Background

Peach (Prunus persica L.) is a member of the Rosaceae family and is considered the second most important stone fruit in Pakistan (GOP 2015). In addition to carbohydrates, organic acids, pigments, volatiles, nutrient minerals, and trace amounts of proteins and lipids, a peach fruit contains an immense diversity of biologically bioactive compounds such as vitamin C, carotenoids, flavonoids, and phenols that act as antioxidants, making the peach fruit very attractive to consumers for nutritional and health issues (FAOSTAT 2016). In Pakistan, the peach cultivation area is 13.819 thousand hectares, and the total annual production is 70.75 thousand tons. The most commonly used peach cultivars in Pakistan are Early Grand, Florida King, Shireen, Shah Pasand, Golden Early, 6th A, 8th A, etc. In KP, peaches occupy 19% of the total fruit land. In Malakand Division, the average production of peach is 12.53 tons/ha including Swat (4.2 thousand hectares) and Mardan (0.38 thousand hectares) with a production of 43.94 and 3.64 thousand tons, respectively (FAOSTAT 2016). Peach fruit is considered to be one of the most perishable in nature and is susceptible to many diseases (scab, anthracnose, bacterial spot, brown rot, etc.), insects, and pests, and at various stages of growth (Hartman 2007). Peach fruit is also susceptible to pre-harvest contamination and physical damage, leading to problems such as surface discoloration etc. (Crisosto et al. 2000). Due to its perishable nature, it does not maintain its quality after harvest for an extended period. In order to increase or enhance the shelf life of peach to meet consumer’s demand, a number of techniques such as fumigation and pre-harvest spraying of nutrients are used to overcome the post-harvest losses of fruit commodities (Neo and Saikia 2010). During marketing or shipping, peach fruits suffer from high susceptibility to flesh softening that makes it more sensitive for pathogen attack and deterioration leading to a shorter handling period and limited marketability. Therefore, post-harvest practices for maintaining fruit characters of improved marketing capability and extended shelf life are seriously considered. It would be achieved by reducing the quality losses due to the physiological and biochemical changes that fruits undergo after harvesting. Physiological weight loss of about 20–30% (Ullah et al. 2018) is determined by both water loss, due to transpiration of the living fruit tissues, and by dry matter loss due to respiration. Also, a wide range of post-harvest fruit losses is caused by several post-harvest diseases. In this regard, efforts are being made to find effective and safe techniques to control fruit post-harvest diseases, reduce quality losses, and increase the production and quality of fruits, as an alternative to the use of synthetic fungicides (Mohamed and Akladious 2017; Mohamed et al. 2018).

Jasmonates, essential oils, benzothiadiazole, and trichoderma are examples of natural compounds that help to minimize plant infections (Aly et al. 2012, 2013, 2017; Abd El-Rahman and Mohamed 2014; Ashry et al. 2018). In addition, the use of natural compounds such as chitosan is one of the most fascinating and satisfactory methods.

Chitosan is a naturally occurring compound that is commercially produced from seafood shells. It has been used to induce the defense system for both pre- and post-harvest fruits and vegetables against fungi, bacteria, viruses, and other abiotic stresses. In addition to that, chitosan effectively improves the physiological properties of plants and also enhances the shelf life of post-harvest products. In addition, the treatment of chitosan regulates several genes in plants, particularly the activation of plant defense signaling pathways (Sofy et al. 2020a, 2020b). Chitosan is a less toxic and economical compound that is biodegradable and environmentally friendly with a variety of applications in agriculture (Basit et al. 2020) and is edible and safe for both animals and plants. Chitosan bears a negative charge due to the amino and hydroxyl groups responsible for its distinctive physiological, biological, and coating properties on the surface of fruit and vegetables which are positively charged due to the presence of organic acids. The use of chitosan helps to induce drought resistance and improves the efficiency of water use (Hassnain et al. 2020). Due to its biological activities and mode of action, it is considered as an antimicrobial compound and can be used against microorganisms and as an inducer of the plant defense mechanisms (Sofy et al. 2020a, 2020b). It also helps stimulate plant immune systems, plant growth, and plant protection against various insects, pests, diseases, and microorganisms (Sofy et al. 2020a, 2020b). chitosan effects on fruit physiology and agronomic traits have been highly studied using different concentrations of chitosan in a variety of fruits. In line with this, foliar spraying of 5 mL L−1 chitosan over mango trees improved the number of fruit tree−1, the weight, the size of the fruit, and the vegetative growth (Zagzog et al. 2017). However, information regarding the use and effect of exogenous application of chitosan at different times on the quality production of peach fruit has not yet been systematically documented. Therefore, the present is planned to study the effects of chitosan and its time of application alone and in combination on the yield-related characteristics and biochemical attributes of peach fruit.

