAPE AND ROTATION (2013) (58)
- The formation of Jupiter by hybrid pebble–planetesimal accretion (2018) (58)
- Phase Diagram of Hydrogen and a Hydrogen-Helium Mixture at Planetary Conditions by Quantum Monte Carlo Simulations. (2017) (57)
- The effect of composition on the evolution of giant and intermediate-mass planets (2013) (56)
- K2-106, a system containing a metal-rich planet and a planet of lower density (2017) (55)
- The science case for an orbital mission to Uranus: exploring the origins and evolution of ice giant planets (2014) (54)
- THE EVOLUTION AND INTERNAL STRUCTURE OF JUPITER AND SATURN WITH COMPOSITIONAL GRADIENTS (2016) (54)
- Saturn’s fast spin determined from its gravitational field and oblateness (2015) (53)
- Uranus Pathfinder: exploring the origins and evolution of Ice Giant planets (2012) (53)
- THE FORMATION OF URANUS AND NEPTUNE: CHALLENGES AND IMPLICATIONS FOR INTERMEDIATE-MASS EXOPLANETS (2014) (53)
- Uranus and Neptune: Origin, Evolution and Internal Structure (2019) (53)
- Jupiter's evolution with primordial composition gradients (2018) (53)
- Forming Mercury by Giant Impacts (2018) (52)
- Jupiter’s Formation and Its Primordial Internal Structure (2017) (52)
- Uranus and Neptune: Shape and rotation (2010) (52)
- Scientific rationale for Saturn's in situ exploration (2014) (51)
- Planetesimal capture in the disk instability model (2006) (50)
- Two empirical regimes of the planetary mass-radius relation (2017) (47)
- OSS (Outer Solar System): a fundamental and planetary physics mission to Neptune, Triton and the Kuiper Belt (2011) (47)
- The formation of Jupiter’s diluted core by a giant impact (2019) (46)
- Metallicity of the massive protoplanets around HR 8799 If formed by gravitational instability (2009) (46)
- Jupiter's Moment of Inertia: A Possible Determination by JUNO (2011) (45)
- Jupiter and Saturn rotation periods (2009) (43)
- Measuring Jupiter's water abundance by Juno: the link between interior and formation models (2014) (42)
- The Formation of Mini-Neptunes (2017) (40)
- Effect of non-adiabatic thermal profiles on the inferred compositions of Uranus and Neptune (2019) (40)
- A remnant planetary core in the hot-Neptune desert (2020) (38)
- THE HEAVY-ELEMENT COMPOSITION OF DISK INSTABILITY PLANETS CAN RANGE FROM SUB- TO SUPER-NEBULAR (2011) (38)
- CONVECTION AND MIXING IN GIANT PLANET EVOLUTION (2015) (35)
- Neptune and Triton: Essential pieces of the Solar System puzzle (2014) (34)
- The origin of the high metallicity of close-in giant exoplanets (2019) (33)
- Explaining the low luminosity of Uranus: a self-consistent thermal and structural evolution (2019) (32)
- Large Interferometer For Exoplanets (LIFE). I. Improved exoplanet detection yield estimates for a large mid-infrared space-interferometer mission (2021) (31)
- Ice Giant Systems: The scientific potential of orbital missions to Uranus and Neptune (2020) (31)
- Empirical models of pressure and density in Saturn's interior: Implications for the helium concentration, its depth dependence, and Saturn's precession rate (2008) (29)
- WHAT DO WE REALLY KNOW ABOUT URANUS AND NEPTUNE? (2012) (28)
- Threshold Radii of Volatile-rich Planets (2018) (27)
- ON THE EVOLUTION AND SURVIVAL OF PROTOPLANETS EMBEDDED IN A PROTOPLANETARY DISK (2012) (26)
- Internal Structure of Giant and Icy Planets: Importance of Heavy Elements and Mixing (2017) (26)
- CONSTRAINING SATURN'S CORE PROPERTIES BY A MEASUREMENT OF ITS MOMENT OF INERTIA—IMPLICATIONS TO THE CASSINI SOLSTICE MISSION (2011) (25)
- Bifurcation in the history of Uranus and Neptune: the role of giant impacts (2019) (25)
- The Deposition of Heavy Elements in Giant Protoplanetary Atmospheres: The Importance of Planetesimal–Envelope Interactions (2018) (25)
- The challenge of forming a fuzzy core in Jupiter (2020) (24)
- Understanding dense hydrogen at planetary conditions (2020) (23)
- The interiors of Uranus and Neptune: current understanding and open questions (2020) (23)
- The effect of differential rotation on Jupiter's low-degree even gravity moments (2017) (22)
- On the Diversity in Mass and Orbital Radius of Giant Planets Formed via Disk Instability (2018) (21)
- Saturn’s Probable Interior: An Exploration of Saturn’s Potential Interior Density Structures (2019) (21)
- Jupiter’s heavy-element enrichment expected from formation models (2019) (20)
- Neptune and Uranus: ice or rock giants? (2020) (20)
