This statistic shows the required increase from 2013 levels in agricultural production in order for projected demand in 2050 to be met. In order to meet the global food demand in 2050, agricultural production has to increase by **** percent worldwide.

In April 2025, global industrial production, excluding the United States, increased by************* compared to the same time in the previous year, based on three month moving averages. This is compared to an increase of 1*** percent in advanced economies (excluding the United States) for the same time period.

Dunmore quarry production increase

United States TMOS: sa: Future Production: Increase data was reported at 30.400 % in Apr 2020. This records an increase from the previous number of 27.700 % for Mar 2020. United States TMOS: sa: Future Production: Increase data is updated monthly, averaging 48.900 % from Jun 2004 (Median) to Apr 2020, with 191 observations. The data reached an all-time high of 75.100 % in Sep 2004 and a record low of 24.700 % in Jan 2009. United States TMOS: sa: Future Production: Increase data remains active status in CEIC and is reported by Federal Reserve Bank of Dallas. The data is categorized under Global Database’s United States – Table US.S016: Texas Manufacturing Outlook Survey.

In July 2024, global industrial production, excluding the United States, increased by 1.5 percent compared to the same time in the previous year, based on three month moving averages. This is compared to an increase of 0.2 percent in advanced economies (excluding the United States) for the same time period. The global industrial production collapsed after the outbreak of COVID-19, but increased steadily in the months after, peaking at 23 percent in June 2021. Industrial growth rate tracks the output production in the industrial sector.

Future Production; Percentage Reporting Increases for Texas was 42.70% in June of 2025, according to the United States Federal Reserve. Historically, Future Production; Percentage Reporting Increases for Texas reached a record high of 75.50 in September of 2004 and a record low of 23.00 in November of 2022. Trading Economics provides the current actual value, an historical data chart and related indicators for Future Production; Percentage Reporting Increases for Texas - last updated from the United States Federal Reserve on July of 2025.

The total amount of data created, captured, copied, and consumed globally is forecast to increase rapidly, reaching *** zettabytes in 2024. Over the next five years up to 2028, global data creation is projected to grow to more than *** zettabytes. In 2020, the amount of data created and replicated reached a new high. The growth was higher than previously expected, caused by the increased demand due to the COVID-19 pandemic, as more people worked and learned from home and used home entertainment options more often. Storage capacity also growing Only a small percentage of this newly created data is kept though, as just * percent of the data produced and consumed in 2020 was saved and retained into 2021. In line with the strong growth of the data volume, the installed base of storage capacity is forecast to increase, growing at a compound annual growth rate of **** percent over the forecast period from 2020 to 2025. In 2020, the installed base of storage capacity reached *** zettabytes.

Manual Production Systems Market Outlook

The global Manual Production Systems market size was valued at approximately USD 12.5 billion in 2023 and is projected to reach around USD 21.8 billion by 2032, growing at a CAGR of 6.4% during the forecast period. The primary growth factor driving this expansion is the increasing demand for efficient, flexible, and cost-effective production systems across various industries such as automotive, electronics, and medical devices.

One of the major growth factors for the Manual Production Systems market is the rising demand for customized products. Industries, especially those focused on consumer goods and electronics, are increasingly adopting manual production systems to offer tailored solutions to meet individual customer requirements. These systems provide the flexibility to accommodate low-volume, high-mix production runs, which is critical for companies looking to differentiate themselves in a competitive market. The ability to quickly adjust to new designs and specifications without substantial retooling costs makes manual production systems highly attractive.

Another significant factor contributing to the market growth is the increasing focus on quality and precision. Manual production systems allow for better control over the manufacturing process, thereby enhancing the quality of the end product. This is particularly important in industries such as aerospace and medical devices, where even minor defects can have serious consequences. The use of manual systems enables greater oversight and more stringent quality checks, ensuring that products meet the required standards and specifications.

Moreover, the growing trend towards sustainable manufacturing practices is also driving the market. Manual production systems typically consume less energy and generate less waste compared to fully automated systems. This makes them an attractive option for companies looking to reduce their environmental footprint. In addition, the ability to easily integrate human skills with advanced technologies in manual production systems offers a balanced approach that can enhance productivity while minimizing energy consumption and waste generation.

