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Author(s): Pirjo Peltonen-Sainio, Lauri Jauhiainen, Juuso Joona, Tuomas Mattila, Tony Hydén & 
Hannu Känkänen 
Title: Sowing and Harvesting Measures to Cope with Challenges of Cover Crops 
Experienced by Finnish Farmers 
Year: 2023 
Version: Published version 
Copyright:   The Author(s) 2023 
Rights: CC BY 4.0 
Rights url: http://creativecommons.org/licenses/by/4.0/ 
 
Please cite the original version: 
Peltonen-Sainio, P.; Jauhiainen, L.; Joona, J.; Mattila, T.; Hydén, T.; Känkänen, H. Sowing and 
Harvesting Measures to Cope with Challenges of Cover Crops Experienced by Finnish Farmers. 
Agronomy 2023, 13, 499. https://doi.org/10.3390/agronomy13020499 
Citation: Peltonen-Sainio, P.;
Jauhiainen, L.; Joona, J.; Mattila, T.;
Hydén, T.; Känkänen, H. Sowing and
Harvesting Measures to Cope with
Challenges of Cover Crops
Experienced by Finnish Farmers.
Agronomy 2023, 13, 499. https://
doi.org/10.3390/agronomy13020499
Academic Editors: Tiziano Gomiero,
Lisa Lobry de Bruyn and Ji Li
Received: 21 December 2022
Revised: 2 February 2023
Accepted: 7 February 2023
Published: 9 February 2023
Copyright: © 2023 by the authors.
Licensee MDPI, Basel, Switzerland.
This article is an open access article
distributed under the terms and
conditions of the Creative Commons
Attribution (CC BY) license (https://
creativecommons.org/licenses/by/
4.0/).
agronomy
Article
Sowing and Harvesting Measures to Cope with Challenges of
Cover Crops Experienced by Finnish Farmers
Pirjo Peltonen-Sainio 1,* , Lauri Jauhiainen 2, Juuso Joona 3, Tuomas Mattila 4, Tony Hydén 5
an Hannu Känkänen 2
1 Natural Resources Institute Finland (Luke), Latokartanonkaari 9, FI-00790 Helsinki, Finland
2 Natural Resources Institute Finland (Luke), Tietotie 2, FI-31600 Jokioinen, Finland
3 Tyynelä Farm, Etu-Aholantie 78, FI-55100 Imatra, Finland
4 Finnish Environment Institute (SYKE), Latokartanonkaari 11, FI-00790 Helsinki, Finland
5 Koivumäki Farm, Lovisavägen 355, FI-07900 Loviisa, Finland
* Correspondence: pirjo.peltonen-sainio@luke.fi
Abstract: Farmers may promote the cultivation of under-sown cover crops (CCs) in various ways
without jeopardizing the yield of a cash crop. With this survey, we aimed to understand how Finnish
farmers manage possible challenges with under-sown CCs. A farmer survey was carried out in 2021.
We invited 6493 farmers who had selected CCs as a registered measure to answer a questionnaire
with 20 statements (a Likert scale), and 1130 responded (17.4%). A Cochran–Mantel–Haenszel test
was used to measure the strength of the association between 11 farm/farmer characteristics of the
respondents and 20 statements. Responses indicated that farmers often took under-sown CCs into
account during the growing season. Sowing was considered an especially critical measure and the CC
seeding rate was often assessed with a test run before sowing. Thirty-nine per cent of the respondents
had made investments, most often to facilitate sowing. The farmers usually adjusted the fertilizer
rate only according to the cash crop. Early harvesting of a cash crop was considered important by
58% of farmers to ensure that the CCs do not hamper the harvest. Farmers harvested cash crops as
soon as they matured and were harvestable, though they had mixed views on whether CCs impacted
the quality of the cash crop. Subsidized, investing farmers were likely to be oriented towards the
benefits from the ecosystem services provided by CCs. Their experiences should be shared among
the farming community to support the large-scale implementation of CCs.
Keywords: cover crops; crop management; harvesting; investment; sowing; survey
1. Introduction
Cover crops (CCs) represent an important, though underutilized, potential to con-
tribute to the sustainability of agricultural systems by providing a high number of ecosys-
tem services [1–4]. Farmers’ adoption of CCs has not been primarily driven by the benefits
provided by CCs per se, and agricultural policy has been found to be the strongest determi-
nant of adoption rates and intensities in the European Union (EU) [5]. Adoption rates have
varied depending on the region and in general have been low in the EU. Interest towards
CCs has continued to grow in Finland since the first report highlighting such a trend [6]. In
addition to differences in existing subsidies available for farmers, regional differences in
farm adoption intensities [5] may be attributable to the lack of region-specific knowledge
and experiences of the cultivation of CCs, especially considering the local conditions and
challenges. This is not least because success in cultivation and the potential benefits of CCs
are highly dependent on conditions [7].
Recent research initiatives have expanded our understanding on the cultivation of CCs
depending on the region. Decision support systems have been developed to provide further
support for farmers [8–10]. Lamichhane and Alletto [11] published a research road map of
cover crops, in which they highlighted current knowledge gaps impeding the realization of
Agronomy 2023, 13, 499. https://doi.org/10.3390/agronomy13020499 https://www.mdpi.com/journal/agronomy
Agronomy 2023, 13, 499 2 of 16
potential ecosystem services which could be provided by CCs. Furthermore, they proposed
six research priorities to bridge the current knowledge gaps in defining, managing, and uti-
lizing CCs. Key reasons leading to the current gap include: (1) lack of appropriate selection
of CCs, poor seed quality, and limited market availability, (2) poor establishment quality
and insufficient biomass production of CCs, as well as (3) inappropriate or nonoptimal
management and utilization of CCs [11].
This study is part of a large farmer survey carried out in Finland with a focus on CCs,
that are usually sown in spring, but also in autumn, to provide an over-wintering green
biomass. We have concluded so far that farmers value various benefits provided by CCs for
the environment and production system [12]. Furthermore, farmers allocated CCs to field
parcels that were next to waterways, and conventional farmers allocated them on large
parcels with a history of cereal monoculture [13]. It was also found that farmers had gained
expertise with a surprisingly high number of CCs [14] when considering how the climate
in Finland, in general, limits crop production [15,16]. Conservation agriculture combines
zero tillage [17] with the use of CCs and diverse crop rotations. Such a combination is not,
however, common in Finland, where zero tillage is primarily used in fields with cereal
monocultures [18]. With this study we gathered experiences considering the potential
challenges faced by Finnish farmers considering impressions related to seed availability, the
establishment of CC-stands, and harvesting. Thereby, with this survey we aimed to gain
an understanding of the challenges farmers face in the cultivation of CCs, how they have
overcome these via basic management practices during the growing season, and whether
they have invested in special machinery and equipment to make the cultivation of CCs
more successful.
2. Materials and Methods
A farmer survey was carried out in Finland in spring 2021 with the aim to collect
hidden, up-to-date information about farmers’ views, experiences, and motives for culti-
vation of CCs to support transition towards extensive use. The sought set of respondents
were organic and conventional farmers who had applied for CC subsidy payments in 2020.
The subsidies were registered on the field parcel scale. In total, requested details of 7025
farms (16% of Finnish farms in 2021) were obtained from the registry of the Finnish Food
Authority (FFA). These included farm identification numbers, farm types, locations, and
the farmers’ email-addresses. A total of 6493 farmers were invited to participate in the
survey, and they were contacted by email. The number of invitees was less than the full list
of farms obtained from the FFA, because a farmer may own several farms (and only one
invitation was sent), and some of the farmers had no email address as contact information.
In total, 1130 farmers answered the survey, which corresponded to a 17.4% response rate.
The survey started on 16 March 2021 and ended on 11th April 2021. Both official
languages, Finnish and Swedish, were available for the participants to choose from. One
reminder message was sent on 30th March 2021. The questionnaire was large, and some
subject areas have already been published [12,13,19]. This paper is based on data gained
from 11 statements under the general question “What do you think about the following
statements concerning the cultivation of CCs?” and another eight statements under the
general question of “How do you act with CCs?”. The statements reported here concerned
potential down-to-earth challenges faced by farmers and measures concerning seed avail-
ability, sowing, harvesting, and quality impacts. The respondent farmers were also asked
about possible investments with the statement “I have invested in special machinery to
make cultivation of CCs more successful”. Furthermore, farmers were given an opportunity
to describe their investments (machine and/or reason) in their own words, and 435 farmers
(i.e., 39% of all respondents) used this opportunity. The survey respondents were requested
to answer all the questions in the survey to be able to return their answers. According
to the preliminary examination, the answers of all the 1130 respondents were considered
acceptable and were used for statistical analyses.
Agronomy 2023, 13, 499 3 of 16
The statistical analyses began by grouping the respondents according to: (1) the farm-
ing system (organic and conventional), (2) farm type [cereal, specialized crop production
(e.g., oilseed rape, grain legumes, caraway (Carum carvi L.), potatoes (Solanum tuberosum L.)
and sugar beet (Beta vulgaris var. altissima), horticulture, cattle, pig, poultry and horse/sheep
farm], (3) the farm size (<40, 40–79, 80–119 and ≥120 ha), (4) geographical region (South,
West, East/North Finland and the inland region), (5) the farmers’ ages (≤50 and >50 years),
(6) education (basic, vocational, college level and university education), (7) share of cereal
area on the farm (<25%, 25–50% and ≥50%), (8) share of grassland area on the farm (<25%,
25–50% and ≥50%), (9) share of area of other crops (e.g., potatoes and sugar beet) on the
farm (<25%, 25–50% and ≥50%), (10) share of special crop area (e.g., rapeseed and grain
legumes) on the farm (0%, <10% and ≥10%, and (11) the number of CC-species that the
farmer was experienced with (1–5, 6–10 and ≥11 CCs). The most common CCs used by
farmers were Italian ryegrass (Lolium multiflorum L.), timothy (Phleum pratense L.), white
clover (Trifolium repens L.), red clover (T. pratense L.), oats (Avena sativa L.) and meadow
fescue (Festuca pratensis L.) [14]. These were used as under-sown, catch, and break CCs to
provide an over-winter biomass that is preferably naturally terminated by harsh winter
conditions and if not, then mechanically. More details on the grouping and data sources
are available in [12]. Some non-response bias was found when the characteristics of the
respondents who returned the survey were compared to those of the non-respondents [12].
In such cases weights are used to bring the sample and the population more in line. This
‘non-response weighting’ was considered in the statistical analysis. However, such weights
were needed only for a few respondents and hence, the total effect remained marginal,
if any, and therefore this procedure was not used. A schematic presentation of the data
processing has been published [12]. A Cochran–Mantel–Haenszel test (CMH) was used
to test the relationship between the row and column variables. The row variables were
formed from 11 characteristics of the respondents and the column variables were the results
of the 20 statements with responses indicated on a 5-point Likert scale. The only exception
was the statement “I have invested in special machinery to make the cultivation of CCs
more successful” which used a 3-point Likert scale (“often”, “occasionally” or “seldom
or never”). Typically, both variables were ordinal scales and “the correlation statistic” of
the CMH with 1 degree of freedom was used. If a row variable was not an ordinal scale
(region and farm type), the ANOVA (Row Mean Scores, RMS) statistic for the CMH was
used. ANOVA (RMS) tests were used for all pairwise comparisons, as well as when testing
the interaction between the farming system and other characteristics of the respondents.
This study was focused on farmers with experience of CCs and hence, no control group of
unexperienced farmers was used. All CMH tests were performed using SAS/FREQ and
SAS/GLM procedures.
The number of CCs that a farmer experienced was defined as:
yi =
28
∑
k=1
Iij (1)
where i refers to the respondent (i = 1, . . . , N), while yi is a new variable that defines the
experience of a respondent i. The experience of each respondent is calculated based on
28 CC-species (k refers to a species, k = 1, . . . , 28) and yi is calculated as the sum of zeros
and ones so that the binary variable Iij is 1 if a respondent i has answered to have either
“somewhat”, “plenty” or “very much” experience with CC-species k. Otherwise, a zero
is added to the sum of the corresponding yi. For the statistical analysis, the number of
CCs that the farmers had experience with were classified into three groups (1–5, 6–10 and
≥11 CCs). After that, all statistical analyses were based on the CMH and ANOVA tests.
Agronomy 2023, 13, 499 4 of 16
3. Results
3.1. Farmers’ Views on Potential Weak Links in the Cultivation of CCs
Seventy-one per cent of farmers agreed that the availability of CC seeds was not a
bottleneck, whereas 13% of respondents experienced it as a problem (Figure 1). Farmers
with horticultural farms disagreed the most (Figure S1). On the other hand, 62% of farmers
considered that unconventional CC seeds were expensive compared to risk of failure, while
only 9% disagreed (Figure 1): aged farmers (>50 years) were slightly more concerned
(66% agreed) than younger ones (58%) (Figure 2). Forty-five per cent of the respondents
agreed and 27% disagreed that CC seeds were expensive compared to the benefits gained
from their cultivation. Especially farmers with <80 ha farm size found the seeds expensive
compared to the benefits (Figure 3), as did less educated farmers when compared to those
with a university degree (Figure 4).
Agronomy 2023, 13, x FOR PEER REVIEW 4 of 17 
 
