About this dataset

Context

The dataset tabulates the Plant City population over the last 20 plus years. It lists the population for each year, along with the year on year change in population, as well as the change in percentage terms for each year. The dataset can be utilized to understand the population change of Plant City across the last two decades. For example, using this dataset, we can identify if the population is declining or increasing. If there is a change, when the population peaked, or if it is still growing and has not reached its peak. We can also compare the trend with the overall trend of United States population over the same period of time.

Key observations

In 2023, the population of Plant City was 40,571, a 0.40% increase year-by-year from 2022. Previously, in 2022, Plant City population was 40,410, an increase of 1.55% compared to a population of 39,795 in 2021. Over the last 20 plus years, between 2000 and 2023, population of Plant City increased by 10,594. In this period, the peak population was 40,571 in the year 2023. The numbers suggest that the population has not reached its peak yet and is showing a trend of further growth. Source: U.S. Census Bureau Population Estimates Program (PEP).

Content

When available, the data consists of estimates from the U.S. Census Bureau Population Estimates Program (PEP).

Data Coverage:

• From 2000 to 2023

Variables / Data Columns

• Year: This column displays the data year (Measured annually and for years 2000 to 2023)
• Population: The population for the specific year for the Plant City is shown in this column.
• Year on Year Change: This column displays the change in Plant City population for each year compared to the previous year.
• Change in Percent: This column displays the year on year change as a percentage. Please note that the sum of all percentages may not equal one due to rounding of values.

Good to know

Margin of Error

Data in the dataset are based on the estimates and are subject to sampling variability and thus a margin of error. Neilsberg Research recommends using caution when presening these estimates in your research.

Custom data

If you do need custom data for any of your research project, report or presentation, you can contact our research staff at research@neilsberg.com for a feasibility of a custom tabulation on a fee-for-service basis.

Inspiration

Neilsberg Research Team curates, analyze and publishes demographics and economic data from a variety of public and proprietary sources, each of which often includes multiple surveys and programs. The large majority of Neilsberg Research aggregated datasets and insights is made available for free download at https://www.neilsberg.com/research/.

Recommended for further research

This dataset is a part of the main dataset for Plant City Population by Year. You can refer the same here

About this dataset

Context

The dataset tabulates the Plant City population by year. The dataset can be utilized to understand the population trend of Plant City.

Content

The dataset constitues the following datasets

• Plant City, FL Population Dataset: Yearly Figures, Population Change, and Percent Change Analysis

Good to know

Margin of Error

Data in the dataset are based on the estimates and are subject to sampling variability and thus a margin of error. Neilsberg Research recommends using caution when presening these estimates in your research.

Custom data

If you do need custom data for any of your research project, report or presentation, you can contact our research staff at research@neilsberg.com for a feasibility of a custom tabulation on a fee-for-service basis.

Inspiration

Neilsberg Research Team curates, analyze and publishes demographics and economic data from a variety of public and proprietary sources, each of which often includes multiple surveys and programs. The large majority of Neilsberg Research aggregated datasets and insights is made available for free download at https://www.neilsberg.com/research/.

About this dataset

Context

The dataset tabulates the data for the Plant City, FL population pyramid, which represents the Plant City population distribution across age and gender, using estimates from the U.S. Census Bureau American Community Survey (ACS) 2019-2023 5-Year Estimates. It lists the male and female population for each age group, along with the total population for those age groups. Higher numbers at the bottom of the table suggest population growth, whereas higher numbers at the top indicate declining birth rates. Furthermore, the dataset can be utilized to understand the youth dependency ratio, old-age dependency ratio, total dependency ratio, and potential support ratio.

Key observations

• Youth dependency ratio, which is the number of children aged 0-14 per 100 persons aged 15-64, for Plant City, FL, is 27.2.
• Old-age dependency ratio, which is the number of persons aged 65 or over per 100 persons aged 15-64, for Plant City, FL, is 20.8.
• Total dependency ratio for Plant City, FL is 48.0.
• Potential support ratio, which is the number of youth (working age population) per elderly, for Plant City, FL is 4.8.

Content

When available, the data consists of estimates from the U.S. Census Bureau American Community Survey (ACS) 2019-2023 5-Year Estimates.

