Experimental site

Field experiments were conducted during the winter seasons of 2015–2016 and 2016–2017 at Bahauddin Zakariya University (BZU), Multan, Punjab, Pakistan (30.19° latitude N, 71.46° longitude E and 125 m above the sea level). The soil of the experimental site belongs to ‘Sindhlianwali’ soil series (fine silty, mixed, hyperthermic, sodic haplocambids) (Ahmad et al., Reference Ahmad, Raza, Ali, Shahzad, Atique-ur-Rehman and Sarwar2014). Soil measurements for physical and chemical properties were obtained prior to sowing of canola in both years.

Experimental procedure

The canola experiments (Table S1) were sown following a randomized complete block design. The experimental field was irrigated eight days before seed-bed preparation and then ploughed three times, followed by planking. Canola was hand drilled in rows at a spacing of 45 cm and around 15 cm between plants. Weeds were controlled manually and mechanically. Irrigation water was provided via tube wells. All other management practices were implemented in accordance with the instructions of the local agriculture department and consistent across all trials and years.

Plant sampling and measurements

Growth and development data were obtained weekly following the methodology described by Deligios et al. (Reference Deligios, Farci, Sulas, Hoogenboom and Ledda2013) and Jing et al. (Reference Jing, Shang, Qian, Hoogenboom, Huffman, Liu, Ma, Geng, Jiao, Kovacs and Walters2016). Development stages were recorded when half of the plants from each experimental unit reached a given stage. Plants in a 1 m² quadrat were collected at 25-day intervals from each plot for growth final biomass and yield and yield components. Samples were oven-dried for 72 h at 65°C for dry weight. A leaf area meter (model LI-3100; LICOR Inc., Nebraska, USA) was used to obtain leaf area. Canola was hand-harvested with the help of a sickle in all experiments during the third week of March in 2016 and 2017 to obtain for final yield and yield components. The samples were then dried for five days and manually threshed.

On-farm survey data

A survey, prepared following the procedure from Fermont et al. (Reference Fermont, van Asten, Tittonell, van Wijk and Giller2009), was used to obtain information from 100 growers across four districts (Multan, Khanewal, Vehari and Bahawalpur) (Fig. 1) in Punjab, Pakistan during the 2016–2017 growing season. We recorded on-farm canola yield along with management practices including the seeding rate, sowing time, sowing method, canola cultivar, N fertilizer strategy and irrigation strategy. The CROPGRO-Canola model was then used to simulate canola grain yield from each of the 100 farmer fields surveyed using traditional farming practices.

Fig. 1. The selected locations for the simulation of potential and achievable yield of canola and the major causes for the yield cap, i.e. water limited, nitrogen limited, water and nitrogen limited and other crop management practices, for four districts in southern Punjab, Pakistan. The circles indicate locations of field experiments used for CSM-CROPGRO-Canola model calibration and evaluation.

CSM-CROPGRO-Canola model description

The CSM-CROPGRO-Canola model (Deligios et al., Reference Deligios, Farci, Sulas, Hoogenboom and Ledda2013; Jing et al., Reference Jing, Shang, Qian, Hoogenboom, Huffman, Liu, Ma, Geng, Jiao, Kovacs and Walters2016) of the Decision Support System for Agro-technology Transfer (DSSAT v4.7.5; Hoogenboom et al., Reference Hoogenboom, Porter, Boote, Shelia, Wilkens, Singh, White, Asseng, Lizaso, Moreno, Pavan, Ogoshi, Hunt, Tsuji, Jones and Boote2019a, Reference Hoogenboom, Porter, Shelia, Boote, Singh, White, Hunt, Ogoshi, Lizaso, Koo, Asseng, Singels, Moreno and Jones2019b), was used in this study. The model simulates the growth and development of canola based on carbon, water, N and energy balance principles. The model requires information on crop management practices, soil characteristics, genetic coefficients and weather parameters for the simulation of daily growth and development and final yield prediction.

The model was calibrated with results from a nitrogen rates study conducted during the 2015–2016 growing season for the cultivar Faisal at a rate of 150 kg N/ha. A trial-and-error procedure was used for calibration by comparing the model predicted data with the field experimental observed data (Table S2) and the process generated Genetic coefficients for canola cultivars (Table S3).

The performance of the model was evaluated with the N rate treatments that were not used for calibration and three other field experiments that included irrigation regimes, N strategies and sowing dates as treatments.

