Convide Amigos e Ganhe Moedas Gratuitas para Ambos
an aerial view of a large mountain in the desert
Xenoesis
Gerador de Imagens IA
v1
Ultra-high-resolution, scientifically accurate depiction of Olympus Mons from the summit of Arsia Mons on Mars. True-to-scale Martian topography with correct elevation differences and vast volcanic plains stretching toward Olympus Mons. The foreground captures the rugged terrain of Arsia Mons, including jagged rock formations, fine regolith layers, and dust-coated boulders. Ancient lava flows, impact craters, and fractured basaltic slabs are scattered across the scene, revealing the complex geological history of the Tharsis region. Olympus Mons, the largest volcano in the solar system, rises in the background with its massive shield structure, clearly visible escarpments, and an expansive caldera at the summit. Aeolian erosion patterns, dust devil trails, and layered sediment deposits provide additional geological complexity. The terrain exhibits a variety of mineralogical compositions: iron-rich oxidized dust giving the surface its characteristic rust-red hue, dark basaltic plains formed from ancient lava flows, and lighter sulfate deposits indicating past interactions with liquid water. The regolith is finely detailed, with variations in texture reflecting wind-sculpted patterns and micrometeorite impacts. Compact sedimentary layers and fragmented volcanic rock showcase Mars’ dynamic geological past. Scattered rock debris from ancient landslides and tectonic activity contrast with the otherwise smooth volcanic plains, revealing the erosional forces that have shaped the Martian landscape over billions of years. Realistic lighting and atmospheric effects enhance the scene. The thin CO₂-rich Martian atmosphere scatters sunlight, creating a faint reddish-pink sky with a subtle gradient darkening toward the horizon. Wisps of high-altitude clouds, composed of water-ice crystals, drift faintly above the volcanoes, adding a touch of realism. The interplay of light and shadow highlights the ruggedness of the terrain, with elongated shadows cast by rock formations and crater rims emphasizing depth and scale. Surface albedo variations are present, with darker basaltic regions absorbing more light, while brighter dust-covered areas reflect it, contributing to a natural contrast. The horizon features a slightly curved perspective, matching the true dimensions of Mars’ landscape. Olympus Mons’ escarpments and lava channels are accurately represented, showcasing its steep cliff faces that rise up to 8 km (5 miles) above the surrounding plains. The massive caldera at its summit, a remnant of past volcanic activity, features multiple nested collapse pits and solidified lava lakes. Faint traces of past pyroclastic flows and ancient volcanic ash deposits can be seen along its slopes. Large-scale landslide deposits are visible at the volcano’s base, where gravitational collapses have shaped the terrain. The surrounding plains are marked by radial lava flows, showcasing both smooth pāhoehoe formations and rougher ʻaʻā lava textures. The middle ground between Arsia Mons and Olympus Mons features a diverse landscape of tectonic fractures, rift valleys, and impact craters of varying ages. Some craters remain sharply defined, while others have been partially buried by wind-blown dust or resurfaced by volcanic activity. Yardangs—streamlined ridges formed by aeolian erosion—carve through the dust-laden plains, shaped by persistent Martian winds. The region also includes evidence of past glacial activity, with lobate debris aprons and remnants of ice-rich deposits hinting at Mars’ climatic evolution. Subtle color variations across the terrain reflect different mineralogical compositions, including hematite-rich zones, olivine-bearing basalt, and silicate-rich sediments. In the far distance, additional Tharsis volcanoes, including Pavonis Mons and Ascraeus Mons, emerge faintly through the atmospheric haze. Their peaks, though distant, contribute to the grandeur of the landscape, reinforcing the scale of this massive volcanic province. The curvature of Mars becomes subtly apparent, with distant terrain fading into the horizon under the diffuse Martian sunlight. Mars’ surface shows clear evidence of past hydrothermal activity, with mineralogical signatures of silica-rich deposits and sulfate-bearing layers suggesting interactions between water and volcanic materials. Small impact craters in the scene exhibit ejecta blankets with high-albedo streaks, indicative of recent impacts that have exposed subsurface material. Some craters display signs of ancient aqueous alteration, with channels hinting at transient liquid water flow in Mars’ distant past. The landscape is entirely devoid of biological presence, emphasizing the harsh, arid conditions