<div>A more vital soil science future 11Acceptance speech at the
Presidential Award ceremony of the 2022 <i>Soil Science Society of
America</i> (SSSA) meeting in Baltimore</div><div>Alfred E. Hartemink</div><div>University of Wisconsin-Madison, Department of Soil Science, FD Hole
Soils Lab, 1525 Observatory Drive, Madison Wi 53711, USA. E-mail
hartemink@wisc.edu</div><div>By some measures, soil science is doing fine. We have gained a battery
of aspiring young scientists, and became more gender-balanced although
still not as diverse as we should be (Carter et al., 2021). The number
of soil scientific papers and books are growing at an almost exponential
rate reflecting increased research and funding and, hopefully, an
expanding knowledge base. An enormous amount of soil information is
available, and increasingly peer-reviewed publications are freely
accessible. Soon there will be no barrier for humanity between what is
known and what information can be retrieved about soil.</div><div>Soil awareness has grown among policy makers and the general public,
following enduring campaigns by national and international soil
organizations. It is not uncommon to hear podcasts, talks on the tv, or
read articles about soil health, regenerative agriculture, or the
relationships between soil management, greenhouse gases and the changing
climate. Scientific disciplines ranging from medical geology to urban
planning recognize the relevance of soils and have embarked on soil
research.</div><div>Countless technological advances enable us to observe, measure, model
and monitor soil attributes at accelerating speed (Wadoux and McBratney,
2021). The private sector and industry have entered the soil carbon
market, discovered the commercial value of the soil microbiome, and
continues to develop technologies to optimize soil water use. But as
soil science is rapidly evolving with a particular focus to solve the
grand environmental challenges, it is vital that the science is done
efficiently and impactful, and that it stays well-ahead of the
technology.</div><div>Some soil research approaches are holding us back. First, a lot of soil
science is conducted at the fringe of traditional soil science centers
and departments by a community that has not had the benefit of primary
schooling in soil science. Our discipline has always been enriched by
approaches and theory from other scientific disciplines but, at the same
time, a lot of fundamental knowledge about our soils, knowledge that was
learned the hard way, is ignored (Hartemink, 2015; Schimel and Chadwick,
2013). This particularly refers to the lack of viewing soils as a
four-dimensional system that cannot be reduced to measuring a limited
set of attributes in one or a few timesteps and from shallow soil depth.</div><div>Quite a lot of research purports to investigate systems and aims to
derive knowledge from differences among the systems. For example, soils
under different vegetation or cropping systems are sampled for certain
fractions, say, soil organic carbon, and the differences are attributed
to land use and management. Too often, samples are collected only from
the uppermost 20 cm (Yost and Hartemink, 2020) and, in many studies,
diverse vegetation or a ‘range of agricultural soils’ are sampled across
the continent so as to maximize variation. No wonder that differences
are unearthed, but such studies rarely progress beyond the description
of loosely connected phenomena that are hard to extrapolate, or
interpolate.</div><div>With research framed within one or other grand environmental challenge
(Wortman and Lovell, 2013), it remains unclear how the results translate
or contribute to solving those challenges. Studying and understanding
soils is noy easy. The best studies are those that investigate a
multitude of soils and their attributes across a range of spatial and
timescales using a wide range of tools and, above all are based on a
solid framework and sound theory. We need to speculate more and think
deeper and longer, and require more explorations that combine
measurements with modelling and predictions across time and space.</div><div>Next, there is <i>soil anxiety</i> – that might be described as the
hidden apprehension of doing something new and novel. This seems to
occur, for example, at the research proposal stage whereby new ideas are
met with: ‘Why?’ instead of a firm: ‘Why not!’. This goes along with the
lack of study whether the research has already been done: it is easier
to repeat than to formulate and invent. Part of the soil anxiety is the
strictly regional approach that can be summed up as: ‘We have done in
North Dakota. Now we do it in South Dakota.’ Science needs verification
but there is quite a limit to progress in this direction. Progress comes
from tirelessly chasing of new ideas, quite often with only partial
success, but the lack of ideas - equivalent to maintaining a status quo
- is regressive. It is not: ‘Go big or go home’ but: ‘Do something new
or go home. Dare to fail - and dare to publish it.’</div><div>And, finally, a lot more effort is needed to develop sound theory. Sound
theory is the bedrock of all the soil science subdisciplines. This could
be the last chapter of every PhD thesis. It is not the same thing as
hypothesis formulation and testing. Research considered ‘high
impact-high risk’ is no guarantee of novelty or an overture for theory
development if that is not the overarching aim. Funding bodies might
hesitate to support foundational soil science research but it is good to
see that methodology development is advancing in most soil science
subdisciplines. It seems to go hand in hand with increased technological
availability.</div><div>So, soil science is thriving, but it can do better. As much of our
research findings are available, we have all the more responsibility to
deliver the best. The future directions of our science are by no means
solely determined by funding or the environmental challenges but, in
particular, by the community, its education and willingness to strive
for excellence. There is surely a role for the soil science journals to
weed out problematic research approaches, but it is the task of the
community, research centers and universities to guarantee that the
research approaches are solid, reproducible, and innovative. Innovation
should be the foundation of our research and not a special program
defined as ‘high risk’ or ‘quick impact’. Concerted efforts should be
made to force breakthroughs, for the growth of soil science theory and
frameworks, and to think about the vitality of our discipline – now and
in the future. And in all that, there is no need to think outside the
box. There is no box.</div>