Weather conditions

The climate of the region is of continental type with hot and dry summers and cold and dry winters (Ahmad et al., Reference Ahmad, Ashfaq, Rasul, Wajid, Khaliq, Rasul, Saeed, Habib ur Rahman, Hussain, Baig, Naqvi, Bokhari, Ahmad, Naseem, Hoogenboom, Hillel and Rosenzweig2015; Tariq et al., Reference Tariq, Ahmad, Fahad, Abbas, Hussain, Fatima, Nasim, Mubeen, Habib ur Rehman, Khan, Adnan, Wilkerson and Hoogenboom2018). During the 2015–2016 and 2016–2017 growing seasons, weather conditions were characterized by daily maximum and minimum temperatures that ranged from 8 to 37°C and 2 to 27°C, total solar radiation that ranged from 4.6 to 21.6 MJ/m²/d, and total seasonal rainfall that ranged from 45 to 56 mm (Fig. 2).

Fig. 2. Daily maximum and minimum temperatures (a, c), solar radiation and precipitation (b, d) for canola growing seasons 2015–2016 (a, b; unfilled symbols) and 2016–17 (c, d; filled symbols) in Multan, Pakistan.

Simulation scenarios for yield-gap analysis

Long-term simulations of canola yield were conducted for conditions for all the 100 farms that were surveyed using historical weather data. The simulation scenarios of included potential yield (Y _P, without water and N limitations), achievable yield (Y _A, recommended/approved management practices), water-limited yield (Y _WL, limited water conditions), N-limited (Y _NL, N-limited conditions), water and N-limited yield (Y _WNL, both water and N limited conditions) and overall farmer field (Y _OFF, observed yield at a farm). Observed canola yield from 1980 to 2016, collected for selected districts from the Department of Agriculture (Extension Wing), Government of the Punjab, Pakistan were also used. Management practices other than water and N were kept the same across the simulations. We defined the yield-gap (YG) as follows:

(1)$${\rm Y}{\rm G}_i = Y_j {-} Y_k$$

where i correspond to yield gap under conditions of WL, NL, WNL and OFF; j = Y _P, Y _A; and k = Y _WL, Y _NL, Y _WNL and Y _OFF. The YG was then expressed as per cent loss of the potential and achievable yields, as follows:

(2)$${\rm Y}{\rm G}_{\rm i} = {\rm \;}\displaystyle{{Y_j\;-\;Y_k} \over {Y_j}}$$

The percentages indicating how close Y _WL, Y _NL, Y _WNL and Y _OFF are from the simulated Y _P and achievable yield Y _A (Zu et al., Reference Zu, Mi, Liu, He, Kuang, Fang, Ramp, Li, Wang, Chen, Li, Jin and Yu2018).

Statistical analysis

The results from the field experiments were subjected to analysis of variance techniques using STATISTICS 8.1. Treatment means were subjected to post-hoc comparisons using the least significant difference test (Steel et al., Reference Steel, Torrie and Dickey1997) at alpha = 0.05. The farm survey data were analysed using linear regression and probability of exceeding. The performance of the CSM-CROPGRO-Canola model was evaluated using the root mean square error (RMSE) and normalized RMSE (RMSEn) (Wallach and Goffinet, Reference Wallach and Goffinet1987) and the Wilmott (Willmott, Reference Willmott1981) index of agreement (d-index):

(3)$${\rm RMSE} = \left[{\sqrt {\displaystyle{{\mathop \sum \nolimits_{i = 1}^n {( {Si-Oi} ) }^2} \over N}} } \right]$$

(4)$${\rm RMS}{\rm E}_n = {\rm \;\;}\left[{\displaystyle{{{\rm RMSE\;} \times 100} \over {\bar{O}}}} \right]$$

(5)$$d \hbox{-}{\rm index} = 1 {-} \left[{\displaystyle{{\mathop \sum \nolimits_{i = 1}^n {( {S_i {-} O_i} ) }^2} \over {\mathop \sum \nolimits_{i = 1}^n {( \vert {{{S}^{\prime}}_i} \vert + \vert {{{O}^{\prime}}_i} \vert ) }^2}}} \right]$$

where ‘S_i’ and ‘O_i’ are simulated and observed values ‘N’ is the sample size, $\bar{O}$ is the average for the observed values, $S^{\prime}_i = ( {S_i-\bar{O}} )$ and $O^{\prime}_i = ( {O_i-\bar{O}} )$. The lower values of RMSE represent a better fit. The RMSE_n provides a comparative change of simulated v. observed data expressed in percentage. Simulations were considered excellent, good, fair and poor when RMSE_n is <10%, >10 and <20%, >20% and <30% and >30%, respectively (Loague and Green, Reference Loague and Green1991). According to Willmott (Reference Willmott1981), a value of 1 indicates a perfect match while a value of 0 indicates no agreement.