This statistic shows the yield per harvested acre of corn for grain in the U.S. from 2001 to 2024. According to the report, the corn for grain yield per harvested acre amounted to ***** bushels in 2024, an increase of about two bushels per harvested acre from the previous year.

This statistic shows the yield per harvested acre of corn for silage in the United States from 2001 to 2024. According to the report, the corn for silage yield per harvested acre amounted to **** tons in 2024. The yield per harvested acre has remained fairly constant over the past several years, staying just around ** tons per harvested acre.

United States Crop Production: Corn for Grain: Yield Per Acre data was reported at 176.600 Bushel in 2017. This records an increase from the previous number of 174.600 Bushel for 2016. United States Crop Production: Corn for Grain: Yield Per Acre data is updated yearly, averaging 118.000 Bushel from Dec 1963 (Median) to 2017, with 55 observations. The data reached an all-time high of 176.600 Bushel in 2017 and a record low of 62.100 Bushel in 1964. United States Crop Production: Corn for Grain: Yield Per Acre data remains active status in CEIC and is reported by National Agricultural Statistics Service. The data is categorized under Global Database’s USA – Table US.B068: Agriculture Crop Production.

United States Crop Production: Corn for Silage: Yield Per Acre data was reported at 19.900 Ton in 2017. This records a decrease from the previous number of 20.300 Ton for 2016. United States Crop Production: Corn for Silage: Yield Per Acre data is updated yearly, averaging 17.600 Ton from Dec 1997 (Median) to 2017, with 21 observations. The data reached an all-time high of 20.400 Ton in 2015 and a record low of 14.000 Ton in 2002. United States Crop Production: Corn for Silage: Yield Per Acre data remains active status in CEIC and is reported by National Agricultural Statistics Service. The data is categorized under Global Database’s USA – Table US.B068: Agriculture Crop Production.

Studies comparing profitability of tillage systems often examine narrow historic windows or exclude annual price fluctuations. This study uses a continuous corn (Zea mays L.) (CC; 1970–1990) and corn–soybean Glycine max (L.) Merr. Tillage × Fertilizer study in somewhat poorly drained soils in southern Illinois to reconstruct partial annual budgets with historical prices for crops, fertilizers, lime, herbicides, fuel, labor, and machinery. Combinations of tillage (moldboard plow [MP], chisel tillage [ChT], alternate tillage [AT], and no-till [NT]) and fertilizer (Control, N-only, N+NPK starter, NPK+NPK starter, and NPK broadcast) treatments were evaluated. The CC profits were highest in NPK-applied treatments followed by N-only and Control. The MP treatments were similar to ChT and more profitable than NT, while AT fell between. In CS, NPK-applied treatments were similar regardless of tillage. Combined costs for herbicide, machinery, labor, and diesel were higher in MP ...

This statistic displays the average revenue of indoor and outdoor farming worldwide as of 2016, by crop type. According to the report, the average revenue of indoor horticulture (greens, microgreens, herbs, and vine crops) was about **** million U.S. dollars per acre, while revenue of conventional outdoor commodity crops (corn, wheat, soybean, cotton, and rice) amounted to *** dollars per acre.

In 2024/2025, it is expected that the United States will be the largest producer of corn worldwide with a production volume amounting to about ***** million metric tons. China and Brazil rounded off the top corn producing countries. Corn production Corn, also known as maize, is a grain plant cultivated for food. The origin of this grain remains unknown, however, many historians believe that corn was first domesticated in Mexico's Tehuacan Valley. Types of corn include sweet corn, popcorn, pod corn, flint corn, flour corn, waxy corn and dent corn. Corn is one of the most important crops in the United States. Over the last years, the country's corn farmers experienced constant increases in annual revenues. In 2022/23, the U.S. was responsible for almost one-third of the global corn production. Iowa and Illinois were the top U.S. states based on harvested area of corn for grain in 2023. That year, Iowa's corn for grain production value amounted to approximately ***** million acres. In 2022/23, the United States exported around **** million metric tons of corn, making the nation the world's second largest corn exporter. Mexico and China were the leading buyers of U.S. corn in 2022, purchasing approximately *** million bushels and *** million bushels respectively.

