Kiwi Plant Growth Monitoring with Soil and Climatic Conditions in the Semi-Arid Region of Pakistan

: Crop growth and yield are inﬂuenced by the genetic potential of the cultivar, soil, weather, and cultivation practices, i


Introduction
Kiwifruit is a deciduous perennial climber plant that originated from eastern and southern Asia [1].Kiwifruit seeds and peels are an excellent source of beneficial compounds, including carotenoids, terpenoids, and polyphenols, and have anti-inflammatory, antimicrobial, antidiabetic, and antioxidant properties; therefore, this fruit has excellent industrial and pharmaceutical potential [2].Commercial cultivation of kiwifruit started in New Zealand and later spread all over the world [3].This plant is susceptible to extreme temperatures and frost and requires an optimum temperature ranging from 22 °C to 30 °C for better fruit production [4].A total of 70 varieties of kiwifruit are grown worldwide, among which only green and golden kiwifruit are used for commercial purposes [5].In 2020, China had the highest kiwifruit exports, valued at USD 454 million [6].
Approximately 4.41 million metric tons of kiwifruit were produced worldwide in 2020-an increase from the 1.87 million metric tons produced in 2000.In 2020, China and New Zealand produced 2.2 and 0.6 million metric tons, respectively [5].Commercial kiwi cultivars, including Arctic, Abbott, Allison, Bruno, Hayward, Monty, and Tomuri, are significant globally and are imported into Pakistan from China and other producers.The Pakistan Agricultural Research Council has been testing the Hayward type of kiwi plants in the Hazara belt in past few years.The fruit has also been grown in Battagram, Abbottabad, and Havalian [7].
In Pakistan, kiwi is an exotic plant that is not cultivated at a commercial level.However, research is being conducted to determine suitable climatic zones for fruit production.Climate and soil variability are the two most important factors in plant growth and are essential for determining suitable climatic zones for fruit crop production.Soil characteristics and climatic suitability are the primary factors affecting optimal plant growth and fruit quality [8][9][10].
The growth cycle of kiwifruit (including budburst, blooming, and fruit maturity) is affected by environmental and soil conditions [9], which determine the occurrence of phenological phases, i.e., lower temperatures in late autumn and winter cease dormancy.Rainfall affects fruit development, and cooler mean temperatures in the fall seem to boost brix.Accordingly, warmer temperatures accelerate phenological phases from budburst through early fruit development, whereas cooler mean temperatures encourage faster maturation rates in autumn and the end of dormancy in winter.In this way, kiwifruit vine is sensitive to frost and high temperatures and cannot withstand harsh weather [2,11].
Soil nutrient status also affects plant productivity, as excess or deficient N, P, and K can represent potential risks, reducing fruit quality, quantity, and plant growth [12,13].Like soil nutrient status, pH and electric conductivity can also affect kiwifruit crop productivity, as high pH can significantly constrain nutrient availability [14].
As the world population is increasing daily and modern technologies are progressing rapidly, agriculture interventions to monitor crop growth need time to fulfill nutritional requirements.In the current research, GIS and sensor-based approaches were applied to monitor the growth of kiwifruit, considering climate and soil parameters [15,16].It is a well-established practice to employ GIS and RS data for crop monitoring during all stages of activity, i.e., planning, analysis, and output [17].For this purpose, different sensors are used to determine fertilizer requirements, water availability, and pest infestations.Precision agriculture provides explicit real-time estimations through satellite systems.This technology provides accurate field data [18], reduces labor costs and input resources, and boosts agricultural productivity [17,19,20].
It is essential to study the two crucial factors of climate and soil to monitor the growth of kiwifruit.Using proximal sensors, in this study, we intended to evaluate the morphological response of kiwifruit in a semi-arid region, determine the influence of climate and soil variability on kiwifruit, and compare the growth of different kiwifruit varieties in terms of climate and soil suitability.