 
3. Results 
3.1. Farmers’ Views on Potential Weak Links in the Cultivation of CCs 
Sev nty-one per ce t of farmers agreed that the availability of CC seeds was not a 
bottleneck, whereas 13% of respondents experienced it as a problem (Figure 1). Farmers 
with horticultural farms disagreed the most (Figure S1). On the other hand, 62% of farmers 
considered hat unconventional CC seeds were expe sive comp red to risk of failure, 
while only 9% disagreed (Figur  1): ag d farmers (>50 years) were slightly more 
concerne  (66% agreed) than younger ones ( 8%) (Figure 2). Fort -five per nt of the 
respond nts agreed a d 27% disagreed that CC seeds wer  expensive compared to the 
benefits gained from their cultivation. Especially farmers with <80 ha farm size found the 
seeds expensive compared to the benefits (Figure 3), as did less educated farmers when 
compared to those with a university degree (Figure 4). 
 
Figure 1. The distribution and mean (in order of decreasing value) of the farmers’ answers (N = 
1130) to the principal question: “What do you think about the following statements concerning the 
cultivation of cover crops (CCs)?”. The answer choices were: “1 = fully disagree, 2 = disagree, 3 = 
neither agree nor disagree, 4 = agree and 5 = fully agree”. The share of each answer choice (%) is 
shown within each bar. 
 
Figure 2. The distribution of farmers’ answers (N = 1130) depending on the farmer’s age (NZC, 
nonzero correlation; CCs, cover crops). The share of each answer choice (%) is shown within each 
bar. Means with the same letter do not differ significantly from each other (at p ≤ 0.05). 
Figure 1. The distribution and mean (in order of decreasing value) of the farmers’ answers (N = 1130)
to the principal question: “What do you think about the following statements concerning the
cultivation of cover crops (CCs)?”. The ans er choices were: “1 = fully disagree, 2 = disagree,
3 = neither agree nor disagree, 4 = agree an 5 f lly agree”. The share of each answer choice (%) is
ithin each bar.
Agronomy 2023, 13, x FOR PEER REVIEW 4 of 17 
 
 
3. Results 
3.1. Farmers’ Views on Potential Weak Links in the Cultivation of CCs 
Seventy-one per cent of farmers agreed that the availability of CC seeds was not a 
bottleneck, whereas 13% of respondents experienced it as a problem (Figure 1). Farmers 
with horticultural farms disagreed the most (Figure S1). On the other hand, 62% of farmers 
considered that unconventional CC seeds were expensive compared to risk of failure, 
while only 9% disagreed (Figure 1): aged farmers (>50 years) were slightly more 
concerned (66% agreed) than younger ones (58%) (Figure 2). Forty-five per cent of the 
respondents agreed and 27% disagreed that CC seeds were expensive compared to the 
benefits gained from their cultivation. Especially farmers with <80 ha farm size foun  the 
seeds expensive c mpared to the benefits (Figure 3), as did less educat  farmers when 
 t  thos  with a university egr e (Figure 4). 
 
i  . The distribution and mea  (in order of decreasing valu ) of the f rmers’ answers (N = 
1130) to the principal question: “What do you think about the following statements co cerning the 
cultivation of cover crops ( s)?”. The answer choices ere: “1 = fully disagree, 2 = disagree, 3 = 
neither agree nor disagree, 4 = agree and 5 = fully agree”. The share of each answer choice (%) is 
shown within each bar. 
 
