Morphophysiology of mini watermelon in hydroponic cultivation using reject brine and substrates

Silva, José S. da; Sá, Francisco V. da S.; Dias, Nildo da S.; Ferreira Neto, Miguel; Jales, Gleydson D.; Fernandes, Pedro D.

doi:10.1590/1807-1929/agriambi.v25n6p402-408

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Articles • Rev. bras. eng. agríc. ambient. 25 (6) • June 2021 • https://doi.org/10.1590/1807-1929/agriambi.v25n6p402-408 copy

Morphophysiology of mini watermelon in hydroponic cultivation using reject brine and substrates¹ 1 Research developed at Universidade Federal Rural do Semi-Árido, Mossoró, RN, Brazil

Morfofisiologia da mini melancieira em cultivo hidropônico usando rejeito salino e substratos

Authorship SCIMAGO INSTITUTIONS RANKINGS

HIGHLIGHTS

Growth and leaf area of mini watermelon in hydroponic cultivation are reduced at electrical conductivity above 4.00 dS m^-1.

Electrical conductivity of up to 6.90 dS m^-1 does not reduce the net photosynthesis of mini watermelon in hydroponic cultivation.

Coconut fiber is the best hydroponic substrate for mini watermelon.

Key words:
Citrullus lanatus; salt stress; chlorophyll fluorescence; gas exchange

ABSTRACT

The objective of the study was to evaluate the growth and physiological aspects of the ‘Sugar Baby’ mini watermelon grown in a hydroponic system with different substrates and mixtures of reject brine in the preparation of the nutrient solution. For this purpose, the experiment was carried out in a plastic greenhouse, using a randomized block design, in a 5 x 4 factorial scheme, corresponding to the combination of five mixtures of reject brine (electrical conductivity - EC = 9.50 dS m^-1) and tap water (EC = 0.54 dS m^-1) and four types of substrates (coconut fiber, sand, 70% sand + 30% rice husk and 40% sand + 60% rice husk), distributed in four replicates. Using the mixture of reject brine and tap water with EC above 4.00 dS m^-1 to prepare the nutrient solution of mini watermelon plants markedly reduced their growth. Increments in carboxylation efficiency and activity in the electron transport chain act as tolerance mechanisms to compensate for the net photosynthesis of mini watermelon under salt stress. Coconut fiber promoted the best growth and photosynthetic activity for mini watermelon plants, while the substrate with 100% washed sand led to the lowest performance.

Key words:
Citrullus lanatus; salt stress; chlorophyll fluorescence; gas exchange

Water sources	Attributes
	pH	EC (dS m^-1)	K⁺	Na⁺	Mg²⁺	Ca²⁺	Cl^-	CO₃^2-	HCO₃^-	SAR (mmol L^-1)^0.5
	pH	EC (dS m^-1)	(mmol_c L^-1)							SAR (mmol L^-1)^0.5
Tap water	7.57	0.54	0.31	3.79	1.20	0.83	2.40	0.60	3.20	3.76
Reject brine	7.10	9.50	0.83	54.13	24.20	37.80	116.00	0.00	3.40	9.70

Source of variation	Probability of F test
Source of variation	PH	SD	NL	LA
Block	0.0781	0.3690	0.5017	0.2756
Water mixtures	0.0000	0.0020	0.0000	0.0000
Substrates	0.0000	0.0000	0.0000	0.0000
Water mixtures x Substrates	0.0878	0.0743	0.6634	0.0648
CV (%)	21.97	8.71	14.74	19.28
Water mixtures (M)	Means
Water mixtures (M)	(cm)	(mm)	(und)	(m²)
M₁ - 100% TW (control)	47.31 a	4.001 ab	7.75 a	0.0403 a
M₂ - 85% TW + 15% RB	43.62 a	4.134 a	7.56 a	0.0350 a
M₃ - 70% TW + 30% RB	34.87 b	3.681 b	6.50 b	0.0289 b
M₄ - 55% TW + 45% RB	33.50 b	3.740 b	6.18 b	0.0232 b
M₅ - 40% TW + 60% RB	31.87 b	3.927 ab	6.37 b	0.0231 b
Substrates (S)	(cm)	(mm)	(und)	(m²)
S₁ - Coconut fiber	71.15 a	4.783 a	9.70 a	0.0585 a
S₂ - 100% Sand (S)	18.65 c	3.296 c	5.05 c	0.0138 c
S₃ - 70% S + 30% RH	30.75 b	3.773 b	6.45 b	0.0246 b
S₄ - 40% S + 60% RH	32.40 b	3.744 b	6.30 b	0.0236 b

