Influence of Climatic Factors on the Phenology of Chokeberry Cultivars Planted in the Pedoclimatic Conditions of Southern Romania

Abstract

This paper aimed to study the adaptation of a crop to the specific climatic conditions of southern Romania, Pitești-Mărăcineni, Romania, in terms of the phenology of two chokeberry (Aronia melanocarpa) cultivars (‘Melrom’ and ‘Nero’). The BBCH (Biologische Bundesantalt, Bundessortenamt and Chemische Industrie) scale was used for phenological observations. The recorded data were statistically processed, calculating the average onset time and duration of fruiting phenophases and dormancy duration, average air temperatures, total solar radiation, and the cold and heat accumulation. Bud swelling was registered between 28 January and 8 February, budburst occurred starting on 3 March, while flowering began in stages, between 15 April and 1 May, and was completed between 27 April and 14 May. During the 154 days of 53–87 BBCH, the average air temperature, 16.1 °C, ranged between the extremes of −6.1 and 36.8 °C. The onset data and spring–summer phenophases were mainly related to the minimum air-temperature oscillations. The flowering timing shortened as the maximum temperature and total solar radiation increased. The relation between the environmental factors and the flowering strategy indicates the A. melanocarpa as a species adapted to the temperate continental climate of southern Romania.

1. Introduction

Climate change’s impact on plants is an ever-growing research challenge that scientists in plant biology and agricultural sciences need to address in this period. In the present study, the authors selected chokeberry as the object of study. Chokeberry (Aronia melanocarpa) is a deciduous shrub native to eastern North America and Canada, whose cultivation spread to Europe after the 19th century [1,2], due mainly to the interest in its antioxidant compounds [3]. Chokeberry is a deciduous shrub belonging to the Rosaceae family. The fruit is edible, although very astringent, and is produced from five to six bunches of flowers that bloom in late spring. Chokeberry has proven to be a species with a superior ability to adapt to pedoclimatic conditions (such as wet habitats, but also dunes, rocky slopes and steep cliffs, and on over-grown or bare rocky outcrops). In addition, chokeberry crops need a low nutrient supply [4], succeeding even in the absence of fertilizer administration. This was proven by studies on the chokeberry spreading, like an invasive plant, in spontaneous flora [5,6]. It tolerates arid or excessively moist soils [4] and very low temperatures, and is also resistant to diseases and pests [7]. These features enable the cultivation of chokeberry with fewer phytosanitary treatments, as well as for the rehabilitation by populating with the vegetation of lands abandoned after the extraction of peat [4].

The success of a species depends mainly on pedoclimatic conditions and its ability to develop strategies for adapting to a constantly changing environment. Temperature, soil moisture, available nitrogen levels, light, and high levels of carbon dioxide variations affect plant phenology. Among the environmental factors, temperature plays a predominant role in controlling the proper growth and flowering of plants [8,9,10,11,12]. Most of plants require a “hot-cold-hot” sequence to complete their annual cycle [13]. Lack of exposure to low temperatures leads to slow growth of shoots in spring and severe flowering disorders, with consequences on fruit production [14,15]. The timing of phenological events, such as the appearance of leaves and flowering, strongly influences the survival of plants and is closely dependent on the evolution of environmental factors [16]. Their study is vital to understanding how plants will respond to climate change. Moreover, advancing our understanding of the triggers of phenological responses may provide insight into future states of species distribution [17,18]. Eastern Europe has a temperate continental climate, but following the global warming trend is, at the same time, experiencing increasing climatic accidents [19]. In many cases, plant growth and development (especially the quantity and quality of the fruit crop) are mainly determined by the extreme climatic phenomena that impact the physiological processes that are running during that moment. Plant phenology—the timing of plant life-cycle events, such as flowering or leafing out—plays a fundamental role in the functioning of terrestrial ecosystems, including human agricultural systems [20]. Variations in plant phenology also influence the organisms that depend on them in terrestrial ecosystems and, vice versa, the gaps between the phenology of plants and their pollinators have repercussions on crop productivity [21]. Moreover, changes in the timing of plant development sequences can expose plants not only to climatic accidents but also to diseases [22] and pest attacks [23]. In addition, one of the main strategies of sustainable agriculture is the efficient management of cultural practices, which can be accomplished by the use of well-adapted species and cultivars.

