Population density (people per sq. km of land area) in Greenland was reported at 0.13805 sq. Km in 2022, according to the World Bank collection of development indicators, compiled from officially recognized sources. Greenland - Population density (people per sq. km) - actual values, historical data, forecasts and projections were sourced from the World Bank on September of 2025.

Historical dataset showing Greenland population density by year from 1961 to 2022.

Greenland GL: Population Density: People per Square Km data was reported at 0.137 Person/sq km in 2017. This records a decrease from the previous number of 0.137 Person/sq km for 2016. Greenland GL: Population Density: People per Square Km data is updated yearly, averaging 0.139 Person/sq km from Dec 1961 (Median) to 2017, with 57 observations. The data reached an all-time high of 0.164 Person/sq km in 1996 and a record low of 0.099 Person/sq km in 1961. Greenland GL: Population Density: People per Square Km data remains active status in CEIC and is reported by World Bank. The data is categorized under Global Database’s Greenland – Table GL.World Bank.WDI: Population and Urbanization Statistics. Population density is midyear population divided by land area in square kilometers. Population is based on the de facto definition of population, which counts all residents regardless of legal status or citizenship--except for refugees not permanently settled in the country of asylum, who are generally considered part of the population of their country of origin. Land area is a country's total area, excluding area under inland water bodies, national claims to continental shelf, and exclusive economic zones. In most cases the definition of inland water bodies includes major rivers and lakes.; ; Food and Agriculture Organization and World Bank population estimates.; Weighted average;

Greenland population density for 400m H3 hexagons.

Built from Kontur Population: Global Population Density for 400m H3 Hexagons Vector H3 hexagons with population counts at 400m resolution.

Fixed up fusion of GHSL, Facebook, Microsoft Buildings, Copernicus Global Land Service Land Cover, Land Information New Zealand, and OpenStreetMap data.

Greenland Population Density: Inhabitants per sq km data was reported at 0.140 Person in 2022. This stayed constant from the previous number of 0.140 Person for 2021. Greenland Population Density: Inhabitants per sq km data is updated yearly, averaging 0.140 Person from Dec 1990 (Median) to 2022, with 33 observations. The data reached an all-time high of 0.160 Person in 1996 and a record low of 0.140 Person in 2022. Greenland Population Density: Inhabitants per sq km data remains active status in CEIC and is reported by Organisation for Economic Co-operation and Development. The data is categorized under Global Database’s Greenland – Table GL.OECD.GGI: Social: Demography: Non OECD Member: Annual.

Comprehensive socio-economic dataset for Greenland including population demographics, economic indicators, geographic data, and social statistics. This dataset covers key metrics such as GDP, population density, area, capital city, and regional classifications.

Regionally distinguished demographic estimates for GI-1d-a based on dataset A (all sites).

Population structure and dynamics of Ascophyllum nodosum were analysed in late summer (August/September) 2012-2019 across ten permanent plots (0.25x0.25 cm) situated in the mid-tidal zone of Kobbefjord. Population biomass was non-destructively estimated each year by measuring the length from the holdfast to the tip of the longest shoot and the circumference 2-3 cm above the holdfast (comprising all basal shoots) for all marked individuals. The fresh weight of each individual was then detemined using a previously derived equation between individual biomass and the corresponding lenght and circumference specific to A. nodosum in Kobbefjord (see Olesen et al. xx). Population density was determined as the number of adult (marked) individuals, the number of unmarked juveniles divided into 2-10 cm long individuals and less than 2 cm individuals in each plot. Minimum estimate of biomass production was calculated by summing the biomass gain from all marked individuals showing an increase in biomass from one year to the next, and omitting losses from those experiencing a reduction in biomass between years. Net population growth rate was estimated ln(Nt/N0) where N0 and Nt are the number of marked individuals at year 0 and year t, respectively. Recruitment rate was estimated as ln(N0+Nnew)-ln(N0), where N0 is the number of marked individual at year 0 and Nnew is the count of new indviduals (>10 cm) observed the following year. Mortality rate was estimated as ln(N0/Nsurv) where N0 is the number of marked individual at year 0 and Nsurv the number suvivining until the following year.

With 450,295 square kilometers, Sweden is the largest Nordic country by area size, followed by Finland and Norway. This makes it the fifth largest country in Europe. Meanwhile, Denmark is the smallest of the five Nordic countries with only 43,094 square kilometers, however, the Danish autonomous region of Greenland is significantly larger than any of the Nordic countries, and is almost double the size of the other five combined.

Population

Sweden is also the Nordic country with the largest population. 10.45 million people live in the country. Denmark, Finland, and Norway all have between five and six million inhabitants, whereas only 370,000 people live in Iceland. Meanwhile, Denmark has the highest population density of the five countries. Greenland is the most sparsely populated permanently-inhabited country in the world, followed by the regions of Svalbard and Jan Mayen.