Regionally, Asia Pacific is expected to dominate the Manual Production Systems market during the forecast period, driven by rapid industrialization, especially in countries like China and India. These nations are witnessing a surge in manufacturing activities, coupled with significant investments in infrastructure development. The availability of a skilled labor force at a relatively lower cost further boosts the adoption of manual production systems in this region. North America and Europe are also significant markets, driven by advancements in technology and a strong focus on high-quality production standards.

The Can Body Production Line is an integral part of the manufacturing process in industries such as food and beverage, where the demand for canned products is on the rise. These production lines are designed to efficiently handle the complex tasks of forming, sealing, and labeling cans, ensuring that they meet the required quality standards. The flexibility of manual production systems makes them well-suited for can body production, as they allow for quick adjustments to accommodate different can sizes and designs. This adaptability is crucial in a market where consumer preferences and packaging requirements are constantly evolving. By integrating advanced tools and technologies, such as automated inspection systems and precision forming equipment, manufacturers can enhance the efficiency and quality of their can body production lines. The focus on sustainability is also driving innovations in this area, with companies seeking to reduce waste and energy consumption in their production processes.

Component Analysis

Tools

The tools segment is a critical component of the Manual Production Systems market. This segment includes various hand tools, power tools, and specialized instruments required for different manufacturing processes. The demand for high-quality tools is driven by the need for precision and efficiency in manual production settings. Tools are often the backbone of manual systems, enabling workers to perform tasks with greater accuracy and speed. The increasing adoption of ergonomically designed tools to enhance worker comfort and reduce fatigue is also contributing to market growth.

Key information about Brazil Industrial Production Index Growth

• Brazil Industrial production rose 1.7 % YoY in Jan 2025, following an increase of 0.3 % YoY in the previous month.
• Brazil Industrial production index growth rate YoY data is updated monthly, available from Jan 1986 to Jan 2025, with an average rate of 1.4 %.
• The data reached an all-time high of 34.5 % in Apr 1991 and a record low of -28.4 % in Apr 1990.

Evaluating seasonal soil water dynamics using a simple soil water balance model in northern Ghana. Paper accepted for the African Soil Science Society Conference, Ouagadougou, Burkina Faso. Agro-climatic and hydrological characterization of selected watersheds of northern Ghana. IWMI draft working paper (in review) Comparative yield performance and fodder quality of Napier grass in Northern Ghana. (Conference paper accepted)

Post Production Services Market Outlook

The global post production services market size was valued at approximately USD 23.5 billion in 2023 and is projected to reach USD 40.2 billion by 2032, growing at a CAGR of 6.1% during the forecast period. This substantial growth is driven by the increasing demand for high-quality visual content across various media platforms and the continuous advancements in post production technologies.

One of the primary growth factors in the post production services market is the rising demand for high-quality visual content. With the proliferation of streaming services, social media platforms, and digital advertising, there is an ever-increasing need for professional post production services to ensure content meets high standards. The advent of 4K and 8K video resolution, as well as the emergence of virtual reality (VR) and augmented reality (AR), has further heightened the need for specialized post production techniques, thus driving market growth.

Technological advancements have also significantly contributed to the growth of the post production services market. Innovations such as artificial intelligence (AI) and machine learning (ML) are revolutionizing the way post production tasks are executed. AI-powered software can automate various aspects of editing, color correction, and visual effects, significantly reducing the time and cost involved in the post production process. Additionally, cloud-based post production solutions are gaining traction, allowing for seamless collaboration among teams dispersed across different geographic locations.

Another key driver is the growing trend of content globalization. As production houses and broadcasters aim to reach a global audience, they require post production services that can handle multi-language subtitling, dubbing, and localization efficiently. This has opened up new opportunities for companies offering specialized post production services, particularly in regions with a high demand for localized content. Furthermore, the increasing number of film festivals and international co-productions has fueled the need for high-quality post production work to meet diverse audience expectations.

In the realm of medical imaging and diagnostics, Stroke Post Processing Software has emerged as a pivotal tool in enhancing the accuracy and efficiency of stroke diagnosis and management. This software leverages advanced algorithms and machine learning techniques to process and analyze imaging data, providing clinicians with detailed insights into the extent and nature of a stroke. By automating the interpretation of complex imaging results, Stroke Post Processing Software not only speeds up the diagnostic process but also reduces the likelihood of human error, thereby improving patient outcomes. As healthcare providers increasingly adopt digital solutions to streamline operations, the integration of such software into clinical workflows is becoming more prevalent, highlighting its critical role in modern healthcare settings.

