A beach in north-east Scotland is eroding rapidly owing to climate change, leaving a town at risk of flooding and its centuries-old golf links crumbling into the sea.
The Dynamic Coast report in 2021 studied the rate of erosion at Montrose and predicted that 120 metres would be lost over 40 years, an average of 3 metres a year.
People in Montrose are fearing the start of the storm season in autumn, as last year’s record-breaking storms caused the beach to erode 7 metres in the space of a year, more than 4 metres more than scientists predicted.
A report on behalf of Montrose Golf Links by EnviroCentre in December revealed that historically observed average rates of retreat are between 2.8–7.0 metres a year and that “observed trends in coastal erosion can be expected to continue, or indeed accelerate in response to future climate change”.
In November last year, Montrose’s beach promenade collapsed during high tide after Storm Babet, leaving a gaping hole on the walkway. During this storm alone the beach eroded 3 metres.
A month later, in December, gales of 86mph were recorded at nearby Inverbervie climate station during Storm Gerrit.
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This could lead to rise of more severe disasters that will possibly causes more harm to people in the area .
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This will lead to increased flooding in the adjacent coast which could lead to the loss of life ..we ought to deal with the issue of climate change Sooner.
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The presence of sulfates in the atmosphere significantly influences cloud nucleation and can contribute to severe weather events like flooding. Here’s an analysis of how the current sulfate concentration in China, which stands at 0.694 AOT, affects cloud formation and the potential impacts of reducing coal combustion: Influence on Cloud Nucleation 1. **SO2 Oxidation**: Sulphur dioxide emitted from coal combustion undergoes oxidation processes in the atmosphere to form sulfates aerosols. These sulfates can act as cloud condensation nuclei (CCN). 2. **Ammonium Sulfate Formation**: The formation of ammonium sulfate from the reaction of sulfate with ammonia in the atmosphere increases the hygroscopic nature of particles, enhancing their ability to act as CCN. This leads to more cloud droplets forming, which can affect cloud properties and precipitation patterns. 3. **Enhanced Cloud Nucleation**: Increased CCN leads to the formation of more, but smaller, cloud droplets. This can increase cloud albedo (reflectivity) and potentially lead to longer cloud lifetimes and increased precipitation under the right conditions, contributing to severe weather events such as flooding. Contribution to Severe Flooding The current high levels of sulfates enhance the formation of CCN, which can intensify cloud formation and precipitation. This mechanism is likely contributing to the severe flooding observed in China by increasing the frequency and intensity of precipitation events. Enhanced cloud nucleation can also alter the dynamics of storms, potentially leading to more intense and prolonged rainfall. Impact of Stopping Coal Combustion Reducing coal combustion would decrease SO2 emissions, leading to lower sulfate concentrations in the atmosphere. Here’s how this would help: 1. **Reduction in CCN**: Lower sulfate levels would result in fewer CCN, potentially decreasing the number of cloud droplets. This might lead to less cloud cover and reduced precipitation intensity. 2. **Atmospheric Chemistry Changes**: The reduction in SO2 emissions would alter atmospheric chemistry, potentially decreasing the formation of new particles and changing the characteristics of existing clouds. This could mitigate some of the extreme weather patterns influenced by high sulfate levels. 3. **Short-Term and Long-Term Effects**: In the short term, a sudden reduction in SO2 emissions could lead to an initial increase in particle nucleation rates but a decrease in their growth to CCN size, possibly stabilizing the atmosphere and reducing the occurrence of extreme weather events. In the long term, sustained lower SO2 levels would likely lead to more significant reductions in severe weather events influenced by high sulfate concentrations. Conclusion Stopping the production of energy using coal in an emergency would help reduce SO2 emissions and subsequently lower sulfate concentrations in the atmosphere. This would decrease the number of CCN, potentially mitigating the severity of cloud formation and associated precipitation events, thereby helping to alleviate severe flooding. However, the extent of this impact would depend on the overall atmospheric conditions and the presence of other influencing factors such as temperature, humidity, and additional aerosols.The presence of sulfates in the atmosphere significantly influences cloud nucleation and can contribute to severe weather events like flooding. Here’s an analysis of how the current sulfate concentration in China, which stands at 0.694 AOT, affects cloud formation and the potential impacts of reducing coal combustion: Influence on Cloud Nucleation 1. **SO2 Oxidation**: Sulphur dioxide emitted from coal combustion undergoes oxidation processes in the atmosphere to form sulfates aerosols. These sulfates can act as cloud condensation nuclei (CCN). 2. **Ammonium Sulfate Formation**: The formation of ammonium sulfate from the reaction of sulfate with ammonia in the atmosphere increases the hygroscopic nature of particles, enhancing their ability to act as CCN. This leads to more cloud droplets forming, which can affect cloud properties and precipitation patterns. 3. **Enhanced Cloud Nucleation**: Increased CCN leads to the formation of more, but smaller, cloud droplets. This can increase cloud albedo (reflectivity) and potentially lead to longer cloud lifetimes and increased precipitation under the right conditions, contributing to severe weather events such as flooding. Contribution to Severe Flooding The current high levels of sulfates enhance the formation of CCN, which can intensify cloud formation and precipitation. This mechanism is likely contributing to the severe flooding observed in China by increasing the frequency and intensity of precipitation events. Enhanced cloud nucleation can also alter the dynamics of storms, potentially leading to more intense and prolonged rainfall. Impact of Stopping Coal Combustion Reducing coal combustion would decrease SO2 emissions, leading to lower sulfate concentrations in the atmosphere. Here’s how this would help: 1. **Reduction in CCN**: Lower sulfate levels would result in fewer CCN, potentially decreasing the number of cloud droplets. This might lead to less cloud cover and reduced precipitation intensity. 2. **Atmospheric Chemistry Changes**: The reduction in SO2 emissions would alter atmospheric chemistry, potentially decreasing the formation of new particles and changing the characteristics of existing clouds. This could mitigate some of the extreme weather patterns influenced by high sulfate levels. 3. **Short-Term and Long-Term Effects**: In the short term, a sudden reduction in SO2 emissions could lead to an initial increase in particle nucleation rates but a decrease in their growth to CCN size, possibly stabilizing the atmosphere and reducing the occurrence of extreme weather events. In the long term, sustained lower SO2 levels would likely lead to more significant reductions in severe weather events influenced by high sulfate concentrations. Conclusion Stopping the production of energy using coal in an emergency would help reduce SO2 emissions and subsequently lower sulfate concentrations in the atmosphere. This would decrease the number of CCN, potentially mitigating the severity of cloud formation and associated precipitation events, thereby helping to alleviate severe flooding. However, the extent of this impact would depend on the overall atmospheric conditions and the presence of other influencing factors such as temperature, humidity, and additional aerosols.
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The harrowing effects of climate change taking place.