IntroductionThe potato is widely cu

Introduction
The potato is widely cultivated and consumed by most cultures across the world. The production in countries like South Africa has been growing due to increasing demand for food which has led to an increased area of production (FAO 2008). One of the main constraints in the cultivation of the potato is, however, the cost of producing seed tubers since this can account for between 30 to 50% of the total production expenses, depending on the country or region. A further limitation is the long asexual propagation cycle during which infection by viruses or bacteria can give rise to degenerative diseases (Corrêa et al. 2009).
There is a number of potato propagation procedures that are currently being used worldwide to multiply seed potatoes; conventional seed potato production, micro propagation, hydroponics and aeroponics. The uses of biotechnological techniques such as tissue culture and hydroponics have resulted in increased yields (Corrêa et al. 2009). Most farmers in developing countries, however, are not utilizing the more advanced methods of seed production due to a lack of resources (Chiipanthenga et al. 2012). Aeroponics is one of the most effective techniques because of its numerous advantages (Otazu, 2008) although it is still not used extensively. Over and above being safe and ecologically friendly, this system produces healthy plants and tubers (CIP, 2008) and the system also has the ability to conserve water and energy. The nutrient solution is recirculated in the aeroponics system, hence a limited amount of water and fertilisers is used (Farran et al. 2006). It provides the precise plant nutrient requirement for the crop and minimizes the risk of excessive fertiliser residues moving into the subterranean water table (Nichols 2005). The biggest challenge using an extensive system such as aeroponics is, however, the increased production cost. Management decisions become increasingly important due to the selection of the most profitable crops and cropping systems (Hagin and Tucker 1982). Research around the world is actively trying to improve the vigour and quality of seed potato tubers and consequently maximising production efficiency and increasing the crop yield (Corrêa et al. 2009).
Planting density is known to affect both crop morphology and yield. Several studies have shown that plant density is an important factor affecting the entire production process of a plant. The importance of the leaf area index size in translocation of assimilates has been acknowledged in different crops such as potato (Kempen 2007), tomato (Scholberg et al. 2000) and cucumber (Tanemura et al. 2008). Mojiri and Arzani, (2003) described that increasing plant population had an incremental effect on plant height and negatively affects stem girth and head diameter in sunflower. Maize differs in its responses to plant density (Luque et al. 2006) with stand density affecting plant architecture, altering growth and developmental patterns and influencing carbohydrate production. Many modern maize varieties at low densities do not tiller efficiently and quite often produce only one ear per plant whereas, the use of high plant populations increases interplant competition for light, water and nutrient which ultimately decreases the number of ears (Sangoi 2001). In soybean (Torigoe et al. 1982) narrow row sowing