Source of variation	Probability of F test
Source of variation	gs	A_N	Ci	E	WUEi	A_N/Ci
Block	0.0003	0.0058	0.7631	0.0310	0.3027	0.1259
Water mixtures	0.2429	0.3287	0.0000	0.0000	0.0000	0.0056
Substrates	0.0000	0.0005	0.0574	0.0000	0.3321	0.0077
Water mixtures x Substrates	0.8992	0.4849	0.3805	0.9379	0.6403	0.2021
CV (%)	13.54	11.08	7.37	9.00	8.89	15.24
	Means
Water mixtures (M)
M₁ - 100% TW (control)	0.246 a	20.13 a	193.1 a	4.48 d	4.365 a	0.1013 b
M₂ - 85% TW + 15% RB	0.222 a	18.63 a	179.1 b	5.10 bc	3.634 b	0.1051 b
M₃ - 70% TW + 30% RB	0.238 a	19.97 a	182.1 ab	4.79 cd	4.177 a	0.1105 ab
M₄ - 55% TW + 45% RB	0.232 a	19.40 a	173.0 bc	5.70 ab	3.397 b	0.1131 ab
M₅ - 40% TW + 60% RB	0.227 a	19.50 a	164.6 c	5.53 a	3.646 b	0.1236 a
Substrates (S)
S₁ - Coconut fiber	0.199 b	17.64 b	175.8 a	4.67 b	3.821 a	0.1006 b
S₂ - 100% Sand (S)	0.253 a	19.96 a	185.5 a	5.39 a	3.737 a	0.1083 ab
S₃ - 70% S + 30% RH	0.241 a	20.41 a	175.5 a	5.26 a	3.737 a	0.1179 a
S₄ - 40% S + 60% RH	0.238 a	20.07 a	176.5 a	5.17 a	3.898 a	0.1160 a

Sources of variation	Probability of F test
Sources of variation	Fo	Fm	Fv	Fv / Fm
Block	0.7149	0.6227	0.6010	0.6083
Water mixtures	0.0479	0.0011	0.0012	0.0189
Substrates	0.0080	0.0844	0.2905	0.1453
Water mixtures x Substrates	0.0582	0.8161	0.7121	0.0766
CV (%)	6.25	4.59	5.75	2.15
	Means
Water mixtures (M)
M₁ - 100% TW (control)	960.00 a	3859.12 a	2899.12 a	0.7509 a
M₂ - 85% TW + 15% RB	1002.94 a	3801.87 ab	2798.94 abc	0.7357 a
M₃ - 70% TW + 30% RB	947.12 a	3802.06 ab	2854.94 ab	0.7504 a
M₄ - 55% TW + 45% RB	952.19 a	3651.87 b	2699.69 bc	0.7382 a
M₅ - 40% TW + 60% RB	944.19 a	3638.75 b	2694.56 c	0.7394 a
Substrates (S)
S₁ - Coconut fiber	993.60 a	3783.05 a	2789.45 a	0.7366 a
S₂ - 100% Sand (S)	928.30 b	3662.85 a	2734.55 a	0.7455 a
S₃ - 70% S + 30% RH	972.05 ab	3774.55 a	2802.50 a	0.7416 a
S₄ - 40% S + 60% RH	951.20 ab	3782.50 a	2831.30 a	0.7478 a

Sources of variation	Probability of F test
Sources of variation	ETR	Y_II	qL	Y_NPQ	Y_NO
Block	0.9221	0.7828	0.9342	0.7544	0.8993
Water mixtures	0.0022	0.0001	0.4596	0.0001	0.0024
Substrates	0.5753	0.1791	0.0009	0.1479	0.0060
Water mixtures x substrates	0.9471	0.5445	0.1196	0.6396	0.2871
CV (%)	48.85	6.06	18.90	12.74	11.69
	Means
Water mixtures (M)
M₁ - 100% TW (control)	59.22 bc	0.693 a	0.0079 a	0.252 c	0.054 b
M₂ - 85% TW + 15% RB	68.42 abc	0.643 bc	0.0075 a	0.295 ab	0.062 a
M₃ - 70% TW + 30% RB	56.01 c	0.677 ab	0.0085 a	0.269 bc	0.054 b
M₄ - 55% TW + 45% RB	93.49 ab	0.635 c	0.0083 a	0.305 ab	0.059 ab
M₅ - 40% TW + 60% RB	99.79 a	0.633 c	0.0081 a	0.306 a	0.060 ab
LSD	36.58	0.039	0.0015	0.036	0.006
Substrates (S)
S₁ - Coconut fiber	78.93 a	0.652 a	0.0092 a	0.293 a	0.055 b
S₂ - 100% Sand (S)	68.91 a	0.665 a	0.0073 b	0.274 a	0.060 ab
S₃ - 70% S + 30% RH	83.09 a	0.642 a	0.0074 ab	0.297 a	0.061 a
S₄ - 40% S + 60% RH	70.60 a	0.666 a	0.0083 a	0.278 a	0.055 ab
LSD	30.82	0.033	0.0012	0.030	0.005

Unidade Acadêmica de Engenharia Agrícola Unidade Acadêmica de Engenharia Agrícola, UFCG, Av. Aprígio Veloso 882, Bodocongó, Bloco CM, 1º andar, CEP 58429-140, Campina Grande, PB, Brasil, Tel. +55 83 2101 1056 - Campina Grande - PB - Brazil
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[1] * Corresponding author - E-mail: vanies_agronomia@hotmail.com

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Morphophysiology of mini watermelon in hydroponic cultivation using reject brine and substrates1 1 Research developed at Universidade Federal Rural do Semi-Árido, Mossoró, RN, Brazil

Morfofisiologia da mini melancieira em cultivo hidropônico usando rejeito salino e substratos

HIGHLIGHTS

ABSTRACT

Morphophysiology of mini watermelon in hydroponic cultivation using reject brine and substrates¹ 1 Research developed at Universidade Federal Rural do Semi-Árido, Mossoró, RN, Brazil