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 CHEMICAL ENGINEERING TRANSACTIONS  
 

VOL. 58, 2017 

A publication of 

 
The Italian Association 

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

Guest Editors: Remigio Berruto, Pietro Catania, Mariangela Vallone
Copyright © 2017, AIDIC Servizi S.r.l. 
ISBN 978-88-95608-52-5; ISSN 2283-9216 

Life Cycle Assessment of Flax and Camelina for Biodiesel 
Production in Sicily (Southern Italy) 

Jacopo Bacenetti*a, Andrea Restucciab, Gianpaolo Schillacib, Marco Fialaa, Sabina 
Faillab 
a Department of Agricultural and Environmental Sciences – Production, Landscape, Agroenery. Università degli Studi di 
Milano, via Giovanni Celoria 2, 20133, Milan, Italy. 
b Department of Agricoltura, Alimentazione e Ambiente (Di3A), Section of Mechanics and Mechanisation, University of 
Catania, Via Santa Sofia, 100, 95123 Catania, Italy.  
jacopo.bacenetti@unimi.it 

The use of renewable vegetable oils derived from oilseed crops could have serious environmental impacts 
especially regarding competition for land and emissions in air and water. 
The environmental performances of Linum usitatissimum L. (Flax) and Camelina sativa L. (Camelina) oilseed 
crops for biodiesel production has been assessed by means of Life Cycle Assessment (LCA) approach, 
considering three steps: i) the cultivation, ii) oil seeds transport to pressing plant and seed pressing, iii) 
biodiesel production from vegetable oil by transesterification. 
For the biodiesel from flax and camelina, more than 90% of the environmental impact is related to seed 
production, followed by the transesterification of raw vegetable oil and seed pressing at lab scale. The 
environmental performances are worst for the camelina mainly due to a lower seed yield. Nevertheless, these 
differences are slightly reduced thanks to the higher HHV (Higher Heating Values) of the camelina biodiesel. 
For both the biodiesel, the main environmental hotspots are: the production of factors production, the nitrogen 
emissions associated with the application of fertiliser and the mechanisation of the field operations (in 
particular soil tillage and sowing) and the emission of N and P compounds related to fertilisers application. 
In comparison with rapeseed (from data of Ecoinvent 3), the biodiesel from flax and camelina shows a higher 
environmental impact due to the higher consumption of fertilizers in rapeseed crop management. 

1. Introduction 

The production of first generation biofuels is mainly based on agriculture raw material such as oleaginous 
edible and non-edible plants. Brassica carinata, soybean, canola, sunflower, camelina and flax are the main 
used crops. 
Besides to important socio-economical aspects (greater energy security, diversification of energy sources and 
agriculture, accelerated development of rural areas), the first generation biofuels can involve negative 
environmental impacts (e.g., competition for land, emissions of pollutants, biodiversity loss) (Castanheira et 
al., 2014) depending on the crops used and the efficiency of biodiesel production process. The choice of the 
proper crop can reduce the associated environmental impact (Escobar et al., 2009).  
Linseed or flax (Linum usitatissimum L.) and Camelina sativa L. are two interesting crops for biodiesel 
production, above all for their adaptability to grow in different pedo-climatic conditions; nevertheless, until now, 
there is a lack of knowledge concerning the environmental performances of these two oil crops. Some studies 
addressed this sustainability aspect (Dangol et al., 2015; Godard et.al, 2013; Krohn and Fripp, 2012; Li and 
Mupondwa, 2014) but not in the Mediterranean areas. 
In this study, using a Life Cycle Assessment (LCA) approach, the environmental impact of biodiesel from flax 
and camelina cultivated in Sicily (Southern Italy) was evaluated. LCA is a useful method to determine the 
environmental impact of products and services (ISO, 2006a; 2006b) and has been already applied to biofuels 
production processes (Escobar et al., 2009, Castanheira et al., 2014). 

                               
 
 

 

 
   

                                                  
DOI: 10.3303/CET1758081

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

Please cite this article as: Bacenetti J., Restuccia A., Schillaci G., Fiala M., Failla S., 2017, Life cycle assessment of flax and camelina for 
biodiesel production in sicily (southern italy), Chemical Engineering Transactions, 58, 481-486  DOI: 10.3303/CET1758081 

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2. Materials and methods 

The environmental performances of Linum usitatissimum L. and Camelina sativa L. oilseed crops for biodiesel 
production has been assessed by means of LCA approach. 