Geography

The five Nordic countries vary geographically. While Denmark is mostly flat, its highest point only stretching around 170 meters above sea level, Norway's highest peak is nearly 2,500 meters high. Moreover, Finland is known for its many lakes and is often called the land of a thousand lakes, whereas Iceland is famous for its volcanoes.

GL：人口密度：每平方公里人口在12-01-2017达0.137Person/sq km，相较于12-01-2016的0.137Person/sq km有所下降。GL：人口密度：每平方公里人口数据按年更新，12-01-1961至12-01-2017期间平均值为0.139Person/sq km，共57份观测结果。该数据的历史最高值出现于12-01-1996，达0.164Person/sq km，而历史最低值则出现于12-01-1961，为0.099Person/sq km。CEIC提供的GL：人口密度：每平方公里人口数据处于定期更新的状态，数据来源于World Bank，数据归类于全球数据库的格陵兰岛 – 表 GL.世行.WDI：人口和城市化进程统计。

1. Environmental variability, through interannual variation in food availability or climatic variables, is usually detrimental to population growth. It can even select for constancy in key life-history traits, though some exceptions are known. Changes in the level of environmental variability are therefore important to predict population growth or life-history evolution. Recently, several cyclic vole and lemming populations have shown large dynamical changes, that might affect rodent predator demography or life histories. 2. Skuas constitute an important case study among rodent predators, because of their strongly saturating breeding productivity (they lay only two eggs) and high degree of site fidelity, in which they differ from nomadic predators raising large broods in good rodent years. This suggests that they cannot capitalize on lemming peaks to the same extent as nomadic predators, and might be more vulnerable to collapses of rodent cycles. 3. We develop a model for the population dynamics of long-tailed skuas feeding on lemmings to assess the demographic consequences of such variable and nonstationary prey dynamics, based on data collected in NE Greenland. The model shows that populations of long-tailed skua sustain well changes in lemming dynamics, including temporary collapses (e.g. 10 years). A high floater-to-breeder ratio emerges from rigid territorial behaviour and a long life expectancy, which buffers the impact of adult abundance's decrease on the population reproductive output. 4. The size of the floater compartment is affected by changes in both mean and coefficient of variation of lemming densities (but not cycle amplitude and periodicity per se). In Greenland, the average lemming density is below the threshold density required for successful breeding (including during normally cyclic periods). Due to Jensen's inequality, skuas therefore benefit from lemming variability; a positive effect of environmental variation. 5. Long-tailed skua populations are strongly adapted to fluctuating lemming populations, an instance of demographic lability in the reproduction rate. They are also little affected by poor lemming periods, if there are enough floaters, or juveniles disperse to neighbouring populations. The status of Greenland skua populations therefore strongly depends upon floater numbers and juvenile movements, which are not known. This reveals a need to intensify colour-ringing efforts on the long-tailed skua at a circumpolar scale.

人口密度：每平方公里的居民在12-01-2022达0.140人，相较于12-01-2021的0.140人保持不变。人口密度：每平方公里的居民数据按年更新，12-01-1990至12-01-2022期间平均值为0.140人，共33份观测结果。该数据的历史最高值出现于12-01-1996，达0.160人，而历史最低值则出现于12-01-2022，为0.140人。CEIC提供的人口密度：每平方公里的居民数据处于定期更新的状态，数据来源于Organisation for Economic Co-operation and Development，数据归类于全球数据库的格陵兰岛 – Table GL.OECD.GGI: Social: Demography: Non OECD Member: Annual。

We report on a revisit in 2009 to sites where vegetation was recorded in 1967 and 1970 on Disko Island, West Greenland. Re-sampling of the same clones of the grass Phleum alpinum after 39 years showed complete stability in biometrics but dramatic earlier onset of various phenological stages that were not related to changes in population density. In a fell-field community, there was a net species loss, but in a herb-slope community, species losses balanced those that were gained. The type of species establishing and increasing in frequency and/or cover abundance at the fell-field site, particularly prostrate dwarf shrubs, indicates a possible start of a shift towards a heath, rather than a fell-field community. At the herb-slope site, those species that established or increased markedly in frequency and/or cover abundance indicate a change to drier conditions. This is confirmed both by the decrease in abundance of Alchemilla glomerulans and Epilobium hornemanii, and the drying of a nearby pond. The causes of these changes are unknown, although mean annual temperature has risen since 1984. Data extracted in the frame of a joint ICSTI/PANGAEA IPY effort, see http://doi.pangaea.de/10.1594/PANGAEA.150150 Supplement to: Callaghan, Terry V; Christensen, Torben R; Jantzen, Elin J (2011): Plant and Vegetation Dynamics on Disko Island, West Greenland: Snapshots Separated by Over 40 Years. AMBIO, 40(6), 624-637