Figure 2. The distribution of farmers’ answers (N = 1130) depending on the farmer’s age (NZC, 
nonzero correlation; CCs, cover crops). The share of each answer choice (%) is shown within each 
bar. Means with the same letter do not differ significantly from each other (at p ≤ 0.05). 
Figure 2. The distribution of farmers’ answers (N = 1130) depending on the farmer’s age (NZC,
nonzero correlation; CCs, cover crops). The share of each answer choice (%) is shown within each bar.
Means with the same letter do not differ significantly from each other (at p ≤ 0.05).
Agronomy 2023, 13, 499 5 of 16Agronomy 2023, 13, x FOR PEER REVIEW 5 of 17  
 
 
Figure 3. The distribution of farmers’ answers (N = 1130) depending on the farm size (RMSD, row 
mean scores difference; CCs, cover crops). 
 
Figure 4. The distribution of farmers’ answers (N = 1130) depending on the farmer’s education 
(NZC, nonzero correlation; CCs, cover crops). 
In addition, 60% of the respondents agreed and 16% disagreed that the sowing time 
was critical for success with CCs (Figure 1). This statement was supported more 
frequently in the case that farm was very large (66%) and located in South Finland (66%), 
it was in organic production (66%), it had a low area under grassland (65%) or a high area 
was used for special crops (66%), while less frequently in the case of horse/sheep, 
horticulture, and cattle farms (Figures 3, 5, 6 and S1‒S2). The sowing time was considered 
to determine whether CCs competed with the cash crop by 57% of respondents (Figure 1) 
and more frequently in the case of organic farmers (66%), while this was reported least 
often by horticulture farms (28%) (Figures 6 and S1). The failure of CCs was agreed to be 
attributable to overly deep sowing by 51% of respondents (Figure 1), and more so by aged 
farmers and those with less education or those who had small farms (Figures 2‒4). 
Furthermore, farmers who did not cultivate special crops tended to agree more frequently 
with this statement (Figure S2). However, the farming system × special crop area 
interaction was significant (p-value 0.041) and only the answers from organic farmers 
differed (p-value 0.004) depending on the special crop area: organic farmers agreed less 
often that failure was attributable to deep sowing in the case that they had higher field 
areas under special crops (data no shown). Farmers agreed least often (34% agreed, 40% 
disagreed) of all with the statements that the seeds of CCs should be sown after the cash 
Figure 3. The distribution of farmers’ answers (N = 1130) depending on the farm size (RMSD, row
mean scores difference; CCs, cover crops).
Agronomy 2023, 13, x FOR PEER REVIEW 5 of 17 
 
 
 
Figure 3. The distribution of farmers’ answers (N = 1130) depending on the farm size (RMSD, row 
mean scores difference; CCs, cover crops). 
 
Figure 4. The distribution of farmers’ answers (N = 1130) depending on the farmer’s education 
(NZC, nonzero correlation; CCs, cover crops). 
In addition, 60% of the respondents agreed and 16% disagreed that the sowing time 
was critical for success with CCs (Figure 1). This statement was supported more 
frequently in the case that farm was very large (66%) and located in South Finland (66%), 
it was in organic production (66%), it had a low area under grassland (65%) or a high area 
was used for special crops (66%), while less frequently in the case of horse/sheep, 
horticulture, and cattle farms (Figures 3, 5, 6 and S1‒S2). The sowing time was considered 
to determine whether CCs competed with the cash crop by 57% of respondents (Figure 1) 
and more frequently in the case of organic farmers (66%), while this was reported least 
often by horticulture farms (28%) (Figures 6 and S1). The failure of CCs was agreed to be 
attributable to overly deep sowing by 51% of respondents (Figure 1), and more so by aged 
farmers and those with less education or those who had small farms (Figures 2‒4). 
Furthermore, farmers who did not cultivate special crops tended to agree more frequently 
with this statement (Figure S2). However, the farming system × special crop area 
interaction was significant (p-value 0.041) and only the answers from organic farmers 
differed (p-value 0.004) depending on the special crop area: organic farmers agreed less 
often that failure was attributable to deep sowing in the case that they had higher field 
areas under special crops (data no shown). Farmers agreed least often (34% agreed, 40% 
disagreed) of all with the statements that the seeds of CCs should be sown after the cash 
Figure 4. The distribution of farmers’ answers (N = 1130) depending on the farmer’s education (NZC,
nonzero correlation; CCs, cover crops).
In addition, 60% of the respondents agreed and 16% disagreed that the sowing time
was critical for success with CCs (Figure 1). This statement was supported more frequently
in the case that farm wa very large (66%) and located in South Finland (66%), it was in
organic production (66%), it had a low area und r grassl (65%) or a high area w s used
for special crops (66%), while less frequently in the case of horse/sheep, horticulture, and
c ttle farms (Figures 3, 5, 6, S1 and S2). The sowing time was considered t determine
whether CCs competed with the cash crop by 57% of respondents (Figure 1) and more
frequently in the case of organic farmers (66%), while this was reported least often by
horticulture farms (28%) (Figure 6 and S1). The failure of CCs was agreed to be attributable
to overly deep sowing by 51% of respondents (Figure 1), and more so by aged farmers
nd those with less education or those who had mall farms (Figures 2–4). Furthermore,
f r ers who did not cultivate speci l crops tended to agree more frequently with this
statement (Figure S2). However, the farming system × special crop area interaction was
significant (p-value 0.041) and only the answers from organic farmers differed (p-value
0.004) depending on the special crop area: organic farmers agreed less often that failure
was attributable to deep sowing in the case that they had higher field areas under special
crops ( ata no shown). Farmers agreed least often (34% agreed, 40% disagreed) of all with
th statements that the seeds of CCs should be sow after the h crop but before seedling
Agronomy 2023, 13, 499 6 of 16
emergence (Figure 1). Conventional farmers agreed less frequently (31%) than organic
producers (43%) on this topic (Figure 6).
Agronomy 2023, 13, x FOR PEER REVIEW 6 of 17 
 
 
crop but before seedling emergence (Figure 1). Conventional farmers agreed less 
frequently (31%) than organic producers (43%) on this topic (Figure 6). 
 
Figure 5. The distribution of farmers’ answers (N = 1130) depending on the region in Finland 
(RMSD, row mean scores difference; CCs, cover crops). 
 
Figure 6. The distribution of farmers’ answers (N = 1130) depending on the farming system (NZC, 
nonzero correlation; CCs, cover crops). 
With regards to whether the early harvesting of cash crops ensures that CCs do not 
hamper the harvest, 58% of respondents agreed and only 14% disagreed (Figure 1). 
Farmers in East/North Finland agreed more frequently than those in South Finland 
(Figure 5). Furthermore, 35% of farmers agreed and another 35% disagreed that CCs 
delayed the harvest (Figure 1). Farmers with experience of growing special crops agreed 
less frequently (Figure S2) as did those with a higher education (Figure 4). 
In terms of whether CCs had no impact, negative or positive, on the quality of the 
cash crop, 38% of respondents agreed (31% disagreed) (Figure 1). Furthermore, 69% of 
farmers agreed that CCs had impacts on quality only if they grow above the cash crop: 
farmers in East/North Finland agreed more frequently than those in South Finland (Figure 
5). Older and less educated farmers agreed more frequently on these statements on the 
CCs’ quality impacts than younger and university educated farmers did (Figures 2 and 
4). 
3.2. Farmers’ Cultivation Practices with CCs 
The most common CCs used by farmers were Italian ryegrass, timothy, white clover, 
red clover, oats, and meadow fescue. As these are very common species in Finland, the 
vast majority of farmers neither produce farm-saved CC seeds or purchase them from 
i re 5. The distribution of farmers’ answers (N = 1130) depending on the region in Finland (RMSD,
row mean scores difference; CCs, cover crops).
Agronomy 2023, 13, x FOR PEER REVIEW 6 of 17 
 
 
crop but before seedling emergence (Figure 1). Conventional farmers agreed less 
frequently (31%) than organic producers (43%) on this topic (Figure 6). 
 
