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 CHEMICAL ENGINEERING TRANSACTIONS  
 

VOL. 65, 2018 

A publication of 

 
The Italian Association 

of Chemical Engineering 
Online at www.aidic.it/cet 

Guest Editors: Eliseo Ranzi, Mario Costa 
Copyright © 2018, AIDIC Servizi S.r.l. 
ISBN 978-88-95608- 62-4; ISSN 2283-9216 

Low-ILUC Biofuel Production in Marginal Areas: Can Existing 
EU Policies Support Biochar Deployment in EU MED Arid 

Lands under Desertification? 

David Chiaramonti*a, Calliope Panoutsoub  
a
 RE-CORD and CREAR, Industrial Engineering Dept., Univ. of Florence, Viale Morgagni 40, 50134 Florence ITALY  

b
 Imperial College, Faculty of Natural Sciences, Centre for Environmental Policy, London, UK  

david.chiaramonti@unifi.it 

Arid lands in EU MED areas are increasing in extension year by year, as it is well documented by many 
studies of International Institutions (as EC-JRC, EEA, etc). EU MED farmers face the dramatic effects of 
extended drought conditions, that combined with extreme phenomena as floodings or thunderstorms make 
economic profitability of agriculture very low or even negative. This is associated with a clearly increasing 
abandonment rate of agricultural land in EU. The most EU critical areas are located in Spain, but also Greece, 
Italy and Portugal, as well as in the non-EU Southern rim of the MED basin. Biochar could represent an 
effective approach to fight desertification, together with other agronomic practices which can vary depending 
on the specific location or crops. Biochar can be cheaply produced from residual biomass through processes 
such as slow pyrolysis or hydrothermal carbonization, and its combination with compost obtained from the 
Organic Fraction of Municipal Solid Waste (OFMSW) or digestate from anaerobic digestion can offer both a 
short and a medium-to-long term effect in dryland agriculture. These lands, that otherwise would inevitably 
leave the active utilisation in conventional agriculture, would be suitable for energy crop cultivation, as drought 
resistant oil crop, well meeting the latest indications in the EC REDII proposal. 
Through biochar (and derived product) application, the loss of Utilised Agricultural Land in EU MED drylands 
can be prevented. From the policy side, it thus makes sense to investigate if existing policies are sufficient to 
facilitate the wide market deployment of biochar, or if new instruments are needed. Our analysis demonstrates 
that currently operational EU policies, could be well used to implement biochar related actions in arid lands. 
However, most often these measures are not transferred into concrete programmes at regional level, 
especially in the agricultural sector. In fact, EU and Member States already have quite a large number of 
instruments that can directly or indirectly support actions targeted to increase the resilience of these arid lands 
to Climate Change, generating a significant impact on the environmental and socio-economic situation. Policy 
should support initiatives that can provide clear evidences, be cost- and environmentally-effective, and 
adapted to local conditions. The present work investigated EU/MS policies that could potentially support the 
improvement of soil resilience to climate change in EU MED region, by enabling widespread diffusion of 
biochar.  
The EU legislative elements that were considered are the EU agricultural policy, the EU Carbon sequestration 
& storage policy (seen in the framework of the COP21 agreement and its core goals), and the EU renewable 
energy policy, even if others would also apply. We considered sunflower cultivation in dry land of Central area 
(Tuscany) of Italy. Results showed that marginal land could be seen as an opportunity to produce low-ILUC 
biofuels (as mentioned in the EC REDII proposed Directive), without conflicting with food production or 
generating negative effects on GHG emissions. The Long-term storage of C in the soil through biochar would 
perfectly match with the Climate strategy defined at International level (Paris COP21 and following). Soil, after 
ocean, is the second most abundant C sink: Paris-COP21 called for C-negative actions (and not just C-neutral 
ones). In this respect, the proposed approach would perfectly match with EU (ETS) and International (COP21) 
policy for the coming decades. 

