The experimental cultivar of strawberry was Fragaria ananassa. After 5-6 leaves of strawberry were developed, the experiments were proceeded. Experiments were conducted in three replicates, three plants were planted for every replicate. The first factor was addition of salt including 0 (S₀) and 50 mM (S₅₀) of NaCl. Another factor was the addition of humic acid including 0 (HA₀), 150 mM (HA₅₀) and 300 mM (HA₃₀₀). It was designed for six treatments: S₀HA₀, S₀HA₁₅₀, S₀HA_300, S₅₀HA₀, S₅₀HA₁₅₀ and S₅₀HA₃₀₀. Strawberries were cleaned with ultrasonicator before being planted in a glass container (diameter is 10 cm and height is 15 cm) with a hydroponic solution (Hoagland and Arnon 1938) in triplicate. The pH was maintained at 6.5-7.0. Strawberries were planted in the container that was aerated by air pump, and then planted in growth chamber. The conditions of growth chamber was regulated at 27 °C in the day time (14 h, RH 65%) and 23 °C in the night-time (10 h, RH 85%). Hydroponic solution in the container was renewed every week. The experiments were proceeded for three weeks.

The contents of K⁺ and Na⁺ were estimated as below briefly. At first, plants were grinded, and then 2 g sample was digested by sulfuric acid in 350 °C. After diluting, K⁺ and Na⁺ were analyzed by inductively coupled plasma spectroscopy (ICP-OES, Horiba JY-2000) for K⁺ and Na⁺.

The completely randomized design was used for the experiment with three replicates. The factors were 0 and 50 mM salt concentrations, and 0, 150 and 300 ppm humic acid concentrations. Statistical analysis was performed using the SPSS software. The mean value (P < 0.05) was used for Duncan’s multiple range test.

The effect of the treatments of salt and humic acid concentrations on Na+, K+ and K+/Na+ in root and leaf of strawberry are presented in Table 1. After exposing to NaCl stress, concentrations of Na⁺ in the leaf and root of strawberry were increased (Table 1). However, the addition of humic acid in the hydroponic solution containing NaCl reduced the Na⁺ concentration in root and leaf. In the treatment of no-salt, the Na⁺ and K⁺ contents in root and leaf of strawberry were slightly increased after the concentration of humic acid was increased. However, in the treatments of 50 ppm NaCl, concentrations of Na⁺ were reduced while that of K⁺ were increased in root and leaf after the concentration of humic was increased. The results showed that K⁺/Na⁺ ratio was significantly reduced in both leaf and root after exposure of strawberries to salinity. However, the K⁺/Na⁺ ratio was increased when humic acid was at 300 mg L^-1.

This experiment showed that high salinity decreases K⁺ content of root and leaf in strawberries. However, the addition of HA increases K⁺ content. After treating with salt, Na⁺ in root and in leaf are both high, especially in the leaf. Na+ is absorbed by the roots and moved up by the transpiration of water from leaves (Watson et al. 2001). Saied et al. (2005) also observed that Na+ content increased in strawberry under high salinity. The results of this experiment showed that salt treatment increased Na+ concentration and decreased K⁺ concentration in the root and leaf of strawberry. In root, salinity can increase Na⁺ adsorptive rate and suppress K⁺ uptake (Assaha et al. 2017; Sobahan et al. 2009; Wang et al. 2013). These results coincided with the research of Saidimoradi et al. (2019). They concluded that the Na⁺ was increased and K⁺ was decreased in the roots and leaves of two strawberry cultivars. When strawberries were planted at high salinity soil, the concentration of K⁺ was much lower. However, the application of potassium will enhance the K⁺ concentration of strawberries. Supplementary potassium can improve plant growth under highly saline conditions (Kaya et al. 2015). Na⁺ concentration in tissues of Oso Grande and Camarosa strawberry cultivars was increased in the high NaCl treatment. Leaf concentrations of Ca⁺, K⁺, and N⁺ were not significantly reduced in plants grown at high NaCl concentrations than in the no-sodium stressed treatment (Kaya et al. 2003). However, Al-Shorafa et al. (2014) demonstrated that K+ content in root and shoot of strawberry decreased dramatically with increasing salinity stress in Camarosa and Albino strawberry cultivars. These distinct results may be due to the physiological difference between cultivars. Under salinity stress, Na⁺ may influence the cell membrane stability of root and change the selectivity of ions (Jamil et al. 2012). Addition of humic acid (HA) has a negative correlation value to soil exchangeable Na and SAR (sodium adsorptive ratio) and hence reduce the absorption by plants (Mindari et al. 2019). In this experiment, supple-mentation of humic acid in the hydroponic solution containing high salt stress caused lower concentration of Na⁺ in the leaf and root of strawberry. HA can reduce soil Na⁺ due to exchange with K⁺. The main function is that humic acid contains abundant COOH groups (carboxylic acid) in metal ions bonding (Martyniuk and Więckowska 2003). Under application of HA, Na⁺ adsorbed by humic complex is increased, and the availability of potassium for providing to root increases (Kumar et al. 2013). By the mediation of HA, result in the absorption of K⁺ was increased and Na⁺ was reduced, and led to K⁺/Na⁺ ratio in the root and leaf were increased (Table 1). Khaled and Fawy (2011) found that the application of HA under salinity stress will increase K⁺ uptake of corn and Na⁺ content and Na⁺/K⁺ ratio were both reduced.