Transition from Military to a Democracy Rule in South Korea Research Paper

Transition from Military to a Democracy Rule in South Korea - Research Paper Example This paper considers the process of successful transition from a military dictatorship regime to a democratic led nation in South Korea. It attempts to study that process and give an explanation to success of that transition, that brought economic prosperity to the country. The history of the path to democracy in South Korea began in the year 1945 when the country liberated itself from colonial rule by the Japanese. Economic development was envisaged to pick soon after. However, the postcolonial period saw a shift from Japanese led colonial leadership to an authoritarian rule, also referred to as a strong state. This shift was mostly fuelled by political divisions in the period after liberalization and the Korean War. The continued authoritarian rule elicited country wide protests, which continued to gain support and momentum as the strong state ideology also continued to widen and deepen. The protests were in favor of democratization, with the protestors demanding the adoption of democracy in governance, and consequently formed a resistance union, called the democratization movement’s resistance. Increased confrontations and resultant clashes between the pro democracy and the authoritarian rule parties led to the start of the journey to democracy which was characterized by a series of movements. These include the 1960 revolution which took place on April 19th, the uprising of 1980 popularly known as the Gwangju Popular Uprising, and lastly the 1987 June Democratic Uprising. The direct and democratic election of Kim Dae Jung as president of South Korea in 1997 propelled the country into a state of political and economic stability signifying the strong correlation that exists between democracy and economic development.

The Specific Heat Capacity of Water and Metal Lab Report

The Specific Heat Capacity of Water and Metal - Lab Report Example The temperature of 500 ml of water in a beaker was measured before a warm heater connected to power supply was dipped in the beaker. After 10 minutes of heating and constant stirring of water, the power supply was switched off, and water temperature measured. The same procedure was repeated for a period of 15 minutes. The results were recorded in table 1. The temperature of aluminium block was recorded before a heater connected to a power supply was used to heat the block for a period of 8 minutes. The above procedure was repeated using Copper block and the results were recorded in table 2. The experimental specific heat capacity of water was 4785 JKg-1 oC-1 while the literature value was 4187 JKg-1 oC-1. Therefore, the percentage error for water was calculated using the formula: % Error= |Experimental value-Theoretical value| Ãâ€"100 The specific heat capacity of water determined in this experiment had a numerical value of 4785  ± 263 JKg-1 oC-1 while that of aluminium and copper were 1278 and 545 JKg-1 oC-1, respectively. The standard (literature) specific heat capacities of water, aluminium and copper are 4187, 900 and 386 JKg-1 oC-1, respectively (Table of specific heats). The obtained values were more than the literature values. The anomalies observed between these values were probably due to random errors in the experimental procedures e.g. the loss of heat to the surrounding and the presence of impurities in the water hence leading to an increase in the boiling points. Systematic errors could be due to the weights of the metal blocks and temperature readings as well as fluctuations in pressure. In future experiments, loss of energy to the surroundings could be avoided by using more energy to heat the water for it to attain the required temperature. In addition, water with higher levels of purity can be u sed in the experiments so that the effect of impurities on