Age groups:

• Under 5 years
• 5 to 9 years
• 10 to 14 years
• 15 to 19 years
• 20 to 24 years
• 25 to 29 years
• 30 to 34 years
• 35 to 39 years
• 40 to 44 years
• 45 to 49 years
• 50 to 54 years
• 55 to 59 years
• 60 to 64 years
• 65 to 69 years
• 70 to 74 years
• 75 to 79 years
• 80 to 84 years
• 85 years and over

Variables / Data Columns

• Age Group: This column displays the age group for the Plant City population analysis. Total expected values are 18 and are define above in the age groups section.
• Population (Male): The male population in the Plant City for the selected age group is shown in the following column.
• Population (Female): The female population in the Plant City for the selected age group is shown in the following column.
• Total Population: The total population of the Plant City for the selected age group is shown in the following column.

Good to know

Margin of Error

Data in the dataset are based on the estimates and are subject to sampling variability and thus a margin of error. Neilsberg Research recommends using caution when presening these estimates in your research.

Custom data

If you do need custom data for any of your research project, report or presentation, you can contact our research staff at research@neilsberg.com for a feasibility of a custom tabulation on a fee-for-service basis.

Inspiration

Neilsberg Research Team curates, analyze and publishes demographics and economic data from a variety of public and proprietary sources, each of which often includes multiple surveys and programs. The large majority of Neilsberg Research aggregated datasets and insights is made available for free download at https://www.neilsberg.com/research/.

Recommended for further research

This dataset is a part of the main dataset for Plant City Population by Age. You can refer the same here

Urban environments are warmer, have higher levels of atmospheric CO2, and altered patterns of disturbance and precipitation than nearby rural areas. These differences can be important for plant growth and are likely to create distinct selective environments. We planted a common garden experiment with seeds collected from natural populations of the native annual plant Lepidium virginicum, growing in five urban and nearby rural areas in the northern United States to determine whether and how urban populations differ from those from surrounding rural areas. When grown in a common environment, plants grown from seeds collected from urban areas bolted sooner, grew larger, had fewer leaves, had an extended time between bolting and flowering, and produced more seeds than plants grown from seeds collected from rural areas. Interestingly, the rural populations exhibited larger phenotypic differences from one another than urban populations. Surprisingly, genomic data revealed that the majority of individuals in each of the urban populations were more closely related to individuals from other urban populations than they were to geographically proximate rural areas – the one exception being urban and rural populations from New York which were nearly identical. Taken together our results suggest that selection in urban environments favors different traits than selection in rural environments and that these differences can drive adaptation and shape population structure.

District Cooling Carbon-Free Plant Market Outlook

According to our latest research, the global District Cooling Carbon-Free Plant market size is estimated at USD 4.8 billion in 2024, with a robust compound annual growth rate (CAGR) of 10.3% expected through the period 2025 to 2033. By 2033, the market is projected to reach approximately USD 12.6 billion. The primary growth driver for this market is the accelerating global transition towards carbon neutrality and sustainable urban infrastructure, propelled by stringent governmental regulations and rising awareness about climate change impacts.

The growth of the District Cooling Carbon-Free Plant market is underpinned by the increasing adoption of district cooling systems as a viable alternative to conventional air conditioning, especially in rapidly urbanizing regions. Urban centers are facing mounting pressure to reduce carbon emissions and energy consumption, making the adoption of carbon-free district cooling plants a strategic move for city planners and developers. Additionally, the integration of renewable energy sources and advanced cooling technologies is further enhancing the efficiency and sustainability of these systems. The market is also benefiting from public and private sector investments aimed at modernizing infrastructure and reducing the carbon footprint of large commercial and residential developments.

Another significant growth factor is the rapid technological advancements in cooling technologies such as absorption cooling, electric chillers, and free cooling. These innovations are making district cooling systems more energy-efficient and environmentally friendly, aligning with global climate goals. Furthermore, the development of smart city projects worldwide is creating a fertile ground for the deployment of carbon-free district cooling plants. As cities aim to become more resilient to climate change, the demand for sustainable cooling solutions is expected to surge, driving further market expansion. The increasing prevalence of green building certifications and energy efficiency standards is also compelling developers to integrate district cooling systems into new and existing buildings.