Data from hybrid maize yeild trails conducted by the University of Illinois at Urbana-Champaign, Iowa State University, Kansas State University, and the University of Nebraska-Lincoln between 1934 and 2014. This digitized data was orginally published in Agricultural Experiment Station and Cooperative Extension Service reports and bulletins distributed in paper and, in later years, as Excel files.
The data set includes brand and hybrid names, trial location, and yield (bushels per acre) for all trials and years. Additional data on agronomic phenotypes, soil type, and average weather is included when reported in the orginal publications. Details about the orginal publications, data processing, etc. can be found in the included readme file. A GitHub repositiry containing the R code used to munge the data is also publically available and linked as a reference.

United States Long Term Projections: Corn: Yield (Bushels per Harvested Acre) data was reported at 200.000 Bushel/Acre in 2034. This records an increase from the previous number of 198.000 Bushel/Acre for 2033. United States Long Term Projections: Corn: Yield (Bushels per Harvested Acre) data is updated yearly, averaging 188.000 Bushel/Acre from Dec 2022 (Median) to 2034, with 13 observations. The data reached an all-time high of 200.000 Bushel/Acre in 2034 and a record low of 173.400 Bushel/Acre in 2022. United States Long Term Projections: Corn: Yield (Bushels per Harvested Acre) data remains active status in CEIC and is reported by U.S. Department of Agriculture. The data is categorized under Global Database’s United States – Table US.RI005: Agricultural Projections: Feed Grains: Corn.

Corn Based Ethanol Fuel Market Outlook

The global corn based ethanol fuel market size was estimated to be $XX billion in 2023 and is forecasted to reach $XX billion by 2032, growing at a compound annual growth rate (CAGR) of XX% during the forecast period. The market growth is primarily driven by the increasing demand for renewable energy sources and government mandates on blending ethanol with gasoline to reduce greenhouse gas emissions and dependence on fossil fuels.

One of the primary growth factors of the corn based ethanol fuel market is the increasing environmental awareness and the need to curb carbon emissions. Ethanol, being a renewable source of energy, contributes to lower carbon emissions when compared to traditional fossil fuels. This has led to various governments implementing policies and incentives to promote the use of ethanol. Additionally, the agriculture sector's vast production capacity of corn provides a stable supply of the raw material needed for ethanol production, bolstering market growth.

Technological advancements in production processes are another significant driver for market growth. Innovations such as enzyme technologies and genetically modified crops that yield higher ethanol output per acre of corn have made the production process more efficient and cost-effective. This has significantly reduced the overall cost of ethanol production, making it more competitive with conventional fuels. Furthermore, the development of advanced fermentation techniques and distillation processes has enhanced the quality and efficiency of ethanol production, encouraging its adoption across various industries.

The rising focus on energy security is also a crucial factor contributing to the market's expansion. Countries are increasingly looking to diversify their energy portfolios to reduce reliance on oil imports. Corn based ethanol fuel offers a domestically produced alternative that can help achieve this goal. The volatility of oil prices and geopolitical tensions further underscore the importance of developing a stable and renewable energy source like ethanol, which can be produced locally in many agricultural regions.

Regionally, North America holds a significant share of the corn based ethanol fuel market, driven by the United States' leadership in ethanol production. The U.S. has long been a front-runner in implementing biofuel policies, and the Renewable Fuel Standard (RFS) program mandates substantial ethanol blending in fuels. In contrast, the Asia Pacific region is expected to witness the highest growth rate during the forecast period, fueled by increasing industrialization, urbanization, and government initiatives promoting biofuels in countries like China and India.

Production Process Analysis

The production process of corn based ethanol fuel is primarily segmented into dry milling and wet milling. Dry milling is the most commonly used process for ethanol production, accounting for a significant share of the market. In this process, the corn kernel is ground into a fine powder, and the starch is converted into ethanol through fermentation. The simplicity and cost-effectiveness of the dry milling process make it a popular choice among ethanol producers. Additionally, advancements in dry milling technologies have improved the yield and efficiency of ethanol production, further boosting its adoption.

