Issue
OCL
Volume 31, 2024
How oil- and protein- crops can help fight against climate change? / Contribution des oléoprotéagineux à la lutte contre le changement climatique
Article Number 25
Number of page(s) 19
DOI https://doi.org/10.1051/ocl/2024020
Published online 15 November 2024

© D.I.N. Mogollon et al., Published by EDP Sciences, 2024

Licence Creative CommonsThis is an Open Access article distributed under the terms of the Creative Commons Attribution License (https://creativecommons.org/licenses/by/4.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

Highlights

  • Biodiesel production through the interspecific hybrid OxG and Elaeis guineensis.

  • Overall efficiency of 61.82 and 55.62 for E. guineensis and OxG hybrid, respectively.

  • Energy productivity per hectare of 1086.90 GJ ha-1 and 1131.02 GJ ha-1 for E. guineensis and OxG hybrid, respectively.

  • 12.5 g MJBD-1 and 13.8 g MJBD-1 are emitted in biodiesel from E. guineensis and OxG hybrid, respectively.

Abbreviations

CPO: Crude Palm Oil

ICE: Internal Combustion Engine

CPKO: Crude Palm Kernel Oil

LCA: Life Cycle Assessment

PKC: Palm Kernel Cake

LCI: Life Cycle Inventory

EFB: Empty Fruit Bunch

LHV: Lower Heating Value

POME: Palm Oil Mill Effluent

FER: Fossil Energy Ratio

POM: Palm Oil Mill

NER: Net Energy Ratio

FFB: Fresh Fruit Bunch

ηgl: Global efficiency of the system

CHP: Combined heat and power

σpalm: Energy productivity per hectare

LUC: Land-use change

ηO: Global thermal efficiency

WL: Net electrical power generation

EUF: Energy Utilization Factor

Qu: Useful thermal energy

CEST : Condensing extraction steam turbine

m· : Mass flow

BPT: Back pressure steam turbine

E.G.: Elaeis guineensis

E.O.: Elaeis oleifera

1 Introduction

Biofuel production is growing worldwide because its use contributes to the mitigation of greenhouse gas (GHG) emissions and reduces the consumption of fossil fuels (Leblanc et al., 2022; Jeswani et al., 2020). One biofuel feedstock is crude palm oil (CPO). Considering the increase in the demand for bio-based products (food, bioenergy, and materials), CPO production is also expected to increase supply of the required raw material (Dey et al., 2020). CPO is one of the most important crops worldwide because of its versatility, high productivity (approximately 3.4 tons of CPO per hectare), and lower production cost compared to that of other vegetable oils (Ramirez–Contreras et al., 2020). Globally, more than 23 million hectares are used for producing oil yielding palm (Fedepalma, 2021), which accounts for more than 76.2 million tons CPO produced (Salvi and Panwar, 2012; Blackshaw et al., 2011; Issariyakul and Dalai, 2014; Rocha et al., 2021; Sales et al., 2022; Bajpai and Tyagi, 2006; Alexandre et al., 2022; de Oliveira et al., 2021; Balat, 2011). Malaysia and Indonesia are the main producer countries with approximately 84% of the total production (Fedepalma, 2021). Colombia ranks fifth, with 2% share of global production (Fedepalma, 2021). The source of the largest commercial production of palm oil is Elais guieneensis Jacq. (African oil palm) (Corley and Tinker, 2003). However, there are some crosses between the African oil palm and American oil palm (Elaeis oleifera Cortes) genotypes, resulting in interspecific hybrid OxG, commonly referred to as hybrid OxG (de Lima et al., 2020). In Colombia, the interspecific OxG hybrid is a promising genotype because of its higher resistance to certain diseases (e.g., bud rot disease caused by Phytophthora palmivora), high productivity, and oil quality (Daza et al., 2021; Ayala, 2013; Johnson, 2017). Currently, the area planted in Colombia is approximately 600 thousand hectares, of which the OxG represents 13%, however an increase in production is expected in the coming years (Fedepalma, 2021).

Research on palm oil production has focused on Elais guineensis cultivar. For example, Ramirez-Contreras et al. (2020) described the GHG emissions generated in the Colombian palm oil production chain, in addition to reporting the economic performance of its production both for the current situation and for two production scenarios using all the biomass generated in the CPO production chain. The results showed 55% reduction emissions in an optimized production chain based on good management practices, 20% reduction in capital expenditure and operating costs, and a reduction in the fossil energy consumed in the life cycle compared to the renewable energy produced. Results of a study by (Rivera-Méndez et al., 2017), which assessed the carbon footprint of fresh fruit bunch (FFB) production of E guineensis, showed that carbon storage in the plantation was greater than the emissions associated with the whole oil palm production chain. Both studies agree on the possibility of producing sustainable oil palms in terms of GHG emissions and the economy in Colombia. However, sustainability is a complex aspect to analyze, as both environmental and socioeconomic issues converge in it (Ray, 2019). Sustainable production requires the use of the total biomass produced to maximize the efficiency of the energy used in the supply chain and reduce potential environmental impacts. In this regard, some studies (Yáñez Angarita et al., 2009; Ali et al., 2015; Garcia-Nunez et al., 2016; Ocampo Batlle et al., 2020) have proposed implementing the concept of biorefinery to produce CPO in a palm oil mill (POM), using all the biomass produced as a feedstock for energy and other co-products such as compost, biochar, pellets, bioethanol, biobutanol, biohydrogen, bioplastics, biocomposites, and bioadsorbers. Moreover, these studies showed that a fraction of pressed mesocarp fibers, generating the steam and electricity, can be used as fuel for combined production of heat and power (CHP) required to run the POM. Anaerobic digesters have been proposed for the degradation of palm oil mill effluent (POME) as well as to obtain biogas that can be converted into electricity. The energy balance and environmental impacts of palm oil biodiesel have also been evaluated by (Pleanjai and Gheewala, 2009; De Souza et al., 2010; Mata et al., 2011), who reported the environmental benefits of palm oil biodiesel (E. guineensis) compared with other vegetable oil feedstocks.