of the Martian environment. Dust accumulation is evident in certain low-lying areas, where fine-grained particles have settled over time, creating subtle dunes and ripple formations. Electrostatic effects from Martian dust storms contribute to the redistribution of fine sediments, altering the appearance of surface features over extended timescales. Thermal inertia variations are also present, with rocky surfaces retaining heat longer than finer dust-covered areas, leading to observable temperature-driven color shifts. Scientific realism is maintained throughout the image, ensuring that all terrain features, mineralogical compositions, and atmospheric conditions adhere to real Mars data obtained from orbiters and landers. The image accurately reflects surface roughness, regolith layering, and impact histories, aligning with established geological models of Mars. No artificial exaggeration of terrain features or unrealistic lighting effects—only a physically plausible representation of Mars as it would appear to a human observer or robotic lander. Precision-rendered textures ensure that fine-scale geological details are captured, including vesicular basalt formations, shock-metamorphosed breccia, and exfoliated rock surfaces shaped by thermal expansion and contraction cycles. The dust layer is subtly uneven, adhering to natural deposition patterns dictated by prevailing wind currents and topographic influences. The surface brightness variations accurately depict reflectance properties observed in real Mars imagery, including localized bright patches caused by freshly exposed material from recent impacts. The composition remains true to planetary science principles, incorporating high-fidelity terrain reconstructions based on real elevation data. Subsurface geological structures, inferred from orbital radar scans, suggest hidden complexities beneath the visible surface, such as buried lava tubes and ancient volcanic conduits. Gravitational anomalies hint at potential magma chambers that may still exist deep below Mars’ crust, preserving the possibility of residual geothermal activity. No signs of artificial structures, spacecraft debris, or human activity are included in the scene. This remains an untouched alien landscape, shaped solely by natural Martian processes over billions of years. The realism extends to the physical conditions of Mars, where the lower gravity (0.38g) subtly affects the distribution of loose rock and dust. Atmospheric scattering effects are accurately rendered, ensuring that light diffusion matches real-world physics observed in Mars rover imagery. The final scene captures the awe-inspiring scale of Olympus Mons as viewed from Arsia Mons, providing a scientifically accurate, photorealistic, and physically plausible representation of Mars’ most iconic volcanic landscape. A perfect blend of planetary geology, atmospheric science, and remote sensing accuracy, ensuring that every detail aligns with real-world Mars exploration data.
Estilo:
Arte Conceitual-Ficção Científica 04
Cena:
Na Cratera do Vulcão
Perspectiva:
Vista Aérea
Prompt Negativo:
No exaggerated terrain deformations—no artificially heightened Olympus Mons—no unrealistic vertical scaling of Martian topography—no over-accentuated cliffs or exaggeratedly deep calderas—no overly dramatic escarpments beyond scientifically verified heights—no surrealistic landforms—no fantasy-style exaggerated mountains—no physically impossible slopes—no cliffs steeper than natural basaltic formations allow—no overly smoothed landscapes—no artificially sharpened geological features—no unnaturally even terrain—no synthetic symmetry—no unnatural geological formations not found on Mars—no alien-like unrealistic mountain peaks—no artificial smoothness in lava flows—no softening of terrain details—no cartoony or stylized geological patterns—no non-existent terrain anomalies—no imaginary rock formations—no crystal spires or unrealistic mineral deposits—no impossible basaltic structures—no speculative geological formations beyond planetary science consensus—no unnatural tessellations in regolith texture—no procedurally generated patterns that don’t exist in reality. No incorrect atmospheric effects—no Earth-like blue sky—no exaggeratedly thick atmosphere—no clouds beyond realistic Mars conditions—no cumulus clouds—no water vapor clouds at altitudes where they cannot form—no cloud cover inconsistent with Mars’ thin CO₂-dominated atmosphere—no excessive humidity effects—no visible liquid water—no fog or mist that wouldn’t occur under Martian pressure conditions—no haze beyond documented dust scattering—no over-saturation of atmospheric dust—no extreme storm conditions unless scientifically plausible—no incorrect atmospheric gradients—no auroras that are too intense or unrealistic—no