Methods

Experimental site and plant material

This research was conducted at Horticulture Research Farm, Agriculture Peshawar University in 2018 (longitude 710 o50, latitude 340 o01), Peshawar, Pakistan. The research farm is located at 34.01° N latitude, 71.35° E longitude at an altitude of 350 m above sea level in Peshawar valley with a sub-tropical climate (Ahmad et al. 2019). Peshawar is located approximately 1600 km north of the Indian Ocean. The research farm is irrigated by the Warsak canal from river Kabul (Alam et al. 2020). Both the summer and winter weathers are extreme (Basit et al. 2019), characterized by severe winter and hot prolonged summer where the average minimum temperature during winter is 50 °C while during summer, the average maximum temperature reaches up to 45 °C. The wettest month (with the highest rainfall) is March (78 mm) and driest month (with the lowest rainfall) is June (7 mm) approximately. Peach orchard already established at Horticultural Research Farm, Peshawar University of Agriculture, was used for the experiment. Peach cv. Early Grand of age approximately 10 years were selected to be pruned in the months of November to December on a regular basis to avoid alternating bearings. Peach trees were planted in a square system with a plant-to-plant and row-to-row distance of 6 m. Cultural practices such as weeding, irrigation, fertilizer application, and pruning have been carried out on a regular basis. Uniform-sized disease-free trees were selected for the experiment.

Experimental design and treatment combinations

The experiment was carried out using randomized complete block design (RCBD) with split plot arrangement having two factors which were replicated three times. Peach cv. Early Grand was sprayed with different concentrations of chitosan (0, 0.50, 0.75, and 1.0%) at three different timings (30, 50, and 70 days after full bloom). The number of treatments per replication is 12, while the total number of treatments is 36. Three trees were assigned for each experimental treatment, so the total number of trees used for this experiment was 108. Growth conditions are the same. The concentration of chitosan is selected according to the previous studies (Hong et al. 2016). Peach fruit cv Early Grand was harvested at the edible maturity stage with golden yellow color. The fruits had been cleaned and washed with distilled water. Fruit sorting was done by removing the disease-affected, injured, and damaged fruit. The remaining fruit was selected for physiochemical analysis.

Procedure for preparation and foliar spray of chitosan solution

For the preparation of different concentrations (0.5, 0.75, and 1.0%) of chitosan solutions, 0.5, 0.75, and 1.0 g of chitosan (C18H35N3O13) were then dissolved in 100-mL distilled water. Since chitosan cannot be dissolved easily in water, a few drops of diluted acids in the form of citric acid have been added to the solution for the uniform dissolution of chitosan. Each solution was stirred for 1 h on a magnetic stirrer to completely dissolve chitosan particles in the water (Sandeep et al. 2013). Each peach required 4 L of water, so the chitosan solution was prepared in a 4-L solution in each treatment. Three trees are sprayed with chitosan.

Yield-contributing traits of peach fruit

Three fruits were selected randomly from each treatment to determine the weight of the fruit (g). For each treatment volume, the water displacement method (WDM) was used. A simple graduated cylinder of 1 L was used containing water. Randomly selected fruits were placed into it, and the difference between the initial and final readings was noted. The final harvested fruits (yield tree−1) of all randomly selected trees for each treatment in each replication were measured in kilograms (kg) with the aid of balancing, and then their average was calculated. Percent incidence of disease was estimated using the following formula:

$$ \mathrm{Disease}\ \mathrm{incidence}\ \left(\%\right)=\frac{\mathrm{No}.\mathrm{of}\ \mathrm{infected}\ \mathrm{fruits}\ \mathrm{per}\ \mathrm{treatment}}{\mathrm{Total}\ \mathrm{no}.\mathrm{of}\ \mathrm{fruits}\ \mathrm{per}\ \mathrm{treatment}}\times 100 $$

