4.1. Global Warming Potential (GWP)
Greenhouse gas (GHG) emissions from SIS and EOS are shown in
Figure 2. The global results were 22.3 kg CO
2-eq kg
−1 for SIS and 16.4 kg CO
2-eq kg
−1 for EOS. Results for SIS regarding GWP are close to those estimated in studies such as Lupo et al. [
41] with 23.0 kg CO
2-eq kg
−1 for the USA, Ruviaro et al. [
42] with estimates of 23.4 kg CO
2-eq kg
−1 for beef production in Brazil, or Mogensen et al. [
43] with 23.1 kg CO
2-eq kg
−1 in Denmark and 25.4 kg CO
2-eq kg
−1 in Sweden. Nguyen et al. [
44] reported results between 16.0 and 27.3 kg CO
2-eq kg
−1 for the European Union. According to Leip et al. [
45], the average GHG emissions from the production of ruminants in the European Union, including feed production, is approximately 20–23 kg CO
2-eq per kg of meat and the average is 22.2 kg CO
2-eq kg
−1 to beef produce.
GHG emissions estimated for EOS are close to those presented by Casey and Holden [
46], who obtained emissions 13.8 kg CO
2-eq kg
−1 when studying different animal production systems. In addition, the authors argue that different animal production may reduce GHG emissions, but this should not affect meat production, while trying to find the balance between production and environmental protection. Peters et al. [
47], using Australian case studies, found 17.5 kg CO
2-eq kg
−1, Williams et al. [
48] found 18.2 kg CO
2-eq kg
−1 for the United Kingdom (UK), and Alig et al. [
49] found 14.8 kg CO
2-eq kg
−1 for Switzerland; all of these studies reported similar results for GHG emissions in EOS. Organic animal production appears as a valuable alternative that can meet the need for promoting low environmental impact production. Studies carried out by Haas et al. [
50] in Germany and by Wood et al. [
51] in Australia concluded that a transition to organic production could be a viable way to reduce energy use and GHG emissions.
Figure 3 shows the main GHG emissions for SIS and EOS systems. CH
4 from the enteric fermentation process represents 60.5% and 62.8% of the total GHG emissions for SIS and EOS, respectively. However, when analysis is based on the absolute emission values, potentially higher CH
4 emissions are found in SIS (13.5 kg CO
2-eq kg
−1) when compared with those from EOS (10.3 kg CO
2-eq kg
−1). These results are consistent with research addressing enteric fermentation with a weight of 40–70% of the total GHG emissions [
52]. Moreover, Salvador et al. [
20] addressing the environmental impact of organic and conventional small-scale production in mountain areas estimated contributions from enteric CH
4 of 52.8% for EOS and 48.6% for SIS. Similar proportions were obtained in studies developed by Meier et al. [
25] in which the EOS systems enteric CH
4 contribution to GHG emissions was 55% and 50% for SIS. These authors argued that such higher CH
4 emissions are a consequence of forage based diets used in the organic system.
Nitrous oxide (N
2O) emitted from the manure handling accounted for 35.9% (SIS) and 34.7% (EOS) of the total emissions. These results are at the upper limit of the interval presented in Cerri et al. [
53], which reported a contribution in N
2O to the GHG between 19–33%. In this sense, the feed composition in the different varieties of exploitation can affect the flow of N
2O emitted into the atmosphere. The protein content consumed by the cattle affects the digestion of nitrogen and the amount of nitrogen gaseous emission that are excreted [
54].
Emissions from the use of fuel and electric energy, mostly CO
2, have low contributions, 3.5% in SIS and 2.5% in EOS. Wiedemann et al. [
55], in a study to estimate GHG emissions in Australian beef cattle industry, found CO
2 contributions to be in the range of 3–5% from fossil fuels and electrical energy used. It seems clear that direct and indirect CO
2 emissions from fuel and electricity use represent a relatively small part of the carbon footprint in beef production chain [
56]. Transport and treatment of meat waste by incineration also appear to have little relevance in this category of environmental impact [
29].
Hyslop [
57] carried out simulations for the UK context to evaluate strategies to reduce GHG emissions and concluded that short-term finishing systems, linked to higher production efficiency using feeding stuffs, could substantially reduce GHG. The development of management techniques for the productive systems and the increase in quality of the feeding of animals could reduce the enteric emissions of methane by up to 22% [
58].
Furthermore, there may be substantial reductions in GHG emissions in animal production through genetic screening, forage selection and management, inhibition of methane, and animal care [
59]. Another solution to reduce these GHG emission is to improve the production and intensification of pastures to reduce the fattening time before animal slaughter [
60].
