The Guangdong–Hong Kong–Macao Greater Bay Area (GBA) is a critical region for coordinated low-carbon development in China, yet the structure and drivers of intercity carbon-emission spillovers remain poorly understood, especially under alternative development pathways. In addition, the carbon consequences of land-use change have received little attention. To fill these gaps, this study develops a coupled multi-scenario analytical framework to examine the spillover structure and drivers of land-use carbon emissions (LUCE), using observational data from 2000, 2010, and 2020, together with 2030 simulations under natural development (NDS), economic development (EDS), and ecological protection (EPS) scenarios. The results show that the northeastern and southwestern GBA function as relatively stable carbon sinks, whereas the central corridor exhibits persistent emission growth. Intercity LUCE disparities are largest under EDS and shrink markedly under EPS. The LUCE network is highly connected, multilevel, and transmission-efficient, indicating a robust yet centralized spillover system. Shenzhen remains the dominant hub, and the increasing number of intermediary cities further strengthens intercity carbon flows. Driver analysis reveals that historical network linkages are significantly associated with differences in per capita GDP and geographic proximity. Under the 2030 scenarios, however, industrial structure upgrading becomes increasingly influential, highlighting a scenario-dependent shift in the key drivers of intercity spillovers. Overall, this study offers a transferable multi-scenario framework for analyzing regional LUCE spillovers and provides management-relevant evidence for coordinated mitigation, cross-jurisdictional carbon governance, and policy design in the GBA.
Li et al. (Sun,) studied this question.