The application of artificial light sources in crop production has been explored for many years; however, due to the relatively large plant size of fruit trees, there has been limited research on the use of artificial light for fruit trees. This study investigates the extension of the flowering period in sugar apple (Annona squamosa cv. Damu) through night break (NB) treatments using different artificial light sources to identify the key wavelengths that promote flowering and to elucidate the underlying transcriptomic mechanisms. Additionally, the study aims to screen artificial light sources that can control the litchi fruit borer (Conopomorpha sinensis Bradley) without compromising litchi (Litchi chinensis Sonn.) fruit quality, leveraging the photophobic behavior of the pest. The research involved selecting appropriate artificial light sources to support fruit tree production according to the specific crop and objective. Over four consecutive years, we investigated the year-round flowering capacity of sugar apple, cherimoya (Annona cherimola cv. Spain), atemoya (Annona × atemoya cv. Gefner), and Bullock’s-heart (Annona reticulata cv. Red). The results indicated that flowering quantity was most strongly correlated with temperature, followed by cumulative temperature, and was less correlated with photoperiod and rainfall. As temperatures gradually decreased in autumn, the number of flowers diminished; however, night break treatment could stimulate flowering. To understand the molecular mechanisms by which night break extends the flowering period of sugar apple, LED (Light-emitting diodes) lights with wavelengths of 450 nm blue light, 660 nm red light, and 740 nm infrared light were used for night break treatments, followed by phenological observations and transcriptome analysis. The results demonstrated that night break treatment with 660 nm red light significantly promoted stem and leaf growth and increased flowering quantity in autumn compared to 450 nm blue light, 740 nm infrared light, and control groups. RNAseq transcriptome analysis revealed that red light night break treatment in autumn did not significantly regulate genes related to cytokinin and photoperiod pathways, but it did promote the expression of genes associated with plant hormones such as auxin, ethylene, gibberellic acid (GA), and abscisic acid (ABA). Some genes that were significantly upregulated by red light night break were involved in reducing oxidative stress, removing damaged proteins, reducing cold injury, and delaying senescence, which may collectively maintain the plant's growth capacity and facilitate successful flowering. During the short-day conditions of winter, sugar apple faces challenges in flowering. Attempts to promote flowering by employing nighttime red light (660 nm) interruption and supplementation with four types of plant growth regulators failed to induce flowering by late December. However, temperature elevation in a greenhouse, increasing daytime and nighttime temperatures by 5.7°C and 1.8°C, respectively, significantly enhanced flowering. By early January, the average number of flowers per bud in the heated greenhouse treatment reached 0.49, significantly higher than the open-field and open-field red-light treatments, which produced 0 and 0.05 flowers per bud, respectively. These results indicate that elevated temperatures have a greater effect on floral development in sugar apple than red light interruption under short-day conditions. Furthermore, to identify the most effective wavelength for controlling the litchi fruit borer, eight different LED light sources were tested, including 400 nm violet light, 460 nm blue light, 520 nm green light, 600 nm yellow light, 660 nm red light, 740 nm infrared light, mixed white light (MixW), and mixed yellow light (MixY). The results showed that the litchi fruit borer is indeed highly sensitive to light, exhibiting reduced activity in illuminated environments and increased activity in darkness. Nighttime application of green light illumination at 520 nm wavelength demonstrated significant suppression of litchi fruit borer activity, reducing moth mobility by 99%, oviposition rate by 93%, and fruit damage rate by 91% compared to the non-illuminated control (CT). While alternative wavelengths of illumination resulted in adverse effects on fruit size and sugar content, the 520 nm green light treatment uniquely maintained optimal litchi fruit quality. Eight different wavelengths of light were applied for whole-plant nighttime illumination of 'Yu Her Pau' litchi prior to flowering, with sampling conducted before flowering and after fruit ripening to investigate changes in plant carbohydrate levels. The results showed that only leaves exposed to nighttime green light at 520 nm exhibited a 5.5% increase in total soluble sugars and a 2.5% reduction in starch content from fruit ripening to post-ripening. These changes were significantly higher than those observed in leaves under no light or other light treatments, which consumed approximately 20–50% of total soluble sugars and starch. Leaves treated with nighttime green light at 520 nm maintained a higher carbohydrate status, which may be a key factor contributing to the improved soluble solid content and sugar-to-acid ratio in the fruit. Field validation studies conducted across three distinct litchi-producing regions—southern, central, and northern Taiwan—substantiated that green light illumination at 520 nm wavelength effectively controls litchi fruit borer, resulting in substantial reduction of fruit damage and associated economic losses. This study successfully screened suitable artificial light sources to support fruit tree production, based on different fruit tree types and objectives.