Figure 4 shows the direct and indirect GHG emissions from the slaughterhouse with natural gas boilers (Mng) and from the slaughterhouse with a pellet boiler (Mp). Emissions of GHG per functional unit were similar in both slaughterhouses and relatively low when compared to GHG emissions from farming 0.233 kg CO
2-eq kg
−1 for Mng and 0.285 kg CO
2-eq kg
−1 for Mp (includes all emissions).
The use of pellets is commonly regarded an energy consumption that reduces GHG emission. Pellets used as biomass fuels are generally considered to be carbon-neutral due to the production of wood and the accumulation of CO
2 for their growth [
61,
62,
63].
Mogensen et al. [
64] estimated GHG emissions throughout the beef production system, from food production to slaughter, with a global amount of 19 kg CO
2-eq kg
−1, and only 0.2 kg CO
2-eq kg
−1 was inputted to processes taking place at the slaughterhouse.
Similarly, Desjardins et al. [
65] reported that transport-associated GHG emissions for slaughter and slaughter operations were 0.18 kg CO
2-eq kg
−1, or about 2% of GHG emissions from animal production. These results show that the environmental impact intensity related to GHG emissions in slaughterhouses is lower when compared to the animal production processes.
Therefore, the contributions and emissions to the GWP were lower than the Mng. For this study, total GHG emission values were reduced by 53% by neutralizing the output of carbon by the pellet boiler (from 0.285 kg CO2-eq kg−1 to 0.134 kg CO2-eq kg−1).
Contributions by source of GHG emissions from the slaughter process can be observed in
Figure 5. The use of inputs such as heat and electricity were the largest contributors (Mng with 75.0% and Mp with 77.5%), followed by the incineration of meat wastes (Mng with 20.5% and Mp with 16.6%) and of transport (4.5% for Mng and 5.9% for Mp). These results agree with those on the studies of Mogensen et al. [
64] that analyzed different beef production systems, focusing on the slaughter phase.
Mp has a specific energy consumption lower than Mng. The amount of GHG emissions from the meat waste treatment process produced is also an indicator of the efficiency of the slaughter process, as it indirectly identifies the amount of waste that is destined for incineration. That means, that the lower the losses during the slaughter process, the greater the amount of meat available for commercialization.
Also relevant is the contribution of boiler emissions, in which Mp had higher GHG emission (58.0%) than Mng (34.9%) (
Figure 5). Boiler combustion using natural gas as fuel provides a better energy yield, generates less waste emitted to the atmosphere, and, consequently, leads to an improvement in air quality [
66]. However, when the Mp (neutral C) is taken into account, the boiler decreases its contribution to 22% lower than the Mng.
4.2. Acidification Potential (AP)
Table 3 indicates main results for the animal production systems under study for acidification potential (AP). SIS had 168.0 g SO
2-eq kg
−1 for AP. In a study by Lupo et al. [
41] using a model of LCA to estimate the environmental impacts associated with four different systems of North American beef production, an impact of 165 g SO
2-eq kg
−1 was estimated for a semi-intensive system. In studies conducted by Nguyen et al. [
44] in the EU, authors found AP values ranging from 101 to 210 g SO
2-eq kg
−1. In France, results for the AP were also close to those estimated in the present study, with a value of approximately 170 g SO
2-eq kg
−1 [
34].
On the other hand, for EOS the estimated value of AP was 71.9 g SO
2-eq kg
−1, less than half the value found in the SIS system. The AP associated with beef production in organic or conventional systems with higher slaughter ages has additional impacts than in systems that obtain the ideal slaughter weight in less time [
44,
48]. There are several factors which justify these differences, including: (i) longer life to produce one kg of beef requires additional power and effort in soil maintenance and thus provides greater leaching of pollutants and gaseous emissions; (ii) higher production of manure per kg of beef in systems where the age of slaughter is highest increases the rate of nitrogen and ammonia losses. Williams et al. [
48] compared ammonia losses for steers with slaughter ages from 22 to 24 months with steers from 18 to 20 months and found that in the first case the losses were higher. These results can also be explained by the different methods used in this study for modeling nitrogen and ammonia flows and emissions, since emissions of these constituents depends on the time of animal slaughter.
The difference in AP values may be related to the emissions of acidic pollutants from feed and higher emissions of ammonia (NH
3) from manure [
24]. The main acidifying pollutants of livestock are NH
3 and SO
2 [
67]. Acidifying pollutants affect soil, surface and groundwater, biological organisms, and other materials, causing fish mortality, forest decline, and erosion of buildings, among other effects [
68].
The NH
3 emission factors related to the manure are higher for SIS system due to their storage in animal shelters, which is reflected in the higher AP in SIS compared to EOS. On the other hand, despite the higher contribution from cattle manure, the deposition of animal feces directly into the soil can result in a lower environmental impact (e.g., global warming, energy needs, land use, and eutrophication) than the application of synthetic fertilizers [
69].