Although much research has been conducted on issues related to the OxG cultivar focusing on its plantation, pollination, and oil characteristics, very little or no information is available regarding the energy efficiency or environmental impacts related to this oil palm genotype. Furthermore, as the largest production of palm oil in Colombia still depends on Elaeis guineensis cultivar, a comparative life cycle assessment between the two most produced oil palm genotypes is needed. The analysis included (i) conducting the energy balance considering the thermodynamic principles, and calculating the global efficiency of the system, energy productivity per hectare, net energy ratio (NER), and fossil energy ratio (FER) using Gate Cycle v.6.1.2 and Simapro v.8 .0.3 software; and ii) determination of the environmental impacts, including carbon footprint and life cycle impact assessment (LCIA) of seven midpoint categories (non-renewable energy, global warming, aquatic eutrophication, aquatic acidification, terrestrial acidification, ozone layer depletion, and respiratory inorganics) using the Impact 2002+ method.

When comparing studies similar to the one proposed here, it can be seen that in the last 10 years (2014–2024) at least 7,314 studies have been published on the Web of Science, which assess the life cycle of palm oil for biodiesel production. However, when we evaluate only the studies that carry out LCA of biodiesel production using only the interspecific hybrid OxG genotypes or Elaeis guineensis, we see that nine studies were carried out in the same period. Tab. 1 shows the five papers with the greatest impact, i.e., the most cited. The methods and main results of each paper are also described.

Therefore, the novelty of this work is the evaluation and comparison of the environmental impacts of producing biodiesel from palm oil from Elaeis guineensis and the interspecific hybrid OxG. As well as all the energy required in the process from transporting the palm to producing biodiesel, based on a case study from Colombia.

Table 1

Main studies that carry out an LCA of the use of interspecific hybrid OxG and Elaeis guineensis genotypes for biodiesel production.

2 Methodology

This study analyzes the energy and environmental performance of palm oil biodiesel from two oil palm genotypes planted commercially around the world, Elaeis guineensis and the interspecific hybrid OxG, as a case study in Colombia. The life cycle assessment of biodiesel production was analyzed in terms of energy efficiency, including the global system efficiency, energy productivity per hectare, NER, and FER. It was also analyzed in terms of potential environmental impacts, such as carbon footprint and LCIA of seven midpoint categories (non-renewable energy, global warming, aquatic eutrophication, aquatic acidification, terrestrial acidification, ozone layer depletion, and respiratory inorganics) using the Impact 2002+method. Fig. 1 shows an overview of the methodology.

thumbnail Fig. 1

Methodology flowchart for thermodynamic and environmental analysis of the different genotype considered.

2.1 Key characteristics between the two genotypes evaluated

The interspecific hybrid OxG is one of several palm genotypes developed in the Americas. It is the product of the crossing between two species that are economically important for the palm oil industry worldwide: Elaeis oleifera Cortes, native to the American continent, and Elais guieneensis Jacq., native to Central and West Africa (Daza et al., 2021). The OxG genotype exhibited some specific characteristics different from those of Elaeis guineensis. Such characteristics includes a higher productivity of palm oil per hectare (>33 t of FFB ha−1 year−1), a better response to bud rot disease, longer plant life (more than 25 years), and, in most of cases, a higher content of oleic acid (55%) in the palm oil produced (Rincón et al., 2013; Barcelos et al., 2015; Ayala and Romero, 2019).

In Colombia, the cultivation of OxG started in the 1980s in a few hectares of area that represented less than 0.5% of the total area of oil palm cultivation at that time. Due to the resistance of OxG against bud rot disease, the crop has reported continuous growth until it reached more than 80 thousand hectares in 2021 (SISPA, 2021). For the next few years, the cultivation area for OxG is expected to grow, especially in areas reporting the disease (Ayala and Romero, 2019). Having palm buds with a high tolerance to rot is extremely advantageous for agricultural production, especially in regions where this crop is economically significant. However, palm bud rot also presents considerable challenges. Here are the main advantages of rot-resistant palm buds: they tend to have a longer shelf life, reducing losses during storage and transportation (Rincón et al., 2013). This is crucial for maintaining the quality and safety of the food until it reaches the end consumer. Resistance to rot can result in lower costs for chemical products to control diseases and fungi, as well as reducing the need for special handling to avoid damage during harvest and transportation. The reduction in the use of fungicides and other chemical treatments due to greater resistance to rot contributes to more sustainable agricultural practices, with less environmental impact and a lower risk of pathogen resistance development (Hassan et al., 2024). One of the biggest challenges is to identify or develop palm varieties that are naturally resistant to rot. This may involve genetic improvement programs and plant selection. Many small producers may not have access to information or resources to implement effective management practices against rot. Agricultural extension and education programs are essential to spread best practices (Nurazah et al., 2021). Tab. 2 shows the main characteristics of the OxG cultivars with respect to those of the E guineensis cultivar.

