Nathan Strange scite author profile

Life Investigation For Enceladus (LIFE) presents a low-cost sample return mission to Enceladus, a body with high astrobiological potential. There is ample evidence that liquid water exists under ice coverage in the form of active geysers in the "tiger stripes" area of the southern Enceladus hemisphere. This active plume consists of gas and ice particles and enables the sampling of fresh materials from the interior that may originate from a liquid water source. The particles consist mostly of water ice and are 1-10 μ in diameter. The plume composition shows H(2)O, CO(2), CH(4), NH(3), Ar, and evidence that more complex organic species might be present. Since life on Earth exists whenever liquid water, organics, and energy coexist, understanding the chemical components of the emanating ice particles could indicate whether life is potentially present on Enceladus. The icy worlds of the outer planets are testing grounds for some of the theories for the origin of life on Earth. The LIFE mission concept is envisioned in two parts: first, to orbit Saturn (in order to achieve lower sampling speeds, approaching 2 km/s, and thus enable a softer sample collection impact than Stardust, and to make possible multiple flybys of Enceladus); second, to sample Enceladus' plume, the E ring of Saturn, and the Titan upper atmosphere. With new findings from these samples, NASA could provide detailed chemical and isotopic and, potentially, biological compositional context of the plume. Since the duration of the Enceladus plume is unpredictable, it is imperative that these samples are captured at the earliest flight opportunity. If LIFE is launched before 2019, it could take advantage of a Jupiter gravity assist, which would thus reduce mission lifetimes and launch vehicle costs. The LIFE concept offers science returns comparable to those of a Flagship mission but at the measurably lower sample return costs of a Discovery-class mission.

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300-kW Solar Electric Propulsion System Configuration for Human Exploration of Near-Earth Asteroids

Brophy

Gershman²,

Strange³

et al. 2011

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The use of Solar Electric Propulsion (SEP) can provide significant benefits for the human exploration of near-Earth asteroids. These benefits include substantial cost savingsrepresented by a significant reduction in the mass required to be lifted to low Earth orbitand increased mission flexibility. To achieve these benefits, system power levels of 100's of kW are necessary along with the capability to store and process tens of thousands of kilograms of xenon propellant. The paper presents a conceptual design of a 300-kW SEP vehicle, with the capability to store nearly 40,000 kg of xenon, to support human missions to near-Earth asteroids.

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Graphical Method for Gravity-Assist Trajectory Design

Strange

Longuski

2002

Journal of Spacecraft and Rockets

134

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We introduce a new analytical technique directly related to Tisserand's criterion, which permits us to quickly identify all viable gravity-assist sequences to a given destination from an energy standpoint. The method is best presented by a simple graphical technique. The graphical technique readily demonstrates that VEE, VEME, and VEEJ (gravity assists via Venus, Earth, and Jupiter) are tremendously effective sequences. Estimates are made for the shortest flight times for a given launch energy to each planet. This graphical technique should provide mission designers with a potent tool for finding economical gravity-assist trajectories to many targets of high scientific interest in the Solar System.

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Science Goals and Mission Architecture of the Europa Lander Mission Concept

et al. 2022

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Europa is a premier target for advancing both planetary science and astrobiology, as well as for opening a new window into the burgeoning field of comparative oceanography. The potentially habitable subsurface ocean of Europa may harbor life, and the globally young and comparatively thin ice shell of Europa may contain biosignatures that are readily accessible to a surface lander. Europa’s icy shell also offers the opportunity to study tectonics and geologic cycles across a range of mechanisms and compositions. Here we detail the goals and mission architecture of the Europa Lander mission concept, as developed from 2015 through 2020. The science was developed by the 2016 Europa Lander Science Definition Team (SDT), and the mission architecture was developed by the preproject engineering team, in close collaboration with the SDT. In 2017 and 2018, the mission concept passed its mission concept review and delta-mission concept review, respectively. Since that time, the preproject has been advancing the technologies, and developing the hardware and software, needed to retire risks associated with technology, science, cost, and schedule.

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Solar Electric Propulsion Gravity-Assist Tours For Jupiter Missions

Strange

Landau

Hofer

et al. 2012

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Nathan Strange

LIFE: Life Investigation For EnceladusA Sample Return Mission Concept in Search for Evidence of Life

300-kW Solar Electric Propulsion System Configuration for Human Exploration of Near-Earth Asteroids

Graphical Method for Gravity-Assist Trajectory Design

Science Goals and Mission Architecture of the Europa Lander Mission Concept

Solar Electric Propulsion Gravity-Assist Tours For Jupiter Missions

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