Seed Collection

Mature seeds of barnyardgrass were collected from September to October 2019 from four populations from the east and west sides of Oslofjorden, Norway (East1, East2, West1, and West2). A Polish population sampled in August to September 2019 (Radocza, Poland) was also included. The characteristics of the fields where the populations were sampled are presented in Table 1. At least 20 g of seeds of each population were collected in each field by carefully bending and shaking as many seed-bearing tillers as possible into paper bags. Then pooled seeds were stored under dry conditions at room temperature in paper bags for at least 6 wk, counted (50-seed lots), and transferred into small glass containers with lids and then again stored at room temperature until they were used in the experiments. We estimated the mean 1,000-seed weight for each population by counting and weighing 10 samples of 50 seeds. In June 2020, we checked the germination percentage of the seeds (Table 1).

Table 1. Sites, 1,000-seed weights, germination percentage, and field characteristics where seeds from five different populations of barnyardgrass were sampled for the experiments.

Experimental Treatment and Data Collection

To find the effective soil temperature to kill seeds and test whether exposure duration is important, we considered target soil temperatures of 60, 70, 80, and 99 C with an exposure duration of 90 s (Experiment 1) and three exposure durations of 30, 90, or 180 s following a target soil temperature of 99 C (Experiment 2). Before steaming, seeds were transferred from the glass containers (50 seeds) to polypropylene-fleece bags (9 × 7 cm). To mimic a seed bank with ranges of seed moisture content (as assumed to co-occur in piles of infected soil masses), four pretreatments were included: seeds without premoistening (i.e., dry seeds) and seeds moistened with water for 12, 24, or 48 h at room temperature prior to steaming. Each treatment combination (pretreatment × target soil temperature × exposure duration) had four replicates. Except for two of the populations (West1 and West2), we used 50 seeds per replicate (1 bag × 50 seeds). Owing to relatively poor germination in the germination tests for populations West1 and West2, only 12-h premoistening and 200 seeds per replicate (4 bags × 50 seeds) were used for these populations. For each combination of target soil temperature and exposure duration, all bags (with seeds) in the same replicate were placed at the bottom of a plastic perforated basket container (60 × 40 × 20 cm) and covered with a 7-cm soil layer. Soil was from a local soil reseller. A commercial laboratory characterized it as a loam soil (10% to 25% clay, 25% to 50% silt, <3% organic matter). We estimated the soil to have a moisture content of 40% before being subjected to steaming. This was estimated by drying soil samples for 72 h at 105 C.

Immediately after reaching the target soil temperature and completion of exposure period, all bags containing steamed seeds were taken out of the basket and the warm soil and stored outdoors in shade at an ambient air temperature (∼15 C) until transported to the greenhouse (a few hours after steaming). Each bag was opened carefully and placed on the soil surface in 12-cm-diameter pots and covered by a thin layer (2 to 3 mm) of soil. Commercial potting soil was used (Tjerbo torvfabrikk AS, Rakkestad, Norway). It was composed of 80% sphagnum peat, 10% composted bark, and 10% sand (v/v/v), limed and fertilized with NPK (950:40:220 mg L⁻¹) with a pH of 5.5 to 6.5. Pots were placed in a greenhouse (21/16 C and 14/10 h for day/night; RH: 68%) in a randomized design and watered from the bottom with tap water, and thereafter as needed during the experimental period. Seed germination was followed for 28 d, and the number of germinated seeds per pot was counted every 7 d. As controls, nonsteamed seeds subjected to various moistening pretreatments and a soil temperature of 25 C were used. A total of 320 treated pots in Experiment 1 and 160 in Experiment 2, as well as 80 control pots, were evaluated.

In a third experiment, we tested the effects of different steaming durations of 90, 180, and 540 s at 99 C on barnyardgrass seed germination. Four replications of 40 barnyardgrass seeds of populations were placed in polypropylene-fleece bags (9 × 7 cm), moistened for 12 h, and covered by the soil at a 7-cm depth in 60 × 40 × 20 cm plastic perforated basket containers. Steam treatment and seed germination assessment were done in the same way as in Experiments 1 and 2.