One of the major differences between OxG cultivars and African palm cultivars is the need for assisted pollination of female flowers because of the low viability and germinability of pollen. In absence of assisted pollination adequate bunches are not formed; therefore, the productivity of the fruit and the palm oil are affected (Rincón et al., 2013). Adequate pollination of the inflorescences (time, quantity, season) can generate a 30% increase in the weight of the bunches compared to that of a non-pollinated fruit. It is possible to improve oilseed potential (disease resistance) by up to 5% and reduce the use of insecticides and pesticides (Osorio-Guarín et al., 2019).

In contrast, studies conducted in Colombia by the Cenipalma Research Center (Nieto et al., 2021), identified significant differences in the palm oil extraction rate in POM when processing OxG fruits compared to Guineensis fruits. The differences were directly correlated with the process variables in the digestion and fruit-pressing stages. These differences are mainly attributed to the pressure required in the screw press (higher), shell and kernel content (lower), palm oil per kg of fruit (higher), volume of press liquor (higher), distribution of volumetric phases (composition), and percentage of acidity of the oil (lower). In general, the processing of OxG fruit bunches reports a drop in capacity in the range of 8–10% with respect to African palm fruit, causing the need to improve the industrial process for the extraction of OxG palm oil (Nieto, 2013).

Table 2

Characteristics of the Elaeis guineensis palm and the Interspecific hybrid (OxG) palm.

2.2 Case study

To analyze the energy and environmental performance of Colombian palm oil biodiesel, a representative scenario of the biodiesel production chain that includes cultivation of oil palm, transport of FFB, oil extraction in the POM, transport of CPO, and refining and transesterification of the oil, was studied. The information used to build this scenario was collected through field visits to a POM located in eastern Colombia, one of the regions with the highest CPO production in the country (Fedepalma, 2021). The POM processes using the two types of fruits evaluated, that is, E. guineensis and interspecific hybrid OxG, with a production capacity of 70 t h−1 of FFB operating at 3583 h y−1. In total, approximately 250 thousand tons of FFB are processed per year in the mill, obtained from approximately 10,000 ha of oil palm, with an average crop yield of 25.08 t FFB ha−1y−1. In order to harmonize the primary data collected for the interspecific hybrid OxG, we considered the same number of planted hectares as in the case of E. guineensis (10,000 ha y−1). However, the OxG crop yield was 30.55 t FFBOxG ha−1 y−1, higher than that of E. guineensis, and the total FFBOxG processed per year in the mill corresponded to 305,500 t FFBOxG. Considering the industrial conditions for processing FFBOxG (i.e., reduction in tons of FFB processed per hour), the production capacity in the mill is on average 62.7 t FFBOxG h−1 in 4872 h y−1 working hours. For the two palm species, the same technical parameters of the cogeneration system were used, as described in Section 2.2.1. Furthermore, it is noteworthy that the POM’s electrical consumption matrix is distributed as follows: 57% is supplied through an internal combustion engine that burns biogas (generated from POME), 37% is generated by back pressure steam turbine (BPT), and 6% through an internal combustion engine that burns diesel used mainly during start-up, failure, and maintenance periods. In contrast, the biodiesel plant (during refining and transesterification stages) consumes electricity from the Colombian electricity grid, and the thermal energy demand is fulfilled through a boiler (80% efficiency) that burns natural gas, which has an energy density of 39.3 MJ/kg.

For FFB, transporting 50 km from the plantation area to the mill was considered. The inputs to the processes in the mill include water, power energy, and diesel. After obtaining the CPO in the mill, it was transported to a biodiesel plant (refining, transesterification, and biodiesel). For CPO transport, trucks were considered to run for 200 km from the mill to the biodiesel plant. The inputs included in this process were steam, electricity, and diesel.

2.2.1 Combined heat and power system

In the Colombian oil palm sector, since the mid-1950s and 1960s, cogeneration systems with fibers and shells have been applied to meet the thermal demand of their industrial processes, as well as to achieve electrical self-sufficiency. In this study, the steam required to run the POM was assumed to be generated by the combustion of the fiber and shell in a high-pressure boiler (300 PSI). The saturated steam produced is used in a backpressure steam turbine (BPT) to generate electricity for the mill (Fig. 2).

Table 3 lists the yields, moisture content, and heating value of the fiber and shell used as fuel in the CHP system. The analyses of E. guineensis and Interspecific hybrid OxG were obtained in a laboratory. The samples were analyzed according to the ASTM D5291 standard and the mass balances carried out by the authors.

