information tables

Index	Table of wealth distribution and food security
	Electricity usage and derivation
	World coal resources (at end 2001)
	World oil resources (at the end of 2004)

Table of wealth distribution and food security This table illustrates wealth differences between countries and within countries. It also shows shows the ability of those countries to feed themselves.								advertising disclaimer advertising disclaimer advertising disclaimer
Table of wealth distribution and food security
country	Gini value	GDP per capita (PPP)	population density (per sq km)	population (in millions)	land area	percentage agriculturally useful land	pop. density per sq km ag. land
Brazil	59.1	$7,400	21	176	8,511,965 sq km 3,277,284 sq m	6%	345
Chile	57.5	$10,000	20	15	756,950 sq km 291,442 sq m	3%	661
Mexico	51.9	$9,000	52	103	1,972,550 sq km 759,473 sq m	13%	402
Venezuela	48.8	$6,100	26	24	912,050 sq km 351,158 sq m	3%	877
Argentina	45.0 *	$12,000	14	38	2,766,890 sq km 1,065,310 sq m	9%	153
USA	40.8	$36,300	27	290	9,363,130 km 3,605,000 sq m	19%	146
Russia	39.9	$8,300	9	145	17,075,200 sq km 6,574,307 sq m	8%	106
UK	36.1	$24,700	238	58	244,755 sq km 94,230 sq m	26%	911
Switzerland	33.1	$31,100	170	7	41,290 sq km 15,898 sq m	10%	1695
France	32.7	$25,400	106	58	547,030 sq km 210,618 sq m	33%	321
Canada	32.0	$29,400	4	31.9	9,220,970 sq km	4.94%	70
Sweden	25.0	$24,700	20	9	449,964 sq km	7%	286
Japan	24.9	$27,200	339	125	369,000 sq km 152,334 sq m	12%	2823
Denmark	24.7	$28,000	116	5	43,094 sq km 16,592 sq m	56%	207
China	40	$4,300	138	1284	9,326,410 sq km	13.31%	1034
Russia	39.9	$8,300	9	145	16,995,800 sq km	7.46%	114
India	37.8	$2,500	318	1,045	3,287,590 sq km	54.35%	585
Iraq	60 **	$2,400	56	24.7	437,072 sq km	11.89%	475
country	Gini value	GDP per capita (PPP)	population density (per sq km)	population (in millions)	land area	percentage agriculturally useful land	pop. density per sq km ag. land
	1	2	3	4	5	6	7
* estimate from World Bank data. ** Approximate only, the most recent figure available dates from 1956.				Data source for table: CIA Factbook
Be aware that much of some countries is mountainous, or otherwise difficult, by virtue of swamps, deserts, cold etc.
Definition: For the column, ‘agricultural useful land’ , I have taken the CIA definition for arable land, that is, land cultivated for crops that are replanted after each harvest like wheat, maize, and rice. The CIA separately defines permanent cropland as land cultivated for crops that are not replanted after each harvest like citrus, coffee, and rubber; includes land under flowering shrubs, fruit trees, nut trees, and vines, but excludes land under trees grown for wood or timber. I have done this because my intention is to have some approximation for the potential food self-sufficiency of the various countries listed. In third-world countries, a great deal of the category defined as permanent crops is production for export and for foreign exchange. Generally, the profits end up in the bank accounts of local agent kleptocracies and their Western corporate paymasters; and, of course, the cheap, luxury items are sold in advanced countries, to the detriment of the local poor. My concern, at this point, is not any ‘moral’ judgement as to whether this is good, bad or neutral (in the present state of the world, my inclination is to regard it as the way of the world and fairly neutral). However, I bring this to your attention in order that you may think clearly about these matters for yourself. You might, for example, decide that you would rather seek out, and add in, the permanent crop figures; or again, you might imagine that increased land could be brought under cultivation by the application of ever-advancing, agricultural technology. You might think that trading crops for Western technology might, in the longer run, raise the general standard of life in backward countries. You might wonder about the strategic importance of food security, especially for some Western countries. Not one of these is an easy, or settled, question. It has been said that trade is like a magic wand, capable of transforming food into aeroplanes, or haircuts, into holidays in Ibiza.
As usual, keep in mind that such figures can only be approximations.

