The surface energy balance from canopy to landscape scales in crop fields plays an essential role in surface-atmosphere interactions. It is strongly influenced by the management strategies and field practices of farmers. These practices also affect the micrometeorological parameters, including energy partitions, soil temperature, and soil moisture. To characterize how different agricultural practices of farmers affect the microenvironment in perennial crop fields, a long-term observation of the radiation budget, energy components, canopy temperature, vapor pressure deficit, soil temperature, and soil water content was conducted in two neighboring tea fields with different management strategies (a conventional operation field and an organic-certified field managed by different farmers) in a hilly terrain area in northern Taiwan. The results showed that the difference in the radiation budget in these two tea fields was minor (only 1% for net radiation). However, the differences in the energy components were more significant (sensible heat was 10% lower and latent heat was 25% higher in the organic-certified field than in the conventional field) due to highly distinct practices in these two fields. Furthermore, the higher diurnal soil temperature (0.45 °C) contributes to the more considerable sensible heat flux in the conventional field. On the other hand, in the organic-certified field, the faster-decreasing rate of (-0.93% d-1) soil water content is consistent with the greater latent heat flux. This finding implies that the organic-certified application could lower the partitioning of sensible heat flux and increase the latent heat flux, thereby reducing the temperature variation and decreasing the vapor pressure deficit. The organic-certified field reduced the surface heating in terms of the long-term energy patterns. The findings of this study also indicate that field practices in the conventional field can increase the sensible heat flux (51.5% at noontime) on short-term time scales, while it is only 9.6% in the organic-certified field. Furthermore, this study offers primary data in the comprehensive understanding of tea field practices, a scientific basis for in-field water conservation, quantitative analysis for modeling from micro to regional scales, and essential information for estimating heat stress index for field workers under different future climate scenarios.