Given these aspects, in the context of global climate change, research concerning the suitable adaptation of temperate fruit crops in different crop areas is needed. This paper aimed to study the adaptation of a crop to the specific environmental conditions of southern Romania, Pitești-Mărăcineni, Romania, in terms of the phenology of two chokeberry (Aronia melanocarpa) cultivars (‘Melrom’ and ‘Nero’).

2. Materials and Methods

2.1. Material and Study Area

The vegetal material was represented by two chokeberry (Aronia melanocarpa) cultivars (‘Melrom’ and ‘Nero’), planted on individual plots, at the Research Institute for Fruit Growing Pitesti—Maracineni (E44°54′11″ N 24°52′29″ E, 287 m elevation a.s.l.) in 2011 (‘Nero’) and 2017 (‘Melrom’). The plants, obtained through micropropagation, were managed as a bush, with planting distances of 1.4 × 3.0 m (2380 plants/ha). In Romania, chokeberry has been cultivated since 1986 and is represented mostly through the ‘Nero’ and ‘Melrom’ cultivars. The phenological observations were made over three seasons of vegetation, from 2019 to 2021, on three groups of 10 mature shrubs for each cultivar, randomly chosen. The experimental chokeberry plots are located on a meadow terrace of Arges River. As Chitu [24] mentioned, according to the Köppen-Geiger classification, the Pitești-Mărăcineni area is characterized by a humid continental climate, Cfbx category. The multiannual average temperature (1969–2019) of the air was 9.9 °C, and the sum of precipitation was 680 mm. As described by Nicola et al. [25], the soil belongs to the class of wet phreatic aluviosol protisols, formed on fluvial deposits, with a loam-sandy granulometric composition. It is characterized by a strongly moderate acid reaction, a low humus content, and a low assimilable phosphorus content in the arable layer. No fertilizer or irrigation was applied.

2.2. Methods

Phenological observations were performed weekly or every 2–3 days, using the BBCH scale (Figure 1) [26]. The registered data were statistically processed to calculate the length, using the number of days from 1 November and 1 January to the landmark stage.

The monthly evolution, in the 49 years that preceded the present experiment (1969–2017), in average air temperatures, absolute maximums, and minimums in the area where the research was conducted were taken as a reference to present the climatic data that described the three experimental years. Data for climate analysis were collected from the automated weather station, WhatchDog900ET (Spectrum Technologies Inc., Aurora, IL, USA), located in the vicinity of the two experimental lots. The following data were recorded: air temperature (collected in the meteorological shelter, at 2 m above ground level) and the minimum temperature measured outside the meteorological shelter (shielded from direct solar radiation). Based on these data, the average temperature and the average values of the minimum and maximum temperatures recorded daily, were calculated. Average total solar radiation (W/m²) was calculated starting from daily mean values measured using WatchDog 2900ET sensor (Spectrum Technologies Inc., USA). The (current) heat accumulation (ADD = actual degree days) for the analyzed phenophases was automatically calculated by the weather station’s integrated program, by summing the determinations made every 10 min, between the initial moment, i = 0, and the final moment, t, based on Formula (1).

$$Actual degree Days, AD{D}_t={{\displaystyle \sum }}_{i=0}^t\left. [\frac{1}{2}\left(T_{t}max-T_{t}min\right)-Tbasal\right]$$

(1)

where, if Tmax is above the upper limit (30 °C), it will be considered that Tmax = 30 °C, and if Tmin has a value below the basal temperature (5 °C), it will be considered that Tmin = Tbasal. Temperatures of 5 and 30 °C, respectively, were considered as the absolute minimum and maximum temperatures of A. melanocarpa species based on similarities with another species of fruit bush, Ribes nigrum [27]. To calculate the cold requirement (CH = Chill Hours, it was applied chill hours), the model originally proposed by Weinberger was applied [28], which has been mentioned quite frequently by other researchers [29,30,31,32]. This model calculates the chill demand at a moment, t (CHt), after a fixed start time is given, by summing up the hours when the temperature is below 7.22 °C and above 0 °C, according to Formula (2).

$${\mathrm{CH}}_t={{\displaystyle \sum }}_{i=0}^{t}H$$

(2)

where, if H is in the range 0.00–7.22 °C, H receives the value 1, and outside the domain 0.00–7.22 °C, it receives the value 0.

