스타일: 현실적인 재료-대리석 35

부정적 프롬프트: Positive prompt: hyperrealistic ultra-detailed close-up macro shot of a thick, semi-translucent, pearly off-white liquid exhibiting a precisely measured dynamic viscosity of 189 millipascal-seconds (mPa·s) at 20°C, characterized by its non-Newtonian shear-thinning properties. The liquid is mid-pour, forming continuous, elongated, stretching strands due to strong cohesive intermolecular forces before detaching into individual spherical droplets. Each primary droplet has an average diameter of 3.2mm, though minor fluctuations occur due to microvariations in shear force distribution at the breaking points of the stream. Microdroplets, formed at the periphery of the liquid stream, range from 0.4mm to 0.9mm in size. The liquid’s molecular structure allows for a gradual thinning effect at the edges, with individual strands tapering before detachment, following predictable fragmentation patterns dictated by the Rayleigh–Plateau instability. The liquid is poured from a cylindrical glass container with a precisely measured internal diameter of 2.5 inches (63.5mm) and a height of 5 inches (127mm). The glass has a uniform wall thickness of 3mm, a refractive index of 1.52, and an optically smooth interior surface with an arithmetic mean surface roughness (Ra) below 0.02μm to minimize irregular adhesion effects. The pouring lip is smoothly curved with a radius of curvature of approximately 1.5mm to facilitate controlled liquid displacement, ensuring an uninterrupted flow with minimal turbulence. Capillary action is observed at the edges, where a residual film measuring approximately 0.03mm adheres to the glass surface. The liquid’s color is a neutral off-white with a base tone resembling natural ivory, with spectrophotometric analysis indicating an average reflectance of 82% in the visible light spectrum, with slight variations due to localized density fluctuations. It contains subtle beige undertones, with no pronounced yellow, pink, or orange shifts. Controlled 5000K soft diffused lighting enhances the semi-translucent quality, allowing partial light penetration through thinner sections while maintaining an opaque appearance in denser regions. The interaction between light and the liquid’s internal microstructures results in faint opalescent highlights without oversaturation. Surface tension, measured at 72.8 millinewtons per meter (mN/m), generates a naturally curved meniscus along the edges of droplets. The contact angle of the liquid against the glass surface is measured at 78 degrees, indicating moderate wettability. The refractive index of the liquid is approximately 1.35, creating minor lensing distortions in localized areas where thickness variations cause differential light refraction. The liquid exhibits a cohesive, structured texture with occasional gel-like strands interspersed within the primary colloidal matrix. These strands appear due to variations in localized viscosity, influenced by differences in molecular interaction strength. The fluid composition remains homogenous, though microscopic analysis reveals sporadic clustering of denser regions. The stretching behavior of the liquid before droplet detachment follows a predictable progression: initial elongation due to gravitational acceleration (9.81 m/s²), subsequent necking at the thinning points, and final separation dictated by a combination of surface tension forces and fluid inertia. Bubbles are sparsely distributed throughout the liquid, with an average diameter of 0.2mm, though larger bubbles reaching 0.5mm are occasionally observed near the surface due to buoyancy effects. The distribution pattern follows Stokes’ law, with smaller bubbles remaining suspended longer due to lower terminal velocities. These bubbles introduce minor variations in local refractive indices, creating subtle distortions in light transmission. Environmental conditions are calibrated for maximum optical accuracy: a neutral 18% gray background with a reflectance value precisely controlled to eliminate unwanted color casts. The lighting setup consists of a primary diffused softbox positioned at a 45-degree angle to the subject, creating controlled highlights without excessive glare. A secondary fill light at 20% intensity, positioned at a 120-degree offset, ensures even illumination across shadowed regions without introducing unnatural reflections. The scene is further balanced by a light-absorbing surface with a spectral reflectance below 5% to prevent unwanted backscatter interference. The image is captured using a professional 100mm macro lens with an f/8 aperture, optimizing depth of field to retain maximum sharpness on the liquid’s surface while introducing a controlled depth gradient in the background. A 1:1 scale ensures accurate representation of molecular-level details. The sensor resolution exceeds 50 megapixels, preserving microscopic structural nuances. The camera is stabilized to sub-pixel accuracy using a vibration-dampened rig to eliminate motion artifacts. The pouring motion is frozen at a precise shutter speed of 1/2000s, effectively capturing each stage of the liquid’s flow dynamics: initial displacement from the glass container, stretching elongation, necking formation, and droplet detachment. Shear points along the stream exhibit gradual thinning, governed by cohesive molecular forces acting in opposition to gravitational pull. The leading edge of the liquid displays subtle wave formations, illustrating internal momentum transfer and surface tension effects. The composition