2.1 Description of the production systems 

The production system has been divided in three subsystems: 
- Seed production, this subsystem concerns the cultivation of these crops in typical Mediterranean 

environmental conditions, using a  system based on no-irrigation and minimum use of fertilizers and 
pesticides.  

- seed transport to pressing plant and seed pressing,  
- biodiesel production by means of the transesterification of vegetable oil. 

More details about the cultivation of the two oil crops can be found in Restuccia et al. (2013) and in Restuccia 
(2014). 

2.2 Life Cycle Assessment  

Four steps are foreseen by the LCA approach: 1) goal and scope, functional unit and system boundary 
definition, 2) inventory data collection, 3) impact assessment and 4) results interpretation (ISO, 2006a, ISO, 
2006b). 
In this study, the selected functional unit was 1 t of biodiesel produced from the camelina and flax while 
“cradle-to-factory gate” system boundary was considered (Figure 1); therefore, all the input related to crop 
cultivation (seeds, fuels, fertilisers, pesticides, capital goods), seed pressing (energy, capital goods) and 
transesterification (heat, electricity, chemicals, capital goods) were considered as well as the related emission 
into air, soil and water.  

 
Figure 1: System boundary of the biodiesel production process 
 
Primary inventory data were collected concerning seed production, pressing and transesterification yield. More 
in details, concerning raw oil production, seed pressing was carried out with a screw press in laboratory while 
regarding to transesterification yield lab scale tests in batch reactors were performed. 
Secondary data from the Ecoinvent Database v.3 (Ecoinvent, 2012) were used for the production of seed, 
diesel fuel, fertilizers, pesticides, tractors and agricultural machines (equipment and combine harvester) as 
well as to consider the infrastructure of real scale pressing and transesterification plants.  
Table 1 and 2 report the main inventory data measured during the cultivation trials and the lab-scale tests. 

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Table 1: Inventory data for seed production 

Subsystem 
Field  
Operation 

Operative 
Machine 

Tractor Input Time 

kW kg Product 
Amount  

(ha-1) 
h ha-1 

Soil 
Preparation 

Shredding Shredder 74 3500   3.17 

Soil Tillage 
and 
Seeding 

Harrowing Cultivator 74 3500   0.97 

Hoeing Rotary tiller 74 3500   1.33 

Mineral 
fertilization1 

Fertilizer 
spreader - - 

N  
P2O5 

80 kg;  
48 kg - 

Sowing1 
Seeder, 
mechanical 
distribution 

74 3500 Seeds 39 kg 0.76 

Mineral 
fertilization2  

Fertilizer 
spreader 52 3200 

N  
P2O5 

80 kg;  
48 kg 0.17 

Sowing 2  
Seeder, 
pneumatic 
distribution 

44 2420 Seeds 4.2 kg 1.55 

Rolling Smooth roller 78 2540   0.57 

Crop 
Management 

Chemical  
weed control Sprayer 52 3200 herbicide 

0.5 dm3 
“linuron”1 
0.5 dm3 

“metazachlor”2  

0.30 

Harvesting 
and 
Storage 

Harvest Combine harvester 167 10400   0.40 

Transport Farm trailer      

1 = flax; 2 = camelina 

Table 2: Yield during the three steps of the production process 

Parameter Flax Camelina
Seed yield  

(t/ha) 
1.45 1.10 

Pressing yield  
(t raw vegetable oil/t seed) 

0.279 0.284 

Transesterification yield  
(t biodiesel/t raw vegetable oil) 

0.980 0.965 

 
Economic allocation between vegetable raw oil and press cake as well as between biodiesel and glycerol was 
carried out considering the following prices: 370, 740 and 140 €/t for press cake, biodiesel and glycerol 
respectively (Argus, 2016; ISMEA, 2016).  
Using the Recipe mid-point method (Goedkoop et al., 2008), the following impact categories were evaluated: 

- climate change (CC, kg CO2 eq),  
- ozone depletion (OD, mg CFC-11 eq),  
- terrestrial acidification (TA, kg SO2 eq),  
- freshwater eutrophication (FE, g P eq),  
- marine eutrophication (ME, kg N eq),  
- particulate matter formation (PM, kg PM10 eq),  
- mineral depletion (MD, kg Fe eq),  
- fossil depletion (FD, kg oil eq). 