The chill requirement was calculated from the moment the plants started dormancy (arbitrary chosen as 1 November) and from 1 January, until bud swelling.

2.3. Data Analysis

The IBM SPSS Statistics 28 software platform was used to calculate the descriptive statistical indicators, the study of the cultivar influence (analysis of variance ANOVA), and the correlations between climatic parameters and phenophase duration, as well as between phenophase length.

3. Results and Discussion

Reproductive processes, including the timing and duration of flowering, as well as fruiting, may determine the limits of species distribution [33] and may influence annual net production [34]. The optimal flowering time of a plant, one of the variables that condition the pollination process, is determined by genetic factors, biotic interactions, and abiotic environmental variables [10,13,35,36]. The results regarding the influence of environmental factors on the chokeberry phenology are presented in

Table 1. Temperature, sunshine hours and rainfall during 2018–2021, compared to multiannual values (1969–2017) (Pitești-Mărăcineni area).

Weather Data	Interval	Nov.	Dec.	Jan.	Feb.	March	April	May	June	July	Aug.	Mean
Average temperature (°C)	2018–2019	4.7	−0.3	−1.2	2.6	7.8	10.8	15.7	21.2	21.1	22.8	10.5
	2019–2020	9.3	2.8	0.3	4.2	7.7	10.9	15.0	19.6	22.1	22.2	11.4
	2020–2021	4.7	3.0	0.5	3.0	4.1	8.6	15.6	19.3	23.5	22.4	10.5
	1969–2017	4.6	0.3	−1.2	0.4	4.8	10.4	15.3	18.8	20.6	19.9	9.4
Maximum temperature (°C)	2018–2019	9.1	4.6	3.5	9.8	15.7	16.8	22.0	28.6	28.5	31.4	17.0
	2019–2020	13.8	9.4	8.5	11.5	14.3	19.5	22.4	26.7	30.2	30.8	18.7
	2020–2021	10.6	6.2	5.3	9.1	10.5	15.0	22.3	26.6	31.1	31.1	16.8
	1969–2017	10.5	5.4	4.0	5.7	10.9	16.9	22.1	25.7	27.8	27.4	15.6
Minimum temperature (°C)	2018–2019	1.3	−3.8	−5.2	−3.3	0.2	5.0	9.5	15.4	14.3	15.3	4.9
	2019–2020	5.4	−1.6	−5.4	−1.7	1.8	2.3	8.4	13.5	15.2	15.3	5.3
	2020–2021	0.8	0.5	−3.3	−2.0	−1.3	2.6	9.0	13.4	16.4	14.8	5.1
	1969–2017	0.5	−3.3	−5.1	−3.7	−0.1	4.6	9.3	12.7	14.2	13.8	4.3
Absolute daily maximum temperature (°C)	2018–2019	18.3	11.8	10.4	19.2	23.6	26.3	28.2	32.2	34.9	35.1	35.1
	2019–2020	21.4	19.4	15.0	19.3	23.3	25.3	30.1	32.8	35.3	35.2	35.3
	2020–2021	17.6	12.9	13.3	22.3	18.8	25.3	28.4	34.0	36.8	36.4	36.8
	1969–2017	25.5	21.0	19.4	21.4	25.5	29.0	33.7	36.5	38.8	38.2	38.8
Absolute daily minimum temperature (°C)	2018–2019	−11.1	−9.6	−13.5	−14.1	−4.4	−0.1	2.4	11.2	7.9	10.2	−14.1
	2019–2020	−1.1	−7.9	−10.2	−8.5	−6.1	−3.9	4.3	4.3	11.6	11.0	−10.2
	2020–2021	−4.9	−7.9	−14.1	−10.3	−6.2	−3.3	2.5	7.0	12.5	9.0	−14.1
	1969–2017	−15.4	−21.2	−24.4	−23.4	−19.5	−6.0	−0.5	3.5	5.5	2.2	−24.4
Sunshine hours (hours, sum)	2018–2019	67.1	80.0	89.5	156.1	223.0	162.2	220.4	273.8	309.1	330.9	1912.1
	2019–2020	72.2	93.2	162.1	143.6	171.4	196.6	243.7	266.3	306.7	294.6	1950.4
	2020–2021	112.6	36.6	91.0	145.6	160.3	176.8	266.2	259.9	288.2	260.3	1797.5
	1969–2017	109.8	91.2	99.1	113.1	158.6	192.8	245.8	277.4	305.0	283.0	1875.8
Rainfall (mm, sum)	2018–2019	39.8	79.2	63.7	14.8	21.2	35.6	46.3	197.1	93.4	9.7	600.8
	2019–2020	56.2	15.5	1.8	22.5	30.0	21.1	104.1	166.2	52.0	29.8	499.2
	2020–2021	8.8	81.9	73.6	12.4	66.8	38.4	65.4	104.0	33.5	74.0	558.8
	1969–2017	45.6	42.3	32.7	33.8	37.6	56.4	81.7	95.3	81.6	63.1	570.1