remains strictly focused on the liquid’s natural properties, avoiding exaggerated artistic interpretations. Every optical characteristic, fluid dynamic behavior, and environmental variable is scientifically accurate, ensuring a precise depiction of the material’s real-world physical attributes. The final image is processed with minimal post-production adjustments, solely correcting for chromatic accuracy and eliminating sensor noise while preserving all intrinsic textural details. The liquid’s adhesive properties are further analyzed through high-magnification close-ups of the glass surface, where residual films exhibit a uniform thickness gradient, transitioning smoothly from the bulk liquid to the adhered layer. This transition is dictated by intermolecular adhesion forces and capillary action, which generate a visually consistent film curvature following the glass’s geometry. Fluid motion studies indicate that as the liquid exits the container, the internal velocity gradient follows a laminar flow profile with minor perturbations near the leading edge due to air resistance and microturbulence formation. The Reynolds number for this pouring scenario remains within the laminar regime, ensuring a smooth, continuous flow with minimal chaotic disruptions. Microscopic analysis of the liquid’s suspended particles reveals a dispersed phase with an average particle size below 1 micron, contributing to its semi-translucent appearance. These suspended structures interact with incident light, creating Mie scattering effects that subtly influence its perceived texture and depth. The scientific precision of this depiction extends to every measurable parameter, from fluid mechanical properties to optical behavior, ensuring a hyperrealistic, physically accurate representation of the liquid’s true characteristics without speculative interpretation or artistic enhancement. Negative prompt: negative prompt: avoid all unrealistic, exaggerated, or stylized elements; strictly adhere to scientific accuracy, ensuring precise representation of fluid dynamics, material properties, lighting physics, and optical behavior with no artistic embellishments or misinterpretations; no unrealistic glossiness—the liquid must exhibit physically correct specular reflection and diffuse scattering without excessive shininess, preventing plastic-like or synthetic appearances; reflections must follow real-world Fresnel equations, avoiding unnatural highlights or exaggerated specular bloom; no unnatural color distortions—strictly maintain an off-white, ivory, or faint beige color profile without artificial pink, yellow, blue, or green shifts that could introduce incorrect material interpretations; no unrealistic transparency levels—semi-translucence should be present only in thinner liquid sections with physically correct light diffusion, avoiding exaggerated glass-like transparency or unnatural opacity shifts; prevent unnatural fluid smoothness—surface must display minor natural variations in thickness, cohesive clustering, and occasional gel-like strands, ensuring realistic viscosity-driven morphology without over-polished artificial smoothness; eliminate unnatural levitation effects—fluid must behave according to Newtonian and non-Newtonian principles without floating, hovering, or exhibiting any suspension effects inconsistent with real-world physics; no unnatural reflection distortions—refractive index must remain within the expected range (1.35), ensuring no overemphasized lensing distortions or unrealistic light bending effects; avoid incorrect droplet formations—individual droplets must form according to real-world surface tension and molecular cohesion principles, maintaining correct spherical or slightly elongated shapes, avoiding unrealistic stretching or unnatural droplet patterns; eliminate incorrect lighting effects—illumination must adhere to controlled 5000K soft diffused lighting, avoiding artificial glows, overexposed highlights, incorrect rim lighting, or stylistic light reflections that deviate from natural behavior; prevent chaotic fluid behavior—motion must strictly follow laminar flow dynamics, adhering to measured viscosity properties (189 mPa·s), preventing incorrect turbulence, splash effects, or non-Newtonian inconsistencies; no excessive air bubbles—sporadic microscopic air bubbles (0.2mm-0.5mm) are acceptable but must be naturally distributed within the liquid, avoiding foam-like textures, clustering, or unnatural void formations; prevent incorrect edge transitions—fluid should exhibit physically accurate smooth edge transitions dictated by shear-thinning effects and cohesive forces, avoiding sharp, jagged, or overly abrupt changes in thickness or structure; eliminate synthetic or plastic texturing—liquid must maintain a naturally organic colloidal appearance with correct molecular interactions, avoiding unnatural uniformity, artificial polishing, or digitally enhanced smoothness; no unnecessary background distractions—the composition should remain entirely focused on the fluid and its scientifically accurate properties, excluding extraneous elements that could introduce interpretative distortions; prevent incorrect physical interactions—liquid adhesion to the glass surface must follow correct physical principles (contact angle ~78 degrees), ensuring realistic film thickness (0.03mm), gravitational pull, and capillary action without artificial suspension or incorrect detachment effects; no incorrect dispersion patterns—fluid must remain cohesive, following accurate molecular