Abstract is: Dirk Schulze-Makuch (born 1964) is a professor at the Center for Astronomy and Astrophysics at the Technical University Berlin, Germany and Adjunct Professor at the School of Earth and Environmental Sciences Washington State University, Pullman, WA. He is best known for his publications on extraterrestrial life, being coauthor of five books on the topic: The Cosmic Zoo: Complex Life on Many Worlds (2017), A One Way Mission to Mars: Colonizing the Red Planet (2011), We Are Not Alone: Why We Have Already Found Extraterrestrial Life (2010), Cosmic Biology: How Life could Evolve on Other Worlds (2010), and Life in the Universe: Expectations and Constraints (2004, 2008, 2018). In 2012 he published with David Darling Megacatastrophes! Nine Strange Ways the World Could End. In 2013 he published the second edition of his science fiction novel Alien Encounter. Together with Paul Davies he proposed in 2010 exploration of Mars by a one-way trip to the planet.
| human | Q5 |
| P166 | award received | Friedrich Wilhelm Bessel Research Award | Q1462893 |
| P27 | country of citizenship | United States of America | Q30 |
| Germany | Q183 | ||
| P1343 | described by source | Obálky knih | Q67311526 |
| P69 | educated at | University of Giessen | Q317053 |
| P108 | employer | Technische Universität Berlin | Q51985 |
| P101 | field of work | astrobiology | Q411 |
| P735 | given name | Dirk | Q1605531 |
| Dirk | Q1605531 | ||
| P1412 | languages spoken, written or signed | German | Q188 |
| English | Q1860 | ||
| P106 | occupation | geologist | Q520549 |
| researcher | Q1650915 | ||
| P21 | sex or gender | male | Q6581097 |
| Q105273702 | A cold hydrological system in Gale crater, Mars |
| Q56814008 | A formation mechanism for hematite-rich spherules on Mars |
| Q55890155 | A possible biogenic origin for hydrogen peroxide on Mars: the Viking results reinterpreted |
| Q34315809 | A sulfur-based survival strategy for putative phototrophic life in the venusian atmosphere |
| Q28250981 | A two-tiered approach to assessing the habitability of exoplanets |
| Q55951726 | Adaptation of an Antarctic lichen to Martian niche conditions can occur within 34 days |
| Q56814011 | Amino acid synthesis in Europa's subsurface environment |
| Q36199588 | Another Earth 2.0? Not So Fast |
| Q56813998 | Applications of particle-tracking techniques to bank infiltration: a case study from El Paso, Texas, USA |
| Q56814003 | Assessing the Possibility of Biological Complexity on Other Worlds, with an Estimate of the Occurrence of Complex Life in the Milky Way Galaxy |
| Q28216682 | Assessing the plausibility of life on other worlds |
| Q92450706 | Bacterial Growth in Chloride and Perchlorate Brines: Halotolerances and Salt Stress Responses of Planococcus halocryophilus |
| Q38513376 | Biologically enhanced energy and carbon cycling on Titan? |
| Q128342838 | Biosignature stability in space enables their use for life detection on Mars |
| Q58471077 | Deliquescence-induced wetting and RSL-like darkening of a Mars analogue soil containing various perchlorate and chloride salts |
| Q56813995 | Drastic environmental change and its effects on a planetary biosphere |
| Q38437782 | Effects of Low-Temperature Plasma-Sterilization on Mars Analog Soil Samples Mixed with Deinococcus radiodurans. |
| Q38494891 | Energy cycling and hypothetical organisms in Europa's ocean. |
| Q52804910 | Enhanced Microbial Survivability in Subzero Brines. |
| Q56814006 | Evidence for Amazonian acidic liquid water on Mars—A reinterpretation of MER mission results |
| Q61728995 | Extraterrestrial hydrogeology |
| Q42099161 | Fluorine-rich planetary environments as possible habitats for life |
| Q57850910 | Formation and disruption of aquifers in southwestern Chryse Planitia, Mars |
| Q113856828 | Fundamental Science and Engineering Questions in Planetary Cave Exploration |
| Q56552123 | GRS evidence and the possibility of paleooceans on Mars |
| Q55953923 | Geological and hydrological histories of the Argyre province, Mars |
| Q117733049 | Habitability of Polygonal Soils in the Hyper‐Arid Atacama Desert After a Simulated Rain Experiment |
| Q48142732 | How Many Biochemistries Are Available To Build a Cell? |
| Q99588824 | In Search for a Planet Better than Earth: Top Contenders for a Superhabitable World |
| Q47364032 | Introduction to the special paper collection: methodologies and techniques for detecting extraterrestrial (microbial) life |
| Q49847379 | Is Searching for Martian Life a Priority for the Mars Community? |
| Q38448749 | Locally targeted ecosynthesis: a proactive in situ search for extant life on other worlds |
| Q35677248 | Locating potential biosignatures on Europa from surface geology observations |
| Q30989395 | Longitudinal dispersivity data and implications for scaling behavior |
| Q51978353 | Low frequency electromagnetic waves as a supplemental energy source to sustain microbial growth? |