,

Table 2. Air temperature, total solar radiation (TSR), cold accumulation (CH), heat accumulation (ADD) and timing of phenophases in chokeberry (1 November 2018–20 August 2021) ^a.

			Air Temperature (°C)
Phenophase	Statistic Descriptors	Duration (Days)	Tmin.	Min. Abs.	Tmed.	Tmax.	Max. Abs.	TSR (W/m2)	CH (Hours)	ADD (°C)
Dormancy (1 November—BBCH 51)	Mean	94.2	−1.2	−14.1	2.7	9.8	21.4	53.2	1120.4	-
	SD	3.9	0.9		1.2	4.5		5.4	276.2	-
	Min	89.0	−2.6		1.0	5.8		48.5	842.5	-
	Max	100.0	−0.5		4.0	18.5		61.0	1521.8	-
1 January—BBCH 53	Mean	65.89	−3.16	−14.1	1.94	8.37	22.3	86.27	693.59	-
	SD	2.87	0.64		0.79	1.59		2.57	68.60	-
	Min	61.00	−4.10		0.83	6.68		82.31	630.30	-
	Max	70.00	−2.62		2.98	10.55		89.62	799.80	-
1 January—BBCH 61	Mean	111.89	−1.20	−14.1	4.48	11.13	26.2	134.40	-	-
	SD	6.52	0.26		0.52	1.25		27.22	-	-
	Min	104.00	−1.56		4.06	9.97		117.71	-	-
	Max	120.00	−0.93		5.26	12.90		192.44	-	-
1 January—BBCH 71	Mean	123.50	−0.59	−14.1	5.29	12.03	28.4	136.65	-	-
	SD	6.17	0.27		0.45	1.15		6.51	-	-
	Min	116.00	−0.97		4.79	11.07		127.39	-	-
	Max	133.00	−0.15		5.95	13.65		144.33	-	-
1 January—BBCH 87	Mean	220.78	5.49	−14.1	11.70	18.63	36.8	197.68	-	-
	SD	7.92	0.45		0.28	0.35		1.96	-	-
	Min	209.00	4.74		11.22	18.24		195.80	-	-
	Max	231.00	6.00		12.00	19.35		202.45	-	-
BBCH 53–61	Mean	46.00	1.68	−6.2	8.15	15.09	26.2	177.04	-	181.10
	SD	4.10	0.38		0.85	1.37		11.16	-	63.74
	Min	40.00	1.25		6.93	13.13		167.64	-	12.90
	Max	52.00	2.39		8.92	16.37		199.47	-	228.20
BBCH 53–71	Mean	57.61	2.38	−6.2	9.13	16.19	28.4	193.56	-	296.93
	SD	3.96	0.26		0.51	0.98		11.71	-	14.49
	Min	52.00	2.02		8.34	14.80		177.15	-	275.10
	Max	64.00	2.92		9.64	17.41		209.95	-	318.20
BBCH 53–87	Mean	153.83	9.10	−6.2	16.08	23.30	36.8	245.15	-	1702.37
	SD	6.10	0.46		1.14	1.24		3.82	-	104.91
	Min	144.00	8.29		15.08	22.60		239.94	-	1512.40
	Max	163.00	9.62		19.12	26.67		253.26	-	1845.20