Electricity usage and derivation
country	energy usage in ‘big power station’ (1 GW) equivalents [GWeq]	energy inputs to produce electricity in ‘big power station’ (1 GW) equivalents** [GWeq]	produced electricity, and as %age of total energy use	electricity from
country			produced electricity, and as %age of total energy use	1 fossil [GWeq]	2 hydro [GWeq]	3 nuclear [GWeq]	4 wind [GWeq]
USA	3065		430.4 [14%]	316.8 [73.6%]	25.1 [5.7%]	87.8 [20.4%]	1.42 [0.3%]
Germany	459.2	164.8	60.75 14%]	36.6 [60.3%]	3.0 [4.9%]	18.53 [30.5%]	2.6 [4.3%]
UK	306.9		41.6 [13.6%]	31.2 [75.1%]	0.8 [1.9%]	9.4 [22.6%]	0.16 [0.4%]
France	351.2	115	59.4 [16.9%]	4.2 [7.0%]	9.4 [15.8%]	45.8 [77.1%]	0.08 [0.1%]
Japan	704.8		107.0 [15.2%]	55.7 [52.1%]	14.6 [13.6%]	36.7 [34.3%]
Spain	184.4		24.3 [13.2%]	[x%]	[x%]	7.0 [28.8%]	1.0 [0.24%]
Brazil	237.8		37.2 [15.6%]	[x%]	[x%]	1.6 [4.3%]
Russia	880.9		92.9 [10.5%]	65 [70.0%]	20.7 [22.3%]	14.3 [15.4%]
China	1150		172.7 [15%]	100.4 [58.12%]	70 [40.5%]	1.9 [1.1%]	0.11 [0.19%]
India	431.1		[x%]	95.7 [94.6%]	16.1 [15.9%]	4.4 [4.3%]
Denmark	25.9		[x%]	[x%]	*	-	2.4 [x%]
1	2	3	4	5	6	7	8
Data source, columns 5, 6, 7: BP Statistical Review. Col 8: various. Column 2: BP figures for primary energy consumption x 1.37 conversion factor subsidary sources: http://www.world-nuclear.org/info/nshare.htm http://www.enerdata.fr/enerdata_UK/Produits/exemples/conso.pdf (total energy use) Column 4 derived from http://www.eia.doe.gov/emeu/cabs/contents.html (electricity generation and consumption tables)
It is easy to confuse the figures in columns 2, 3 and 4. Much electricity generation is done using fossil fuels. Fossil fuel electricity generation is about 38% efficient, and electricity is the end-use form of power used by consumers. Column 2 represents the total input**-energy usage by a country. For every unit of fossil fuel, or other energy source, that is consumed by a country in electrical generation, only 38% of that unit will end up as usable end-user energy. When referring to alternative energy, the inputs are notional and based upon this 38% efficiency figure. In other words, for example, a given quantity of electricity produced by nuclear power generation will be deemed to have taken the same amount of fossil fuel energy as if it had been generated using fossil fuels. The figure of 38% is a crude average, as used by BP. While similar efficiency losses will be involved in non-fossil fuel electricity generation, these losses may not show up clearly, as only the end-use electrical energy will appear in the relevant columns. In column 4, the percentage is the delivered end-user energy, as a percentage of column 2 (the energy input to the country). It can also be read as the degree of electrification of that country. End-user energy is difficult to define and to understand. Is the energy going into the power station to be regarded as the end-user of the energy coming into the country? Or is the end-user to be considered the person who swithches on a light at home? What of the person who switches on a light in a factory? Is the factory the end-user, or is it the person or company who purchases the manufacturer’s goods? What of recycled waste, used to produce further energy? What of the hairdressing salon that blow-dies your hair? Is it different if you do this job at home? These are the questions asked by added-value taxmen, or governments ‘adjusting’ their GNP fictions. Neither am I going to attend to the various energy losses inevitable in the production process. I have no intention of plumbing this sort of complexity, my purpose being to show the broad outlines of energy production and usage without unnecessary confusion. Thus, my definition of end-user energy is related directly to the energy inputs of the country. The percentages in the remaining columns relate to the relative amounts of electricity generated by various means in a country. The percentages in the left part of the table have no bearing on the percentages in the right part of the table. [solar reflection difficulties http://denbeste.nu/cd_log_entries/2002/07/Carbonemissions.shtml] Sustainable Transport Note: idealistic, but useful, reference document (lead source: Lavigne) tide power again sloppy remarks from the Groaniad