dramatic Earth-like sunsets—no artificial blooming effects—no exaggerated refraction distortions—no oversaturated sunrays—no excessive horizon glow beyond Mars’ typical light scattering—no night sky featuring stars that are too bright—no artificially thick fog banks—no lens flares—no cinematic lighting effects—no over-processed post-apocalyptic lighting. No non-Martian terrain elements—no Earth-like vegetation—no alien plants—no trees, shrubs, or grass—no biological activity—no fungal growth—no moss-covered rocks—no bacterial colonies visible to the naked eye—no extraterrestrial life forms—no bioluminescent surfaces—no fossils—no remnants of organic structures—no flowing rivers—no lakes—no standing water—no glaciers where ice deposits do not exist—no oceanic reflections—no rain or precipitation—no puddles—no ice caps misplaced outside of polar regions—no marshy textures—no signs of life in any form—no animal footprints—no non-existent biological residue—no microbial biofilms—no algae growth—no methane plumes inconsistent with Mars’ atmospheric composition—no terraformed landscapes—no artificially added signs of colonization. No artificial structures—no human-made elements—no spacecraft—no satellite debris—no rover tracks—no lander hardware—no artificial lights—no research stations—no antennas—no cities—no roads—no infrastructure—no domes—no futuristic Martian bases—no abandoned buildings—no ruined alien civilizations—no hypothetical archaeology—no statues—no pyramids—no carved rock formations resembling faces or animals—no metallic objects beyond natural meteorite remnants—no unrealistic artifacts—no signs of engineering—no tunnels—no mining operations—no construction sites—no exploratory markers—no unnatural geometric formations—no artificially added rover imprints—no footprints—no futuristic settlements. No incorrect lighting physics—no multiple light sources inconsistent with a single sun—no soft ambient lighting where it shouldn’t be—no glow-in-the-dark elements—no artificially heightened contrast—no hyper-stylized cinematographic color grading—no unscientific light reflections—no artificially glowing minerals—no neon colors—no plasma effects—no excessive bloom—no soft ethereal mist—no shimmering surfaces beyond scientifically accurate ice or frost—no rainbow-colored landscapes—no excessive atmospheric distortion—no dramatic artificial lighting—no backlighting effects inconsistent with Mars’ sun angle—no spotlight-like sun effects—no moon-sized Phobos or Deimos casting shadows far beyond realistic expectations—no inconsistent light sources—no multiple shadows where there should only be one. No misrepresented mineral compositions—no fictional ore deposits—no rare Earth elements misplaced in non-existent Martian geological formations—no shiny metallic veins beyond natural iron oxide—no crystalline caves—no geodes of impossible size—no diamond-like formations—no exaggeratedly reflective surfaces—no translucent rocks—no luminous minerals—no glowing blue or green stones—no visible uranium deposits—no impossible magnetic rock formations—no artificially added meteorite impacts in non-impacted regions—no lava where lava should not exist—no active molten lava—no volcanically active Olympus Mons—no recent lava flows—no geysers beyond realistic CO₂ sublimation—no steam vents without scientific evidence—no planetary cores exposed to the surface—no non-existent lava rivers—no molten rock lakes. No geological inaccuracies—no non-existent tectonic activity—no incorrectly placed fault lines—no artificially deep canyons where none exist—no exaggerated weathering patterns—no over-textured surface that disregards real Martian terrain roughness—no unrealistic erosion—no water-carved formations in areas where no evidence of past water exists—no artificially exaggerated impact craters—no hyper-detailed micrometeorite scars beyond observed realism—no ice-free permafrost areas where they should exist—no misrepresented sulfate deposits—no misplaced hematite regions—no over-polished regolith—no over-simplified terrain transitions—no impossible layering of sediments—no hyper-contrasted mineral variations beyond realistic Mars spectroscopy—no exposed mantle material on the surface—no chemically implausible mineral combinations. No non-Mars environmental effects—no unrealistic temperature gradients—no heatwaves—no lens distortion effects mimicking high humidity—no mirages—no atmospheric lensing that does not match Mars’ gravity and atmospheric pressure—no Earth-like dust clouds—no sandstorms beyond documented Martian storm behaviors—no dynamic weather changes that happen too rapidly—no incorrectly scaled dust devils—no tornadoes—no lightning storms—no auroras visible to the naked eye—no rainbow phenomena—no hurricanes—no large-scale precipitation cycles—no river delta