^a Note: Tmin = air temperature of daily minimums; Tmed = average temperature; Tmax = air temperature of daily maximums.

,

Table 3. Correlations between chokeberry spring–summer phenology (onset and duration) and climatic parameters (air temperature, total solar radiation) (Pitești-Mărăcineni, 2018–2021) ^a.

Phenophase		Air Temperature (°C)			TSR (W/m2)
		Tmin.	Tmed.	Tmax.
1 November—BBCH 53	Pearson Correlation	0.775 ***	0.620 **	0.430	0.451
	Sig. (2-tailed)	0.000	0.006	0.075	0.060
1 January—BBCH 53	Pearson Correlation	0.900 ***	0.651 **	0.339	0.380
	Sig. (2-tailed)	0.000	0.003	0.168	0.120
1 January—BBCH 61	Pearson Correlation	0.951 ***	−0.008	−0.182	−0.072
	Sig. (2-tailed)	0.000	0.976	0.469	0.775
1 January—BBCH 71	Pearson Correlation	0.992 ***	0.076	−0.190	0.468 *
	Sig. (2-tailed)	0.000	0.765	0.449	0.050
1 January—BBCH 87	Pearson Correlation	0.922 ***	0.939 ***	−0.387	−0.236
	Sig. (2-tailed)	0.000	0.000	0.113	0.345
BBCH 53–61	Pearson Correlation	−0.877 °°°	−0.936 °°°	−0.877 °°°	0.177
	Sig. (2-tailed)	0.000	0.000	0.000	0.481
BBCH 53–71	Pearson Correlation	−0.334	−0.885 °°°	−0.813 °°°	0.151
	Sig. (2-tailed)	0.175	0.000	0.000	0.549
BBCH 53–87	Pearson Correlation	0.926 ***	−0.132	−0.289	−0.472 °
	Sig. (2-tailed)	0.000	0.601	0.246	0.048

^a Note: Values in bold are significant. */° Significant correlation at 0.05 level (two tailed); ** Significant correlation at 0.01 level (two tailed); ***/°°° Significant correlation at level 0.001 (two tailed); TSR = total solar radiation.

,

Table 4. Correlations between chokeberry spring–summer phenophases onset and duration (Pitești-Mărăcineni, 2018–2021) ^a.

		BBCH 53	BBCH 61	BBCH 71	BBCH 87	BBCH 53–61	BBCH 53–71	BBCH 53–87
1 November—BBCH 53	Pearson Corel.	0.948 **	0.817 **	0.731 **	0.395	0.636 **	0.498 *	−0.130
	Sig. (2-tailed)	0.000	0.000	0.001	0.105	0.005	0.036	0.607
BBCH 53	Pearson Corel.	1	0.906 **	0.842 **	0.509 *	0.740 **	0.525 *	0.043
	Sig. (2-tailed)		0.000	0.000	0.031	0.000	0.025	0.867
BBCH 61	Pearson Corel.		1	0.973 **	0.695 **	0.955 **	0.708 **	0.282
	Sig. (2-tailed)			0.000	0.001	0.000	0.001	0.257
BBCH 71	Pearson Corel.			1	0.728 **	0.958 **	0.724 **	0.342
	Sig. (2-tailed)				0.001	0.000	0.001	0.165
BBCH 87	Pearson Corel.				1	0.748 **	0.643 **	0.829 **
	Sig. (2-tailed)					0.000	0.004	0.000
BBCH 53–61	Pearson Corel.					1	0.757 **	0.419
	Sig. (2-tailed)						0.000	0.084
BBCH 53–71	Pearson Corel.						1	0.329
	Sig. (2-tailed)							0.183
BBCH 53–87	Pearson Corel.							1
	Sig. (2-tailed)