Regionally, North America holds a significant share of the post production services market, owing to the presence of major film studios, television networks, and a robust entertainment industry infrastructure. However, the Asia Pacific region is expected to witness the highest growth rate during the forecast period. This growth can be attributed to the booming film and television industry in countries like China and India, increasing investments in digital infrastructure, and a growing appetite for high-quality content among the region's population. Additionally, the rise of regional OTT platforms and the increasing penetration of internet services are further propelling the demand for post production services in Asia Pacific.

Service Type Analysis

The post production services market is segmented by service type into editing, visual effects, sound design, color correction, and others. Each of these segments plays a crucial role in the overall production process, contributing to the creation of a polished and engaging final product. Editing, being one of the most fundamental aspects of post production, involves assembling raw footage, trimming excess clips, and arranging sequences to create a coherent narrative. The demand for professional editing services is high, given the need for precision and creativity to ensure the story is effectively conveyed to the audience.

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Instant Noodle Production Line Market Outlook

The global instant noodle production line market size was valued at approximately USD 4.2 billion in 2023 and is expected to reach USD 6.8 billion by 2032, growing at a CAGR of 5.4% during the forecast period. This market growth can be attributed to the increasing demand for convenience foods and the rapid urbanization occurring worldwide, which is influencing consumer eating habits.

One of the key growth factors driving the instant noodle production line market is the rising urban population. As cities expand and lifestyles become more hectic, the need for quick and convenient meal options has surged. Instant noodles, being both easy to prepare and affordable, have become a staple in many urban households. Additionally, the growing number of single-person households has further fueled the demand for instant noodles, as these consumers are more likely to opt for quick, single-serving meal solutions.

Technological advancements in production lines have also played a significant role in market growth. Modern production lines are increasingly automated, which enhances manufacturing efficiency and product consistency. Advances in machinery for mixing, rolling, steaming, frying, cooling, and packaging have significantly reduced production costs and improved the scalability of noodle manufacturing. This technological progress helps manufacturers meet rising consumer demand while maintaining product quality.

The availability of a wide variety of instant noodle flavors and types has also contributed to the market's expansion. Manufacturers are continually innovating to introduce new flavors that cater to regional tastes and preferences. Additionally, the introduction of healthier options, such as noodles made from whole grains or fortified with vitamins and minerals, is attracting health-conscious consumers. This diversification in product offerings is crucial for appealing to a broader consumer base and sustaining market growth.

Regionally, Asia Pacific dominates the instant noodle production line market, driven by high consumption rates in countries like China, Japan, and Indonesia. North America and Europe are also witnessing significant market growth, primarily due to the increasing popularity of Asian cuisine and the growing demand for convenient, ready-to-eat meals. Emerging markets in Latin America and the Middle East & Africa are experiencing steady growth, supported by rising disposable incomes and urbanization. These regional dynamics are shaping the global instant noodle production line market, making it a lucrative sector for investment and expansion.

Machine Type Analysis

The machine type segment of the instant noodle production line market includes various stages such as mixing, rolling, steaming, frying, cooling, and packaging. Each stage involves specific machinery designed to optimize the production process and ensure product quality. The mixing machines are crucial as they ensure a uniform blend of ingredients, which is essential for the consistency and taste of the final product. High-efficiency mixers with precise control systems are increasingly in demand as they contribute to the overall quality and yield of the production process.

Rolling machines play a pivotal role in forming the dough sheets into the desired thickness and texture. The advancements in rolling technology have enabled manufacturers to achieve greater consistency and precision, which is vital for maintaining product standards. Innovations such as adjustable rollers and automated thickness control are enhancing the efficiency and flexibility of rolling machines, allowing for the production of various noodle types and sizes.

Steaming machines are essential for partially cooking the noodles before they are fried or air-dried. The steaming process is critical for achieving the right texture and flavor profile. Modern steaming machines are designed to provide uniform and controlled heating, ensuring that each noodle batch is cooked to perfection. These machines are also equipped with energy-efficient systems that reduce operational costs while maintaining high production standards.