The market is also witnessing a shift in consumer and corporate preferences towards sustainable cooling solutions. End-users, including healthcare facilities, data centers, hospitality venues, and retail complexes, are increasingly opting for carbon-free district cooling to meet regulatory requirements and enhance their sustainability credentials. This trend is especially pronounced in regions with high cooling demand and stringent environmental regulations. The growing awareness of the operational cost savings and long-term benefits of carbon-free cooling solutions is further fueling market growth. In addition, government incentives and subsidies for green infrastructure projects are providing a significant boost to the adoption of district cooling carbon-free plants.

Regionally, the Asia Pacific market is leading the global adoption of district cooling carbon-free plants, driven by rapid urbanization, population growth, and ambitious government initiatives aimed at decarbonizing urban infrastructure. North America and Europe are also significant contributors, owing to their advanced technological landscape and strong regulatory frameworks supporting energy efficiency and sustainability. The Middle East & Africa region, with its extreme climatic conditions and large-scale urban development projects, is emerging as a high-potential market for district cooling carbon-free plants. Latin America, while still in the nascent stage, is expected to witness steady growth as awareness and investments in sustainable infrastructure increase.

Plant Type Analysis

The Plant Type segment of the District Cooling Carbon-Free Plant market is bifurcated into centralized and decentralized systems, each offering unique advantages and challenges. Centralized district cooling plants are characterized by their ability to serve large-scale developments, such as urban districts and commercial complexes, from a single, strategically located facility. This model is highly efficient in terms of energy distribution and maintenance, as it consolidates resources and streamlines operations. Centralized systems are particularly favored in densely populated urban areas where large-scale infrastructure can be justified by the high demand fo

Municipal Solid Waste Power Generation Plant Market Outlook

The global market size for Municipal Solid Waste (MSW) Power Generation Plants was valued at approximately USD 10 billion in 2023 and is projected to reach around USD 25 billion by 2032, growing at a robust CAGR of 11%. The growth of this market is primarily driven by the increasing demand for renewable energy sources, coupled with stringent environmental regulations encouraging waste-to-energy (WTE) technologies. Governments across the globe are increasingly adopting policies to mitigate the environmental impact of waste, which is propelling the market for MSW power generation plants.

One of the primary growth factors for the MSW power generation plant market is the escalating volume of municipal solid waste generated worldwide. With urbanization and population growth, cities are producing unprecedented amounts of waste, leading to heightened demand for efficient waste management solutions. Waste-to-energy technologies offer a dual benefit by reducing waste volumes and generating energy, making them an attractive option for municipalities. The increasing awareness among governments and municipalities regarding sustainable waste management practices is further augmenting market growth. For instance, the European Union's directives on waste management are emphasizing reducing landfill waste and promoting waste-to-energy conversions.

Another significant driver is the growing focus on renewable energy sources. With the global emphasis on reducing carbon footprints and combating climate change, renewable energy sources, including waste-to-energy, are gaining traction. By converting waste into usable energy, MSW power generation plants contribute to a circular economy and provide a sustainable energy source. Additionally, advancements in technology have made waste-to-energy processes more efficient and cost-effective, thereby encouraging their adoption. Countries such as China and India are investing heavily in waste-to-energy technologies to address their mounting waste issues while simultaneously fulfilling their energy requirements.

Economic incentives and government policies are also playing a crucial role in the expansion of the MSW power generation plant market. Subsidies, tax benefits, and funding programs are being introduced to encourage the development of waste-to-energy facilities. Governments are recognizing the potential of these plants not only in waste management but also in generating employment and boosting local economies. For example, in the United States, policies like the Renewable Energy Production Tax Credit (PTC) and the Investment Tax Credit (ITC) are providing significant financial benefits for waste-to-energy projects, thus fostering market growth.

Regionally, the market dynamics vary significantly. Asia Pacific is expected to dominate the market during the forecast period, driven by rapid urbanization and industrialization in countries like China and India. North America and Europe are also substantial markets due to stringent environmental regulations and a mature waste management infrastructure. In contrast, Latin America and the Middle East & Africa are emerging markets with significant growth potential, attributed to increasing investments in waste-to-energy technologies and improving waste management frameworks.