^a Note: Values in bold are significant. * Significant correlation at 0.05 level (two tailed); ** Significant correlation at 0.01 level (two tailed).

and

Table 5. Correlations between chokeberry phenology and preceding climatic parameters (air temperatures, total solar radiation) (Pitești-Mărăcineni, 2018–2021) ^a.

Phenophase	Reference Phenophase		Air Temperature (°C)			TSR (W/m2)
			Tmin.	Tmed.	Tmax.
BBCH 53–61	1 November-BBCH 53	Pearson Corel.	0.536 *	0.256	0.003	−0.077
		Sig. (2-tailed)	0.022	0.305	0.992	0.763
BBCH 53–61	1 January-BBCH 53	Pearson Corel.	0.785 ***	0.294	−0.055	−0.135 135
		Sig. (2-tailed)	0.000	0.237	0.827	0.595
BBCH 61–71	1 November-BBCH 53	Pearson Corel.	−0.548 °	−0.549 °	−0.488 °	−0.495 °
		Sig. (2-tailed)	0.018	0.018	0.040	0.037
BBCH 61–71	1 January-BBCH 53	Pearson Corel.	−0.500 °	−0.570 °	−0.500 °	−0.466
		Sig. (2-tailed)	0.035	0.014	0.035	0.051
BBCH 61–71	BBCH 53–61	Pearson Corel.	0.394	0.066	−0.015	−0.546 °
		Sig. (2-tailed)	0.106	0.795	0.954	0.019
BBCH 71–87	1 November-BBCH 53	Pearson Corel.	−0.825 °°°	−0.865 °°°	−0.827 **	−0.788 °°°
		Sig. (2-tailed)	0.000	0.000	0.000	0.000
BBCH 71–87	1 January-BBCH 53	Pearson Corel.	−0.641 °°	−0.834 °°°	−0.809 °°°	−0.742 °°°
		Sig. (2-tailed)	0.004	0.000	0.000	0.000
BBCH 71–87	BBCH 53–61	Pearson Corel.	0.545 *	0.043	−0.106	−0.637 °°
		Sig. (2-tailed)	0.019	0.865	0.674	0.004
BBCH 71–87	BBCH 61–71	Pearson Corel.	−0.003	−0.329	−0.470 *	−0.373
		Sig. (2-tailed)	0.990	0.183	0.049	0.127

^a Note: Values in bold are significant. */° Significant correlation at 0.05 level (two tailed); **/°° Significant correlation at 0.01 level (two tailed); ***/°°° Significant correlation at level 0.001 (two tailed); TSR = total solar radiation.

. Regarding the study area, compared to the multiannual average values, the study period was mostly characterized by higher average temperatures (Table 1). The absolute maximum values over the three years of study were below the multiannual values, except for February 2021, when the absolute maximum exceeded the multiannual values by 0.9 °C. In addition, the absolute minimum values did not fall below the normal values (−24 °C). The average monthly temperatures generally exceeded the multiannual values, especially over June–August, although the absolute daily maximum values over those three months did not exceed the normal values.