Study Parameters
Morphological growth parameters include the number of leaves, number of shoots, stem diameter (cm), plant height (cm), inter-nodal distance (cm), and leaf area (cm).To monitor the growth of kiwifruit plants, soil (NPK concentration, pH, electrical conductivity, and organic matter) and climate (temperature, rainfall, and relative humidity) parameters were measured.Soil and climate data were utilized to estimate agroclimatic appropriateness their effect on plant morphological growth.

Monitoring Parameters
Rainfall data were collected from the Pakistan Meteorological Department.Temperature data were collected using a data logger installed at the research locations.Soil parameter results from the lab and proximal sensors were compared.A calibrated scale was used to assess morphological growth from March 2022 to August 2022.

Data Evaluation and Analysis
RCBD analysis was used to evaluate data.By considering the soil and climatic parameters, varieties for a specific location were planned for the next growing season, and the influence of these parameters on morphological growth were also considered.

Results and Discussion
The chemical properties of the soil used for experiments at the four locations are shown in Table 1.This test indicated the nutrient status of soil in which kiwifruit plants were grown.

Study Parameters
Morphological growth parameters include the number of leaves, number of shoots, stem diameter (cm), plant height (cm), inter-nodal distance (cm), and leaf area (cm).To monitor the growth of kiwifruit plants, soil (NPK concentration, pH, electrical conductivity, and organic matter) and climate (temperature, rainfall, and relative humidity) parameters were measured.Soil and climate data were utilized to estimate agroclimatic appropriateness their effect on plant morphological growth.

Monitoring Parameters
Rainfall data were collected from the Pakistan Meteorological Department.Temperature data were collected using a data logger installed at the research locations.Soil parameter results from the lab and proximal sensors were compared.A calibrated scale was used to assess morphological growth from March 2022 to August 2022.

Data Evaluation and Analysis
RCBD analysis was used to evaluate data.By considering the soil and climatic parameters, varieties for a specific location were planned for the next growing season, and the influence of these parameters on morphological growth were also considered.