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DOI: 10.3303/CET1865141

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

Please cite this article as: Chiaramonti D., Panoutsou C., 2018, Low-iluc biofuel production in marginal areas: can existing eu policies support 
biochar deployment in eu med arid lands under desertification?, Chemical Engineering Transactions, 65, 841-846  DOI: 10.3303/CET1865141 



1. Introduction 

Lignocellulosic biomass that has been carbonized through slow pyrolysis or hydrothermal carbonisation is 
today identified with the term “biochar” (Brown et al, 2011; Lehmann et al, 2009). Recently, also the solid 
product from biomass gasification is included in the “biochar family”. However, the chemical and physical 
characteristics of these three solid products, as well as the level of contaminants, considerably differ, 
depending on the specific process and technological solution adopted. Biochar and its derived products 
(through chemical or biotech-based upgrading) can be used as soil amendment. Biochar is mainly composed 
by stable carbon, which can resist to microbial and chemical attack: thus, biochar offers a large potential for C 
sequestration on a long-term basis, and provide long-term storage of carbon in the soil. For this reason, 
biochar is seen as a major strategy to store C and mitigate climate change effects (Griscom et al, 2017). 
Biochar, in addition to the use in agriculture, can be employed in a vast number of other uses, from flue 
gas/liquid stream cleaning (activated charcoal), to steel making (metallurgical charcoal), silicon making. In this 
work we will concentrate on the agricultural use of biochar and COMBI (the combination of biochar and 
compost) in agriculture, a field of research that is receiving great attention worldwide recently. Biochar use in 
agriculture can: 
-Increase moisture retention capacity of difficult dry soil, while also restructuring the soil matrix 
-Create a porous suitable environment for microbial 
-Regulate soil pH 
-Sequester and slowly release main nutrients (as nitrogen), favouring crop growth, reducing N-leaching and 
N2O emissions 
-Store stable carbon in the soil 
Biochar – if properly used in the right soil type and climate - attracted the interest of farmers as it can 
potentially increase crop yields, in a virtuous combination with an improved sustainability of farming. 
Nevertheless, the effect of biochar and derived products in agriculture depends on the biochar characteristics, 
the crop and soil characteristics, the volume of biochar deployed on land, the local climate, and other 
elements, thus making the actual impact very biochar-type and site specific. The addition of biochar, a very 
porous material (typically in the range of at least some hundreds g m-2 (Suliman et al, 2017), to the soil 
improves the water retention capacity, one of the key elements for crop growth, which is also function of pore 
dimensions and char surface characteristics. This property of biochar makes it very interesting arid regions, 
including EU MED, favouring agriculture in marginal land while preserving soil organic carbon and 
sequestering stable carbon in the soil. Since decades this area is subject to progressive and continuous 
desertification due to climate change effect, as largely documented by – among many others - the studies of 
the European Environment Agency on the MED basin, and EC JRC in its World Atlas of Desertification (EEA, 
2017; EC JRC, 2017). The combination of biochar with compost from the Organic Fraction of Municipal Solid 
Waste or composted digestate from Anaerobic Digestion can create synergistic effects, with short (from 
compost) and long-term (from biochar) benefits to agriculture (Godlewska et al, 2017).The combined use of 
biochar and compost to improve soil resistance under dry conditions could be a feasible approach to fight land 
abandonment due to desertification in the EU MED area: however, proper support measures are necessary 
for wide deployment of biochar in agriculture. The scope of our work is to address the EU policies and model 
the possible effects of supporting measure in the cultivation of sunflower in central Italy (Tuscany). 

2. Methodology 

The analysis considered the EU Common Agricultural Policy (CAP) as the main instrument to promote biochar 
use in EU arid regions, combining this with the Energy and Climate policies, and investigating if existing EU 
measures could support the biochar chain, or if otherwise new policies are needed. It is worth to mention that 
the EU Circular Economy package could also very well fit to the scope, even if it was not considered in the 
present work. A cost model for Sunflower cultivation in Tuscany has then been developed and used for the 
study. Data for sunflower yields and crop production costs were derived from actual on-field experience of the 
University of Florence in Tuscany. Both conventional and high-oleic sunflower under three different cultivation 
regimes were considered, and the extreme (min and max) values for the following parameters sued: 

• Representative average yield per ha for conventional, minimum tillage and no tillage cultivation; 
• Representative total costs per ha for conventional, minimum tillage and no-tillage sunflower; 
• Minimum and maximum seed selling price for both conventional and high-oleic sunflower. 
 
Based on that, and considering the average CAP support to sunflower cultivation in Italy, the range of gross 
farmers’ income in case of conventional agriculture in conventional land was calculated, and results taken as 
reference case.  