systems with active flow—no lakes forming outside of expected frozen brine conditions—no unrealistic thermal differentials—no temperature inversions not found on Mars. No photographic distortions—no fish-eye lens effects—no artificial vignetting—no unrealistic tilt-shift focus—no Gaussian blur beyond depth-of-field realism—no chromatic aberration—no lens warping—no soft-focus edges—no artificial grain effects—no over-saturated colors—no HDR processing artifacts—no excessive sharpness filters—no artificially clean or “perfect” rock formations—no over-simplified regolith—no synthetic detail enhancements—no artificial high-dynamic-range effects—no image compression artifacts—no digitally exaggerated textures—no post-processed color enhancements—no painterly effects—no impressionistic color schemes—no non-realistic camera distortions. No unrealistic planetary background—no hyper-exaggerated starfields—no nebulae visible from Mars—no nearby supernovae—no other planets visible at unrealistic scales—no incorrect placement of Phobos and Deimos—no artificially large moons—no added asteroid fields—no deep space anomalies—no fictional cosmic phenomena—no Earth appearing too large in the sky—no Saturn-like rings—no colorful cosmic dust clouds—no galactic center appearing bright—no unrealistic planetary conjunctions—no solar flares beyond observed sun activity—no planetary-scale auroras. This image must remain entirely faithful to real Mars terrain, accurate geological formations, and true-to-life atmospheric conditions—ensuring scientific realism with no exaggerations, distortions, or non-existent features.
Proporção:
3:4
Iluminação:
Luz Solar Direta
0
Remix
3
Curtir
jorge eduardo
2025-1-31
Excelente creación
Responder
Xenoesis
2025-1-31
Mars, circa 500,000,000 years before the introduction of the Julian calendar.
Responder
Mais conteúdos semelhantes
an aerial view of a large mountain in the desert
Xenoesis
Gerador de Imagens IA
v1
Ultra-high-resolution, scientifically accurate depiction of Olympus Mons from the summit of Arsia Mons on Mars. True-to-scale Martian topography with correct elevation differences and vast volcanic plains stretching toward Olympus Mons. The foreground captures the rugged terrain of Arsia Mons, including jagged rock formations, fine regolith layers, and dust-coated boulders. Ancient lava flows, impact craters, and fractured basaltic slabs are scattered across the scene, revealing the complex geological history of the Tharsis region. Olympus Mons, the largest volcano in the solar system, rises in the background with its massive shield structure, clearly visible escarpments, and an expansive caldera at the summit. Aeolian erosion patterns, dust devil trails, and layered sediment deposits provide additional geological complexity. The terrain exhibits a variety of mineralogical compositions: iron-rich oxidized dust giving the surface its characteristic rust-red hue, dark basaltic plains formed from ancient lava flows, and lighter sulfate deposits indicating past interactions with liquid water. The regolith is finely detailed, with variations in texture reflecting wind-sculpted patterns and micrometeorite impacts. Compact sedimentary layers and fragmented volcanic rock showcase Mars’ dynamic geological past. Scattered rock debris from ancient landslides and tectonic activity contrast with the otherwise smooth volcanic plains, revealing the erosional forces that have shaped the Martian landscape over billions of years. Realistic lighting and atmospheric effects enhance the scene. The thin CO₂-rich Martian atmosphere scatters sunlight, creating a faint reddish-pink sky with a subtle gradient darkening toward the horizon. Wisps of high-altitude clouds, composed of water-ice crystals, drift faintly above the volcanoes, adding a touch of realism. The interplay of light and shadow highlights the ruggedness of the terrain, with elongated shadows cast by rock formations and crater rims emphasizing depth and scale. Surface albedo variations are present, with darker basaltic regions absorbing more light, while brighter dust-covered areas reflect it, contributing to a natural contrast. The horizon features a slightly curved perspective, matching the true dimensions of Mars’ landscape. Olympus Mons’ escarpments and lava channels are accurately represented, showcasing its steep cliff faces that rise up to 8 km (5 miles) above the surrounding plains. The massive caldera at its summit, a remnant of past volcanic activity, features multiple nested collapse pits and solidified lava lakes. Faint traces of past pyroclastic flows and ancient volcanic ash deposits can be seen along its slopes. Large-scale landslide deposits are visible at the volcano’s base, where gravitational collapses have shaped the terrain. The surrounding plains are marked by