Technology Analysis

The technology segment of the Municipal Solid Waste Power Generation Plant market is broadly categorized into thermal, biological, and physical technologies. Thermal technologies, including incineration and gasification, are the most prevalent due to their high efficiency in converting waste to energy. Incineration, in particular, is widely used for its ability to significantly reduce waste volume while generating substantial amounts of energy. Modern incineration plants are equipped with advanced pollution control systems, making them environmentally viable options. Gasification, though less common, offers higher energy efficiency and lower emissions, making it an attractive technology for future investments.

Biological technologies, such as anaerobic digestion, are gaining popularity for their ability to process organic waste and generate biogas, which can be used for electricity and heat generation. Anaerobic digestion is particularly suitable for managing food waste and other biodegradable materials, making it a critical component of integrated waste management systems. The biogas produced can be upgraded to biomethane and used as a renewable natural gas, further enhancing its utility. Technological advancements and decreasing costs are

Indoor Garden System Market Outlook

The global indoor garden system market size was valued at USD 2.3 billion in 2023 and is projected to reach USD 4.7 billion by 2032, growing at a compound annual growth rate (CAGR) of 8.1% during the forecast period. The market's growth is primarily driven by increasing urbanization, a growing interest in sustainable and organic farming, and advancements in indoor gardening technology.

One of the major growth factors for the indoor garden system market is the increasing urban population, which often lacks access to traditional gardening spaces. As cities expand and more people live in apartments with limited or no outdoor spaces, the demand for indoor gardening solutions is rising. Indoor garden systems provide a practical way to grow fresh produce and ornamental plants within confined spaces, thus appealing to city dwellers who wish to maintain a green environment and have access to home-grown food.

Additionally, there is a growing consumer trend towards sustainable and organic farming practices. Environmental concerns and health consciousness are driving people to seek healthier and environmentally friendly alternatives to conventionally grown produce. Indoor garden systems, which utilize hydroponic, aeroponic, and aquaponic methods, offer a way to grow food without the use of harmful pesticides and with reduced water usage, aligning with the principles of sustainability and conservation.

Technological advancements have significantly contributed to the market's growth. Innovations in grow lights, automated nutrient delivery systems, and smart sensors have made indoor gardening more efficient and accessible. These technologies not only simplify the cultivation process but also enhance crop yields and quality, making indoor gardening a viable option for both amateur gardeners and commercial enterprises. The integration of IoT and AI in indoor garden systems further enhances their appeal by providing users with data-driven insights and automated controls to optimize plant growth.

Indoor Container Farm solutions are becoming increasingly popular as they provide an innovative approach to urban agriculture. These farms utilize repurposed shipping containers equipped with advanced hydroponic systems to grow a variety of crops in controlled environments. This method allows for year-round cultivation, regardless of external weather conditions, making it an ideal solution for urban areas with limited space. Indoor container farms are particularly beneficial for cities facing food security challenges, as they can be strategically placed near urban centers to reduce transportation costs and carbon emissions. The compact design and modular nature of these farms also make them scalable, allowing for easy expansion as demand for fresh produce increases. By integrating technology such as LED lighting and automated climate controls, indoor container farms optimize resource use and enhance crop yields, contributing to the sustainability of urban food systems.

Regionally, North America is expected to hold a significant share of the indoor garden system market due to the high adoption rate of advanced farming technologies and a strong emphasis on organic and sustainable living. Europe is also anticipated to see substantial growth driven by similar trends and supportive government policies promoting urban agriculture. Meanwhile, the Asia Pacific region is poised for rapid growth due to increasing urbanization, rising disposable incomes, and growing awareness of the benefits of indoor gardening.

Product Type Analysis

The indoor garden system market is segmented by product type into hydroponic systems, aeroponic systems, aquaponic systems, and soil-based systems. Hydroponic systems, which involve growing plants in nutrient-rich water without soil, are gaining immense popularity due to their efficiency and the ability to produce higher yields in a controlled environment. These systems are particularly favored for commercial applications where maximizing output within limited space is crucial.

Aeroponic systems, where plant roots are suspended in the air and misted with nutrient solution, offer another innovative approach to indoor gardening. These systems are known for their ability to optimize oxygen exposure to roots, leading to faster growth rates and higher nutrient uptake. Aeroponic systems are increasingly being adopted in both residential and commercial settings for