Wet milling, although less prevalent than dry milling, plays a critical role in the production of corn based ethanol fuel. In this process, the corn kernel is soaked in water and then separated into its various components, including starch, fiber, and germ. The starch is then fermented to produce ethanol. Wet milling allows for the co-production of valuable by-products such as corn oil, gluten feed, and gluten meal, which can be sold to offset production costs. This makes wet milling an attractive option for producers looking to maximize their profitability through multiple revenue streams.

Technological advancements have also impacted the wet milling process, making it more efficient and cost-effective. Innovations in enzyme technologies and fermentation processes have increased the ethanol yield from wet milling, making it a more viable option for large-scale production. Additionally, the ability to produce high-quality by-products has attracted significant investments in wet milling facilities, further driving market growth.

Another critical factor influencing the production process segment is the availability of raw materials. The abundance of c

Two datasets in the EOS-WEBSTER US County Data Collection provide county-level data for crop acreage, production and yield statistics. Crop data for 22 different field crops were acquired from the National Agricultural Statistical Service (NASS) for 1972 through 1998. One dataset provides data for individual varieties/types of each crop while the second dataset provides summary data by crop only. Data can be subset by irrigated and non-irrigated areas. Sucrose content, where applicable, is also included.

EOS-WEBSTER provides seven datasets which provide county-level data on agricultural management, crop production, livestock, soil properties, geography and population. These datasets were assembled during the mid-1990's to provide driving variables for an assessment of greenhouse gas production from US agriculture using the DNDC agro-ecosystem model [see, for example, Li et al. (1992), J. Geophys. Res., 97:9759-9776; Li et al. (1996) Global Biogeochem. Cycles, 10:297-306]. The data (except nitrogen fertilizer use) were all derived from publicly available, national databases. Each dataset has a separate DIF.

The US County data has been divided into seven datasets.

 US County Data Datasets:

 1) Agricultural Management
 2) Crop Data (NASS Crop data)
 3) Crop Summary (NASS Crop data)
 4) Geography and Population
 5) Land Use
 6) Livestock Populations
 7) Soil Properties

According to Cognitive Market Research, the global Agricultural Plastic Films market size will be USD 12514.5 million in 2024. It will expand at a compound annual growth rate (CAGR) of 9.00% from 2024 to 2031.

North America held the major market share for more than 40% of the global revenue with a market size of USD 5005.80 million in 2024 and will grow at a compound annual growth rate (CAGR) of 7.2% from 2024 to 2031.
Europe accounted for a market share of over 30% of the global revenue with a market size of USD 3754.35 million.
Asia Pacific held a market share of around 23% of the global revenue with a market size of USD 2878.34 million in 2024 and will grow at a compound annual growth rate (CAGR) of 11.0% from 2024 to 2031.
Latin America had a market share of more than 5% of the global revenue with a market size of USD 625.73 million in 2024 and will grow at a compound annual growth rate (CAGR) of 8.4% from 2024 to 2031.
Middle East and Africa had a market share of around 2% of the global revenue and was estimated at a market size of USD 250.29 million in 2024 and will grow at a compound annual growth rate (CAGR) of 8.7% from 2024 to 2031.
The middle grade category is the fastest growing segment of the Agricultural Plastic Films industry

Market Dynamics of Agricultural Plastic Films Market

Key Drivers for Agricultural Plastic Films Market

Increased Emphasis on Enhancing Agricultural Output Worldwide to Boost Market Growth

The market for agricultural plastic films is anticipated to rise in the future due to the increased emphasis on enhancing agricultural output worldwide. The overall output per unit of a single input is known as agricultural productivity, or output. Land productivity (yield) and labor productivity are partial factor productivity (PFP) measurements. The need for productivity on existing agricultural lands is increased by the expanding population, the need for food, and the shrinkage of agricultural lands. For instance, the United States Department of Agriculture, a federal agency based in the United States, reported in January 2022 that corn production in the United States was expected to reach 15.1 billion bushels in 2021, an increase of 7% from the 2020 projection. According to estimates, the average production in the US reached a record high of 177.0 bushels per acre. Thus, the market for agricultural plastic films is expanding as a result of the growing emphasis on enhancing agricultural output.