Figure 5. The distribution of farmers’ answers (N = 1130) depending on the region in Finland 
(RMSD, row mean scores difference; CCs, cover crops). 
 
Figure 6. The distribution of farmers’ answers (N = 1130) depending on the farming system (NZC, 
nonzero correlation; CCs, cover crops). 
With regards to whether the early harvesting of cash crops ensures that CCs do not 
hamper the harvest, 58% of respondents agreed and only 14% disagreed (Figure 1). 
Farmers in East/North Finland agreed more frequently than those in South Finland 
(Figure 5). Furthermore, 35% of farmers agreed and another 35% disagreed that CCs 
delayed the harvest (Figure 1). Farmers with experience of growing special crops agreed 
less frequently (Figure S2) as did those with a higher education (Figure 4). 
In terms of whether CCs had no impact, negative or positive, on the quality of the 
cash crop, 38% of respondents agreed (31% disagreed) (Figure 1). Furthermore, 69% of 
farmers agreed that CCs had impacts on quality only if they grow above the cash crop: 
farmers in East/North Finland agreed more frequently than those in South Finland (Figure 
5). Older and less educated farmers agreed more frequently on these statements on the 
CCs’ quality impacts than younger and university educated farmers did (Figures 2 and 
4). 
3.2. Farmers’ Cultivation Practices with CCs 
The most common CCs used by farmers were Italian ryegrass, timothy, white clover, 
red clover, oats, and meadow fescue. As these are very common species in Finland, the 
vast majority of farmers neither produce farm-saved CC seeds or purchase them from 
Figure 6. The distribution of farmers’ answers (N = 1130) depending on the farming system (NZC,
nonzero correlation; CCs, cover crops).
With regards to whether the early harvesting of cash crops ensures that CCs do not
hamper t e harvest, 58% of respondents agreed and only 14% disagre d (Figure 1). Farmers
in East/North Finland agreed more frequently than those in South Finland (Figure 5).
Furthermore, 35% of farmers agreed and another 35% disagreed that CCs delayed the
harvest (Figure 1). Farmers with experience of rowing special crops agreed less frequently
(Figure S2) as did those with a higher education (Figure 4).
In terms of wheth r CCs had no impact, negative or positive, on the quality of the cash
crop, 38% of respondents agreed (31% disagreed) (Figure 1). Furthermore, 69% of farmers
agreed that CCs had impacts on quality only if they grow above the cash crop: farmers in
East/North Finland agreed more frequently than those in South Finland (Figure 5). Older
and less educated farmers agreed more frequently on these statements on the CCs’ quality
impacts than younger and university educated farmers did (Figures 2 and 4).
3.2. Farmers’ Cultivation Practices with CCs
The most common CCs used by farmers were Italian ryegrass, timothy, white clover,
red clover, oats, and meadow fescue. As these are very common species in Finland, the
vast majo ity of farmers neither produce farm-saved CC seeds or purchase them from
abroad (82% and 89% answered seldom/never, respectively) (Figure 7). Some farmers
Agronomy 2023, 13, 499 7 of 16
had experience with special CCs such as lucerne (Medicago sativa L.), phacelia (Phacelia
tanacetifolia L.), sweet clover (Melilotus alba L.), crimson clover (T. incarnatum L.), common
bird’s-foot trefoil (Lotus corniculatus L.), black medick (M. lupulina L.), and sickle medick
(M. falcata L.) [14]. Hence, the respondents who reported that they purchased CC seeds
often or always from abroad (3% of respondents) or did so occasionally (8%) were likely
those having rarely used CCs. On the other hand, 3% always produced farm-saved seeds,
6% did so often and 9% occasionally. Seeds were imported slightly more frequently in
the case that the farm had ≥80 ha field area, it was located in South Finland, it was in
organic production (Figures 8–10), the cereal area was low, other crop areas high and/or
the farmer was experienced with special crops (Figures S3–S5), the farmer was ≤50 years
old and highly educated (Figures S6 and S7) and he/she cultivated a high number (≥11) of
CC-species (Figure 11). Findings on differences between farm and farmer characteristic
were often parallel with import and on-farm production of CC seeds. In addition, cereal
farms produced farm-saved seeds of CCs more often than cattle farms (Figure S8).
Agronomy 2023, 13, x FOR PEER REVIEW 7 of 17 
 
 
abroad (82% and 89% answered seldom/never, respectively) (Figure 7). Some farmers had 
experience with special CCs such as lucerne (Medicago sativa L.), phacelia (Phacelia 
tanacetifolia L.), sweet clover (Melilotus alba L.), crimson clover (T. incarnatum L.), common 
bird’s-foot trefoil (Lotus corniculatus L.), black medick (M. lupulina L.), and sickle medick 
(M. falcata L.) [14]. Hence, the respondents who reported that they purchased CC seeds 
often or always from abroad (3% of respondents) or did so occasionally (8%) were likely 
those having rarely used CCs. On the other hand, 3% always produced farm-saved seeds, 
6% did so often and 9% occasionally. Seeds were imported slightly more frequently in the 
case that the farm had ≥80 ha field area, it was located in South Finland, it was in organic 
production (Figures 8–10), the cereal area was low, other crop areas high /or the farmer 
was experien ed with special crops (Figures S3‒S5), the farmer w s ≤50 years old and 
highly educated (Figures S6‒S7) and he/she cultivated a high number (≥11) of CC-species 
(Figure 11). Fin ings on diff rences between farm and farmer characteristic were often 
parallel with import and on-farm production of CC seeds. In addition, cereal farms 
produced farm-saved seeds of CCs more often than cattle farms (Figure S8). 
 
Figure 7. The distribution and mean (in order of decreasing value) of the farmers’ answers (N = 
1130) to the principal question: “How often do you act with cover crops (CCs)?”. The answer choices 
were: “1 = never, 2 = seldom, 3 = occasionally, 4 = often and 5 = always”. The share of each answer 
choice (%) is shown within each bar unless it was <3%. 
 
Figure 8. The distribution of farmers’ answers (N = 1130) depending on the farm size (RMSD, row 
mean scores difference; CCs, cover crops). 
Figure 7. The distribution and mean (in order of decreasing value) of the farmers’ answers (N = 1130)
to the principal question: “How often do you act with cover crops (CCs)?”. The answer choices were:
“1 = never, 2 = seldom, 3 = occasionally, 4 = often and 5 = always”. The share of eac answer choice
(%) is shown within each bar unless it was <3%.
Agronomy 2023, 13, x FOR PEER REVIEW 7 of 17 
 
 
abroad (82% and 89% answered seldom/never, respectively) (Figure 7). Some farmers had 
experience with special CCs such as lucerne (Medicago sativa L.), phacelia (Phacelia 
tanacetifolia L.), sweet clover (Melilotus alba L.), crimson clover (T. incarnatum L.), common 
bir ’s-foot trefoil (Lotus orniculat s L.), black medick (M. lupulina L.), nd sickle medick 
(M. falcata L.) [14]. Hence, the respondents who reported that they p rchased CC seeds 
often or always from abroad (3% of respondents) or did so occasionally (8%) were likely 
those having rarely used CCs. On the other hand, 3% always produced farm-saved seeds, 
6% did so often and 9% occasionally. Seeds were imported slightly more frequently in the 
case that the farm had ≥80 ha field area, it was located in South Finland, it was in organic 
production (Figures 8–10), the cereal area was low, other crop areas high and/or the farmer 
was experienced with special crops (Figures S3‒S5), the farmer was ≤50 years old and 
highly educated (Figures S6‒S7) and he/she cultivated a high number (≥11) of CC-species 
(Figure 11). Findings on differences between farm and farmer characteristic were often 
parallel with import and on-farm production of CC seeds. In addition, cereal farms 
produced farm-saved seeds of CCs more often than cattle farms (Figure S8). 
 