- HEAVY-ELEMENT ENRICHMENT OF A JUPITER-MASS PROTOPLANET AS A FUNCTION OF ORBITAL LOCATION (2009) (19)
- Mass determinations of the three mini-Neptunes transiting TOI-125 (2020) (19)
- The contribution of the ARIEL space mission to the study of planetary formation (2018) (18)
- The Interiors of Jupiter and Saturn (2018) (17)
- TOI-824 b: A New Planet on the Lower Edge of the Hot Neptune Desert (2020) (17)
- Giant Planet Formation Models with a Self-consistent Treatment of the Heavy Elements (2020) (17)
- Ariel: Enabling planetary science across light-years (2021) (17)
- Revelations on Jupiter's formation, evolution and interior: Challenges from Juno results (2022) (15)
- The Interior of Saturn (2009) (14)
- The role of ice lines in the formation of Uranus and Neptune (2020) (14)
- TESS Reveals a Short-period Sub-Neptune Sibling (HD 86226c) to a Known Long-period Giant Planet (2020) (14)
- The primordial entropy of Jupiter (2018) (13)
- Detailed Calculations of the Efficiency of Planetesimal Accretion in the Core-accretion Model (2019) (12)
- Internal water storage capacity of terrestrial planets and the effect of hydration on the M-R relation (2020) (11)
- Constraining the depth of the winds on Uranus and Neptune via Ohmic dissipation (2020) (11)
- Core-assisted gas capture instability: a new mode of giant planet formation by gravitationally unstable discs (2014) (11)
- The science of exoplanets and their systems. (2013) (10)
- Constraining the initial planetary population in the gravitational instability model (2019) (10)
- TW Hya: an old protoplanetary disc revived by its planet (2020) (10)
- A possible correlation between planetary radius and orbital period for small planets (2015) (10)
- A Quantitative Comparison of Exoplanet Catalogs (2018) (9)
- Shapes and gravitational fields of rotating two-layer Maclaurin ellipsoids: Application to planets and satellites (2011) (8)
- Theoretical versus Observational Uncertainties: Composition of Giant Exoplanets (2020) (8)
- A wide-orbit giant planet in the high-mass b Centauri binary system (2021) (8)
- TOI-431/HIP 26013: a super-Earth and a sub-Neptune transiting a bright, early K dwarf, with a third RV planet (2021) (8)
- Jupiter's inhomogeneous envelope (2022) (8)
- Impact of the measured parameters of exoplanets on the inferred internal structure (2020) (8)
- The depth of Jupiter’s Great Red Spot constrained by Juno gravity overflights (2021) (8)
- Science Goals and Mission Objectives for the Future Exploration of Ice Giants Systems: A Horizon 2061 Perspective (2020) (7)
- Meteor light curves: the relevant parameters (2004) (6)
- METHANE PLANETS AND THEIR MASS–RADIUS RELATION (2015) (6)
- TOI-269 b: an eccentric sub-Neptune transiting a M2 dwarf revisited with ExTrA (2021) (6)
- Uranus Pathfinder: exploring the origins and evolution of Ice Giant planets (2011) (5)
- Author Correction: Formation of intermediate-mass planets via magnetically controlled disk fragmentation (2021) (5)
- Radar and optical leonids (2004) (5)
- Exploring the link between star and planet formation with Ariel (2021) (5)
- A hot mini-Neptune in the radius valley orbiting solar analogue HD 110113 (2021) (5)
- Ariel planetary interiors White Paper (2021) (5)
- Linking Uranus’ temperature profile to wind-induced magnetic fields (2021) (5)
- Ice Giant Systems: The Scientific Potential of Missions to the Uranus and Neptune Systems (ESA Voyage 2050 White Paper) (2019) (5)
- Updated Equipotential Shapes of Jupiter and Saturn Using Juno and Cassini Grand Finale Gravity Science Measurements (2020) (5)
- Enrichment of Jupiter’s Atmosphere by Late Planetesimal Bombardment (2022) (5)
- THE CHANGE IN JUPITER'S MOMENT OF INERTIA DUE TO CORE EROSION AND PLANETARY CONTRACTION (2012) (5)
- Super stellar abundances of alkali metals suggest significant migration for Hot Jupiters (2021) (4)
- Prospects for Measuring Planetary Spin and Frame-Dragging in Spacecraft Timing Signals (2017) (4)
- Jupiter's occultation radii: Implications for its internal dynamics (2011) (4)
- Keys of a Mission to Uranus or Neptune, the Closest Ice Giants (2020) (4)
- Jupiter's Temperature Structure: A Reassessment of the Voyager Radio Occultation Measurements (2022) (4)
- The influence of infall on the properties of protoplanetary discs (2020) (4)
- Giant Planets from the Inside-Out (2022) (4)
