Explanation: The IPCC Sixth Assessment Report explicitly defines a drought as a period of drier-than-normal conditions, signifying a moisture deficit relative to average water availability for a given location and season.

Explanation: The National Integrated Drought Information System (NIDIS) defines drought as 'a deficiency of precipitation over an extended period of time (usually a season or more), resulting in a water shortage.'

Explanation: Defining and monitoring drought is a complex task, with over 150 definitions published by the early 1980s, reflecting diverse regional and disciplinary approaches.

Explanation: A meteorological drought is defined by a prolonged period of less than average precipitation and typically precedes other drought types, setting the stage for subsequent water deficits.

Explanation: Hydrological droughts develop more slowly as stored water is depleted and are significantly influenced by human water management practices, not solely natural precipitation deficits.

Explanation: An agricultural or ecological drought can manifest due to plant stress from low soil moisture, even without precipitation changes, if factors like increased irrigation demand or poor soil conditions result in insufficient water for crops.

Explanation: A socioeconomic drought is primarily concerned with the demand for an economic good, such as water, surpassing its supply due to a weather-related shortfall, rather than solely the environmental impact on ecosystems.

Explanation: The IPCC Sixth Assessment Report defines a drought as a period of conditions that are drier than normal, signifying a moisture deficit compared to average water availability.

Explanation: The National Weather Service office of NOAA defines drought as 'a deficiency of moisture that results in adverse impacts on people, animals, or vegetation over a sizeable area.'

Explanation: A meteorological drought is characterized by a prolonged period with less than average precipitation, serving as the initial stage for other drought types.

Explanation: A hydrological drought is defined by water reserves in sources such as aquifers, lakes, and reservoirs falling below average or a locally significant threshold.

Explanation: The Palmer Drought Severity Index (PDSI) utilizes both precipitation and temperature data to analyze moisture supply and demand through a water balance model, not solely precipitation data.

Explanation: The Standardized Precipitation Index (SPI) is indeed recommended by the World Meteorological Organization for identifying and monitoring meteorological droughts due to its simplicity and reliance on precipitation data.

Explanation: The Standardized Precipitation Evapotranspiration Index (SPEI) is unique among multiscalar drought indices for its inclusion of atmospheric evaporative demand, which is crucial for assessing drought severity, especially during precipitation deficits.

Explanation: Applying multiple drought indices with different datasets is crucial for effective drought management and monitoring, particularly in data-scarce regions, as a single dataset may not capture the full range of drought characteristics and impacts.

Explanation: The Standardized Precipitation Index (SPI) is recommended by the World Meteorological Organization for identifying and monitoring meteorological droughts.

Explanation: The Standardized Precipitation Evapotranspiration Index (SPEI) uniquely incorporates the role of increased atmospheric evaporative demand in its assessment of drought severity.

Explanation: Heat waves intensify drought conditions by increasing evapotranspiration, which in turn dries out vegetation and elevates the risk of wildfires.

Explanation: Droughts are triggered by atmospheric conditions such as winds carrying continental air masses (not oceanic) and high-pressure systems (not low-pressure) that restrict rainfall.

Explanation: La Niña events are indeed associated with drier and hotter conditions, which exacerbate droughts in regions such as California and the Southwestern United States.

Explanation: During El Niño events, Southeast Asia and Northern Australia typically experience increased bushfires, worsening haze, and dramatically decreased air quality, rather than increased rainfall and reduced bushfires.

Explanation: Global droughts have increased in occurrence due to rising temperatures and atmospheric evaporative demand, with climate variability and human activities further aggravating their frequency and severity.

Explanation: The IPCC Sixth Assessment Report emphasizes that warming over land *increases* atmospheric evaporative demand, thereby *intensifying* the severity of drought events and plant water stress.

Explanation: Global warming is projected to exacerbate droughts in many regions, including Central America, the Amazon, and the Mediterranean.

Explanation: Human activities such as over-farming, excessive irrigation, and deforestation directly worsen drought conditions by impairing the land's capacity to capture and retain water.

Explanation: Ridges of high-pressure areas aloft that prevent or restrict thunderstorm activity or rainfall are a key atmospheric condition that can trigger and worsen droughts.