Figure 7. The distribution and mean (in order of decreasing value) of the farmers’ answers (N = 
1130) to the principal question: “How often do you act with cover crops (CCs)?”. The answer choices 
were: “1 = never, 2 = seldom, 3 = occasionally, 4 = often and 5 = always”. The share of each answer 
choice (%) is shown within each bar unless it was <3%. 
 
Figure 8. The distribution of farmers’ answers (N = 1130) depending on the farm size (RMSD, row 
mean scores difference; CCs, cover crops). 
Figure 8. The distribution of farmers’ answers (N = 1130) depending on the farm size (RMSD, row
mean scores difference; CCs, cover crops).
Agronomy 2023, 13, 499 8 of 16Agronomy 2023, 13, x FOR PEER REVIEW 8 of 17  
 
 
Figure 9. The distribution of farmers’ answers (N = 1130) depending on the region in Finland 
(RMSD, row mean scores difference; CCs, cover crops). 
 
Figure 10. The distribution of farmers’ answers (N = 1130) depending on the farming system (NZC, 
nonzero correlation; CCs, cover crops). 
Only 8% of farmers answered that they never checked the sowing density of CCs 
beforehand and 13% made a test run seldom, while 56% checked it always or often (Figure 
7). No differences were found between farm and farmers characteristics except for farmers 
who had experience of a higher number of CCs (≥11) checked the sowing density more 
frequently that those with 1‒5 CC species (Figure 11). Farmers who checked the sowing 
density of CCs more frequently agreed more often that the sowing time of CCs was critical 
for success, and it determines whether CCs compete with cash crops, and that the failure 
of CCs was most often attributable to deep sowing (Figure S9). 
The majority of farmers adjusted their fertilizer use according to the cash crop 
without considering the requirements or impacts of the CC on the cash crop nutrition: 
46% of respondents did so always and 32% often (Figure 7). The respondent farmers 
agreed with this statement more frequently in the case of ≥40 ha farm size (Figure 8), they 
were conventional producers (Figure 10), they had a cattle or pig farm (Figure S8), they 
had a low area of grassland or other crops, while they had a high area of cereals on the 
farm (Figures S3, S5 and S10), they were experienced with a lower number of CC species 
(Figure 11), and they had a higher than basic education (Figure S7). The farming system × 
farm size interaction was significant (p-value 0.038) for the statement on fertilizer use: 
conventional farmers did not differ depending on the farm size (p-value 0.237) in contrast 
Figure 9. The distribution of farmers’ answers (N = 1130) depending on the region in Finland (RMSD,
row mean scores difference; CCs, cover crops).
Agronomy 2023, 13, x FOR PEER REVIEW 8 of 17 
 
 
 
Figure 9. The distribution of farmers’ answers (N = 1130) depending on the region in Finland 
(RMSD, row mean scores difference; CCs, cover crops). 
 
Figure 10. The distribution of farmers’ answers (N = 1130) depending on the farming system (NZC, 
nonzero correlation; CCs, cover crops). 
Only 8% of farmers answered that they never checked the sowing density of CCs 
beforehand and 13% made a test run seldom, while 56% checked it always or often (Figure 
7). No differences were found between farm and farmers characteristics except for farmers 
who had experience of a higher number of CCs (≥11) checked the sowing density more 
frequently that those with 1‒5 CC species (Figure 11). Farmers who checked the sowing 
density of CCs more frequently agreed more often that the sowing time of CCs was critical 
for success, and it determines whether CCs compete with cash crops, and that the failure 
of CCs was most often attributable to deep sowing (Figure S9). 
The majority of farmers adjusted their fertilizer use according to the cash crop 
without considering the requirements or impacts of the CC on the cash crop nutrition: 
46% of respondents did so always and 32% often (Figure 7). The respondent farmers 
agreed with this statement more frequently in the case of ≥40 ha farm size (Figure 8), they 
were conventional producers (Figure 10), they had a cattle or pig farm (Figure S8), they 
had a low area of grassland or other crops, while they had a high area of cereals on the 
farm (Figures S3, S5 and S10), they were experienced with a lower number of CC species 
(Figure 11), and they had a higher than basic education (Figure S7). The farming system × 
farm size interaction was significant (p-value 0.038) for the statement on fertilizer use: 
conventional farmers did not differ depending on the farm size (p-value 0.237) in contrast 
Figure 10. The distribution of farmers’ answers (N = 1130) depending on the farming system (NZC,
nonzero correlation; CCs, cover crops).
Only 8% of farmers answered that they never checked the sowing density of CCs
beforehand and 13% ade a test run seldom, while 56% checked it always or often (Figure 7).
No differences were found between farm and farm rs characterist cs except for armers
who had experi nce of a higher number of CCs (≥11) checked the sowing density mo e
frequently that thos with 1–5 CC species (Figure 11). Farmers who checked the sowing
density of CCs more frequently agreed more often that the sowing time of CCs was critical
for success, and it determines whether CCs compete with cash crops, and that the failure of
CCs was most often attributable to deep sowing (Figure S9).
The majority farmers adjusted their fertilizer use according to the cash crop without
considering the requirements or impacts of the CC on the cash crop utrition: 46% of
resp ndents did so always and 32% often (Figure 7). The respondent farmers agreed
with this statement more frequently in the case of ≥40 ha farm size (Figure 8), they were
conventional producers (Figure 10), they had a cattle or pig farm (Figure S8), they had
a low area of grassland or other crops, while they had a high area of cereals on the
farm (Figures S3, S5 and S10), they were experienced with a lower number of CC species
(Figure 11), and they had a higher than basic education (Figure S7). The farming system
× farm size interaction was significant (p-value 0.038) for t e stateme t on fertilizer use:
Agronomy 2023, 13, 499 9 of 16
conventional farmers did not differ depending on the farm size (p-value 0.237) in contrast
to organic farmers (p-value < 0.001) who agreed more frequently that they applied fertilizer
according to the cash crop only in the case of a higher farm size (data not shown).
Figure 7 shows that 93% of farmers harvested cash crops as soon as they matured and
were harvestable. Despite a high total share of always- (63%) and often-answers (30%),
the share was higher when the farmer had a very large farm rather than a small farm
(Figure 8), and in the case of a high area allocated to cereals, while a low area allocated
to grassland and other crops (Figures S3–S5 and S10). The farmers’ readiness to harvest
cash crop as soon as possible differed significantly between the following farm types: in
descending order of cereal farms→ special crop and cattle farms→ horticulture farms
(Figure S8). Most farmers acknowledged CCs during harvest: 64% of respondents answered
that they harvested cash crops always or often at a high stubble height to avoid damage to
CCs, and 45% of famers said they took measures to avoid cash crop residues suppressing
CCs (Figure 7). High stubble was more frequently used during harvesting by organic
than conventional producers, farmers who had cereal farms than those with special crops,
horticulture, and pig farms, farmers who were experienced with a higher number of CCs,
were less educated and >50 years old (Figures 10, 11 and S6–S8). Farmers who were organic
producers, had a higher share of grassland area, no expertise in cultivation of special crops,
expertise with higher number of CC-species, and who were >50 years old and less educated
applied measures more frequently to avoid the suppression of CC growth caused by cash
crop residues (Figures 10, 11, S4, S6, S7 and S10).
Agronomy 2023, 13, x FOR PEER REVIEW 9 of 17 
 