The CHP system shown in Fig. 2 was simulated in GateCycle v.6.1.2 software, developed by General Electric, and corresponds to the current configuration of the POM process. A simulation was performed for each type of fruit. In the both cases, the isentropic efficiency of the turbine is 75%. The CHP system considers the use of two boilers to produce saturated steam (a 30-bar boiler with 70% efficiency and a 3.5-bar boiler with 62% efficiency) for cogeneration. The fuel for the boiler is palm biomass, which is a fiber-shell mixture. Based on the characteristics of each palm fruit evaluated, the percentage of each component of the mixture was established as follows: when processing E. guineensis, the mixture by weight was 70% fiber and 30% shell. When OxG was processed, the mixture contained 68% fiber and 32% shell. Two indicators were used for the CHP system efficiency evaluation: (a) global thermal efficiency (ηo), which considers the net electrical power (WL) generated by the system (Eq. (2.1)), and (b) the energy utilization factor (EUF), a concept widely used in cogeneration systems as it includes the net generated electrical power and useful heat (Qu) generated to meet the thermal demand of the system (Eq. (2.2)).

ηo=WLm˙fuel(LHVfuel)(2.1)

EUF=WL+Qum˙fuel(LHVfuel)(2.2)

thumbnail Fig. 2

Combined heat and power (CHP) system.

Table 3

Energy characteristic of the biomass used in the cogeneration system.

2.3 Energy performance

The energy performance indicators include i) the global efficiency of the system (ηgl) and ii) energy productivity per hectare (σpalm). The global efficiency of the system, which is defined as the ratio between the useful energy of the products (CPO, CPKO, PKC, methane, biodiesel, and glycerin) and the energy of the inputs of the process (FFB, fiber, and shell), was calculated according to Equation (2.3).

ηgl=(m·prod×LHVprod)m·Ins×LHVIns(2.3)

where, prod = Energy of the manufactured products; LHVprod= Low heating value of the products; Ins = Energy of the inputs; LHVIns = Low heating value of the inputs.

The indicator energy productivity per hectare shows the amount of energy converted into products, that is, CPO, CPKO, PKC, methane, biodiesel, and glycerin per hectare. It is determined by considering the production of one hectare of palm cultivation, according to Equation (2.4).

σPalm=(m·produtoPCIproduto)m·PalmψPalm (2.4)

where Ψ represents the productivity of FFB per hectare for Elaeis guineensis and Interspecific hybrid OxG and corresponds to 25.08 t FFB ha−1 and 30.55 t FFB ha−1, respectively). The σpalm value is expressed as GJ ha−1. The remaining parameters are listed in Tab. 4 (Yusniati Parinduri and Sulaiman, 2018).

Table 4

Energy density of the analyzed products.

2.4 Environmental analysis

LCA methodology was used to calculate the environmental performance of the conversion of palm oil from the two fruit genotypes (Elaeis guineensis and interspecific hybrid OxG) into biodiesel. The environmental analysis was carried out for each type of oil palm fruit, assuming a cradle-to-grave system boundary, i.e., evaluating each process/technology required to produce biodiesel through the genotypes above and the environmental and energy costs to produce it. The functional unit (FU) was defined as 1.0 MJ of energy produced, i.e., the unit of energy under which the number of pollutants and energy required or emitted in the process is calculated. The analysis included five sub-processes: crop cultivation (fertilizer application, pesticides), transportation (FFB and CPO), crude oil palm extraction, refining, and transesterification. The input data for calculating the environmental analysis for all cases were taken from i) data collected during the field visit to a POM, ii) Ecoinvent database (Simapro v.8.0.3), iii) information from a previous study by (Nieto, 2013), and iv) information from (Ramirez–Contreras et al., 2020; Garcia-Nunez et al., 2016; Nieto et al., 2021; Garcia-Nunez et al., 2016; Arrieta et al., 2007; Yáñez Angarita et al., 2009), Figure 3.

thumbnail Fig. 3

System boundaries of the analyzed products.

2.4.1 Life cycle inventory

The LCI data for crop cultivation for both fruit genotypes were obtained from a field visit to a POM in eastern Colombia. For this study, the crop lifespan for E. guineensis palm was estimated to be 25 years, and for interspecific hybrid OxG it was estimated to be 30 years. The main inputs for each stage of the biodiesel production chain, located in the annexes, are shown in Tables A.1, A.2, A.3, A.4 and A.5.

2.4.2 Life cycle impact assessment (LCIA)

In this phase of the LCA, the potential environmental and human impacts of biodiesel production were evaluated. These impacts were translated into indicators that consider a series of steps according to the ISO 14040 and ISO 14044 standards (selection, classification, and characterization) (Dongyan Mu and Xin, 2020; Zhichao and Fang, 2021). Of the three major endpoint categories (ecosystem impacts, human health, and resource depletion) with 15 midpoint categories, seven midpoint categories were considered: non-renewable energy, global warming, eutrophication, aquatic acidification, terrestrial acidification, ozone depletion, and respiratory inorganics. The impacts were quantified using the Impact 2002+ method, whereas GHG emissions were calculated using SimaPro v.8.0.3 software. Data inputs to estimate the carbon footprint were obtained from the Ecoinvent database, field studies, and literature. For land-use change (LUC), the percentage of areas converted to oil palm E. guineensis corresponded to 37.8% for rice, 25.9 % for replanted E. guineensis, and 36.4% for grazing areas. For LUC, the percentage of areas converted to interspecific hybrid OxG corresponded to 40.8% for rice, 18.8% for renovation of OxG plantations, and 40.4% for pasture areas. The carbon stock of the crop was calculated considering data from the previous study (Rivera-Méndez et al., 2017) and the lifetime of the plantation for each type of fruit evaluated. It included both belowground and aboveground biomass. We assumed that CO2 absorption in the palm crop occurred on the fronds and trunk of the plant. The products contained in the FFB, that is, CPO, fiber, kernel, shell, and empty fruit bunches, were considered carbon-neutral.