Physiological attributes of peach

The firmness of peach fruit was measured with the penetrometer (Model-Wagner FT-327, fruit firmness analyzer) with a capacity of 28 lb (Basit et al. 2020). For this purpose, the instrument’s probe was inserted into the pulp of peach fruit, and reading was noted. The firmness of the three fruits was determined from each treatment, and then their average was calculated. The refractometer was used to analyze the total soluble solids (0Brix) in peach fruit. The total soluble solids and titrable acidity were calculated using the AOAC (2000). For this purpose, few drops of juice were placed on the prism and slide, and the reading was then recorded. For titratable acidity, the juice was extracted from the randomly selected peach fruit and used to extent titratable acidity and then was expressed in percent. Burette reading was noted, and the percentage of titrable acidity was observed with the help of the given formula.

$$ \mathrm{Titratable}\ \mathrm{Acidity}\ \left(\%\right)=\frac{N\times T\times F\times 100}{D\times S}\times 100 $$

where N is the normality of NaOH (0.1), T is the titration reading, F is the constant acid factor (0.067) (citric acid), D is the volume (mL) of the sample taken for dilution (10 mL), and S is the volume (mL) of the diluted sample taken for titration (10 mL).

The “dye method” was used (Ranganna 1977) for the purpose of ascorbic acid (mg 100 g−1) content. Reading for ascorbic acid content was taken by using the following described formula.

$$ \mathrm{Ascorbic}\ \mathrm{Acid}\ \mathrm{contents}=\frac{T\times F\times 100}{D\times S}\times 100 $$

whereas T is the volume (mL) of the dye solution used from the burette, F is the dye factor (0.11), D is the fruit juice (g) taken for dilution (10 mL), and S is the volume (mL) of the diluted sample taken for titration (10 mL).

The pH of the fruit was determined by using an electronic pH-meter by using the procedure as suggested by Sajid et al. (2019). For this purpose, the instrument probe (pH-meter) was inserted into the extracted juice from peach, and pH value was noted after the instrument was standardized

Results

Yield contributing traits of peach fruit

The effect of the concentration of chitosan and its time of application on the physical attribute of peach fruit was found to be significant (p ≤ 0.05) while their interaction was found non-significant (Table 1 and Fig. 1). Comparing the mean concentration of chitosan, it was observed that treatment with 1.0% of chitosan caused a significant increase in fruit weight (91.11 g), fruit volume (101.33 cm3), and fruit yield (92.89 kg) tree−1, but caused a significant decrease in the number of fruit (11.78) kg−1 and disease incidence (2.11%) of peach compared to control plants (0% chitosan) which showed the minimum fruit weight (61.56 g), volume (75.11 cm3), and yield (68.78 kg) tree−1 and maximum number of fruit (17.78) kg−1 and disease incidence (10.33%) of peach (Fig. 3a). Regarding the time of application, peach plants treated with chitosan after 50 days of full bloom achieved the highest fruit weight (81.25 g), fruit volume (90.33 cm3), fruit yield (86.58 kg) tree−1, and minimum fruit (14.08) kg−1 and disease incidence (4.82%) of peach. On the other side, the lowest value of fruit volume (87.17 cm3) and yield (77.25 kg) tree−1 of peach was recorded in fruits sprayed with chitosan after 70 days of full bloom. The maximum number of fruits (90.33) and disease incidence (5.52%) was observed in plants sprayed with chitosan after 50 days of full bloom (Fig. 4a).

Table 1 Mean square value of various attributes of peach influenced by chitosan concentration and its time of application
Fig. 1
figure 1

Fruit weight, fruit volume, number of fruits, fruit yield kg−1, and disease incidence of peach as influenced by different chitosan concentrations and application time. The vertical bars represent standard error. Different letters next to the mean values in each bar indicate a significant difference (LSD p ≤ 0.05)