 
to organic farmers (p-value < 0.001) who agreed more frequently that they applied 
fertilizer according to the cash crop only in the case of a higher farm size (data not shown). 
Figure 7 show  that 93% of farmers harvest d cash cro s s soon as they m tured 
and were harvestable. Despite a high total share of always- (63%) and often-answers 
(30%), the share was higher when the farmer had a very large farm rather than a small 
farm (Figure 8), and in the case of a high area allocated to cereals, while a low area 
allocated to grassland and other crops (Figures S3‒S5 and S10). The farmers’ readiness to 
harvest cash crop as soon as possible differed significantly between the following farm 
types: in descending order of cereal farms  special crop and cattle farms  horticulture 
farms (Figure S8). Most farmers acknowledged CCs during harvest: 64% of respondents 
answered that they harvested cash crops always or often at a high stubble height to avoid 
damage to CCs, and 45% of famers said they took measures to avoid cash crop residues 
suppressing CCs (Figure 7). High stubble was more frequently used during harvesting by 
organic than conventional producers, f rm rs wh  had ce eal farms than those with 
special crops, horticulture, and pig farms, farmers who were experienced with  higher 
number of CCs, we e less educat d and >50 years old (Figures 10, 11 and S6‒S8). Farmers 
who were organic producers, had a higher share of grassland area, no experti e in 
cultivation of special crops, expertise with higher number of CC-species, and who were 
>50 years old and less educated applied measures more frequently to avoid the 
suppression of CC growth caused by cash crop residues (Figures 10, 11, S4, S6, S7, and 
S10). 
 
Figure 11. The distribution of farmers’ answers (N = 1130) depending on the number of cultivated 
cover crops (CCs) on the farm (NZC, nonzero correlation). 
3.3. Farmers’ Investments in Special Machinery and Equipment 
When the respondent farmers were asked if they had invested in special machinery 
or equipment to make the cultivation of CCs more successful, 29% answered that they had 
done so often, 15% occasionally, while 56% reported they had done so seldom/never 
(Figure 12). Farmers who were experienced in cultivating a higher number of CC species 
had made more investments as had those with farms in South Finland. Farmers had 
invested more frequently also in the case of a larger farm size and lower share of field area 
Figure 11. The distribution of farmers’ answers (N = 1130) depending on the number of cultivated
cover crops (CCs) on the farm (NZC, nonzero correlation).
3.3. Farmers’ Investments in Special Machinery and Equipment
When the respondent farmers were asked if they had invested in special machinery
or equipment to make the cultivation of CCs more successful, 29% answered that they
had done so often, 15% occasionally, while 56% reported they had done so sel om/never
(Figure 12). Farmers who were experienc d in cultivating a igher number of CC species
had made more investments as had those w th farms i South Finland. Farmers had
invested more f quently also in the case of a larger farm size and lower sh re of field area
Agronomy 2023, 13, 499 10 of 16
allocated as grassland. Organic producers, farmers with experience in the cultivation of
special crops, and those who were more educated and ≤50 years old tended to invest more.
Considering the farm types, horticulture and cattle farms invested least often contrary to
poultry, pig, cereal, and special crop farms (in descending order).
In addition, 44% of respondents had invested in special machinery or equipment often
or occasionally (Figure 12) and 39% of all respondents provided free-word specifications
(i.e., 89% of those who invested). The majority of the investments were made to improve
the success of sowing. Most often (≥29% of those who had invested) farmers reported that
they had purchased a sowing unit for small seeds that was used to enable the simultaneous
sowing of CCs with a cash crop, and to enable better conditions for CC germination and
seedling emergence (Figure 13). In general, farmers who had higher shares of grasslands
tended to invest less frequently than those with cereals and other seed crops (data not
shown). Farmers had also invested in seed spreaders (21%) that were used ahead or behind
the tractor and/or accomplished with some other field machine or even a quad bike. In
addition, 11% of the farmers who had made investments had purchased a harrow with
a sowing unit and 8% a new sowing machine with sowing facilities also for small seeds.
Other machines/equipment with more than 10 mentions included weed harrows (5%),
choppers (4%), direct drills (3%) and chaff spreaders (2%). The rest of the investments (5%)
included: rollers, rollers with sowing units, mowers, cultivators, baling machines, steering
assistance (GPS guidance), and subsoilers.
Agronomy 2023, 13, x FOR PEER REVIEW 10 of 17 
 
 
allocated as grassland. Organic producers, farmers with experience in the cultivation of 
special crops, and those who were more educated and ≤50 years old tended to invest more. 
Considering the farm types, horticulture and cattle farms invested least often contrary to 
poultry, pig, cereal, and special crop farms (in descending order). 
In addition, 44% of respondents had invested in special machinery or equipment 
often or occasionally (Figure 12) and 39% of all respondents provided free-word 
specifications (i.e., 89% of those who invested). The majority of the investments were 
made to improve the success of sowing. Most often (≥29% of those who had invested) 
farmers reported that they had purchased a sowing unit for small seeds that was used to 
enable the simultaneous sowing of CCs with a cash crop, and to enable better conditions 
for CC germination and seedling emergence (Figure 13). In general, farmers who had 
higher shar s of grasslands tended to invest l s  frequently t an t ose with cereals and 
other seed crops (data not shown). Farmers had also invested in se d sp eaders (21%) that 
were used ah ad or behind the tractor and/or accomplished with some other field machine 
or even a quad bike. In addition, 11% of the farmers w o had made investm nts had 
purchased a harrow with a sowing unit and 8% a new sowing machine with sowing 
facilities also for small seeds. Other machines/equipment with more than 10 mentions 
included weed harrows (5%), choppers (4%), direct drills (3%) and chaff spreaders (2%). 
The rest of the investments (5%) included: rollers, rollers with sowing units, mowers, 
cultivators, baling machines, steering assistance (GPS guidance), and subsoilers. 
 
Figure 12. The distribution and means of farmers’ answers to the statement: “I have invested in 
special machinery to make the cultivation of CCs more successful”, (N = 1130) depending on farm 
and farmer characteristics (CCs, cover crops). 
Figure 12. The distribution and means of farmers’ answers to the statement: “I have invested in
special machinery to make the cultivation of CCs more successful”, (N = 1130) depending on farm
and far er characteristics (CCs, cover crops).
Agronomy 2023, 13, 499 11 of 16Agronomy 2023, 13, x FOR PEER REVIEW 11 of 17 
 
 
 
Figure 13. On the left, the share of machines and equipment (%) that farmers had invested in 
according to their free-word answers: 435 responses (corresponding to 39% of all respondents) with 
information on 461 investments. On the right, reasons given by farmers for the three most common 
investment. 
4. Discussion 
The cash crop is “the master” of a field parcel as it provides immediate income for 
the farmer, while CCs are more like “a farmhand” providing ecosystem services but 
requiring additional care and costs [20]. Many responding farmers considered CCs during 
the growing season (Figure 7). Many of them had also recognized or were at least aware 
[12] of the various ecosystem services provided by CCs [7,21]. On the other hand, the other 
end of the farmer community was represented by those who said that they considered 
CCs to be trivial as such, but “money talks”, i.e., the subsidies encouraged the cultivation 
of CCs. This is understandable because a 100 € subsidy per hectare to support the 
cultivation of CCs is significant for Finnish farms, many of which are facing a profitability 
crisis [22]. The policy is indeed an important driver for the adoption of CCs in Europe, 
where the adoption intensity is in general low, though it ranges depending on the region 
[5]. Especially the requirements of the Nitrates Directive were found to encourage farmers 
to grow CCs in nitrate vulnerable zones [23]. Many non-adopters might become adopters 
in the case of stronger policy obligations or additional subsidies [5]. However, it is 
essential that the cultivation of CCs is not merely a “cosmetic” measure for a farmer just 
to acquire subsidies, but a cost-effective and target-oriented measure, and these call for 
farmers’ commitment. 
In 2021, when this farmer survey was carried out, the CC adoption intensity was 16% 
of Finnish farms. The respondents corresponded to 17.4% of all adopters, and they often 
took under-sown CCs into account during the growing season—and not only after 
harvest, when the land is completely at the CCs’ disposal. This indicates some 
commitment to redeem expected benefits provided by the adoption of CCs for the 
production system per se [12], even though Kathage et al. [5] found that any agronomic 
motive was a much weaker driver for adoption of CCs than policies to encourage their 
use. 
  