radial lava flows, showcasing both smooth pāhoehoe formations and rougher ʻaʻā lava textures. The middle ground between Arsia Mons and Olympus Mons features a diverse landscape of tectonic fractures, rift valleys, and impact craters of varying ages. Some craters remain sharply defined, while others have been partially buried by wind-blown dust or resurfaced by volcanic activity. Yardangs—streamlined ridges formed by aeolian erosion—carve through the dust-laden plains, shaped by persistent Martian winds. The region also includes evidence of past glacial activity, with lobate debris aprons and remnants of ice-rich deposits hinting at Mars’ climatic evolution. Subtle color variations across the terrain reflect different mineralogical compositions, including hematite-rich zones, olivine-bearing basalt, and silicate-rich sediments. In the far distance, additional Tharsis volcanoes, including Pavonis Mons and Ascraeus Mons, emerge faintly through the atmospheric haze. Their peaks, though distant, contribute to the grandeur of the landscape, reinforcing the scale of this massive volcanic province. The curvature of Mars becomes subtly apparent, with distant terrain fading into the horizon under the diffuse Martian sunlight. Mars’ surface shows clear evidence of past hydrothermal activity, with mineralogical signatures of silica-rich deposits and sulfate-bearing layers suggesting interactions between water and volcanic materials. Small impact craters in the scene exhibit ejecta blankets with high-albedo streaks, indicative of recent impacts that have exposed subsurface material. Some craters display signs of ancient aqueous alteration, with channels hinting at transient liquid water flow in Mars’ distant past. The landscape is entirely devoid of biological presence, emphasizing the harsh, arid conditions of the Martian environment. Dust accumulation is evident in certain low-lying areas, where fine-grained particles have settled over time, creating subtle dunes and ripple formations. Electrostatic effects from Martian dust storms contribute to the redistribution of fine sediments, altering the appearance of surface features over extended timescales. Thermal inertia variations are also present, with rocky surfaces retaining heat longer than finer dust-covered areas, leading to observable temperature-driven color shifts. Scientific realism is maintained throughout the image, ensuring that all terrain features, mineralogical compositions, and atmospheric conditions adhere to real Mars data obtained from orbiters and landers. The image accurately reflects surface roughness, regolith layering, and impact histories, aligning with established geological models of Mars. No artificial exaggeration of terrain features or unrealistic lighting effects—only a physically plausible representation of Mars as it would appear to a human observer or robotic lander. Precision-rendered textures ensure that fine-scale geological details are captured, including vesicular basalt formations, shock-metamorphosed breccia, and exfoliated rock surfaces shaped by thermal expansion and contraction cycles. The dust layer is subtly uneven, adhering to natural deposition patterns dictated by prevailing wind currents and topographic influences. The surface brightness variations accurately depict reflectance properties observed in real Mars imagery, including localized bright patches caused by freshly exposed material from recent impacts. The composition remains true to planetary science principles, incorporating high-fidelity terrain reconstructions based on real elevation data. Subsurface geological structures, inferred from orbital radar scans, suggest hidden complexities beneath the visible surface, such as buried lava tubes and ancient volcanic conduits. Gravitational anomalies hint at potential magma chambers that may still exist deep below Mars’ crust, preserving the possibility of residual geothermal activity. No signs of artificial structures, spacecraft debris, or human activity are included in the scene. This remains an untouched alien landscape, shaped solely by natural Martian processes over billions of years. The realism extends to the physical conditions of Mars, where the lower gravity (0.38g) subtly affects the distribution of loose rock and dust. Atmospheric scattering effects are accurately rendered, ensuring that light diffusion matches real-world physics observed in Mars rover imagery. The final scene captures the awe-inspiring scale of Olympus Mons as viewed from Arsia Mons, providing a scientifically accurate, photorealistic, and physically plausible representation of Mars’ most iconic volcanic landscape. A perfect blend of planetary geology, atmospheric science, and remote sensing accuracy, ensuring that every detail aligns with real-world Mars exploration data.