Explanation: La Niña events are generally associated with drier and hotter conditions, which exacerbate droughts in regions such as California and the Southwestern United States.

Explanation: During El Niño events, Southeast Asia and Northern Australia typically experience increased bushfires, worsening haze, and dramatically decreased air quality.

Explanation: The IPCC Sixth Assessment Report states that warming over land is the primary driver of increased atmospheric evaporative demand and heightened drought severity.

Explanation: Over-farming and excessive irrigation are human activities that directly worsen drought conditions by negatively impacting the land's ability to capture and retain water.

Explanation: Droughts lead to lower water flows, which diminish the dilution of pollutants, thereby increasing water contamination and negatively impacting water quality.

Explanation: Higher temperatures increase evaporation and plant stress, negatively impacting agriculture even in regions with stable rainfall by drying out the soil and reducing crop yields.

Explanation: Woody plant encroachment into grasslands can *increase* soil porosity, which in turn can *heighten* the chances of soil drought by altering water infiltration and retention properties.

Explanation: Droughts lead to drought-induced mortality of trees, which negatively impacts the carbon sink function of forests and is often underrepresented in climate models.

Explanation: Dust Bowls are a sign of erosion and landscape degradation, and dust storms are directly linked to drought conditions, desertification, and erosion, not improved soil health or unrelated phenomena.

Explanation: Drought fundamentally affects crop production by causing poor germination, impairing seedling development, and hindering plant growth through the disruption of cell division (mitosis) and cell elongation due to loss of turgor pressure.

Explanation: Drought conditions limit a plant's nutrient uptake and decrease photosynthetic activity due to reduced photosynthetic tissues, stomatal closure, and impaired photosynthetic machinery, all contributing to lower plant growth and yields.

Explanation: In response to drought stress, plants commonly reallocate more resources to root development to enhance water uptake, a strategy that, while beneficial for survival, often results in reduced growth of other plant parts and lower overall yields.

Explanation: Reduced water quality during droughts is primarily due to a *decrease* in the dilution of pollutants from *lower* water flows, leading to increased contamination of water sources.

Explanation: Loess is a fine-grained, windblown sediment that tends to develop into highly rich soils, making regions with loess agriculturally productive under suitable climatic conditions.

Explanation: Loess deposits are geologically unstable and erode very easily, particularly due to wind erosion, which can be thousands of times greater during drought years.

Explanation: Droughts lead to lower surface and subterranean water levels and reduced river flow, which diminishes the dilution of contaminants, thereby increasing water pollution.

Explanation: Woody plant encroachment can increase soil porosity, which, by altering water infiltration and retention, can heighten the chances of soil drought.

Explanation: Drought-induced mortality of trees significantly impacts the carbon sink function of forests, a factor often underrepresented in climate models, leading to an underestimation of drought's effect on carbon absorption.

Explanation: Dust Bowls and dust storms are primarily linked to erosion and desertification, phenomena exacerbated by dry conditions and a lack of vegetation, leading to significant soil loss.

Explanation: Drought fundamentally affects crop production by causing poor germination, impairing seedling development, and hindering cell division and elongation due to loss of turgor pressure.

Explanation: A common plant adaptation to drought stress involves allocating more resources to root development to enhance water uptake, often at the expense of above-ground growth.

Explanation: Loess is agriculturally important because it typically develops into highly rich soils, making regions with loess among the most productive in the world under suitable climatic conditions.

Explanation: Droughts can persist for days, months, or even years, and they significantly impact ecosystems and agricultural sectors, not just urban water supplies, often causing harm to local economies.

Explanation: The three main categories of drought effects are environmental, economic, and social, not meteorological, hydrological, and agricultural, which are types of drought.

Explanation: Economic impacts of drought extend beyond agriculture and livestock farming to include forestry, public water supplies, river navigation, electric power supply (hydropower), and various industrial sectors such as metallurgy, mining, and chemical production.

Explanation: Droughts contribute to increased air pollution through higher dust concentrations and wildfires, which are recognized as significant social and health costs.