Biochemical attributes of peach fruit

It is clear from Table 1 and Fig. 2 that the different concentrations of chitosan and its time of application significantly affected the biochemical attributes of peach fruit, whereas their interaction was found to be insignificant. The chitosan concentration ranged from 0 to 1.0%, fruit firmness ranged from 1.07 to 2.50 kg/cm2, total soluble solid (9.98 to 7.33 0Brix), fruit juice pH (5.40 to 4.69), titrable acidity (0.19 to 0.64%), ascorbic acid (0.28 to 0.71 mg 100 g−1) (Fig. 3b). Comparing the means of application time of chitosan, treatment with chitosan after 50 days of full bloom caused a significant increase in the fruit firmness (1.93 kg/cm2), total soluble solids (8.97 0Brix), and titrated acidity (0.45%) and a significant decrease in ascorbic acid contents (0.48 mg100 g−1) of peach, whereas plants treated with chitosan after 70 days of full bloom showed a significant decrease in fruit firmness (1.74 kg/cm2), titrated acidity (0.41%), and ascorbic acid contents (0.48 mg 100g−1). In addition, the minimum total soluble solids (8.70 0Brix) and fruit juice pH (4.97) of peach were recorded in fruit plants treated with chitosan after 50 days of full bloom (Fig. 4b).

Fig. 2
figure 2

Fruit firmness, total soluble solid, fruit juice pH, titratable acidity, and ascorbic acid of peach as influenced by different chitosan concentrations and application time. The vertical bars represent standard error. Different letters next to the mean values in each bar indicate a significant difference (LSD p ≤ 0.05)

Fig. 3
figure 3

Various attributes of peach as influenced by different chitosan concentrations. The vertical bars represent standard error. Different letters next to the mean values in each bar indicate a significant difference (LSD p ≤ 0.05)

Fig. 4
figure 4

Various attributes of peach as influenced by the application time of chitosan. The vertical bars represent standard error. Different letters next to the mean values in each bar indicate a significant difference (LSD p ≤ 0.05)

Discussion

The improvement in fruit weight may be due to the increase in the metabolic activity of some important enzymes (protease, nitrate reductase, and glutamine synthetase) and increased photosynthesis which enhanced plant growth and development (Mondal et al. 2012). Besides this, chitosan induces the synthesis of plant hormones such as gibberellins, which are responsible for the development of ovaries into fruits. It also increases growth through some signaling pathways related to the biosynthesis of auxin (El-Bassiony et al. 2014). In addition, it has also been accredited to intensification in the availability and uptake of water and essential nutrients by adjusting osmotic pressure cells and reducing the accumulation of harmful free radicals by enhancing antioxidants and enzymatic activities (Guan et al. 2009; El-Beltagi et al. 2020). As a result, the use of chitosan increases photosynthetic pigment by increasing photosynthesis (El-Tantawy 2009) and the common plant growth compared to control plants (Abu-Muriefah 2013). These results are in accordance with those found by El-Miniawy et al. (2013) on cucumber that time of application of chitosan significantly affected the plant growth parameters. Applying chitosan after 50 days of full fruit shows a maximum increase in fruit weight, as stone fruit is currently undergoing cell elongation. Applying chitosan at the cell elongation stage of stone fruit enhances essential enzyme activity and provides more nutrients for the growth and development of fruit. Mahmood et al. (2017) reported that the foliar application of 0.5% chitosan (at 7-day intervals, starting from 2 weeks after transplantation) increases the fruit weight, the diameter, and the yield of bell pepper (Capsicum annum L.). Usually, fruit volume and weight are directly correlated with each other where an increase in volume may result in an increase in weight. The increase in fruit volume may be due to the high content of starch and plant hormones, especially cytokines, which play a vital role in enhancing cell division and expansion, ultimately leading to increased volume (Uthairatanakij et al. 2007). Chitosan may induce gibberellin in the ovary of the carpel, which plays a key role in the cell elongation and therefore causes an increase in size and volume (Mondal et al. 2012). It may also be attributed to an increase in the availability and uptake of water and important nutrients from the adjusting cells and xylem tissues due to osmotic pressure. This uptake of water causes turgidity of cells and dropping the accumulation of harmful free radicals by increasing antioxidants and enzyme activities (Guan et al. 2009). Applying chitosan after 50 days of full bloom showed a maximum increase in fruit weight and volume because at this time, stone fruit undergoes through the cell elongation stage. During this stage, cells absorb water from adjacent cells or xylem, which can cause turgidity of the cells and elongation of the fruit cells, activation of some essential enzymes and supply of more nutrients for the growth and development of fruit. Fruit weight and fruit volume are directly related to each other but show inverse relation with that of the number of fruits kg−1. Increased fruit weight causes a decrease in the number of fruits kg−1 (Gornik et al. 2008) and therefore inversely causes a decrease in the number of fruits kg−1. In case of control, the fruit weight and volume were smaller, which is why the number of fruit kg−1 was high. The foliar application of chitosan may cause an increase in the number of fruit plant−1, which ultimately leads to an increase in yield and productivity. This increase of yield in treated plants compared to untreated plants is due to the increased plant height, fruit-bearing nodes, chlorophyll contents, reduced disease incidence (Bautista et al. 2006), etc. Foliar spray of chitosan at early growth stages increases plant growth and development therefore increases seed yield in rice and soybean (Islam et al. 2016). Pre- and post-harvest foliar application of chitosan may increase fruit yield and productivity in both in vivo and in vitro growing plants. The significant effect of chitosan on yield and its components may be due to the simulative effect of chitosan on physiological processes and enhanced transference of nitrogen in the functional leaves that improve vegetative growth and development (Gornik et al. 2008). Massimo and Cerana (2018) reported that two applications of chitosan (250–500 ppm) at 7-day intervals, from pre-flowering to post-flowering stage, have resulted in 56% higher yields of fruit in strawberry cultivated plants compared to control plants. Chitosan is a natural polycation compound that reduces fungal spoilage and decay of fruit by its direct antifungal activity and by inducing host resistance to pathogens Liu et al. (2007). In the earlier comparable experiments, the application of chitosan coatings has shown benefits from reduced decay in peach, strawberry, and litchi (Chailoo and Asghari 2011; Sun et al. 2010). Chitosan induces chitinase enzymes that accelerated the hydrolysis of chitin, which is an important component of fungi cell walls, thus avoiding the growth of fungi on the fruit (Han et al. 2004). The application of chitosan stimulates the formation of structural defense barriers as it induces cellulose synthesis, thickening of host cell walls, formation of papillae, and plugging of some intercellular spaces with fiber material, probably impregnated with phenolic-like antifungal compounds (Sofy et al. 2020a).