- Theory of Figures to the Seventh Order and the Interiors of Jupiter and Saturn (2021) (4)
- Possible Chemical Composition And Interior Structure Models Of Venus Inferred From Numerical Modelling (2022) (4)
- Constraining the origin of giant exoplanets via elemental abundance measurements (2022) (4)
- Earth as an Exoplanet. I. Time Variable Thermal Emission Using Spatially Resolved Moderate Imaging Spectroradiometer Data (2020) (3)
- Ice Giant Systems: The Scientific Potential of Missions to Uranus and Neptune (ESA Voyage 2050 White Paper) (2019) (3)
- Ice giant system exploration within ESA’s Voyage 2050 (2021) (3)
- Possible In Situ Formation of Uranus and Neptune via Pebble Accretion (2022) (2)
- Could Uranus and Neptune form by collisions of planetary embryos? (2020) (2)
- New Frontiers-class Uranus Orbiter: Exploring the feasibility of achieving multidisciplinary science with a mid-scale mission (2021) (2)
- Connecting the Gravity Field, Moment of Inertia, and Core Properties in Jupiter through Empirical Structural Models (2021) (2)
- Forming Iron-rich Planets with Giant Impacts (2022) (2)
- Synthetic evolution tracks of giant planets (2021) (2)
- Potential long-term habitable conditions on planets with primordial H–He atmospheres (2022) (2)
- ANDES, the high resolution spectrograph for the ELT: science case, baseline design and path to construction (2022) (2)
- Did Uranus' regular moons form via a rocky giant impactor? (2021) (1)
- An approximation for the capture radius of gaseous protoplanets (2021) (1)
- The impact of exoplanets' measured parameters on the inferred internal structure. (2020) (1)
- A low accretion efficiency of planetesimals formed at planetary gap edges (2022) (1)
- Jupiter's interior from Juno: Equation-of-state uncertainties and dilute core extent (2023) (1)
- Empirical structure models of Uranus and Neptune (2022) (1)
- Why do more massive stars host larger planets? (2021) (1)
- Heavy-element accretion by proto-Jupiter in a massive planetesimal disk, revisited (2022) (1)
- Earth as an Exoplanet. II. Earth’s Time-variable Thermal Emission and Its Atmospheric Seasonality of Bioindicators (2022) (1)
- Planetary Formation and Evolution Revealed with a Saturn Entry Probe: The Importance of Noble Gases (2009) (1)
- Solar System Interiors, Atmospheres, and Surfaces Investigations via Radio Links: Goals for the Next Decade (2021) (1)
- The similarity of multi-planet systems (2021) (1)
- Zonal Winds of Uranus and Neptune: Gravitational Harmonics, Dynamic Self-gravity, Shape, and Rotation (2022) (1)
- TESS and HARPS reveal two sub-Neptunes around TOI 1062 (2021) (1)
- The fuzziness of Jupiter's core: linking formation and evolution models (2017) (1)
- Atmosphere of the mini-Neptune transiting the bright M dwarf GJ 3090 can be characterized (2022) (1)
- Towards a new era in giant exoplanet characterisation (2022) (1)
- Constraining the interior density profile of a Jovian planet from precision gravity field data (2017) (0)
- Rotation Rates of the Giant Planets (Invited) (2009) (0)
- The formation of Jupiter by hybrid pebble–planetesimal accretion (2018) (0)
- Critical Core Mass (Giant Planet Formation) (2014) (0)
- Planet Formation (2021) (0)
- The rotation of planet-hosting stars (2022) (0)
- Connecting gravity field, moment of inertia, and core properties in Jupiter through empirical structure models (2021) (0)
- Constraining Saturn's interior density profile from precision gravity field measurement obtained during Grand Finale (2017) (0)
- Mean Molecular Weight Gradients in Proto-Jupiter (2015) (0)
- Our inhomogeneous and unique outer planets (2011) (0)
- Thermal and structural evolution of Uranus (2019) (0)
- OSS (Outer Solar System): a fundamental and planetary physics mission to Neptune, Triton and the Kuiper Belt (2012) (0)
- Uranus Pathfinder : Exploring the Origins and Evolution 1 of Ice Giant Planets 2 3 (2011) (0)
- Impact of the measured parameters of exoplanets on the inferred internal structure. (2021) (0)
- Threshold Radii for Water Worlds and Neptune-like Planets (2018) (0)
- Exoplanet Characterization: linking theory & observations (2019) (0)
- VizieR Online Data Catalog: K2-106 radial velocities measurements (Guenther+, 2017) (2017) (0)
- Influence of cloud collapse on the fragmentation of protoplanetary discs (2019) (0)
- Metallic Aluminum Suboxides with Ultrahigh Electrical Conductivity at High Pressure (2022) (0)