Frying machines are used for cooking the noodles to achieve their characteristic texture and taste. The demand for high-capacity frying machines with precise temperature control is on the rise, as these machines ensure consistent frying quality and reduce oil usage. Additionally, there is a growing trend towards healthier noodle options, leading to innovations in air-frying t

Toyota's global production increased by 6% in February, driven by domestic growth. Despite North American challenges and U.S. tariffs, global revenue rose by 6%.

Bacterial Panicle Blight (BPB), caused by Burkholderia glumae, is a bacterial disease in rice (Oryza sativa) that reduces rice yield and quality for producers and consequently creates higher market prices for consumers. BPB is caused by the simultaneous occurrence of high daily minimum temperatures (~22°C) and relative humidity (~77%), which may increase under the current scenario of global warming. This study hypothesized that the economic damage from warming may cause an increase in economic losses, though at a decreasing rate per degree. Thus, this study estimates the yield losses associated with BPB occurrences at the county level in the Mid-South United States (US) for annual rice production in 2003–2013 and under +1–3°C warming scenarios using daily weather information with appropriate thresholds. From the estimated losses, the total production potential of a BPB-resistant rice was quantified using a spatial equilibrium trade model to further estimate market welfare changes with the counterfactual scenario that all US county-level rice production were BPB resistant. Results from the study indicate that the alleviation of BPB would represent a $69 million USD increase in consumer surplus in the US and a concomitant increase in rice production that would feed an additional 1.46 million people annually assuming a global average consumption of 54 Kg per person. Under the 1°C warming scenario, BPB occurrences and production losses would cause price increases for rice and subsequently result in a $112 million USD annual decrease in consumer surplus in the US and a loss of production equivalent to feeding 2.17 million people. Under a 3°C warming scenario, production losses due to BPB cause an annual reduction of $204 million USD in consumer surplus in the US, and a loss in production sufficient to feed 3.98 million people a year. As global warming intensifies, BPB could become a more common and formidable rice disease to combat, and breeding for BPB resistance would be the primary line-of-defense as currently no effective chemical options are available. The results of this study inform agriculturalists, policymakers, and economists about the value of BPB-resistance in the international rice market and also help support efforts to focus future breeding toward climate change impact resilience.

It is projected that the global production of thermoplastics will amount to 445.25 million metric tons in 2025. Annual production volumes are expected to continue rising in the following decades, rising to approximately 590 million metric tons by 2050. this would be an increase of more than 30 percent compared with 2025. Between 2010 and 2020, the global production of plastics has increased from 270 million metric tons to almost 370 million metric tons.

Climate change affects both water resources and agricultural production. With rising temperatures and decreasing summer precipitation, it is expected that agricultural production will be increasingly limited by drought. Where surface- or groundwater resources are available for irrigation, an increase in water withdrawals for irrigation is to be expected. Therefore, quantitative approaches are required to anticipate and manage the expected conflicts related to increased water abstraction for irrigation. This project aims to investigate how agricultural production, water demand for irrigation, runoff and groundwater dynamics are affected by future climate change and how climate change impacts combined with changes in agricultural water use affect groundwater dynamics. To answer these research questions, a comprehensive, loosely coupled model approach was developed, combining models from three disciplines: an agricultural plant growth model, a hydrological model and a hydrogeological model. The model coupling was implemented and tested for an agricultural area located in Switzerland in which groundwater plays a significant role in providing irrigation water. Our suggested modelling approach can be easily adapted to other areas. The model results show that yield changes are driven by drought limitations and rising temperatures. However, an increase in yield may be realized with an increase in irrigation. Simulation results show that the water requirement for irrigation without climate protection (RCP8.5) could increase by 40% by the end of the century with an unchanged growing season and by up to 80% with varietal adaptations. With climate change mitigation (RCP2.6) the increase in water demand for irrigation would be limited to 7%. The increase in irrigation (+12 mm) and the summer decrease in recharge rates (similar to 20 mm/month) with decreasing summer precipitation causes a lowering of groundwater levels (40 mm) in the area in the late summer and autumn. This impact may be accentuated by an intensification of irrigation and reduced by extensification. (C) 2021 The Authors. Published by Elsevier B.V.