| Q53606806 | Mechanisms of Evolutionary Innovation Point to Genetic Control Logic as the Key Difference Between Prokaryotes and Eukaryotes. |
| Q56503655 | Meteorites at Meridiani Planum provide evidence for significant amounts of surface and near-surface water on early Mars |
| Q92491515 | Methanogenic Archaea Can Produce Methane in Deliquescence-Driven Mars Analog Environments |
| Q114027723 | Microbial Hotspots in Lithic Microhabitats Inferred from DNA Fractionation and Metagenomics in the Atacama Desert |
| Q34177278 | Microbial life in a liquid asphalt desert |
| Q33435235 | Microbial survival rates of Escherichia coli and Deinococcus radiodurans under low temperature, low pressure, and UV-Irradiation conditions, and their relevance to possible Martian life |
| Q38443624 | Nearly Forty Years after Viking: Are We Ready for a New Life-Detection Mission? |
| Q56814004 | New evidence for a magmatic influence on the origin of Valles Marineris, Mars |
| Q38466174 | New priorities in the robotic exploration of Mars: the case for in situ search for extant life. |
| Q33982037 | Noachian and more recent phyllosilicates in impact craters on Mars. |
| Q30841386 | Oil biodegradation. Water droplets in oil are microhabitats for microbial life |
| Q28654990 | Pavilion lake microbialites: morphological, molecular and biochemical evidence for a cold-water transition to colonial aggregates |
| Q98177587 | Physicochemical Salt Solution Parameters Limit the Survival of Planococcus halocryophilus in Martian Cryobrines |
| Q39315496 | Planetary imaging in powers of ten: a multiscale, multipurpose astrobiological imager |
| Q56814007 | Possibilities for the detection of hydrogen peroxide–water-based life on Mars by the Phoenix Lander |
| Q57859319 | Prime candidate sites for astrobiological exploration through the hydrogeological history of Mars |
| Q34163078 | Reassessing the possibility of life on venus: proposal for an astrobiology mission |
| Q59789022 | Scenarios for the evolution of life on Mars |
| Q57595339 | Science goals and mission concept for the future exploration of Titan and Enceladus |
| Q56813996 | Searching for Life Beyond Our Planet: Are We There Yet? |
| Q45336025 | Searching for Life on Mars Before It Is Too Late |
| Q42931685 | Simulations of Prebiotic Chemistry under Post-Impact Conditions on Titan |
| Q56672591 | Sorption heat engines: Simple inanimate negative entropy generators |
| Q38491953 | Strategy for modeling putative multilevel ecosystems on Europa |
| Q56814010 | Structural and tidal models of Titan and inferences on cryovolcanism |
| Q42037844 | Supercritical carbon dioxide and its potential as a life-sustaining solvent in a planetary environment |
| Q56813999 | Survey of the Outline of an Early Roman Marching-camp in Germany by Rammner's Current Line Pertubation Method |
| Q53965468 | TandEM: Titan and Enceladus mission |
| Q38477401 | Testing the H2O2-H2O hypothesis for life on Mars with the TEGA instrument on the Phoenix lander. |
| Q47241097 | The 100-year Starship Symposium: a historic meeting? |
| Q43033334 | The Adaptability of Life on Earth and the Diversity of Planetary Habitats |
| Q34511987 | The Argyre Region as a Prime Target for in situ Astrobiological Exploration of Mars. |
| Q118319082 | The Biological Oxidant and Life Detection (BOLD) mission: A proposal for a mission to Mars |
| Q28598278 | The Cosmic Zoo: The (Near) Inevitability of the Evolution of Complex, Macroscopic Life |
| Q38439674 | The Last Possible Outposts for Life on Mars |
| Q38442928 | The Physical, Chemical and Physiological Limits of Life |
| Q56814001 | The Solar Wind Power Satellite as an alternative to a traditional Dyson Sphere and its implications for remote detection |
| Q56960485 | The case for life on Mars |
| Q43366586 | The effect of critical pH on virus fate and transport in saturated porous medium |
| Q56814000 | The immune system as key to cancer treatment: Triggering its activity with microbial agents |
| Q38465053 | The next phase in our search for life: an expert discussion. |
| Q56814009 | The overprotection of Mars |
| Q56814002 | The power of social structure: how we became an intelligent lineage |
| Q28301006 | The prospect of alien life in exotic forms on other worlds |
| Q38473627 | The search for alien life in our solar system: strategies and priorities |
| Q57409304 | The search for life beyond Earth through fuzzy expert systems |
| Q28236859 | Thermal energy and the origin of life |
| Q57409308 | Tier-Scalable Reconnaissance Missions For The Autonomous Exploration Of Planetary Bodies |
| Q51150971 | Transitory microbial habitat in the hyperarid Atacama Desert. |
| Q56813997 | Variations in hydraulic conductivity with scale of measurement during aquifer tests in heterogeneous, porous carbonate rocks |
| Q22066097 | Venus, Mars, and the Ices on Mercury and the Moon: Astrobiological Implications and Proposed Mission Designs |
| azb | دیرک شولز-مکوچ | wikipedia |
| Dirk Schulze-Makuch | wikipedia |
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