- Learning a Planet's Deep Interior Secrets from Its External Gravity Field: A New Approach for Empirical Planet Modeling (2020) (0)
- First-Order Theory of Figures for Synchronous Rotation and Tides: Application to Rhea and Titan (2011) (0)
- Dynamo Simulations of Jupiter's Magnetic Field: The Role of Stable Stratification and a Dilute Core (2022) (0)
- A Common Evolutionary Pathway for Uranus and Neptune (2019) (0)
- Radar-optical leonids (2004) (0)
- The PLATO 2.0 mission (2014) (0)
- outputs The PLATO 2 . 0 mission Journal Item (2016) (0)
- Draft version October 21, 2021 Typeset using LTEX preprint style in AASTeX631 Theory of Figures to the 7th order and the interiors of Jupiter and Saturn (2021) (0)
- Composition of massive giant planets (2010) (0)
- Unveiling the Interior of Jupiter with Juno (2017) (0)
- Shapes and Gravitational Fields of Two-Layer Maclaurin Spheroids: Application to Planets and Satellites (2010) (0)
- Alternative Evolution and Internal Structure for Jupiter and Saturn (2016) (0)
- Author Correction: Formation of intermediate-mass planets via magnetically controlled disk fragmentation (2021) (0)
- Uranus and Neptune: from origin to current-state structure (2019) (0)
- Giant Planet Formation and Evolution with a Self-consistent Treatment of the Heavy Elements (2019) (0)
- 1 The PLATO 2 . 0 Mission 28 . 02 . 2014 (2014) (0)
- The contribution of the ARIEL space mission to the study of planetary formation (2018) (0)
- Understanding dense hydrogen at planetary conditions (2020) (0)
- Formation of intermediate-mass planets via magnetically controlled disk fragmentation (2021) (0)
- Methane planets and the mass-radius diagram (2014) (0)
- Saturn's Interior After the Cassini Grand Finale (2023) (0)
- Inferring the depth of the atmospheric flows on Jupiter from the Juno gravity measurements (2017) (0)
- Fe Earth-like H 2 O Ice Solar System Planets Radial Velocity TTV (2019) (0)
- Theory of Figures to the 7th order and the interiors of Jupiter and Saturn (2021) (0)
- Ju n 20 06 Planetesimal Capture in the Disk Instability Model (2006) (0)
- An Updated Shape Model for Jupiter from Juno Gravity Science Measurements (2018) (0)
- The nature of gas giant planets (2022) (0)
- The Underexplored Frontier of Ice Giant Interiors and Dynamos (2021) (0)
- Disk Instability, Model for Giant Planet Formation (2015) (0)
- Partially Diffusive Helium-Silica Compound under High Pressure (2022) (0)
- On the Mass-Radius Relation of Methane Planets (2015) (0)
- Exoplanet Radius Dependence on Host Star Type (2019) (0)
- Uranus and Neptune: Origin, Evolution and Internal Structure (2020) (0)
- The link between infall location, early disc size, and the fraction of self-gravitationally fragmenting discs (2022) (0)
- The Evolution and Survival of Gaseous Protoplanets Embedded in a Disk (2013) (0)
- The depth and structure of the atmospheric flows on Jupiter: results from the Juno gravity measurements (2017) (0)
- Calibrated gas accretion and orbital migration of protoplanets in 1D disc models (2022) (0)
- Past DPS Meetings (2020) (0)
- Convection in Uranus and Neptune (2015) (0)
- Discussion of Session 4 (2017) (0)
- The Case for a New Frontiers–Class Uranus Orbiter: System Science at an Underexplored and Unique World with a Mid-scale Mission (2022) (0)
- Ice lines and the formation of Uranus and Neptune (2020) (0)
- Models of Jupiter's Interior that match Juno's Gravity Measurements (2017) (0)
- A chemical survey of exoplanets with ARIEL (2018) (0)
- GJ 3090 b: one of the most favourable mini-Neptune for atmospheric characterisation (2022) (0)
- Revealing Saturn's Rotation Period from its Gravitational Field (2015) (0)
- A remnant planetary core in the hot-Neptune desert (2020) (0)
- Jupiter's Rotation Period Derived from Minimization of the Dynamic Heights of its Isobaric Surface (2008) (0)
- Warm giant exoplanet characterisation: current state, challenges and outlook (2023) (0)
- Earth as an Exoplanet: Thermal Emission and Time Variability using Spatially Resolved MODIS Data (2019) (0)
- Constraints on the formation of Jupiter from Juno (2018) (0)
- Partially Diffusive Helium-Silica Compound in the Deep Interiors of Giant Planets (2021) (0)
- Water-rich (exo)-planets: formation and interior structure (2019) (0)
- Interior Structure Models Of Venus (2021) (0)
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