Figure 13. On the left, the share of machines and equipment (%) that farmers had invested in
according to their free-word answers: 435 responses (corresponding to 39% of all respondents)
with information on 461 investments. On the right, reasons given by farmers for the three most
common investment.
4. Discussion
The cash crop is “the master” of a field parcel as it provides immediate income for the
farmer, while CCs are mor like “a farmhand” providing ecosystem services but requiring
additional care and costs [20]. Many responding farmers considered CCs during the
growing season (Figure 7). Many of them had also recognized or were at least aware [12] of
the various ecosystem services provided by CCs [7,21]. On the other hand, the other end
of the farmer community was represented by those who said that they considered CCs to
be trivial as such, but “money talks”, i.e., the subsidies encouraged the cultivation of CCs.
This is understandable because a 100 € subsidy per hectare to support the cultivation of
CCs is significant for Finnish farms, many of which are facing a profitability crisis [22]. The
policy is indeed an important driver for the adoption of CCs in Europe, where the adoption
intensity is in general low, though it ranges depending on the region [5]. Especially the
requirements of the Nitrates Directive were found to encourage farmers to grow CCs in
nitrate vulnerable zones [23]. Many non-adopters might become adopters in the case of
stronger policy obligations or additional subsidies [5]. However, it is essential that the
cultivation of CCs is not mer ly a “cosm tic” measure for a farmer just to acquire subsi ies,
bu a cost- ffective a d target-oriented measure, an these call for farmers’ commitm nt.
In 2021, when th s farmer survey was car ied out, the CC adoption intensity was
16% of Finnish farms. The respondents corresponded to 17.4% of all adopters, and they
often took under-sown CCs into account during the growing season—and not only after
harvest, when the land is completely at the CCs’ disposal. This indicates some commitment
to redeem expected benefits provided by the adoption of CCs for the production system
per se [12], even though Kathage et al. [5] found that any agronomic motive was a much
weaker driver for adoption of CCs than policies to encourage their use.
4.1. Farmers Acknowledged CCs in Sowing but Not in Fertilizer Use
Farmers sow CCs simultaneously or right after planting of the cash crop, and they took
additional measures to enhance the establishment of CC under a cash crop. For example, the
majority and especially those familiar with a high number of CCs, checked that the actual
Agronomy 2023, 13, 499 12 of 16
seeding rate corresponded to the planned density (Figures 7–11), while 8% of farmers never
checked this, and 13% did so seldom. An adequate seed rate and careful establishment
are prerequisites for the successful cultivation of CCs [24], but farmers may save costs by
using low seed rates, which again may lead to sparse and uneven CC stands. Another
measure to better ensure the success with cultivation of CCs was that as many as 44% of
the respondents had made investments in machinery and equipment, from which 39%
gave free-word specifications. Farmers with the propensity to invest were characterized as:
educated, ≤50 years old, experienced with many CC species, having a large farm, a farm
in South Finland, being an organic producer, and either having a poultry, pig, cereal, or
special crop farm (Figure 12). Most frequently (≥29%) farmers had purchased an additional
seed-box used for the drill of small CC seeds simultaneously with a cash crop (Figure 13).
They argued this was to provide better conditions for CCs to germinate and emerge, and to
reduce field traffic. The simultaneous drilling of CCs with a cash crop also partly explains
why the most disagreed statement was that CC seeds should be sown after the cash crop
but before seedling emergence (Figure 1). On the whole, equipment that facilitated the
sowing of CC seeds was among the most popular investments, including seed spreaders for
broadcast-planting (21% of invested farmers) which are used ahead or behind a tractor or a
quad bike, harrows with a sowing unit (11%), and new sowing machines suitable for small
seeds (8%). Drill- and broadcast-planting methods differ considering germination, plant
stand establishment, growth, and biomass production of CCs [24,25], and thereby affecting
the CCs’ capacity to suppress weeds, scavenge nutrients, and control erosion [2,26–29].
Even though seed drilling provides better seed-to-soil contact and broadcast seeding may
require higher seeding rate to compensate for the lower germination rate, success with
either method is dependent on the CC-species and growing conditions [24]. In this study,
farmers who invested in a seed spreader appreciated its multi-functionality and flexibility,
e.g., the timing of CC sowing, as did farmers who invested in harrows with a sowing unit
(Figure 13).
The majority (60%) of respondents agreed that the sowing time is critical for success
with CCs (Figure 1). The respondents agreed with this statement more frequently in the
case that the farm was very large and in South Finland (Figures 8 and 9). The time frame
for optimal sowing is often limited in South-West Finland, where clay soils dominate, and
the upper soil layer may dry fast due to low precipitation [30]. Hence, farmers with large
field areas may face challenges with optimized sowing times especially for small-seeded
CCs, while the seeds of the cash crops are usually larger and sown deeper. On the other
hand, half of the farmers agreed that failure with CCs may as well be attributable to overly
deep sowing (Figure 1). The challenge of sowing CCs was emphasized for broadcast-
planting: farmers who specified their investments often highlighted that they used a seed
spreader earlier but were dissatisfied with the uneven establishment of CCs and bought a
sowing unit that enables the mulching of the small seeds (Figure 13). Organic producers
were in general more concerned than conventional farmers about the criticality of the
sowing time for success with CCs (Figure 6), which is most likely to be attributable to a
higher dependency and the provision of ecosystem services [31]. It was agreed by 57% of
respondents that the sowing time determines whether CCs compete with the cash crop
(Figure 1). This may happen especially in the case of failures with cash crop sowing and
establishment [32], e.g., due to harmful weather events [16], poorly germinating farm-saved
seeds [33] or use of an aggressively growing CC-species like sweet clover [14].
The availability of seeds was not experienced as a problem (Figure 1) and most farmers
neither produced farm-saved seeds for CCs (82%) nor purchased them from abroad (89%)
(Figure 7). Experience with a high number (≥11) of CC species tended to increase the
farmers’ interest in importing seeds (Figure 11)—which is likely to be those with minor
cultivation areas so far in Finland [14]. Moreover, 62% of farmers considered that seeds for
unconventional CCs were expensive considering the risk of failure (Figure 1). Furthermore,
45% agreed—especially those with small or medium size farms (Figure 3)—that CC seeds
Agronomy 2023, 13, 499 13 of 16
are expensive compared to the benefits gained from their cultivation. Younger and/or more
educated farmers tended to be less concerned about the price of CC seeds (Figures 2 and 4).
The majority of Finnish farmers adjusted their fertilizer use according to the cash crop
only (46% always, 32% often) without considering the requirements of CCs or impacts
of the CC on cash crop nutrition (Figure 7). Hence, CCs were not seen to compete for
nutrients with a cash crop. In fact, CCs often reduce the reliance on N fertilizers in cropping
systems [3,34]. Another farmer survey carried out in four EU-countries revealed that
improved N use per se was hardly ever (≤2.7%) the primary reason for adopting CCs [5],
even though CCs reduced nitrate leaching by 69% globally [4]. In Finland, organic farmers
acknowledged the contribution of CCs to fertilizer use more often than conventional
producers (Figure 10), and especially in the case of large organic farms (p-value < 0.001,
data not shown). The timing of the release of the temporal N storage of CCs determines
how and when N is eventually used. Management practices and CC choices contribute to
the effectiveness of CCs in optimizing soil N retention and supplying N for a cash crop [35].
4.2. Harvesting and Quality of a Cash Crop
Farmers considered the existence of the CCs when they harvested the cash crop.
They mostly agreed (58%) that early cash crop harvesting ensured that the CCs did not
hamper the harvest (Figure 1): more frequently in East/North Finland with short growing
season and higher risks to the harvest than in South Finland (Figure 5). On the other hand,
respondents did not strongly agree that CCs delayed harvesting (Figure 1). The statement