2.4.3 Life cycle efficiency

Several energy indicators are available for quantifying the net energy flow and assess the overall efficiency of the processes. The most commonly used ones are the net energy balance (NEB), net energy yield (NEY), and NER (Ocampo Batlle et al., 2020; Rocha et al., 2014). Nonetheless, NER, also called Life Cycle Energy Efficiency (LCEE), is the most used indicator for calculating the net energy produced from a system and can be considered an indicator of the sustainability of the life cycle energy balance (Zhang et al., 2017; Mayer et al., 2020; Brambilla et al., 2018). In this study, NERTotal was used to comparatively evaluate palm genotypes. NERtotal is expressed as the sum of the net energy production (biodiesel and co-products) divided by the net energy input, which includes the energy inputs in the cultivation stages (fertilizers, agrochemicals, lubricants, and fossil fuel), transport (fossil fuel), and industry (thermal/electric energy and fossil fuel), as presented in equation (2.5).

NERtotal=Net energy production(MJ)Net energy input(MJ)(2.5)

As a complementary indicator of LCEE, we used the FER, also called the renewability factor (Mata et al., 2011), which is defined as the ratio between the final energy of the fuel and the fossil energy required to produce it (Eq. (2.6)).

FER=Fuel EnergyOutputFossil EnergyInput(2.6)

3 Results and discussion

3.1 Energy performance

Figure 4 shows the mass and energy balance for E. guineensis genotype. When E. guineensis FFB is processed, POM has an energy consumption of 15.09 MWt (steam at 350 kPa) and 2.1 MWele. For the processing of palm oil of this genotype in the biodiesel plant (refining and transesterification), a demand of 18.33 MWt (steam at 350 kPa) and 1.95 MWele is reported. It should be noted that the energy demanded by the biodiesel plant is obtained from processes external to the evaluated system. The POME obtained in the POM was sent to a covered anaerobic lagoon, aiming to obtain biogas through anaerobic digestion producing 1981 m3 biogas. Of the total biogas, 634.4 m3 was used to generate 1.63 MWele using an internal combustion engine (ICM). Furthermore, 71.4% of fiber and 48.5% of shell generated by the extraction of CPO were burned in a cogeneration system that provided 37% of the electricity required by the POM and it fully supplied the thermal energy required by the POM.

In Figure 5, the mass and energy balance of the interspecific hybrid (OxG) genotype is presented. The amount of fruit processed in this case is less than that of E. guineensis as explained in Section 2.1. The energy (thermal and electric) required to process OxG fruit at the mill is higher (15.1 MWt and 2.2 MWele) compared to that needed in case of E. guineensis due to low or no nut content in the OxG FFBs, which are used as fuel for power generation. A decrease of 4.2% in the POME was also observed with respect to the processing of E. guineensis fruit, possibly due to the characteristics of the OxG fruit and the use of less water for its processing in the mill. A lower production of biogas (1774 m3) and consumption of this biogas in the ICEbiogas system (858 m3) are reported to generate the 1.6 MWel required to complement the energy required to run the POM. The biodiesel plant (refining and transesterification plant) demands 14.7 MWt (steam at 350 kPa) and 1.19 MWele. It should be noted that the energy demanded by the biodiesel plant was supplied through processes that were external to the evaluated system.

The net efficiency of electricity generation is low for those of the genotypes involving more than 5% for guineensis and OxG fruits in relation to the energy flow in the biomass fed in the boilers. This can be explained by the fact that the cogeneration cycle operates using 50% of the mass flow coming from the superheated steam boiler (30 bar and 70% efficiency), and with the remaining 50% of the steam is obtained from a saturated steam boiler (3.5 bar and 62% efficiency). The low net efficiency of the generation cycle refers to the low operating pressures of the boilers (30 bar and 3.5 bar) and the type of turbine used in this cycle (BPT with 75% efficiency) compared to those used in a conventional generation cycle, which operate with 60 bar boilers (90% efficiency) and condensation-extraction turbines (CEST) that have efficiencies greater than or equal to 85%.

Figure 6 shows the ηglo and palm for the fruit genotypes evaluated. For E. guineensis, the ηglo is greater than that for the interspecific hybrid OxG while considering the increase in the consumption of thermal (8.2%) and electric (10.2%) energy during the process the FFB of the OxG fruit. The σpalm of the OxG fruit is higher than that of the guineensis fruit which is attributed to the higher productivity of OxG per hectare (30.55 t FFB ha year−1). It means about 18% more FFB produced in OxG and about 4% more palm oil content per hectare per year (5.04 t CPO ha year−1).

thumbnail Fig. 4

Energy and mass balance of biodiesel production from E. guineensis. The colors in the lines represent the products and by-products of each phase: green line for the extraction phase; purple line for refining; blue line for transesterification; red line for POME and gray line for cogeneration.

thumbnail Fig. 5

Energy and mass balance of biodiesel production from Interspecific hybrid (O × G). The colors in the lines represent the products and by-products of each phase: green line for the extraction phase; purple line for refining; blue line for transesterification; red line for POME and gray line for cogeneration.

thumbnail Fig. 6

Indicators of the first law of thermodynamics of total BD production from E. guineensis and Interspecific hybrid (OxG).