interaction forces without unrealistic fragmentation, misting, or non-physical droplet dispersion; prevent incorrect focus depth—sharpness must be scientifically accurate for macro photography (1:1 scale, f/8 aperture, 100mm lens), preventing unnatural blurring, excessive depth compression, or incorrect depth of field interpretation; no incorrect environmental lighting conditions—background must remain neutral 18% gray with accurate reflectance values, preventing artificial color gradients, unnatural vignetting, or stylistic ambient light effects; avoid fictional, speculative, or interpretative visual elements—representation must be purely grounded in real-world physics, chemistry, and fluid mechanics, eliminating any stylized, exaggerated, or impressionistic alterations; prevent incorrect viscosity behavior—fluid must demonstrate precise shear-thinning properties without artificial viscosity inconsistencies, avoiding unrealistic dripping speeds, incorrect stringing behaviors, or non-physical thinning effects; no exaggerated droplet separation—droplets must form according to real-world detachment mechanics, governed by cohesive and adhesive forces, preventing excessive stretching, artificial elongations, or unnatural strand formations; eliminate incorrect refractive distortions—light transmission through the fluid must obey Snell’s Law, preventing unrealistic warping, incorrect caustics, or artificial dispersion artifacts; no excessive or artificial subsurface scattering—light penetration through the liquid should remain within physically measured translucency limits, preventing glow-like effects, unnatural depth scattering, or non-physical absorption behaviors; prevent incorrect molecular cohesion effects—fluid must exhibit real-world cohesive behavior, maintaining natural clustering and strand formations dictated by intermolecular forces, avoiding excessive separation, artificial stringing, or non-physical stretching; no incorrect adhesion to surfaces—fluid must interact with its container in a physically accurate manner, following measured contact angles and adhesion coefficients, ensuring no floating, repelling, or artificial detachment behaviors; eliminate incorrect film thickness inconsistencies—fluid film adhering to the glass must maintain consistent natural thickness (~0.03mm), following realistic thinning patterns dictated by surface tension and capillary action, avoiding exaggerated film breakages or artificial beading; no non-physical motion blur effects—motion must be captured with scientifically accurate shutter speeds (1/2000s), preventing stylized motion artifacts, incorrect smear effects, or unrealistic fluid stretching due to improper time sampling; eliminate incorrect temperature-dependent behaviors—fluid must maintain constant viscosity properties as measured at standard conditions (assumed 25°C), avoiding artificial phase transitions, incorrect thickening effects, or non-physical viscosity shifts due to nonexistent temperature variations; prevent excessive film or residue accumulation—any remaining liquid residue on surfaces must adhere to real-world drying and evaporation principles, avoiding artificial thickening, unrealistic pooling, or non-physical layering; no non-scientific reflections or mirroring artifacts—fluid surface reflections must strictly obey optical physics, preventing non-physical mirroring effects, incorrect specular bloom, or artificial contrast enhancements; eliminate incorrect gravitational interactions—fluid motion must remain entirely dictated by Earth’s standard gravitational acceleration (9.81 m/s²), ensuring no anti-gravity behaviors, floating effects, or unrealistic suspension; prevent incorrect polarization effects—light interacting with the fluid must maintain physically accurate polarization properties, ensuring no artificial sheen enhancements, non-physical glare effects, or exaggerated surface reflections; no incorrect textural inconsistencies—fluid must exhibit uniform yet naturally varied texturing as dictated by molecular interactions, ensuring no artificial chunking, unrealistic separation layers, or exaggerated phase distinctions; eliminate non-physical stretching dynamics—fluid motion must maintain accurate elongation-to-detachment ratios based on viscosity, surface tension, and cohesive forces, ensuring no exaggerated stretching, unrealistic strand formations, or artificial cohesion breaks; no incorrect spectral distribution—fluid’s coloration and translucency must adhere to real-world spectral absorption properties, preventing artificial color banding, non-physical spectral shifts, or exaggerated opalescent effects; prevent incorrect shadow behavior—shadows cast by the fluid must obey real-world occlusion physics, ensuring no artificial sharpness, non-physical penumbra effects, or unrealistic shadow densities; eliminate incorrect perspective distortions—camera positioning must ensure scientifically accurate fluid proportions, preventing exaggerated depth effects, artificial field-of-view warping, or non-physical compression artifacts; no non-physical residue formations—liquid remnants on surfaces must evaporate or dry according to real-world material interactions, preventing artificial thickening, non-physical layering, or exaggerated adhesion effects; eliminate non-scientific secondary interactions—fluid must interact solely with its container and gravity, preventing artificial external forces, non-physical magnetism, or speculative fluid behaviors inconsistent with measured physical properties.