most agreed with was that the respondents harvested the cash crop as soon as it matured
and was harvestable (Figure 7)—and even more frequently on very large farms, which was
likely to avoid risks of lodging and quality deterioration, as rains become more frequent
later in the growing season [16]. In the cases that the farmers take the CCs into account in
the timing of the harvest, it is likely that an early harvest was valued because it improves
the CCs’ capacity to produce abundant biomass and comprehensive soil cover during
the autumn. According to experiments carried out in Sweden, the biomass production
capacity of CCs after harvesting correlated with the abundance of CC plant stands before
harvest [36]. To further support CC growth, 64% of farmers answered that they harvested
their cash crops always or often with a high stubble height to avoid damaging the CCs,
and 45% reported that they take measures to avoid cash crop residues suppressing the CCs
(Figure 7). Hence, farmers seemed to strive for a win—win situation considering both the
success of the cash crop and the CCs during the harvest, however, without investing much
(in other machines than sowing units) to facilitate the growth and handling of CC stands
later in the growing season (Figure 13). Only some mentions of equipment investments
were given in the free-word section of the questionnaire including weed harrows (5%),
chopper (4%), chaff spreaders (2%), and even less frequently mowers and baling machines.
The farmers’ views were mixed on the statement that CCs have no impacts on the
quality of the cash crops: 38% of respondents agreed and 31% disagreed (Figure 1). In
some studies CCs have improved quality of a cash crop [37]. Sixty-nine per cent of the
respondents agreed that CCs have impacts on quality only if they grow above the cash crop:
farmers in East/North Finland with short time frame for harvest agreed more frequently
than those in South Finland (Figure 5), as did older and less educated farmers when
compared to younger and university educated farmers (Figures 2 and 4). Abundant green
biomass including weeds, green tillers, and CCs among the cash crop may keep the stand
moist, expose grains and seeds to sprouting and fungal growth, as well as delay the harvest
and make it difficult [38]. Quality may be at risk in such cases especially because rains are
common during the late growing season in Finland [39].
5. Conclusions
A survey of farmers carried out in Finland indicated that farmers often took under-
sown CCs into account during the growing season. Sowing was especially considered
critical for success with CCs, and therefore, the majority of respondent (56%) always
Agronomy 2023, 13, 499 14 of 16
checked the CCs’ seeding rate before sowing. Furthermore, when farmers made invest-
ments, they prioritized machines that facilitate sowing. The availability of commercial
seeds was not a problem, and most farmers neither produced farm-saved seed of CCs (82%)
nor purchased them from abroad (89%). Farmers adjusted the fertilizer rate according to the
cash crop: only 10% considered the CCs’ needs as well. Early harvesting of a cash crop was
considered important by 58% of farmers to ensure that the CCs did not hamper the harvest.
Farmers harvested cash crops as soon as they matured and were harvestable. The farmers’
views were mixed as to whether CCs had an impact on the quality of a cash crop or not. The
finding that Finnish farmers often took under-sown CCs into account during the growing
season implies the farmers’ aims to reap potential benefits from CCs. Agricultural policy
is a focal tool to support the shift towards the adoption of CCs in Europe. It is, however,
important that it is a cost-effective and target-oriented policy measure. It was recognized
that those farmers who were inclined to make an investment to support the cultivation
of CCs were often educated, ≤50 years old, had experience with many CC species, had
a large farm (as often in South Finland), were organic producers, and had poultry, pig,
cereal, or special crop farms. Subsidized farmers who also make investments are likely to
aspire reaping the ecosystem services, especially improved soil health provided by CCs.
Hence, their experiences are of core importance when sharing knowledge between farmers
to encourage the implementation of CCs on a larger scale. It is, however, essential that
knowledge gaps are filled with tailored experiments and extension services have access to
the latest know-how to support farmers during the transition phase towards extensive use
of CCs.
Supplementary Materials: The following supporting information can be downloaded at: https://
www.mdpi.com/article/10.3390/agronomy13020499/s1. Figure S1: The distribution of farmers’
answers (N = 1130) depending on the farm type (RMSD, row mean scores difference; CCs, cover
crops). The share of each answer choice (%) is shown within each bar except unless it was <3%.
Means with the same letter do not differ significantly from each other (at p ≤ 0.05). Figure S2: The
distribution of farmers’ answers (N = 1130) depending on the share of the area under different crop
types on the farm (NZC, nonzero correlation; CCs, cover crops). The share of each answer choice
(%) is shown within each bar. Means with the same letter do not differ significantly from each other
(at p ≤ 0.05). Figure S3: The distribution of farmers’ answers (N = 1130) depending on the share
of cereal area on the farm (NZC, nonzero correlation; CCs, cover crops). The share of each answer
choice (%) is shown within each bar unless it was <3%. Means with the same letter do not differ
significantly from each other (at p ≤ 0.05). Figure S4: The distribution of farmers’ answers (N = 1130)
depending on the share of special crop area on the farm (NZC, nonzero correlation; CCs, cover crops).
The share of each answer choice (%) is shown within each bar unless it was <3%. Means with the
same letter do not differ significantly from each other (at p ≤ 0.05). Figure S5: The distribution of
farmers’ answers (N = 1130) depending on the share of other crop areas on the farm (NZC, nonzero
correlation; CCs, cover crops). The share of each answer choice (%) is shown within each bar unless
it was <3%. Means with the same letter do not differ significantly from each other (at p ≤ 0.05).
Figure S6: The distribution of farmers’ answers (N = 1130) depending on their age (NZC, nonzero
correlation; CCs, cover crops). The share of each answer choice (%) is shown within each bar unless
it was <3%. Figure S7: The distribution of farmers’ answers (N = 1130) depending on the farmer’s
education (NZC, nonzero correlation; CCs, cover crops). The share of each answer choice (%) is
shown within each bar unless it was <3%. Means with the same letter do not differ significantly
from each other (at p ≤ 0.05). Figure S8: The distribution of farmers’ answers (N = 1130) depending
on the farm type (RMSD, row mean scores difference; CCs, cover crops). The share of each answer
choice (%) is shown within each bar unless it was <3%. Means with the same letter do not differ
significantly from each other (at p ≤ 0.05). Figure S9: Bubble charts indicating how the answers on
the farmers’ views on statements concerning sowing-related issues (x-axis) were distributed when
compared to the farmers actions (y-axis) when stated as: “Before sowing I check the sowing density
of cover crops (CCs)”. Figure S10: The distribution of farmers’ answers (N = 1130) depending on the
share of grassland area on the farm (NZC, nonzero correlation; CCs, cover crops). The share of each
answer choice (%) is shown within each bar unless it was <3%. Means with the same letter do not
differ significantly from each other (at p ≤ 0.05).
Agronomy 2023, 13, 499 15 of 16
Author Contributions: Conceptualization, P.P.-S.; methodology, P.P.-S., L.J., H.K., J.J., T.H. and T.M.;
validation, L.J. and P.P.-S.; formal analysis, L.J.; investigation, P.P.-S., L.J., H.K., J.J., T.H. and T.M.;
resources, P.P.-S. and L.J.; data curation, L.J. and P.P.-S.; writing—original draft preparation, P.P.-
S.; writing—review and editing, P.P.-S., L.J., H.K., J.J., T.H. and T.M.; visualization, P.P.-S.; project
administration, P.P.-S.; funding acquisition, P.P.-S. All authors have read and agreed to the published
version of the manuscript.
Funding: This work was financed by Ministry of Agriculture and Forestry in Finland, project
Evergreen Revolution with Cover Crops—Best Practices to Enhance C Sequestration (IKIVIHREÄ),
grant no. VN/5082/2021-MMM-2 (Catch the Carbon-program) and Luke’s strategic funding on the
project Farmer-specific Methods to Sustainably Intensify Agricultural Systems by Closing Yield Gaps
(F-Specific).
Data Availability Statement: Not applicable.
Acknowledgments: We thank all the pioneer farmers who answered the survey.
Conflicts of Interest: The authors declare no conflict of interest.
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