3.2 Environmental analysis

3.2.1 Carbon Footprint

Figure 7 shows CO2eq emissions, carbon capture, and the carbon footprint for the biodiesel production cycle from palm oil. The value of emissions in the figure was reported above the zero line and removals as negative values under the zero line. The largest share of CO2eq emissions in the evaluated cases come from the farming (217 and 180 kg CO2eq t BD−1 for OxG and E. guineensis respectively) and transesterifications (131 kg CO2eq t BD−1 for both genotypes) stages. These results are in line with the results reported in the studies by (Ramirez –Contreras et al., 2020; Yáñez Angarita et al., 2009; Pleanjai and Gheewala, 2009; De Souza et al., 2010; Mata et al., 2011). The main emission factors are related to the CO2 released in combustion and chemical fertilization (use and application), where 39% of the total emissions correspond to the fertilization of E. guineensis and 42% of it correspond to the fertilization of interspecific hybrid OxG fruit. The total CO2 emissions related to the plantation are 106.73 kg t−1 FFB for E. guineensis and 120.57 kg t−1 FFB for interspecific hybrid OxG. The carbon captured by FFBs due to photosynthesis is 1.45 t CO2eq t−1 FFB (E. guineensis) and 1.3 t CO2eq t−1 FFB (interspecific hybrid OxG). The carbon footprint of the biodiesel produced from E. guineensis is −960 kg CO2eq t−1 FFB and −760 kg t−1 FFB for that produced from the interspecific hybrid OxG.

The production of palm oil biodiesel from the interspecific hybrid OxG report higher emissions than E. guineensis since it needs a greater consumption of fertilizers in the crop (13.2% N and 3.27% K2O more) and diesel in transport (29.67% more). In addition, a greater energy demand (2.54% higher electric energy and 8.95% higher thermal energy) to produce one ton of palm oil is required. Nevertheless, the emissions from the use of pesticides and insecticides during OxG cultivation was 23.77% lower than that of E. guineensis (genotype with greater susceptibility to pests).

Figure 8 shows a comparative study on GHG emissions for palm oil biodiesel production, including our study. These emissions were reported to range from 4.34 × 10−2 kg CO2eq MJBD−1 (Yáñez Angarita et al., 2009) to 1.21 × 10−2 CO2eq MJBD−1 (De Souza et al., 2010). The palm oil biodiesel production system reported an average emission value of 7.1 g CO2eq MJBD−1) for an agricultural yield of 18.4 t FFB ha−1. The emissions of the cultivation stage for the two cultivars (4.45 and 5.45 g CO2eq MJBD−1 for E. guineensis and interspecific hybrid OxG, respectively) were lower than those reported in the literature. This could be is due to its use in the field of the biomass (28.6% of fiber and 100% of EFB) generated in the POM. Biomass degradation is a major contributor to CO2 release, followed by emissions from the combustion of fibers and shells in steam boilers. These two emission sources are generally not considered in LCA studies of the palm oil process (Garcia-Nunez et al., 2016) because the CO2 released comes from carbon (C) stored in the FFB. However, in this study, all emissions associated with the return of the co-products to the field were considered.

thumbnail Fig. 7

GHG emissions: a) Share of emissions by life cycle stages. b) Carbon Footprint per each genotype.

thumbnail Fig. 8

GHG emissions in several studies of the palm oil sector.

3.2.2 Environmental impact assessment

Seven midpoint categories for biodiesel production from the two palm oil genotypes were evaluated, considering 1 MJ of biofuel produced as a FU, as mentioned previously. Table 5 and Figure 9 show the results by impact category. All categories showed higher values for the interspecific hybrid OxG genotype than that for E. guineensis. This is a consequence of the higher demand for nitrogen (13.2%) and potassium oxide (3.27%) during chemical fertilization. In addition to the higher consumption of diesel in the transport of the fruit to the POM (29.67%), thermal energy (26.1%), and electricity (29.3%) for the processing.

Overall, the impact categories (Fig. 9) related to the production of the interspecific hybrid OxG were higher than those reported for E. guineensis as the category’s aquatic eutrophication, terrestrial acid, and aquatic acidification associated with the quality of the ecosystem increased by 12.2%, 17.5%, and 14.0%, respectively. These changes were related to the release of compounds, such as phosphate, NH3, NOx, SOx, and P, into the soil and water bodies. Emissions of particulate matter (PM2.5), sulfur (S), and nitrogen oxides (NOx) related to diesel consumption had an impact on respiratory inorganics and the depletion of the ozone layer, representing an increase of approximately 47.6 % and 4.3%, respectively. Furthermore, the increase in diesel consumption for transporting the fruit to the mill directly leads to an increase in the indicator non-renewable energy use by 8.4% and to a decrease in carbon capture in the global warming category by 18.6%.

Table 5

Impact categories for biodiesel production (1.0 MJ) from interspecific hybrid OxG and E. Guineensis.

thumbnail Fig. 9

Impact categories comparison for interspecific hybrid OxG and E.Guineensis.