Agriculture, in particular livestock production, accounts for about 83.2% of ammonia emissions in the EU-28 [
70]. Animal production was the major contributor to AP for both SIS and EOS (96.5% and 97.9%, respectively) (
Table 4). These values are mainly a consequence of emissions from waste and the high amount of gases released by enteric fermentation [
20]. Thus, NH
3 is one of the major contributors to AP in cattle production for slaughter (
Table 3).
Feed and fertilizer production had low contributions to the AP indicator in relation to the total animal production, both for SIS and EOS (
Table 4).
Concerning the slaughter stage, estimated AP values were 0.32 and 0.37 g SO
2-eq kg
−1 for Mng and Mp slaughterhouses, respectively (
Figure 6).
AP was 16% higher for Mp than for Mng. The main differences expressed in quantitative terms were found for nitrogen oxides, with 0.166 g SO
2-eq kg
−1 for Mng and 0.198 g SO
2-eq kg
−1 for Mp, and for hydrogen chloride with 0.01 g SO
2 -eq kg
−1 for Mng and 0.0185 g SO
2-eq kg
−1 for Mp (
Figure 6).
The pollutants with the greatest contribution to the AP, both for Mng and Mp, were nitrogen oxides (NO
x) and sulfur dioxide (SO
2). In Mng, NO
x and SO
2 accounted for about 92.5% of total AP while in Mp, the weight of these same pollutants represented 91.5% (
Figure 6). Emissions of nitrogen and sulfur oxides into the atmosphere can lead to the formation of nitric acid and sulfuric acid, respectively. The fate of many of these acids is its deposition in terrestrial and aquatic ecosystems, reducing the pH of soils and waters [
71].
Differences in AP values for slaughterhouses may be related to the type of fuel used in the boiler and the efficiency of the use of electric energy.
Figure 7 shows the main contributions to the AP from Mng and Mp slaughterers. It is estimated that the contribution of the electric energy to the AP was lower in the Mp (21.9%) than in the Mng (43.1%), as for the former slaughterhouse, there was a higher production of slaughtered meat with a lower consumption of electricity. Conversely, the situation reverses with regard to the consumption of thermal energy, which is higher in Mp (Mp = 41.0% and Mng = 23.0%).
The contribution of the incineration of the meat residues to the AP was 10.0% for Mng and 7.7% for Mp. The highest emissions estimated for Mng were attributed to the highest amount of meat waste generated in Mng compared to Mp.
4.3. Eutrophication Potential (EP)
The contribution of animal production to the eutrophication potential (EP) impact category represented more than 96% of the total environmental impact of EP for both SIS and for EOS (
Table 5). Huerta et al. [
10] agree that animal production is the largest contributor to the EP, yet these authors attributed this amount to emissions from animal waste handling. SIS had emissions related to EP 25% higher than those observed in EOS (
Table 5). Many studies show that EP is mainly caused by NH
3 emission and by leaching of NO
3− and PO
43− [
9,
30,
44].
Pelletier et al. [
72], in a LCA study for three bovine production systems, estimated EP values between 104 and 142 g PO
4−3-eq kg
−1. EP values estimated by Nguyen et al. [
44] to conventional systems of beef production in the EU ranged between 87 and 159 g PO
4−3-eq kg
−1. Cederberg and Darelius [
73], in a study of organic bovine production for slaughter, obtained values ranging from 116 to 146 g PO
4−3-eq kg
−1. These emissions are generated mainly from animal waste and from the use of nitrogen or phosphate fertilizers in pasture.
The leaching of nitrate (NO
3−) and phosphate (PO
43−) depends mainly on climatic and soil conditions, and may differ widely among countries or even regions of the same country [
74]. This partially explains the large variation observed in EP among animal production systems.
The losses of NO
3− and PO
43− from manure, either directly deposited on pasture by animals or stored in feedlot, were the largest contribution to eutrophic emissions for both systems (SIS of 71.1% and EOS of 82.7%) (
Figure 8). Gaseous emissions at farm level, mainly NH
3 and N
2O, associated to the deposition of manure on pasture, contributed to 23.6% (SIS) and 12.6% (EOS). The use of fertilizers contributed to 5.3% (SIS) and 4.7% (EOS) for the total EP values.
EP estimated for Mng and Mp slaughterhouses is shown in
Figure 9. Regarding outputs, the flows that most influenced the EP were emissions to the aquatic environment, with 0.152 g PO
4−3-eq kg
−1 for Mng and 0.149 g PO
4−3-eq kg
−1 for Mp, coming mainly from the emissions of chemical oxygen demand (COD) and nitrate. Wastewater from slaughterhouses is considered as a potential pollutant because of its complex composition, with the presence of fats, proteins, and fibers from the slaughter process, as well as parts of the stomach and intestine of the animals [
75].