Estilo:
Arte Conceitual-Ficção Científica 04
Cena:
Na Cratera do Vulcão
Perspectiva:
Vista Aérea
Prompt Negativo:
No exaggerated terrain deformations—no artificially heightened Olympus Mons—no unrealistic vertical scaling of Martian topography—no over-accentuated cliffs or exaggeratedly deep calderas—no overly dramatic escarpments beyond scientifically verified heights—no surrealistic landforms—no fantasy-style exaggerated mountains—no physically impossible slopes—no cliffs steeper than natural basaltic formations allow—no overly smoothed landscapes—no artificially sharpened geological features—no unnaturally even terrain—no synthetic symmetry—no unnatural geological formations not found on Mars—no alien-like unrealistic mountain peaks—no artificial smoothness in lava flows—no softening of terrain details—no cartoony or stylized geological patterns—no non-existent terrain anomalies—no imaginary rock formations—no crystal spires or unrealistic mineral deposits—no impossible basaltic structures—no speculative geological formations beyond planetary science consensus—no unnatural tessellations in regolith texture—no procedurally generated patterns that don’t exist in reality. No incorrect atmospheric effects—no Earth-like blue sky—no exaggeratedly thick atmosphere—no clouds beyond realistic Mars conditions—no cumulus clouds—no water vapor clouds at altitudes where they cannot form—no cloud cover inconsistent with Mars’ thin CO₂-dominated atmosphere—no excessive humidity effects—no visible liquid water—no fog or mist that wouldn’t occur under Martian pressure conditions—no haze beyond documented dust scattering—no over-saturation of atmospheric dust—no extreme storm conditions unless scientifically plausible—no incorrect atmospheric gradients—no auroras that are too intense or unrealistic—no dramatic Earth-like sunsets—no artificial blooming effects—no exaggerated refraction distortions—no oversaturated sunrays—no excessive horizon glow beyond Mars’ typical light scattering—no night sky featuring stars that are too bright—no artificially thick fog banks—no lens flares—no cinematic lighting effects—no over-processed post-apocalyptic lighting. No non-Martian terrain elements—no Earth-like vegetation—no alien plants—no trees, shrubs, or grass—no biological activity—no fungal growth—no moss-covered rocks—no bacterial colonies visible to the naked eye—no extraterrestrial life forms—no bioluminescent surfaces—no fossils—no remnants of organic structures—no flowing rivers—no lakes—no standing water—no glaciers where ice deposits do not exist—no oceanic reflections—no rain or precipitation—no puddles—no ice caps misplaced outside of polar regions—no marshy textures—no signs of life in any form—no animal footprints—no non-existent biological residue—no microbial biofilms—no algae growth—no methane plumes inconsistent with Mars’ atmospheric composition—no terraformed landscapes—no artificially added signs of colonization. No artificial structures—no human-made elements—no spacecraft—no satellite debris—no rover tracks—no lander hardware—no artificial lights—no research stations—no antennas—no cities—no roads—no infrastructure—no domes—no futuristic Martian bases—no abandoned buildings—no ruined alien civilizations—no hypothetical archaeology—no statues—no pyramids—no carved rock formations resembling faces or animals—no metallic objects beyond natural meteorite remnants—no unrealistic artifacts—no signs of engineering—no tunnels—no mining operations—no construction sites—no exploratory markers—no unnatural geometric formations—no artificially added rover imprints—no footprints—no futuristic settlements. No incorrect lighting physics—no multiple light sources inconsistent with a single sun—no soft ambient lighting where it shouldn’t be—no glow-in-the-dark elements—no artificially heightened contrast—no hyper-stylized cinematographic color grading—no unscientific light reflections—no artificially glowing minerals—no neon colors—no plasma effects—no excessive bloom—no soft ethereal mist—no shimmering surfaces beyond scientifically accurate ice or frost—no rainbow-colored landscapes—no excessive atmospheric distortion—no dramatic artificial lighting—no backlighting effects inconsistent