Article | AgroCares

Monitoring of Feed Ingredients

agrocares — Fri, 05 Jul 2024 08:40:52 +0000

Developing a Cost-Efficient Strategy for Continuous Quality Monitoring of Feed Ingredients

Rich-protein grain, cereals, oilseeds and various by-products are the common feed ingredients for poultry and swine. In recent years, farmers worldwide are struggling with the increasing prices of raw materials which resulted in the need to maintain optimal livestock performance in a cost-effective manner. As feed usually represents about 60-70% of the cost of animal production, it is beneficial to have precise information on the nutrient content in your different feed raw materials to formulate feed for animals and achieve effective feed management.

Optimizing feed cost through precise nutrient management

It is important to understand that variables of nutrient content in feed ingredients can be observed and the prices fluctuate all the time. However, optimizing your feed formulation can take time and making the changes too often can be troublesome. Setting a regular schedule to monitor raw material quality can help reduce the costs that could rise due to prices increased.

As an illustration, when optimizing your feed formulation, you may have procured soybean meal with a protein content of 48%. However, in the next batch, the protein content drops to 45%. If there is no monitoring protocol in place and this change is not detected, it can lead to insufficient protein in your feed, preventing your animals from performing well.

Conversely, the costs of feed ingredients are subject to continuous fluctuations. In 2023, for instance, the price of soybean meal increased €66 per ton just within a month. When prices rise significantly, adjusting ingredient ratios to meet nutritional needs can save costs. With a good strategy to adjust feed formulation, the cost can be reduced between €0.1-0.2 per animal per year, which, for example, adds up to €10,000-20,000 for a farm with 100,000 pigs. Therefore, monitoring your nutrient values regularly will enable you to manage your feed cost effectively.

Developing a system to analyze feed ingredient nutrition for optimal rations

Efficient optimization of your feed formulation not only yields cost savings but also minimizes waste, thereby enhancing sustainability. Moreover, a thorough understanding of the nutritional composition of feed ingredients is vital to prevent over- or underfeeding.

Numerous methods exist for analyzing feed nutrient content, with wet chemistry analysis recognized for its precision in feed evaluation. However, in practical applications, there is a demand for methods that are fast, simple, and time efficient. A widely acceptable approach involves the application of Near-Infrared (NIR) spectroscopy. Many companies and laboratories employ NIR devices for feed analysis routinely. While stationary NIR solutions are available, many advisors and farm managers would like to opt for faster, portable, and versatile solutions for measurement of feed composition. Portable NIR device offers robust and high-quality input data from raw materials and feed ingredients for ration calculation or feed formulation software and subsequent formulation adjustments.

Why FeedCares solution?

FeedCares solution comprises of AgroCares Scanner, a portable scanner with NIR sensor technology that measures reflected light of the material and translates the measurement to values with the prediction models built based on the global feed database. Therefore, dry matter, crude proteins, crude fat and other essential qualitative parameters of raw materials can be quickly determined on-site, with a less time-consuming procedure. This enables the animal nutritionist, farm advisors and farmers to routinely monitor the nutrient content of the raw materials, optimize feed formulation, and control the quality of the feed to meet the nutritional requirement of animals in a cost-effective way. Moreover, through the smartphone application, the real-time report can be reviewed.

Cost Savings: On-site analysis saves lab expenses and transportation costs.
Improved Feed Formulation: Accurate data crafts precise diets, enhancing animal growth and health.
Enhanced Feed Quality: Scanner ensures uniform, high-quality feed production.
Faster Decision-Making: Real-time analysis aids prompt feed adjustments.
Sustainable Farming: Balanced diets minimize waste and environmental impact.

For more information or further discussion on the FeedCares solution, please send us a message via Contact Us | AgroCares

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Data-Driven Livestock Farming

agrocares — Thu, 25 Apr 2024 11:19:32 +0000

In recent years, the animal science community has embraced terms such as precision livestock farming (PLF), smart livestock farming, and smart animal agriculture to address a common goal: increasing food production while prioritizing animal welfare and reducing environmental impact. This paradigm combines data collection via sensors, data storage via the Internet of Things (IoT), and data transformation via predictive analytics powered by artificial intelligence (AI) tools.

While these terminologies differ in minor ways, their goal remains the same: to manage livestock operations effectively and precisely. PLF’s primary objective is to use process engineering principles and cutting-edge technology to monitor various elements of livestock production via “smart” sensors. These sensors monitor critical metrics such as animal feed, growth, milk and egg production, disease prevalence, and animal behavior, as well as microenvironmental elements like temperature and gas emissions within the manufacturing unit.

The Importance of Data Modeling in Precision Livestock Farming

Sensor technology has advanced significantly, allowing for the recording of precise physiological, behavioral, and productivity information for specific animals. These data are essential in supporting smart and sustainable production, ensuring optimized livestock management techniques. Despite these advances in data collecting, one ongoing challenge remains: properly combining data modelling with big data. Data collection alone will not be enough to fully realize the potential of precision livestock farming. True value is found in the proper integration of data modelling, which can transform raw data into actionable insights. Without adequate data modelling, the implementation of technology in cattle farming may be constrained, preventing its full potential from being realized. Despite these obstacles, data-driven animal husbandry has significant potential benefits. Farmers may improve animal well-being by utilizing the power of data and AI-driven insights. Furthermore, reducing resource use and environmental effect can help to promote more sustainable farming practices.

