The distribution of remote sensing (RS) images can vary significantly due to seasonal changes and lighting conditions, making it difficult for deep learning models to generalize effectively across different RS datasets. This variation leads to a domain gap that hampers model performance when applied to new, unseen data. To tackle this challenge, we introduce DDCI, a novel unsupervised domain adaptation (UDA) framework designed to bridge the domain gap in RS image perception. Our framework consists of two key components, i.e., the adaptation diffusion distillation (ADD) module and the consistent causal intervention (CCI) module. The ADD module addresses the domain gap by aligning the source and target domains. It enhances the representation of the target domain by distilling semantic knowledge from the teacher model of the source domain. This process allows the target domain to benefit from the rich features of the source domain, leading to improved model generalization. The CCI module focuses on removing spurious correlations between domain-agnostic knowledge and domain-specific knowledge. By carefully considering the distinct characteristics of the target domain while preserving the specificity of the source domain, the CCI module ensures that only relevant, causal information is transferred between domains. This prevents overfitting to irrelevant domain-specific features and enhances model robustness. We demonstrate the effectiveness of the DDCI framework on RS scene classification tasks, utilizing four widely recognized RS datasets. Our results show significant performance improvements, underscoring the potential of this approach to boost the adaptability of deep learning models across diverse RS image datasets.