3.2.3 Assessment of damage categories and life cycle indicators

Figure 10 shows the results of the damage endpoint impact categories (resources, climate change, ecosystem quality, and human health) for biodiesel production. The contributions of these categories were higher for the interspecific hybrid OxG cultivar than in case of E.guinenssis cultivar, except for the climate change category. Human health impact category was the major contributor (47.57%), attributed to the emissions of PM, NOx, SOx during transport of FFB to the mill (diesel consumption is almost 30% more than in the case of E. guinenssis).

The NERTotal and FER indicators were estimated for two alternative productions of biofuel/bioproducts, and the results are shown in Figures 11 and 12. The assessment of NERTotal of the two genotypes (E. Guineesis and interspecific hybrid OxG) in our study demonstrated 3.86 energy units for E. guineensis and 2.82 energy units for interspecific hybrid OxG considering the stages BD, methane gas, glycerin, CPKO, PKC, and PFAD. The energy efficiency of biodiesel production is 4 and 3 times (in E. guineensis and interspecific hybrid OxG, respectively) greater than the energy input. The NERTotal values, reported in the literature that considered biofuels and bioproducts, for the BD chain in Thailand, Malaysia, Indonesia, Colombia, and Brazil were between 1.63 and 3.98 (Fig. 11). Nevertheless, a comparison of the energy balance, including all products and by-products, showed that the potential value of NERTotal was greater for E. guineensis than that for interspecific hybrid OxG. Some studies on bio-based palm oil products have also reported higher values of NER between 17.7 and 22.9 (Garcia-Nunez et al., 2016; Ocampo Batlle et al., 2020). The NERTotal for E. guineensis and interspecific hybrid OxG is higher than the NERTotal for the conventional fossil diesel production cycle (0.19), that is, the same energy unit consumed is produced in 1:4 and 1:3 energetic units from E. guineensis and interspecific hybrid OxG genotypes, respectively.

A total FER of 5.58 and 4.48 (MJout/MJin) was calculated for the E. guineensis and interspecific hybrid (OxG) genotypes, respectively (Fig. 12). These results are comparable to those of previous studies on the production of biodiesel from palm oil (1.6 6.6 MJout/MJin). The FER values reported by (Ramirez–Contreras et al., 2020; De Souza et al., 2010; Yáñez Angarita et al., 2009) are greater than those obtained in this study, given that the cogeneration system operates with more efficient boilers, uses CEST (which have surplus electricity production), and the refining and transesterification plant is attached to the POM.

Notably, the interspecific hybrid (OxG) genotype has a higher consumption of fossil energy than that recorded in case of E. guineensis genotype. This is attributed to the greater demand for fertilizers, agrochemicals, and diesel during the agricultural and transportation stages. However, it was noticed that the interspecific hybrid (OxG) was one and three energy units more renewable than E. guineensis as evaluated in studies done by (Mata et al., 2011; Pleanjai and Gheewala, 2009), respectively.

thumbnail Fig. 10

Damage category impact share for BD production scenarios.

thumbnail Fig. 11

Comparison of the NER obtained with values reported in the literature and conventional diesel, including the present study.

thumbnail Fig. 12

Comparison of the FER obtained with values reported in the literature and conventional diesel, including the present study.

4 Future works

Due to the proposed work, its results and discussions, some topics that can be evaluated in future work are indicated below:

  • The life cycle assessment applied does not consider or compare the economic aspects of the genotypes in question. Therefore, parameters such as the reduction or increase in production costs of the interspecific hybrid OxG and its biodiesel must be calculated. This is because when in the future we want to evaluate not only the life cycle, but also the sustainability of the life cycle, we need the economic values associated with each process.

  • At the start of the proposed work, the main advantage of the OxG interspecific hybrid genotype was its greater resistance to rot compared to Elaeis guineensis. However, this work does not explore resistance to other diseases, pests or variations in climate, so that when compared to Elaeis guineensis we can have a better idea of the viability of replacing one type with another.

  • The work shows that the genotype obtained from crossbreeding is less environmentally damaging when looking at life cycle indicators. On the other hand, replacing the existing genotype may have social implications in terms of the transfer of technology to produce the new genotype. Therefore, in future work it would be pertinent to evaluate the social impact of replacing the current genotype with another, for example, using the hierarchical analytical process method.

5 Conclusions

This study evaluated and compared the energy efficiency and environmental performance of the biodiesel production chain of two oil palm genotypes (E. guineensis Jacq and interspecific hybrid OxG) currently cultivated in Colombia. The energy balance showed that the production of biodiesel from the interspecific hybrid OxG resulted in a 6.2% reduction in the overall efficiency of the system when compared to the biodiesel from E. guineensis. This reduction could be associated with the inefficiency of the machinery currently used at the mills, because these machines were previously designed according to the characteristics of the E. guineensis fruit (mainly related to nut and shell content). Nonetheless, the interspecific hybrid OxG fruit showed a 4% higher potential in energy productivity per hectare (σpalm), without any modification in the mechanical processes of the mill, what can be attributed to higher productivity (30.55 t FFB ha year−1) compared to that of E. guineensis.

The LCA of biofuels produced from palm oil (whether conventional or hybrid) has the potential to reduce both global warming and the impacts generated by changes in land-use in Colombia. The GHG emissions of E. guineensis palm oil biodiesel were 12.5 g MJBD−1 and the emissions from the interspecific hybrid OxG palm oil biodiesel was 13.8 g MJBD−1. This 10.4% increase in emissions from the interspecific hybrid OxG was mainly due to the increase in diesel consumption in the transport of fruit from the crop to the POM, in addition to a greater demand for biomass to run the cogeneration system. However, carbon capture was slightly greater for E. guineensis than that for the OxG interspecific hybrid. Consequently, the carbon footprint reported for E. guineensis biodiesel is slightly higher (–957 kg CO2eq t BD−1) than that of the hybrid studied (–758 kg CO2eq t BD−1).