Steaming Method

All bags in the same replicate of each combination of target temperature and exposure duration were placed at the bottom of one basket and covered by a 7-cm soil layer. A total of 28 baskets (7 combinations of soil temperatures and exposure durations × 4 replicates), each including 20 bags (3 populations × 4 pretreatments × 1 bag + 2 populations × 1 pretreatment × 4 bags), were used in Experiments 1 and 2. Each basket was placed in the steaming container (190 × 144 × 88 cm, 130 kg, effective steaming area of 120 × 80 cm), and 10 thermocouples were placed in the soil (Figure 2). When the container lid was closed, steam was released from the top with a constant temperature of ∼150 C and vacuumed from the bottom of the container. Soil temperature was monitored by means of PT1000 sensors connected to a cRIO-9073 data logger (National Instruments, Austin, TX, USA). A custom-made program was used to record temperature, duration of the period with steam entering the steaming container, and poststeaming exposure duration. Steaming and vacuuming were stopped when at least 5 of the 10 thermocouples had reached the target soil temperature. The basket was removed from the steaming container when the poststeaming exposure duration of either 30, 90, or 180 s was completed. The seed samples were then removed immediately from the basket and the warm soil into a shaded place outdoors.

Figure 2. Steaming prototype device used in the experiments (left) and basket with soil, seed samples, and thermocouples placed inside the steaming container (right). Photograph by Vinh Hong Le.

Postprocessing of Soil Temperature Data

The individual temperature measurement by each of the 10 thermocouples was used to calculate the average soil temperature during steaming for each combination of target soil temperature and poststeaming exposure duration in each replicate. The maximum values of each of the mean soil temperature curves during the steaming process were extracted. Comparison of the target and actual maximum mean soil temperatures showed that it was generally difficult to reach exact target temperatures. Actual maximum mean soil temperature values were 59.3 to 68.5, 73.9 to 75.6, 76.9 to 83, and 94.1 to 99.2 C for the target temperatures of 60, 70, 80, and 99 C, respectively. Examples of mean soil temperature curves are shown in Figure 3. The duration of the target poststeaming exposure was generally obtained. For the planned poststeaming periods 30, 90, and 180 s, actual periods were 29 to 33 s (4 replicate baskets), 87 to 97 s (16 replicate baskets), and 181 to 183 s (4 replicate baskets), respectively.

Figure 3. Examples of soil temperature curves in Experiment 1, in which target temperatures were 60, 70, or 80 C and with an exposure duration of 90 s (A), and in Experiment 2, in which the target soil temperature was 99 C (dotted line) with an exposure duration of either 30, 90, or 180 s (B). Each temperature curve is the average of 10 measurements. The gray horizontal bar shows the period with steam entering the steaming container with the seed samples (Figure 2, left). The black horizontal bar indicates the exposure duration, that is, the period after steaming stopped until the basket with the seeds was removed from the container (Figure 2, right).

Statistical Analysis

Data from Experiments 1 and 2 were analyzed with the statistical software SAS version 9.4 (SAS Institute Inc., Cary, NC, USA). The response variable was the proportion of seeds germinated 28 d after steaming. An initial analysis of variance showed that durations of the measured exposure (29 to 183 s) were unimportant. Therefore the data from the two experiments were analyzed together. Using the NLMIXED procedure, the maximum value of the mean soil temperature curve for each of the 28 experimental units (seven combinations of target soil temperature and exposure duration including nonsteamed controls × four replicates) was used as the independent variable for dose–response modeling using a three-parameter log-logistic dose–response function:

([1]) $$p = {p_i}\left( t \right) = {{{d_{0i}}} \over {1 + {{\left( {{{t - {t_0}} \over {{\alpha _i}}}} \right)}^{{\beta _i}}}}},\;i = 1,2,3,4,5$$

where p is the probability of a random seed germinating and is a function of maximum soil temperature (t) and population i, where i = 1 (Poland), 2 (East1), 3 (East2), 4 (West1), and 5 (West2). Parameters d _0i , α _i , and β _i are to be estimated with the data. Parameter d _0i is the maximum seed germination in population i at t ₀, that is, the nonsteamed control set to 25 C. If t ₀ had been zero, the parameter α _i = LT₅₀, that is, the maximum mean soil temperature killing 50% of the seeds from population i. In the current case, the parameter α _i = LT₅₀–t ₀. Parameter β _i describes the shape, including the steepness, of the function for population i. In the parameter estimations, t ≥ t ₀, 0 < d _0i ≤ 1, α _i > 0, and β _i > 0 were assumed.

To estimate LT₅₀ and LT₉₀ for each population i, the following approach was used. To find the lowest t which for a given proportion q gives p ≤ $$q \cdot {d_{0i}}$$ (where 0 < q < 1), the equation $${p_i}\left( t \right) = q \cdot {d_{0i}}$$ was solved with respect to t for each population i. The general solution, $$T_{100 \cdot q}^{\left( i \right)}$$ , is given by

([2]) $${\rm{LT}}_{100}^{\left( i \right)} = {\alpha _i}\cdot{\left( {{{1 - q} \over q}} \right)^{{1 \over {{\beta _i}}}}} + {t_0},\;i = 1,2,3,4,5$$

LT₅₀ and LT₉₀ for each population i can be expressed as $${\rm{LT}}_{100 \cdot q}^{\left( i \right)}$$ , where q = 0.5 [ $${\rm{LT}}_{50}^{\left( i \right)}$$ ] and q = 0.9 [ $${\rm{LT}}_{90}^{\left( i \right)}$$ ], respectively. Parameter values for $${\rm{LT}}_{100 \cdot q}^{\left( i \right)}$$ for q = 0.5 and 0.9 were estimated by replacing parameters α _i and β _i in Equation 2 with their respective estimates found from solving Equation 1 (Table 2). Finally, differences in parameter estimates (LT₅₀ and LT₉₀) among the five populations were compared using the Bonferroni method (Bonferroni Reference Bonferroni1936).

Table 2. Parameter estimates from fitting Equation 1 (dose–response model) to data on observed germination of seeds from five barnyardgrass populations in response to maximum mean soil temperature imposed by steaming soil. ^{a, b, c}

^a Parameter d _0i denotes the maximum germination in population i and occurs at t ₀, that is, nonsteamed control (set to 25 C). Parameter α _i = LT₅₀–t ₀, and parameter β _i denotes the shape (slope) of the dose–response curve (Figure 4).

^b Estimates not sharing the same letter were significantly different (Bonferroni’s method, P ≤ 0.05 divided by the number of hypotheses test = 0.05/10 = 0.005; Supplementary Table S1).

^c Populations East and West represent populations from east and west sides of the Oslo Fjord, Norway, respectively.

To assess whether moistening of the dry seeds before steaming was affecting the seeds’ tolerance to high temperature and hence the LT estimates, the three populations in which four levels of moistening were imposed (k) were analyzed individually with the following two-parameter model:

([3]) $$p = {p_k}\;\left( t \right) = {{{d_0}} \over {1\; + \;{{\left( {{{t - {t_0}} \over {{\alpha _k}}}} \right)}^{{\beta _k}}}}},\;k = 0,\;12,\;24,\;48$$

where $${\alpha _j} \gt 0{\rm{\;and\;}}{\beta _j} \gt 0$$ are parameters to be estimated, whereas d ₀ was fixed to the estimate values found from solving Equation 1 for populations Poland, East1, and East2, that is, 0.75, 0.84, and 0.68, respectively (Table 2). The expression for LT_100·q (Equation 2) was modified correspondingly by replacing α and β with α _k and β _k , respectively. Finally, differences in parameter estimates (LT₅₀ and LT₉₀) among the four premoistening levels (k) were compared individually for the three actual populations (Poland, East1, East2) using the Bonferroni method (Bonferroni Reference Bonferroni1936).