📝 SummarXiv

Abstract

Humanity is at a critical juncture, marked by rapid technological advances and the pursuit of higher civilization stages on the Kardashev scale. This study explores humanity's potential progression toward Type I and Type II civilizations, defined by planetary and stellar-scale energy utilization. Building on Kardashev's framework, we propose refinements that integrate energy consumption, information processing, construction mass, and population dynamics. Using machine learning, we analyze global energy data to project humanity's energy future, emphasizing exponential growth in renewable and nuclear sources, and incorporate stellar classifications and insolation flux data from the Planetary Habitability Laboratory to establish benchmarks for habitable exoplanets orbiting G, K, and M stars. Our simulations suggest humanity could plausibly reach Type I status by 2271 CE through planetary-scale energy harnessing, advanced computation, and sustainable population management. Under optimistic assumptions of technological progress and resource use, Type II status may emerge between 3200-3500 CE, contingent on breakthroughs in stellar-scale infrastructures such as Dyson swarms or Matrioshka Brains and sustained interplanetary integration. To better track these trajectories, we introduce the Civilization Development Index (CDI), a modified Kardashev metric balancing contributions from energy, information, construction, and population, and demonstrate its robustness under varying assumptions. This study presents an interdisciplinary framework for understanding humanity's long-term trajectory as a multiplanetary civilization, while highlighting both promise and uncertainty. Recognizable existential risks, the so-called "Great Filters", may delay or prevent this pathway, underscoring the urgency of global sustainability and resilience today.