The spring–summer phenology (inflorescence emergence, flowering, fruit development, and maturity of fruit and seed) of the chokeberry species (cultivars ‘Melrom’ and ‘Nero’) did not indicate significant differences between the studied cultivars. Table 2 shows the average data on phenophases’ development in the chokeberry. The 1 November—inflorescence buds swelling (BBCH 51) period covered an average of 94.2 ± 3.9 days (CV = 4.1%). The dormancy (1 November to 51 BBCH) ended between 28 January (2020, ‘Melrom’ and ‘Nero’) and February 8 (2021, ‘Melrom’) and occurred at air temperatures oscillating between the extremes of −14.1 and 21.4 °C, while the average of the minimum daily temperatures (Tmin) varied between −2.6 and −0.5 °C, and the average of the maximum daily temperatures (Tmax) oscillated from 5.8 to 18.5 °C, with an average temperature (Tmed) of 2.7 ± 1.2 °C (Table 2). An amount of 842.5–1521.8 chilling hours was accumulated during the 89–100 days of dormancy. The beginning of budburst (53 BBCH), marked by the appearance above the cataphylls of about a 5 mm green tip (Figure 1), was recorded between 3 March (‘Nero’, 2019) and March 12 (‘Nero’, 2021). As shown in Table 2, starting from January 1 to the bud burst (BBCH 53), 65.8 days were counted, with a mean deviation of 2.8 days (CV = 4.2%) and 693.6 ± 68.6 chill hours accumulated. From January 1 to bud burst (BBCH 53), Tmin recorded an oscillation between −4.10 and −2.62 °C, Tmax rose from 6.6 to 10.5 °C, and Tmed ranged in the interval 0.8–2.9 °C (Table 2). The average number of days from 1 January to the phenophases BBCH61, BBCH 71 and BBCH 87 was, respectively, 111.89 ± 6.5 days (CV = 5.8%), 123.5 ± 6.2 days (CV = 5.0%), and 220.7 ± 7.9 days (CV = 3.6%). From the bud burst stage (BBCH 53) to the fruit ripening ending (BBCH 87), 153.8 ± 6.1 days elapsed; the earliest phenophase fruit ripening occurred on July 28 (‘Nero’, 2020), while the latest has occurred on August 20 (‘Melrom’, 2021).

Over the period from bud burst (BBCH 53) till the fruit ripening end (BBCH 87), the average air temperature oscillated around 16.1 °C with a standard deviation of 1.1 °C, the thermal extremes varied between −6.2 °C and 36.8 °C, and heat accumulation was 1702.37 ± 104.91 °C. The average total solar radiation was 245.1 ± 3.8 W/m². Starting from bud burst (BBCH 53), the beginning of flowering (BBCH 61) started after the accumulation of 181.1 ± 63.7 °C heat and, up to the size of the fruit up to 3 mm (BBCH 71), the heat accumulation was 296.9 ± 14.4 °C (Table 2).

Regarding the influence of late frosts on spring phenophases, in the present study, the bud burst (BBCH 53) occurred in the first half of March, and the full flowering (BBCH 65) began after April 18. Late frosts in March and April (absolute minimum temperatures of −6.1 and −6.2 °C in March 2020 and 2021 and −3.9 °C in April 2020, respectively, data not shown), which affected some species fruit buds in orchards, did not damage the two chokeberry cultivars, which went through their budburst at that time.

Over the three years of observations, after the flowering onset, the minimum temperature did not fall below the freezing point. However, according to Butac and Chitu [8], in the Arges region, climatic accidents can be registered between 11–20 April (with a 4% probability), but also between 21–25 April (with a 6.25% probability).

Results regarding the resistance of the chokeberry to low temperatures, to which the late flowering is added, at a time when the danger of spring climates has passed, have been previously reported by Strik et al. [37]. Although it lasts only 10–12 days, the chokeberry flowering is staggered. By adopting such a strategy, the plants increase their chances of successful pollination in spring, and under conditions of low temperatures (which can affect the evolution of the pollen tube), rain, and wind (which prevents pollination, especially the entomophilic one). This species is self-fertile, which is an advantage given the existence of a small number of cultivars. A similar, staggered flowering strategy has been described by Quesada et al. [38] for a species of Bombacaceae that opens a small number of flowers every day. The staggered flowering of the chokeberry ensured the success of pollination, especially in 2021, when the maximum temperature rose to 28.4 °C (Table 1). In fact, over the three years of study, the absolute maximum temperature recorded during flowering exceeded 25.0 °C (data are not shown). This should be carefully considered because, according to Chitu et al. [19], temperatures exceeding 24–25 °C during flowering are very harmful, causing the stigma to dry out and thus preventing pollen germination.