In Colombia, the growth and production of interspecific hybrid OxG are critical issues because of the resistance of this crop to bud rot disease. Moreover, other characteristics, such as the increase in palm oil yield per hectare and a longer lifetime for this cultivar compared to the other, make its use attractive. This novel study is the first to compare two chief oil palm cultivars planted in Colombia. Therefore, it is crucial to continue comprehensive analyses to evaluate the environmental, social, and economic significance of the production of these cultivars, considering the entire production chain.

Acknowledgments

The authors wish to express they’re thanks to the Research Support Foundation of the State of Minas Gerais (FAPEMIG), the National Council for Scientific and Technological Development (CNPq), the Coordination for the Improvement of Higher-Level Personnel (CAPES), and the Palm Oil Promotion Fund (FFP).

Conflicts of interest

The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper.

Data availability statement

The datasets used during the current study available from the corresponding author on reasonable request.

Author contribution statement

D-I.N.M.: Conceptualization, methodology, data analysis and curation, writing-original draft preparation, review &editing. O.J.V.: Data curation, organization, technical assistance, review &editing. E.A.O.B.: Software, methodology, technical assistance. A.M.G.: Technical assistance, review &editing & improved the language. D.A.M.F.: helped in revising the manuscript & Conceptualization, investigation, writing-reviewing and editing. N.E.R.C.: Methodology, technical assistance, data validation. J.A.G.N.: Software, technical assistance, review &editing. P.T.B.: data analysis and curation, review &editing. E.E.S.L.: Organization, technical assistance, review &editing. All authors have read and approved the final manuscript and agreed to the published version of the manuscript.

Appendix

Table A.1

LCI of crop cultivation per hectare per year.

Table A.2

LCI of the oil extraction stage (t of crude palm oil).

Table A.3

LCI for the cogeneration system (1 kWh of generated electricity).

Table A.4

LCI of palm oil refining stage (t of oil-refined).

Table A.5

LCI of the oil transesterification stage (t of biodiesel).

Source: (Nieto et al., 2021; Nieto, 2013).

References

Cite this article as: Mogollon DIN, Venturini OJ, Batlle EAO, González AM, Munar-Florez DA, Ramirez-Contreras NE, García-Nuñez JA, Borges PT, Lora EES. 2024. Environmental and energy issues in biodiesel production using palm oil from the interspecific hybrid OxG and Elaeis guineensis: a case study in Colombia. OCL 31: 25.

All Tables

Table 1

Main studies that carry out an LCA of the use of interspecific hybrid OxG and Elaeis guineensis genotypes for biodiesel production.

Table 2

Characteristics of the Elaeis guineensis palm and the Interspecific hybrid (OxG) palm.

Table 3

Energy characteristic of the biomass used in the cogeneration system.

Table 4

Energy density of the analyzed products.

Table 5

Impact categories for biodiesel production (1.0 MJ) from interspecific hybrid OxG and E. Guineensis.

Table A.1

LCI of crop cultivation per hectare per year.

Table A.2

LCI of the oil extraction stage (t of crude palm oil).

Table A.3

LCI for the cogeneration system (1 kWh of generated electricity).

Table A.4

LCI of palm oil refining stage (t of oil-refined).

Table A.5

LCI of the oil transesterification stage (t of biodiesel).

All Figures

thumbnail Fig. 1

Methodology flowchart for thermodynamic and environmental analysis of the different genotype considered.

In the text
thumbnail Fig. 2

Combined heat and power (CHP) system.

In the text
thumbnail Fig. 3

System boundaries of the analyzed products.

In the text
thumbnail Fig. 4

Energy and mass balance of biodiesel production from E. guineensis. The colors in the lines represent the products and by-products of each phase: green line for the extraction phase; purple line for refining; blue line for transesterification; red line for POME and gray line for cogeneration.

In the text
thumbnail Fig. 5

Energy and mass balance of biodiesel production from Interspecific hybrid (O × G). The colors in the lines represent the products and by-products of each phase: green line for the extraction phase; purple line for refining; blue line for transesterification; red line for POME and gray line for cogeneration.

In the text
thumbnail Fig. 6

Indicators of the first law of thermodynamics of total BD production from E. guineensis and Interspecific hybrid (OxG).

In the text
thumbnail Fig. 7

GHG emissions: a) Share of emissions by life cycle stages. b) Carbon Footprint per each genotype.

In the text
thumbnail Fig. 8

GHG emissions in several studies of the palm oil sector.

In the text
thumbnail Fig. 9

Impact categories comparison for interspecific hybrid OxG and E.Guineensis.

In the text
thumbnail Fig. 10

Damage category impact share for BD production scenarios.

In the text
thumbnail Fig. 11

Comparison of the NER obtained with values reported in the literature and conventional diesel, including the present study.

In the text
thumbnail Fig. 12

Comparison of the FER obtained with values reported in the literature and conventional diesel, including the present study.

In the text

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