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Reasonable crop yield increase curves versus cultivation in marginal land were then modelled, differentiating 
between the case of biochar only or COMBI addition (the amount of biochar varying accordingly). From a 
policy point of view, we assumed to cover the additional biochar/COMBI deployment costs with CAP 
measures in the range of 110-200 € ha-1 y-1 over a period of 5 years (compared to the effect of C storage 
lasting at least a century). This C-sequestration environmental action is also in full line with the indications of 
Paris COP21 and following COPs. The EU Renewable Energy policy, namely the biofuel policy in RED/REDII, 
was considered to provide a premium for oil crops cultivated in this marginal land. The same support as 
proposed by the EC in its first REDII draft for aviation biofuel (European Commission, 2016), i.e. a 1.2 (or 
120%) multiple counting on the vegetable oil, was considered. This support was weighted on the typical oil 
content of sunflower seed (~40% w/w): 120% premium on oil content is thus equal to an average of ~108% on 
seed. Farmers’ returns were then calculated again, and compared to conventional and marginal land 
sunflower cultivation. 

3. Results 

Regarding the Utilised Agricultural Area (UAA) in the EU MED, EUROSTAT and FAOSTAT provide similar but 
different set of data. These have then been compared for three reference Countries. Even if differences exist, 
the trend over the time (e.g. decades) was the same, and the absolute differences within an acceptable range. 
FAOSTAT was then adopted as reference source for the following analysis. 

 

Figure 1: Comparison between Eurostat and FAOSTAT data on land use in three representative EU MED 
Countries.  

As reported in the following Figure 2 and 3, almost all EU MED Countries showed a considerable reduction in 
UAA. Overall, more than 12 Mha and 18 Mha were lost from the EU MED agriculture in the period 2015-1992 
and 2015-1970 respectively, i.e. 120.000,00 km2 and 180.000,00 km2. 180.000,00 km2 means almost 6 times 
the area of Belgium or 4 times Switzerland, 60% of the Italian, 50% of the German or 25% of the French land. 

   

Figure 2: Reduction of Utilised Agricultural Area (UUA) in EU MED countries. UUA loss ([ha], left), UUA 
remained in the selected time interval (%, right)  

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In the following figures the farmers’ gross returns are given as calculated based on assumptions reported in 
the previous section. Even conventional land and farming can determine very low return if seed yields 
decrease below a certain level. Marginal land is almost always uneconomic, while biochar addition only 
provides minimum benefit (even if in the best case positive) compared to COMBI addition. 
Case 3 below corresponds to a support of 200 € ha-1 y-1 over a period of 5 years for Biochar (Fig 3) and 110 
€/ha to over the same period for COMBI. Case 4 considers an additional premium of 108% on seed value 
(120% multiple counting on produced vegetable oil). Case 1 and 2 instead assume no support to the farmers 
for sunflower cultivation. 

 

Figure 3: Estimated gross farm income with biochar and various policy support  

 

Figure 4: Estimated gross farm income with COMBI and various policy  

4. Discussion 

The investigation on conventional farming of Sunflower in the EU MED area shows that farmers have very 
small benefit from this crop: the real income that is generated becomes almost equals to the CAP support only 
under the highest yields, while on the contrary the profit is lower or even negative, when weather conditions or 

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the type of soil, are unfavourable. Thus, either the farmer switches to a different drought-resistant crop, or the 
agricultural land is abandoned, given the unattractive economics. 
Under these circumstances, adding biochar or biochar and compost (COMBI) improves crop yields and helps 
mitigate the climate change impacts. In particular, the use of COMBI provides both short-term and long-term 
benefit to the soil, adding readily available carbon and nutrients for crop cultivation in a reformed soil 
environment, increasing moisture content, and storing stable carbon. The use of COMBI also minimizes the 
amount of biochar addition per ha, thus reducing the support needed and allowing from multiple applications.  
The analysis for COMBI considered even a rather small (and conservative) support from CAP (110 € ha-1 y-1, 
for 5 years), compared to the case of biochar only (200 € ha-1 y-1 at an application rate of 5 Mg ha-1). The use 
of compost in agriculture would also be stimulated, a widely available material not yet adequately exploited in 
several EU Countries despite its large potential.  
Since current farmers’ returns from sunflower cultivation in conventional land are ~120-200 € ha-1, the study 
concluded that COMBI is the most promising approach, unless higher seed yields from biochar only can be 
achieved (it can happen, depending on the specific site and weather conditions). 
As regards the cost for C sequestration, ~300 € MgC

-1 were estimated, considering conservatively 70% fixed-C 
content in biochar: this figure determines ~82 € MgCO2

-1, a comparable and very similar figure to major Carbon 
Capture Sequestration (CCS) options (estimated in a range between very optimistic ~10 US$ MgCO2