Firmness is one of the most important characteristics that consumers are most interested in, and therefore, economically important in overall products is very high. Pre-harvest foliar application of chitosan may cause maintenance of fruit firmness because of the formation of a chitosan film on the fruit surface. Chitosan film acts as an oxygen barrier that slows down the metabolic activity and oxidative breakdown of glucose that leads to the ripening process (Reddy 2000). Reduction in cell wall degradation is due to chitosan coating, which in turn maintains cell turgidity and protects the structure of the cell wall. Fruit softening may be caused either by the hydrolysis of starch or by the breakdown of insoluble proto-pectins into soluble pectin or by increased membrane penetration due to cellular breakdown (Brummell and Harpster 2001). In the ripening process, the loss of pectic substances in the middle lamellae of the cell wall is the key step leading to the loss of cell integrity or firmness (Mercado et al. 2011). Higher fruit firmness during the period of the storage period of peach fruit due to pre-harvest chitosan treatments is correlated with those discovered in previous experimental studies on peach fruit (Li and Yu 2000). The total soluble solid content of a fruit is considered to be one of the main qualitative features associated with other qualitative characteristics such as firmness, composition, pH, texture, and taste of many fruits (Peck et al. 2006; Weibel et al. 2004). Increased percentages of total soluble solids throughout the storage period are likely due to the increased enzymatic activities which are responsible for the hydrolysis conversion of starch and insoluble sugars into soluble sugars. This conversion may result in the degeneration in the amount of carbohydrates, pectin, and partial hydrolysis of protein and decomposition of glycosides into subunits during respiration (Aranzana et al. 2011). Reduction of total soluble solids with the concentration of negatively charged polysaccharide to congeal adjourned solids increases the bonding capacity of chitosan which makes the bond with sugar having positive charge (Al-Manhel and Niamah 2012). In chitosan-coated mangoes and bananas (Kittur et al. 2001), lower total soluble solid (TSS) was found as compared to control fruits while higher values were noted for treated peaches (Srinivasa et al. 2002). The TSS of chitosan-treated apricots and papayas was the same compared to the untreated fruits. The increase in the respiration rate of untreated fruits compared to treated fruits is due to the production of ethylene, which increases the consumption of organic acids and ultimately reduces the acidity of titrable fruits (Ghasemnezhad et al. 2010). Increased acidity of chitosan-coated fruits may also be due to a decrease in metabolic alteration of organic acids into CO2 and H2O. This metabolic conversion may result in a reduction in the respiration rate, therefore maintaining a higher concentration of organic acids. This statement is consistent with the findings of Ali et al. (2011) who reported that titratable acidity of chitosan-coated papaya and apricot increased with time than uncoated fruits kept under cold storage. Faster reductions in titratable acidity may lead to a faster senescence (Hong et al. 2016). The results reported in this study are in agreement with those found by Elham et al. (2013) on peach and Goutam et al. (2010) on guava. Gayed et al. (2017) reported that chitosan, combined with calcium chloride, reduced the early swelling of peach trees, maintained freshness and firmness of fruits, and decreased the weight loss percentage. In nectarine, chitosan improved the soluble solid content and also helped maintained the post-harvest firmness of the fruit (Giacalone and Chiabrando 2013). Ascorbic acid has a direct relationship to acidity while it is inverse to pH level. The level of ascorbic acid (vitamin C) tends to decrease as the fruit ripens due to a direct action of ascorbic acid oxidase enzyme (ascorbinase), oxidation, and subsequent change of ascorbic acid into 2,3-dicetogulonicacid (Chitarra 2005). Han et al. (2004) reported delayed degradation of vitamin C in chitosan-based luffa fruits (Luffa cylindrical L.). The decrease in fruit ascorbic acid, treated with chitosan, may be due to the low oxygen permeability of the chitosan coating film around the fruit surface. Low passage of oxygen level has led to a reduction in the activity of the ascorbinase which prevents oxidation of ascorbic acid (Dang et al. 2010). Like the present experiment, a high level of ascorbic acid was found consequently to chitosan application in strawberry (Wang and Gao 2013). Post-harvest chitosan coating of mango showed a reduction in the percentage of rotten tissue, increased ascorbic acid content and shelf life, and maintained freshness (Abd-Alla and Wafaa 2010).

