7884079486

Picmcntcl/Problcmy Ekorozwoju/Problcms of Sustainablc Dcvclopmcnt 2/2012,15-22

of 9,500 kg/ha (151 bu/ac) of maize using up-to-date production teclmologies reąuires tlie expendi-ture of about 7.4 million kcal of energy inputs (mostly natural gas and oil). This is the equivalent of about ~743 liters of oil equivalents e\pended per hectare of maize. The production costs total $835/ha for the 9,500 kg/ha or approximately llp/kg ($2.34/ bushel) of maize produced (Table 1).

Table 1. Total amount of biomass and solar energy cap-tured each year in the United States.

An estimated 27.8 x 10¹⁸ BTU of sunlight reaching the U.S. per year suggests that the green plants (crops, grass-es, and forests) in the U.S. are collecting 0.1% of the

	Million ha	tons/lia	x 10⁶tons	Total Energy Collected x 10¹⁵BTU
Crop	160	5.5	901	14.4
Paslurc	300	1.1	33.3	9.6
Forests	264	2.0	527	8.4
TOTAL	724		1.758	27.8

Table 2. Energy inputs and costs of com production per hectare in the United States.__

Inputs	Ouantity	kcal x 1000	Costs $
Labor	11.4 hrs'¹	520"	148.20
Machinery	55 te"	1.018^C	110.00'
Diesel	62 L⁸	620"	46.42
Gasoline	9 L'	90¹	7.14
Nitrogen	150 ku¹	2.475'	85.25'"
Phosphonis	55 kg"	228°	48.98^p
Polassium	62 kg*¹	202^r	26.04⁵
Limę	1.120 kg'	315“	28.64
Seeds	21 kg'	520"	74.81'
Irrigation	8.1 cm^y	320'	123.00³-¹
Hcrbicides	2.3 k_E“	230“	35.29
Insecticides	0.7 kg¹*	70“	32.55
Electricity	103.2 kWh⁸	34"	7.22
Transport	107 kg⁸⁸	122""	61.20
TOTAL Com yield	.500 kg/ha"	7.438 kcal inpi	834.74 t: 1:4.60

Fuli irrigation (when there is insufficient or no rainfall) requires about 100 cm/ha of water per growing season. Because froin 15% to 19% of U.S. maize production is irrigated (USDA, 1997a; Supalla. 2007), only 8.1 cm per ha of irrigation was included for the growing season. On average. irrigation water is pumpcd from a dcpth of 100 in (USDA, 1997a). On this basis. the average energy input associated with irrigation is 320.000 kcal per hectare (Table 2).

Energy Inputs in Maize Fcrmentation/ Distilla-tion

Tlie average costs in terms of energy and dollars for a large, modem dry-grind ethanol plant are signifi-cant and are listed in Table 3. In the fermenta-tion/distillation process. the maize is finely ground and approximatelv 8 liters of water are added per 2.69 kg of ground maize. Some of this water maybe recycled. After fennentation. the mixture is distilled to obtain a liter of 95% purc ethanol from the 8-12% ethanol bcer and 92-88% ethanol concentra-tion. The 1 liter of ethanol must be extracted from approximately 11 liters of the ethanol/water mix-ture. Although ethanol boils at 78°C, and water boils at 100°C, the ethanol is not extractcd from the water in the first distillation, which obtains 95% ethanol (Maiorella, 1985: Wereko-Brobby and Hagan, 1996; S. Lambersoa personal communica-tion, Comell University, 2000). To be mixed with gasoline. the 95% ethanol must be further processed and morę water reinoved, requiring additional fossil energy inputs to achieve 99.5% pure ethanol (Table 3). Thus. a total of 8 liters of wastewater is required

a) NASS, 2005.

b) It is assumed that a person works 2.000 hrs per year and utilizes an average of 9,000 liters of oil equiva-lents per year.

c) It is assumed that labor is paid $20 an hour.

d) Pimentel and Pimentel, 2008.

e) Prorated per hectare and 10 year life of the machin-ety Tractors weigh from 6 to 7 tons and harvesters 8 to 10 tons, plus plows. sprayers, and other equip-ment.

0 Estimated.

g) William McBride. Personal Communication. USDA. 2010.

h) Input 11,400 kcal per liter.

i) Estimated

j) Input 10,125 kcal per liter.

k) NASS. 2003

l) Cost $.55 per kg.

m) Patzek. 2004

n) NASS. 2003.

o) Input 4,154 kcal per kg.

p) Cost $.62 per kg.

q) NASS. 2003.

r) Input 3.260 kcal per kg.

s) Cost $.31 per kg.

t) Estimated.

u) Input 281 kcal per kg.

v) Pimentel and Pimentel, 2008.

w) Pimentel and Pimentel. 2008.

x) Estimated.

y) USDA. 1997a.

z) Batty and Keller. 1980.

aa) Irrigation for 100 cm of water per hectare costs $1.000 (Larsen et al.. 2002). bb) NASS. 2005. cc) USDA 2002. dd) USDA 1991.

ee) Input 100,000 kcal per kg of herbicide and insecti-cide.

ff) Input 860 kcal per kWh and rcquires 3 kWh thennal eneigy to produce 1 kWh electricity. gg) Goods transported include machinery. fuels, and seeds that were shipped an estimated 1,000 km. hli) Input 0.34 kcal per kg per km transported. ii) Ayerage. USDA, 2007: USCB, 2008.

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