Usage of Cutting-edge Farming Techniques to Drive Market Growth

The market for agricultural plastic films is expanding rapidly due to the usage of cutting-edge farming techniques including mulching and greenhouse production. By establishing controlled settings that protect crops from unfavorable weather, pests, and diseases, these cutting-edge methods increase agricultural output and guarantee steady yields. For instance, greenhouse farming uses plastic sheets extensively to control light, humidity, and temperature, allowing high-value crops to be grown all year round. Comparably, mulching, which is covering the soil with plastic sheets, lowers water evaporation, inhibits weed growth, and maintains the ideal soil temperature—all of which enhance crop health and productivity. The need for agricultural plastic films designed for various uses is growing as farmers throughout the world look to maximize resource use and adjust to shifting climatic conditions, spurring innovation and market expansion.

Restraint Factor for the Agricultural Plastic Films Market

Risk of Pollution and Global Warming Will Limit Market Growth

The usage of agricultural plastic films has been increasing. In order to prevent weed growth, increase soil warmth, and decrease soil water evaporation, as well as topsoil and nutrient losses following heavy rain, these films are utilized as silage, stretch, and mulching films. These factors increase crop yields, prolong the growing season, and reduce the need for pesticide, fertilizer, and irrigation treatments. On the other side, plastic mulch films have been found to be a significant contributor to both macro- and microplastic pollution as well as global warming. Their long-term, widespread use, combined with a lack of systematic collection and management, causes them to build up in soils. As a result, it is predicted that this factor will impede the agricultural plastic films market expansion throughout the projection period.

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农作物产量：青贮玉米：Yield Per Acre在12-01-2017达19.900吨，相较于12-01-2016的20.300吨有所下降。农作物产量：青贮玉米：Yield Per Acre数据按年更新，12-01-1997至12-01-2017期间平均值为17.600吨，共21份观测结果。该数据的历史最高值出现于12-01-2015，达20.400吨，而历史最低值则出现于12-01-2002，为14.000吨。CEIC提供的农作物产量：青贮玉米：Yield Per Acre数据处于定期更新的状态，数据来源于National Agricultural Statistics Service，数据归类于Global Database的美国 – 表 US.B068：农作物生产。

长期预测：玉米：Yield (Bushels per Harvested Acre)在12-01-2034达200.000Bushel/Acre，相较于12-01-2033的198.000Bushel/Acre有所增长。长期预测：玉米：Yield (Bushels per Harvested Acre)数据按年更新，12-01-2022至12-01-2034期间平均值为188.000Bushel/Acre，共13份观测结果。该数据的历史最高值出现于12-01-2034，达200.000Bushel/Acre，而历史最低值则出现于12-01-2022，为173.400Bushel/Acre。CEIC提供的长期预测：玉米：Yield (Bushels per Harvested Acre)数据处于定期更新的状态，数据来源于U.S. Department of Agriculture，数据归类于全球数据库的美国 – Table US.RI005: Agricultural Projections: Feed Grains: Corn。

In 2020, ** percent of the soybean crops in the United States were genetically modified to be herbicide tolerant. Genetically modified crops have taken agriculture in the U.S. by storm. By comparison, only ** percent of soybean crops were genetically modified in 1997. Other crops grown in the United States which are mostly genetically modified are cotton and corn. Types of genetic modifications for Crops Herbicide tolerance is one of the most common forms of genetic modification. As the name suggests, these plants are modified so that herbicides meant for weeds will not harm the plant itself, allowing for higher yields and healthier crops. Most of the cotton and corn in the United States is modified to have stacked traits. This refers to the practice of combining several different genes into a single plant. Agricultural production in the United States Gross farming income in the United States has seen an increase since 2000, increasing from about *** billion U.S. dollars to *** billion dollars in 2018. As genetically modified crops became more prevalent during that time period, the total production of soybeans in the United States also grew, amounting to approximately **** billion bushels in 2018. Corn is another important crop in the United States with a variety of different uses, from human consumption to animal feed to ethanol production. Between 2000 and 2018, the area of corn for grain harvested in the U.S. increased by nearly ** million acres.