It was also observed that the timing of phenological stages in the chokeberry species showed significant correlations with climatic variables, such as air temperature and total solar radiation (Table 3). Beaubine et al. [39], too, believe that the timing of spring flowering and leafing of perennials is largely controlled by accumulating temperature.

According to the data presented in Table 3, prolonged vernalization and bud swelling were correlated with the increase in Tmin and Tmed between November 1 and bud burst (BBCH 53; rTmin = 0.775, p = 0.000, rTmed = 0.620, p = 0.006). The analysis of phenophases onset moments, starting from January 1, revealed the highest correlation with Tmin (0.900–0.992, p = 0.000). Thus, a delay in the onset of phenophases correlated with the increase in Tmin was registered. In this context, the delay in the beginning of flowering (BBCH 61), a fruit size up to 3 mm (BBCH 71) and fruit ripe for picking (BBCH 87) appears to be a consequence of the delay in previous phenophases. The bud burst and fruit ripe for picking (BBCH 53–87) phenological range extended in correlation with the increase of Tmin (rTmin = 0.926, p = 0.000), and it was negatively correlated with TSR (r = −0.472, p = 0.048). Positive significant correlations were found between 61 and 53 BBCH (r = 0.906 ***), 71 and 53 BBCH (r = 0.842 ***), 71 and 61 BBCH (r = 0.973 ***), 87 and 53 BBCH (r = 0.509 *), 87 and 61 BBCH (r = 0.695 ***), 87 and 71 BBCH (r = 0.728 ***), respectively (Table 4), and indicated that the late onset of phenophases was preceded by the delayed onset of previous phenophases. Neither the flowering (BBCH 61–71), nor the development and maturation of the fruit (BBCH 71–87), were correlated with the duration length or the onset time of previous phenophases, except for the dormancy and bud burst period (November 1—BBCH 53). In this case, shorter flowering, fruit development and maturation phases followed the prolonged 1 November—bud burst (BBCH 53) interval (r = −0.563 *, −0.517 *, Table 4).

The study of the correlations between the phenophase timing and the previous oscillations in climatic parameters (Table 5) indicated that the higher temperatures during the dormancy and swelling were correlated with the longer bud burst—beginning of flowering period (BBCH 53–61; rTmax = 0.003, p = 0.992) and with the shorter period of beginning of flowering—fruit size up to 3 mm (BBCH 61–71; rTmax = −0.488, p = 0.040) and fruit size up to 3 mm—fruit ripe for picking period (BBCH71–87; rTmax = −0.827, p = 0.000). However, a shorter period of beginning of flowering—fruit size up to 3 mm (BBCH 61–71) was observed after the increase in TSR during bud burst—beginning of flowering (BBCH 53–61), while the Tmin increasing during flowering led to a shorter maturation time (Table 5). In the Arges area, the ripe fruits can be harvested over a 6-week interval. After that, the fruit became visibly dehydrated, but without abscission. Thus, harvesting can be planned based on the dynamics of the level of biologically active components, and also the degree of the dehydration of chokeberry fruits [3].

4. Conclusions

The present study indicated that chokeberry phenology is a dynamic process, which developed in correlation with the ambient temperature and total solar radiation. The chokeberry-flowering strategy and the restricted correlations of flowering duration with temperature and TSR may be the result of the species’ adaptation, gained over time. During dormancy, the decreasing in minimum temperature to −14.1 °C, just like the temperatures of −6.2 °C during bud burst, did not cause any damage to the chokeberry crop. In addition, resistance to high summer temperatures gave the chokeberry the characteristics of a species with a high potential for adaptation to a constantly changing climate. The flowering timing was shortened as a result of the increase in maximum temperature and total solar radiation. The development of phenophases indicates that A. melanocarpa is a species adapted to the temperate continental climate of southern Romania. Further studies will be carried out in order to follow up on the phenological changes under the current climate change and also to formulate additional recommendations for the sustainable management of this crop.