advertising
disclaimer

World coal resources (at end 2001)
country	proved reserves of coal in million tonnes/ [million tonnes oil equiv.]				production
country	Anthracite and bituminous	Lignite and brown (sub-bituminous)	Total coal reserves	%age of world proved coal reserves	in million tonnes oil equivalent	%age of country's coal reserves in 2001	years before reserves exausted
The World	519,062 [346,041]	465,391 [132,969]	984,453 [479,010]	100.0%	2,248.3	0.47%	213
USA	115,891 [77,260]	134,103 [38,315]	249,994 [115,575]	25.4%	590.7	0.51%	246
Russia	49,088 [32,725]	107,922 [30,835]	157,010 [63,560]	15.9%	120.8	0.19%	500 +
China	62,200 [4,167]	52,300 [14,943]	114,500 [19,110]	11.6%	548.5	2.87%	105
India	82,396 [84,264]	2,000 [571]	84,396 [84,834]	8.6%	161.1	0.19%	246
Australia	42,550 [28,366]	39,540 [11,297]	82,090 [39,663]	8.3%	168.1	0.42%	260
Germany	23,000 [1,533]	43,000 [12,286]	66,000 [13,819]	6.7%	54.2	0.39%	326
South Africa	49,520 [33,013]	0	49,520 [33,013]	5.0%	126.7	0.38%	220
Ukraine	16,274 [10,849]	17,879 [531]	34,153 [11,380]	3.5%	43.6	0.38%	407
Poland	20,300 [13,533]	1,860 [531]	22,160 [14,084]	2.3%	72.4	0.51%	136
UK	1,000 [667]	500 [143]	1,500 [810]	1.2%	19.6	2.42%	47
	1	2	3	4	5	6	7
Data source, columns 1, 2, 3, 4, 5, 7: BP Statistical Review 1 tonne oil = 1.5 tonnes ‘hard’ coal / 3.5 tonnes lignite There are claims from the coal industry that it is possible to use coal such that there is lower resulting pollution.

advertising
disclaimer

World oil resources (at the end of 2004)
country	known reserves		extraction
country	in billion barrels (000 million)	%age of world reserves	in 000 barrels daily	%age world extraction (rank)	%age of country's reserves in 2001	years before reserves exausted
The World	1050.0	100.0%	74,493	100%	2.59%	39 years
Saudi Arabia	261.8	24.9%	8,768	11.77% (1)	1.22%	82 years
Iraq	112.5	10.7%	2,414	3.24% (11)	0.78%	128 years
Kuwait	96.5	9.2%	2,142	2.88% (12)	0.81%	123 years
Iran	87.9	8.5%	3,688	4.95% (4)	1.53%	65 years
United Arab Emirates	97.8	9.3%	2,422	3.25% (10)	0.90%	111 years
Russian Federation	48.6	4.6%	7,056	9.47% (3)	5.30%	19 years
Venuzuela	77.7	7.4%	3,418	4.59% (6)	1.61%	62 years
China	24.0	2.3%	3,308	4.44% (8)	5.03%	19.9 yrs
Libya	29.5	2.8%	1,425	1.91% (15)	1.76%	56.8 yrs
Mexico	26.9	2.6%	3,560	4.78% (5)	4.83%	20.7 yrs
Nigeria	24.0	2.3%	2,148	2.88% (13)	3.27%	30.6 yrs
USA	30.4	2.9%	7,717	10.36% (2)	9.27%	10.8 yrs
Norway	9.4	0.9%	3,414	4.58% (7)	13.3%	7.5 years
Algeria	9.2	0.9%	1563	2.01% (14)	6.2%	16.1 yrs
UK	4.9	0.5%	2,503	3.49% (9)	18.6%	5.4 years
Data source: world oil reserves and oil-based fuel development