-1 and ≥ 
100 US$ MgCO2

-1 (Griscom et al, 2017; Rubin et al, 2017). Nevertheless, these CCS solutions do not bring the 
benefits of biochar as: 
• more sustainable agricultural practices, towards circular economy;  
• fight desertification of marginal areas, keeping the land available for food, feed and bioenergy production 
However, biochar and compost only represent part of a possible approach to increase the resilience of 
marginal land to climate change effects, and a set of coordinated measures, especially on the water 
management side, will have to be considered and implemented. Moreover, a very effective control of the 
supply chain will be necessary, with innovative solutions to ensure that suitable and tracked materials are 
processed through slow pyrolysis and composting. 

5. Conclusions 

The analysis provided evidence that biochar, and in particular COMBI, use in EU MED marginal agricultural 
land is a possible solution to fight climate change, and that food, feed and bioenergy could be produced 
combining different policy instruments. 
• The situation of the EU MED agriculture is becoming critical in very large areas due to climate effects, with a 
potential of 8.5 Mha under risk of marginalization. This fact represents a major concern in the EU, and a major 
reason for agricultural land abandonment, well documented over the last decades in many EU Countries.  
• The use of biochar and compost (COMBI) solutions can contribute to mitigate these effects, promoting 
sustainable agriculture. Biochar can be produced from a variety of feedstock, both woody or herbaceous, and 
from dedicated or residual materials. Biochar can offer long-term positive effects by reconstituting the soil 
texture, improving its porosity, and favouring moisture retention and slow fertilisers release. COMBI brings 
additional benefits (in a short-term view), with crop readily available carbon and nutrients. This approach can 
be seen as a possible approach to generate a kind of “positive Land Use Change” effect, since agricultural soil 
is kept productive or recovered, instead of becoming deserted, with net loss of organic carbon and microbial 
life. 
• Given the large area at risk of marginalization in the EU MED Countries, the potential impact of a biochar-
based BECCS (BioEnergy and Carbon Capture and Storage) strategy in the EU MED is considerable: the 
theoretical potential equals ~156 Million MgCO2 sequestered, almost 3.5% of total EU-28 GHG emissions 
(including international aviation and indirect CO2, excluding LULUCF) in 2015 (equal to 4451.8 Million 
MgCO2equiv), or more than 10% of EU MED (PT, ES, FR, I, HR, EL, CY) countries only (1471 Million MgCO2equiv) 
(Eurostat, 2017). 
• To deploy at large scale the potential of biochar and, in particular, COMBI, in the EU MED region, policy 
support is needed: however, the present work found that several instruments already exist in the policy 
framework that could be effectively used to achieve the goal. These are mostly in the area of the Common 
Agricultural Policy, the Energy Policy, and the Climate Change Policy, even if also the Circular Economy 
policy could contribute.  
• These will allow EU MED farmers to reach sufficient profit to continue their activities, preserving in this way 
the socio-economic equilibrium in these rural areas.  
Nevertheless, given the very large range of results given in literature as regards biochar and COMBI addition, 
which strongly depends on the specific type of soil, the local climate, the type of cultivated crop, the 
characteristics of the specific biochar type under investigation, it is necessary to demonstrate the actual 

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effectiveness of this biochar/COMBI-based at site-specific conditions. A dedicated programme is thus 
recommended to provide the necessary resources to carry out this evaluation in well selected EU MED 
regions. 

Acknowledgments  

Authors wish to acknowledge dr E. Palchetti, University of Florence, for the information provided on Sunflower 
cultivation in the South of the Tuscany Region, as well as the members of the pyrolysis team at RE-
CORD/University of Florence, Dept. of Industrial Engineering: R. Nistri, D. Casini, AM Rizzo. Authors also 
wish to acknowledge dr M. Falce, for the support given as regards meteolorogical data in the Sardinia region, 
and dr C. Sacchetto, Secretary General at ELTI (Eur. Leaf Tobacco Interbranch Organization) and Secretary 
of Tobacco Italia, for the insights given about the EU Common Agricultural Policy and the stimulating 
discussions. 

Glossary 

CAP: Common Agricultural Policy ILUC: Indirect Land Use Change 
COMBI: blend of 80% w/w compost and 20% w/w biochar JRC: Joint Research Center 
COP: Conference Of Parties MED area: Mediterranean area  
EC: European Commission MS: Member State 
EEA: Eur.Environment Agency RED: Renewable Energy Directive 
ETS: Emission Trading S  

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