Acetone Market size was valued at USD 4.96 Billion in 2023 and is projected to reach USD 7.55 Billion by 2031, growing at a CAGR of 5.40% from 2024 to 2031.

Key Market Drivers Expanding End-Use Industries: The rising end-use industries are pushing the need for acetone in a variety of sectors. Acetone is an important solvent in pharmaceutical and cosmetic manufacturing operations. The increasing demand for pharmaceuticals and personal care items is driving up the need for acetone. Acetone is also used in the textile sector to degum and degrease materials, improving their quality. Acetone consumption is expected to increase as the textile sector increases, particularly in developing economies. Similarly, in the electronics industry, acetone is used to clean circuit boards and electronic components during production. Rising Disposable Income in Developing Economies: Rising disposable income in developing economies is another important element driving the expansion of the acetone industry. As disposable incomes rise, so does demand for consumer items like medications, cosmetics, and electronics, all of which need acetone in the manufacturing process. Furthermore, developing nations are seeing major infrastructure development, resulting in increased building activity and a greater need for paints and coatings containing acetone as a solvent. Advancements in Production Technologies: Advances in manufacturing technology are also propelling market growth. The development of more efficient and cost-effective acetone production technologies may result in lower prices, making acetone more affordable to a larger range of industries. Furthermore, there is a rising emphasis on sustainability, with research and development initiatives targeted at developing environmentally friendly acetone production processes using renewable feedstocks. These environmentally friendly solutions are drawing new clients and growing the market. Regulatory Landscape: The regulatory landscape has an impact on the acetone market as well. Environmental restrictions governing air and water pollution may have an impact on acetone production and consumption. Stringent rules may necessitate the use of cleaner production technology, thus raising costs. However, increasing environmental requirements may increase demand for bio-based or sustainable acetone alternatives, impacting market dynamics. Fluctuations in Raw Material Costs: Changes in raw material costs, notably propylene, the primary raw material used in acetone manufacturing, can have a substantial impact on acetone prices. Propylene price changes can have an impact on acetone production profitability and, perhaps, market stability.

Change, using 2015 as a reference, of upstream boundary flow during January to April under moderate (RCP 4.5) and extreme (RCP 8.5) climate change scenarios in 2030 and 2050.

These data were created as part of the National Oceanic and Atmospheric Administration Office for Coastal Management's efforts to create an online mapping viewer depicting potential sea level rise and its associated impacts on the nation's coastal areas. The purpose of the mapping viewer is to provide coastal managers and scientists with a preliminary look at sea level rise (slr) and coastal flooding impacts. The viewer is a screening-level tool that uses nationally consistent data sets and analyses. Data and maps provided can be used at several scales to help gauge trends and prioritize actions for different scenarios. The Sea Level Rise and Coastal Flooding Impacts Viewer may be accessed at: https://www.coast.noaa.gov/slr These data depict the potential inundation of coastal areas resulting from a projected 0.5 to 10 feet rise in sea level above current Mean Higher High Water (MHHW) conditions in half foot increments. The process used to produce the data can be described as a modified bathtub approach that attempts to account for both local/regional tidal variability as well as hydrological connectivity. The process uses two source datasets to derive the final inundation rasters and polygons and accompanying low-lying polygons for each iteration of sea level rise: the Digital Elevation Model (DEM) of the area and a tidal surface model that represents spatial tidal variability. The tidal model is created using the NOAA National Geodetic Survey's VDATUM datum transformation software (http://vdatum.noaa.gov) in conjunction with spatial interpolation/extrapolation methods and represents the MHHW tidal datum in orthometric values (North American Vertical Datum of 1988). The model used to produce these data does not account for erosion, subsidence, or any future changes in an area's hydrodynamics. It is simply a method to derive data in order to visualize the potential scale, not exact location, of inundation from sea level rise. Both raster and vector data are provided for each sea level rise amount above MHHW. The raster data represent both the horizontal extent of inundation and depth above ground, in meters. The vector data represent the horizontal extent of both hydrologically connected and unconnected inundation. The vector "slr" data represent inundation that is hydrologically connected to the ocean. The vector "low" data represent areas that are hydrologically unconnected to the ocean, but are below the sea level rise amount and may also flood. For more information, contact coastal.info@noaa.gov.