with Mars’ sun angle—no spotlight-like sun effects—no moon-sized Phobos or Deimos casting shadows far beyond realistic expectations—no inconsistent light sources—no multiple shadows where there should only be one. No misrepresented mineral compositions—no fictional ore deposits—no rare Earth elements misplaced in non-existent Martian geological formations—no shiny metallic veins beyond natural iron oxide—no crystalline caves—no geodes of impossible size—no diamond-like formations—no exaggeratedly reflective surfaces—no translucent rocks—no luminous minerals—no glowing blue or green stones—no visible uranium deposits—no impossible magnetic rock formations—no artificially added meteorite impacts in non-impacted regions—no lava where lava should not exist—no active molten lava—no volcanically active Olympus Mons—no recent lava flows—no geysers beyond realistic CO₂ sublimation—no steam vents without scientific evidence—no planetary cores exposed to the surface—no non-existent lava rivers—no molten rock lakes. No geological inaccuracies—no non-existent tectonic activity—no incorrectly placed fault lines—no artificially deep canyons where none exist—no exaggerated weathering patterns—no over-textured surface that disregards real Martian terrain roughness—no unrealistic erosion—no water-carved formations in areas where no evidence of past water exists—no artificially exaggerated impact craters—no hyper-detailed micrometeorite scars beyond observed realism—no ice-free permafrost areas where they should exist—no misrepresented sulfate deposits—no misplaced hematite regions—no over-polished regolith—no over-simplified terrain transitions—no impossible layering of sediments—no hyper-contrasted mineral variations beyond realistic Mars spectroscopy—no exposed mantle material on the surface—no chemically implausible mineral combinations. No non-Mars environmental effects—no unrealistic temperature gradients—no heatwaves—no lens distortion effects mimicking high humidity—no mirages—no atmospheric lensing that does not match Mars’ gravity and atmospheric pressure—no Earth-like dust clouds—no sandstorms beyond documented Martian storm behaviors—no dynamic weather changes that happen too rapidly—no incorrectly scaled dust devils—no tornadoes—no lightning storms—no auroras visible to the naked eye—no rainbow phenomena—no hurricanes—no large-scale precipitation cycles—no river delta systems with active flow—no lakes forming outside of expected frozen brine conditions—no unrealistic thermal differentials—no temperature inversions not found on Mars. No photographic distortions—no fish-eye lens effects—no artificial vignetting—no unrealistic tilt-shift focus—no Gaussian blur beyond depth-of-field realism—no chromatic aberration—no lens warping—no soft-focus edges—no artificial grain effects—no over-saturated colors—no HDR processing artifacts—no excessive sharpness filters—no artificially clean or “perfect” rock formations—no over-simplified regolith—no synthetic detail enhancements—no artificial high-dynamic-range effects—no image compression artifacts—no digitally exaggerated textures—no post-processed color enhancements—no painterly effects—no impressionistic color schemes—no non-realistic camera distortions. No unrealistic planetary background—no hyper-exaggerated starfields—no nebulae visible from Mars—no nearby supernovae—no other planets visible at unrealistic scales—no incorrect placement of Phobos and Deimos—no artificially large moons—no added asteroid fields—no deep space anomalies—no fictional cosmic phenomena—no Earth appearing too large in the sky—no Saturn-like rings—no colorful cosmic dust clouds—no galactic center appearing bright—no unrealistic planetary conjunctions—no solar flares beyond observed sun activity—no planetary-scale auroras. This image must remain entirely faithful to real Mars terrain, accurate geological formations, and true-to-life atmospheric conditions—ensuring scientific realism with no exaggerations, distortions, or non-existent features.
Proporção:
3:4
Iluminação:
Luz Solar Direta
0
Remix
3
Curtir
jorge eduardo
2025-1-31
Excelente creación
Responder
Xenoesis
2025-1-31
Mars, circa 500,000,000 years before the introduction of the Julian calendar.
Responder