3. Results and discussion 

Table 3 reports the environmental impact for the biodiesel produced from flax and camelina’s raw vegetable 
oil. Respect to biodiesel from flax, the one from camelina shows an increase of the environmental impact for 
all the evaluated impact categories (from +21% in Fossil Depletion to +30% in Terrestrial Acidification and 
Marine Eutrophication) except for Ozone Depletion (-3%). For this last impact category, the higher impact for 

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biodiesel from flax is related to the higher amount of seed used at the sowing (39 kg/ha for flax instead of 4.2 
kg/ha for camelina). 
The differences between the environmental impact of biodiesel from flax and the one from camelina are 
mainly related to the different seed yield. During the lab experimental tests, pressing and transesterification 
yield of the two crops did not present substantial dissimilarities, which means that the higher seed yield for flax 
(+28%) involves a lower environmental impact for raw vegetable oil production and, consequently, for 
biodiesel production (Figure 2).  

Table 3:  Environmental impact assessment for 1 ton of biodiesel 

Impact category Unit Flax Camelina 
Climate change kg CO2 eq 4484 5702 
Ozone depletion mg CFC-11 eq 0.394 0.383 

Terrestrial acidification kg SO2 eq 84.04 109.04 
Freshwater eutrophication g P eq 1.244 1.597 

Marine eutrophication kg N eq 119.42 155.65 
Particulate matter formation kg PM10 eq 15.18 19.60 

Metal depletion kg Fe eq 268.18 345.19 
Fossil depletion kg oil eq 821.43 994.12 

 

 

Figure 2: Relative comparison between the biodiesel produced from: flax (green) and camelina (red)  

Figure 3 and 4 show the environmental hotspots for flax and camelina seed production. 
Respect to camelina, flax has higher yield and, for 7 of the 8 evaluated impact categories, shows better 
environmental performances (impact reduction ranges from -7% to -30%). Respect to camelina, seed flax 
production is responsible for higher environmental impact for OD (+4%, due to higher amount of seed used at 
sowing). 
The impact of seed pressing is considerably smaller respect to the one of trans-esterification and (above all) 
seed production. For pressing, the environmental impact is almost completely related to electricity 
consumption and, therefore, is proportionally lower for camelina (electricity consumption is equal to 0.06 
kWh/kg of seed for camelina and 0.07 kWh/kg of seed for flax). The pressing represents less than 2% of 
biodiesel environmental impact for 6 of the 8 evaluated impact categories (PM, TA, FE, ME, MD and FD). OD 
is the only impact category in which the role of pressing is approximately 5% (5.4% for flax and 4.8% for 
camelina). 

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Figure 3: Environmental hotspots for the flax seed production. 
 

 

Figure 4: Environmental hotspots for the camelina seed production  

The last step of the production process, the trans-esterification of the raw vegetable oil, is responsible for an 
environmental impact lower respect to the one of seed production but higher respect to the pressing. For both 
oil crops, this impact represents less than 2% of the total environmental load for TA and ME, is between 4% 
and 7% for CC, FE, MD and FD while for OD is about 10%. 

4. Conclusions 

This work performed life cycle assessment of biodiesel production from two unconventional oilseed crops, 
Linum usistatissimum and Camelina sativa cultivated in Southern Italy (Siracuse province). The cultivation 
was carried out in Mediterranean environmental conditions using a production system based on no-irrigation 
and minimum use of fertilizers and pesticides. The biodiesel production chain was divided in three different 
sub-systems: seed production, seed pressing and transesterification of vegetable oils. All the main data were 

0

10

20

30

40

50

60

70

80

90

100

Climate
change

Ozone
depletion

Terrestrial
acidification

Freshwater
eutroph.

Marine
eutroph.

Particulate
matter

formation

Metal
depletion

Fossil
depletion

%
Soil Tillage Sowing Crop Management Harvesting

Fertiliser prod. Seed prod. Herbicide prod. Soil emissions

0

10

20

30

40

50

60

70

80

90

100

Climate
change

Ozone
depletion

Terrestrial
acidification

Freshwater
eutroph.

Marine
eutroph.

Particulate
matter

formation

Metal
depletion

Fossil
depletion

%

Soil Tillage Sowing Crop Management Harvesting
Fertiliser prod. Seed prod. Herbicide prod. Soil emissions

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collected during the experimental field of flax and camelina, the laboratory seed pressing of both crops and the 
laboratory transesterification. Among the different subsystems, seed production is by far the most responsible 
of the environmental impact of the produced biodiesel (more than 80%); the role of seed pressing and 
transesterification is limited and usually lower than 2%.  
Between the two biodiesel, the one produced from flax shows better environmental results. Respect to 
camelina, flax has higher seed yield and, except for Ozone Depletion (due to higher amount of seed used at 
sowing), shows lower environmental impacts (ranging from -20% to -30%). 

Reference  

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