Explanation: Economic losses during droughts encompass reduced energy production from hydropower plants and significant challenges with water supply for various industrial sectors, including metallurgy, mining, and chemical production.

Explanation: The most severe human impacts of drought encompass crop failure, food crises, famine, malnutrition, poverty, and mass migration, often resulting in significant loss of life.

Explanation: The UN issued a warning in 2025 that the ongoing retreat of glaciers poses a significant threat to the food and water supply of 2 billion people globally, as these ice masses are vital freshwater sources.

Explanation: The three main categories of drought effects are environmental, economic, and social. Meteorological drought is a *type* of drought, not a category of its effects.

Explanation: The most severe human impacts of drought include widespread crop failure, leading to food crises, famine, malnutrition, and mass migration, often resulting in significant loss of life.

Explanation: The UN warned in 2025 that retreating glaciers could threaten the food and water supply of 2 billion people worldwide, underscoring the critical role of these ice masses as freshwater sources.

Explanation: The Amazon basin, Australia, and the Sahel region are specifically highlighted as areas with *increased* or *worsening* drought risks, not decreased risks.

Explanation: In 2006, scientists warned that the Amazon rainforest could reach a 'tipping point' and irreversibly transform into savanna or desert if it endured three consecutive years of drought, especially when combined with deforestation.

Explanation: Australia's Millennium Drought (1997–2009) prompted the widespread construction of desalination plants across the country to mitigate a severe water supply crisis.

Explanation: A 2005 study proposed that the desertification of interior Australia could be linked to the regular burning practices of human settlers who arrived approximately 50,000 years ago.

Explanation: The Horn of Africa drought from 2020 to 2023 was the third longest and most widespread on record, surpassing the 2010–2011 drought in both duration and severity.

Explanation: Drought affecting the Ganges River in India is a major concern because it serves as a critical source of drinking water and agricultural irrigation for over 500 million people.

Explanation: The '4.2-kiloyear event' was a significant megadrought that occurred between 5,000 and 4,000 years ago, and it has been linked to the collapse of several ancient civilizations across Africa and Asia.

Explanation: Parts of the Amazon basin experienced its worst drought in 100 years in 2005, as highlighted among regions with increased drought risks.

Explanation: In 2006, scientists warned that the Amazon rainforest could irreversibly transform into savanna or desert if it experienced three consecutive years of drought, especially when combined with deforestation.

Explanation: A major consequence of Australia's Millennium Drought (1997–2009) was the widespread construction of desalination plants to address a severe water supply crisis.

Explanation: A 2005 study suggested that the desertification of interior Australia might be linked to the regular burning practices of ancient human settlers who arrived approximately 50,000 years ago.

Explanation: The Horn of Africa drought from 2020 to 2023 was the third longest and most widespread on record, exceeding the 2010–2011 drought in both duration and severity.

Explanation: Drought affecting the Ganges River in India is a major concern because the river is a critical source of drinking water and agricultural irrigation for over 500 million people.

Explanation: The Epic of Gilgamesh, the Biblical story of Joseph's arrival in ancient Egypt, and hunter-gatherer migrations in 9,500 BC Chile are all explicitly linked to drought in the source material, while the construction of the Great Wall of China is not mentioned in this context.

Explanation: The '4.2-kiloyear event,' a megadrought between 5,000 and 4,000 years ago, has been linked to the collapse of several ancient civilizations, including the Old Kingdom in Egypt.

Explanation: The longest drought in recorded history began 400 years ago in the Atacama Desert in Chile and is still ongoing.

Explanation: The 1540 European drought, which affected Central Europe with eleven months of no rain and significantly higher temperatures, is described as the 'worst drought of the millennium.'

Explanation: Despite being a form of intentional weather modification, there is currently no convincing scientific proof of the efficacy of cloud seeding for inducing rainfall and mitigating drought, as reported by the United States National Research Council.

Explanation: Implementing irrigation and carefully planned crop rotation are agricultural practices that can significantly mitigate drought impacts by minimizing erosion and allowing for the cultivation of less water-dependent crops.

Explanation: The United States National Research Council reported in 2004 that there is still no convincing scientific proof of the efficacy of cloud seeding as a drought mitigation strategy.