Results and Discussion
The chemical properties of the soil used for experiments at the four locations are shown in Table 1.This test indicated the nutrient status of soil in which kiwifruit plants were grown.
Temperature data were collected through a data logger, and rainfall data were collected from the Pakistan Meteorological Department, as shown in Table 2.These data, which were observed during a six-month period from March to August, show the average rainfall, minimum temperature, and maximum temperature during each month.As shown in Table 3, different growth patterns were observed among the three varieties at each location.For each variety, stem diameter was almost constant at every location, but the highest stem diameter was recorded (0.85 cm) in the green-fleshed variety at Simly Dam (Pind Begwal).Minute variation in stem diameter is due to variations in soil chemical composition.An increases in stem diameter often followed canopy responses and soil chemical composition, as described in [7].Collected data show a major difference in the plant height of each variety at different locations.This variation is due to weather conditions; rainfall of more than 150 mm in June and July caused water flooding in the root zone, affecting the root zone's oxygen ratio.In terms of plant height, the Hayward kiwi plant reached a height of 126.4 cm in Attock, followed by 125.32 cm in GPU, 125.67 cm in ZTBL, and 75.5 cm in the Simly Dam kiwifruit orchard.The height of the Hayward grafted variety was 128.83 cm at the Simly Dam location.The third variety, green-fleshed, was most heightened at each location as compared to other varieties, with a maximum height of 246.17 cm at the Simly Dam location, followed by 228.17 cm at ZTBL, 219.3 cm at GPU, and 173.35 cm at Attock.Tree growth and development are determined by the plant's height in the local climate [21].The genetic makeup of the variety and the impact of environmental factors lead to diversity in plant height among olive types, which behave differently in various climatic situations.The efficient use of plant nutrients and water at various locations is the cause of the variance in plant height in kiwifruit [12].The climate data at all locations are shown in Figure 2, this climatic data affects kiwifruit morphological growth as shown in Table 3.The data on climatic factors shown in Table 2 indicate that rainfall and temperature variation affected plant growth, as reflected by internodal distance, the number of shoots, and the number of leaves.The internodal distance reached a maximum value (8.62 cm) in the Hayward grafted variety at ZTBL and a minimum value (4.82 cm) in the Hayward variety at Simly Dam.Internodal distance determines the morphology of the canopy and the porosity of the branches, which favors light and air permeability [22].All vegetative tissues of plants share metabolites, so their effects on intermodal tissues vary [22,23].The maximum number of shoots was 11.7 in the Hayward grafted variety, and the maximum number of leaves was 82.7 in the green-fleshed variety.When the internode size of native spearmint tissues is increased, the number of shoots decreases [24].The percentage of disease caused by genera Sphingobium and Phytophthora was 7.133% in the Hayward grafted variety and 2.93% in the Hayward variety at Attock kiwi orchard.These pathogens are responsible for the loss of kiwifruit vine [25].In June and July, temperatures above 40 °C adversely affect kiwifruit plants, making them more vulnerable to sudden and extreme weather events, such as very high, quickly rising temperatures and rains, which occur more frequently in the summer and cause intense and abrupt water stress [26].Heat damage percentage was also recorded as highest in the Hayward grafted and lowest in the Hayward and green-fleshed varieties at Simly Dam.These data show that green-fleshed and Hayward varieties are the most suited to the local climate, and the The percentage of disease caused by genera Sphingobium and Phytophthora was 7.133% in the Hayward grafted variety and 2.93% in the Hayward variety at Attock kiwi orchard.These pathogens are responsible for the loss of kiwifruit vine [25].In June and July, temperatures above 40 • C adversely affect kiwifruit plants, making them more vulnerable to sudden and extreme weather events, such as very high, quickly rising temperatures and rains, which occur more frequently in the summer and cause intense and abrupt water stress [26].Heat damage percentage was also recorded as highest in the Hayward grafted and lowest in the Hayward and green-fleshed varieties at Simly Dam.These data show that green-fleshed and Hayward varieties are the most suited to the local climate, and the Hayward grafted variety is the most susceptible to diseases and heat damage (Table 3), which can have long-term effects on the growth of the kiwifruit plant.The physiological responses of the kiwifruit vine to environmental stress can indicate for opportunities that can be overcome through breeding and, cultural techniques.Spatial variation in leaf arrangement and temporal variation in irradiance conditions lead to highly dynamic irradiance of individual leaves within the canopy [26].Overall, the green-fleshed kiwi variety performed better than the Hayward and Hayward grafted varieties in terms of morphological parameters at all research locations.The climatic conditions at Simly Dam are most suitable for kiwi plants.Because kiwi plants like humidity, they are widely adopted in humid areas of China and New Zealand [27].Rainfall of more than 150 mm causes flooding in the root zoon of kiwi plant, and the physiology of plants and the anatomical characteristics of the xylem point to a potential involvement of weather.This role might be highly harmful to kiwifruit, which is known as an anisohydric plant [28].

Conclusions
Identifying new agro-climatic zones in Pakistan's semi-arid regions for kiwifruit farming is possible.This plant is being introduced in Pakistan to attain significant benefits.For this purpose, a number of kiwifruit varieties were grown in different areas to determine suitable soil and climate conditions for growth and commercial production.The morphological characteristics of three varieties were recorded at four locations, and the effects of climate and soil were observed.Crop simulation models (CSMs) are now being applied in GIS framework to simulate and monitor crop growth with remote sensing inputs, allowing for sensitive evaluation of seasonal weather conditions, local variability, and crop management.In this study, we found that kiwi is very susceptible to warm weather, is sensitive to frost and high temperatures, and cannot bear harsh weather; specifically, temperatures above 40 • C cause mortality in kiwifruit plants.Morphological results show that green-fleshed and Hayward varieties performed slightly better than the Hayward grafted variety, which was found to be the most susceptible to diseases and heat damage, which can have long-term effects on the fruiting of kiwi plants.

Figure 2 .
Figure 2. Climatic factors recorded at different locations.

Figure 2 .
Figure 2. Climatic factors recorded at different locations.

Table 1 .
Average data of chemical properties and nutrient status of soil collected through proximate soil sensors and soil fertility tests.

Table 2 .
Climatic factors recorded at different locations.