The analysis of
Figure 10 shows that the largest contributions are related to the wastewater produced in the slaughterhouses for both Mng (74%) and Mp (70%).
The other relevant shares of emissions influencing EP are air emissions in the form of nitrogen oxides (Mng with 0.045 g PO
4−3-eq kg
−1 and Mp with 0.053 g PO
4−3-eq kg
−1) and ammonia (Mng with 0.001 g PO
4−3-eq kg
−1 and Mp with 0.002 g PO
4−3-eq kg
−1) (
Figure 9). These gases come mainly from transportation, production of electricity, and emissions from boilers.
Differences in slaughterhouse contributions may be related to improved slaughter efficiency. The more the slaughter process can take advantage of meat material, avoiding wastes, the less substances are directed to wastewater and the lower the impact on the EP [
76].
The percentage contribution of transports for Mng and Mp are, respectively, 10% and 13% (
Figure 10). The values differ as a function of the distances traveled in both systems, so that the greater the distance between the slaughterhouse and the meat distribution center, the greater the contribution of this sector to the EP. The electric energy used for the beef slaughtering process had a contribution of 9% and 5% for Mng and Mp, respectively.
Finally, Mp pellet fuel boiler had a higher contribution (9%) to the EP than the natural gas boiler (4%) (
Figure 10). The highest percentage of EP for boilers is mainly due to the presence of NO
x. NO
x emissions can cause health problems in addition to several environmental impacts such as photochemical pollution, acid rain, and eutrophication [
77]. Thus, the boiler with natural gas supply had lower environmental impacts when compared to the EP for the slaughterhouse.
4.4. Photochemical Ozone Creation Potential (POCP)
Overall, the POCP was higher for SIS than for EOS. Volatile organic compounds (VOCs) are the air components that contributed the most to the POCP with 24.50 g C
2H
4-eq kg
−1 and 8.90 g C
2H
4-eq kg
−1, followed by CH
4 with 2.90 and 2.20 g C
2H
4-eq kg
−1, respectively for SIS and EOS (
Table 6).
The primary pollutants commonly found in urban environments are CO, CO
2 NO, SO
2, and VOCs. Carbon compounds and nitrogen oxides are the precursors of tropospheric ozone through complex photochemical reactions [
78]. Each compound has a contribution dependent on its concentration in the atmosphere, the relative proportion of precursors in the atmosphere and their reactivity [
79].
In order to facilitate the comparison with POCP values reported in other studies, results estimated in this study by the CML 2001 model (g C
2H
4-eq kg
−1) were converted to the ReCiPe model (kg VOCs-eq kg
−1). As a consequence, the results of this study for total POCP emissions changed from 27.40 g C
2H
4-eq kg
−1 to 6.99 × 10
−2 kg VOCs-eq kg
−1 in SIS and 11.20 g C
2H
4-eq kg
−1 to 2.85 × 10
−2 kg VOCs-eq kg
−1 in EOS. Environmental impacts of combined milk and meat production in Norway were studied and the POCP values per kg of beef carcass were between 8.88 × 10
−2 and 9.45 × 10
−2 kg VOCs-eq kg
−1 [
80]. For Zucaro et al. [
12], the results for POCP in beef production were approximately 3.40 × 10
−2 kg VOCs-eq kg
−1.
Animal production was identified as the subsystem of the beef value chain with the highest POCP (
Table 7), mainly due to emissions from waste and enteric fermentation which emit large amounts of gases influencing POCP [
81]. Similar results were also obtained in study conducted in Portugal on cattle for milk production, in which the authors attributed emissions mainly to CH
4 and enteric fermentation of animals [
82]. Other processes associated to beef production had low relevance when compared to animal production.
Results regarding the impacts of slaughterhouses in POCP showed negative values in some activities of the beef slaughter process, especially in the boiler, electricity, and incineration of solid waste. These values can be explained by the higher emissions of NO which reacts with atmospheric ozone, reducing its formation and, consequently, causing a negative effect on POCP [
83].
VOCs were the most relevant contributor to the POCP of the slaughterers, with 0.0153 g C
2H
4-eq kg
−1 for Mng and 0.020 g C
2H
4-eq kg
−1 for Mp. VOCs are known ingredients in the photochemical production of tropospheric ozone (O
3) in the presence of nitrogen oxides (NO
x) and sunlight [
84].
The transport of meat waste from the slaughterhouse to the distribution center appears as the largest contributor to POCP (
Figure 11). Generally, VOCs are emitted by vehicles through three ways [
85]: (i) exhaust emission from the engine consisting of unburned fuel and the VOCs generated by fuel combustion during vehicle operation; (ii) evaporative emissions, from fuel vapor escaping from vehicles; and (iii) release of VOCs from vehicle equipment, including plastic panels, leather seats, rubber tires, etc.