In addition, post-harvest mango coating with edible chitosan showed a reduction in the percentage of rotten tissue, increased ascorbic acid content, increased shelf life, and continued freshness (Abbasi et al. 2009). Fruit juice pH is one of the most important qualitative flavor parameters. It has an indirect relationship with titratable acidity and ascorbic acid. The increase in titratable acidity of fruits causes a decrease in pH of the same fruit. Biochemical conditions of the fruit are changed using chitosan, which reduces the rate of respiration and metabolic processes by creating a barrier to oxygen permittivity, a real reason for pH change (Shaik et al. 2017). Findings of Imran et al. (2000) also support our current results which declare that prevention of pectin hydrolysis and development of free acids result in a reduction in pH. In addition, Kelebek et al. (2008) reported that during the storage period, an increase in the rate of respiration caused an increase in various catabolic processes which led to the breaking down of organic acids and ultimately led to an increase of fruit pH. Also, Einbu and Varum (2003) observed that reduction in the buffering properties of the juice showed an increase in juice pH and decrease in the acidity of fruit throughout the storage time. These results are consistent with those of Sun et al. (2010) which have shown that the reduction in acidity during storage causes fruit senescence. The findings of Reddy (2000) revealed that chitosan over the surface of fruit acts as a barrier for the uptake of oxygen, which slows down the metabolic activity and consequently the ripening process. Coating with edible chitosan maintained fruit firmness, surface color, juice content, and other quality attributes (El Guilli et al. 2016). Ripening and fruit senescence in peach are a major issue affecting their economic value. However, treatment with chitosan resulted in a significant increase in antioxidant enzyme activity, senescence arrest, delayed fruit ripeness, and maintenance of shape and color (Ma et al. 2013).

Conclusions

From this experiment, it is concluded that pre-harvest foliar application of chitosan at 1.0% improves fruit weight, fruit volume, yield tree−1, fruit firmness, titrable acidity, ascorbic acid content, minimum number of kg−1 seed, total soluble solids, and peach fruit pH. In fruit plants sprayed with chitosan after 50 days of full bloom, the highest fruit weight, fruit volume, yield tree−1, fruit firmness, titrable acidity, and ascorbic acid content and the minimum number of fruit kg−1, total soluble solids, and pH of peach fruit were recorded in fruit plants sprayed with chitosan compared with other application time. The foliar application of chitosan at 1.0% significantly after 50 days of full bloom increased all peach yield and quality attributes and therefore recommended for Peshawar valley farmers for quality peach fruit production.