The importance of data and effective feed management

As feed represents significant costs in livestock farming, the impact of the rising cost of feed ingredients and raw material can be felt worldwide. Therefore, effective feeding management is required for every farm, due to the constantly changing of the nutrient content and availability of feed ingredients. With the help of advanced sensor technology, data collection and modelling, feed analysis has become a common practice. Specifically with feeding management, precise information on the qualitative parameters of the raw materials and feed ingredients can be obtained through collecting spectrum data and translating them into true values with prediction model. This method allows farmers, animal nutritionists, and feed formulators to make informed decisions. For instance, precise feed formulation can be calculated based on data on protein contents in different raw materials purchased from different origins.

FeedCares Solution for Precise Feed Analysis on the Spot

FeedCares solutions are integral components that contribute to the realization of data-driven animal farming concepts. AgroCares offers an extensive portfolio of integrated digital solutions and services aimed to provide farmers with nutritional expertise and enhanced animal diets, resulting in maximum animal performance.

The smartphone application linked to a handheld sensor and global feed database is the foundation of the FeedCares solution. This effective combination provides producers with quick and easy access to feed raw materials and silage results. The services provided include the ability to see and export test results from scanned feed samples, which can then be used to compute the optimum outcomes for various farm scenarios and optimize diet formulation for ruminant, poultry, and swine.

Producers who use FeedCares get important nutritional insights, which directly translates into improved animal performance. This way producers may confidently make informed decisions that lead to increased growth rates, superior feed conversion, and overall improved health and well-being for their animals if they understand their livestock’s individual nutritional needs.

As we look to the future, data-driven livestock farming holds the promise of revolutionizing the industry. With continued research, technological advancements, and collaboration between stakeholders, the sustainable and efficient path forward for livestock farming can be shaped. It is an animal farm transformation journey where data-driven insights, precision livestock farming, and innovative solutions like FeedCares pave the way for a more prosperous, responsible, and resilient future for farmers and their livestock.

If would you like to learn about our FeedCares Solution, please contact us at info@agrocares.com

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Foliar Analysis

agrocares — Fri, 22 Mar 2024 11:05:30 +0000

What is Leaf tissue testing?

Leaf tissue testing is a crucial process for evaluating the concentration of essential elements within plant tissue. Essential nutrients, categorised as micronutrients and macronutrients, play key roles in sustaining the plant’s life cycle. Micronutrients, required in smaller amounts and macronutrients needed in larger amounts are essential for achieving optimal plant growth. In current agricultural landscape, where reducing production costs, preserving natural resources, and preventing any unfavourable environmental effects, improved fertilizer management is imperative, effective fertilizer management becomes a cornerstone. To achieve this, understanding of crop nutrient requirements is required as well as the application of soil testing to forecast fertilizer needs. Soil tests provide valuable information about the overall nutrient content of the soil. However, it cannot tell us how much of each nutrient is actually available to the growing plant. Leaf tissue analysis fills this gap by providing direct measurements of nutrient concentrations in the plant tissues.

Leaf tissue analysis, a specialized form of plant analysis, focuses on evaluating the nutrient content and physiological condition of leaves. Leaves, as the primary photosynthetic organs of plants, are directly responsible for absorbing nutrients from the soil and converting them into energy for growth and development. Assessing the nutrient levels in leaves allows for a direct assessment of a plant’s nutritional status.

Given that the plant’s nutrient content varies regularly, appropriate tissue testing is the only certain method that can determine the nutritional requirements of a plant and identify if it is suffering from a nutrient deficiency. The analysis of leaves provides vital information necessary to ensure that the crop has all the nutrients it needs to produce the anticipated yields.

Why test plant tissue?

One of the reasons is to monitor the nutrients within the plants during the growing season. This technique is a good management strategy as it helps determine when the best moment is for application is to achieve greater uptake efficiency by the plant, the other reason is to diagnose a suspected nutritional deficiency or toxicity, as toxicities of micronutrients are equally important and can be as yield limiting as deficiencies. It is best to perform this analysis as soon as possible after the symptoms are evident. Once a deficiency manifests itself, the optimum yield may have already been lost. Therefore, routine leaf tissue sampling and analysis at the right time in the season can help to avoid crop losses. With toxicities, information obtained on the current stressed crop can only be used to make management decisions that may benefit subsequent crops. For example, diagnosis of copper toxicity can only be treated by liming the field for the next crop.

How to assess it?

Traditional leaf tissue analysis often involves tedious laboratory procedures, requiring samples to be sent for analysis, often incurring delays and additional costs. To address these limitations, near-infrared (NIR) technology has emerged as a promising alternative. Near infrared spectroscopy (NIRS) is an emerging technique for analysing soil and plant nutrients, where leaf testing is based on the principle that the absorption and reflection of near-infrared light by plant tissues vary depending on their chemical composition, including nutrient levels. This spectroscopy technique, provides rapid, non-destructive, cost-effective, and less labour-intensive analysis of plant nutrients in real time. Using NIRS in combination with accurately built database allows farmers and advisors to directly measure crop nutritional status and apply this information for fertilizer management. Moreover, leaf analysis based on NIRS enables the detection of hidden deficiencies and prevents any excess application of fertilizers. This enables farmers and advisors to be proactive in nutrient management by keeping crop nutrient demand and soil nutrient supply in sync, thereby achieving optimal yields and higher profits, while reducing unnecessary input costs and environmental footprint of agriculture enterprises.

Consequently, plant tissue analysis in combination with soil test information is the recommended approach for diagnosing nutrient deficiencies AgroCares is currently working on the LeafCares solution and will make it available later this year. If you would like to learn more about LeafCares and be the first to test it in the field, please send us a message to info@agrocares.com.

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Ruminants: The importance of feed analysis

agrocares — Thu, 15 Feb 2024 15:03:11 +0000

Why is it important to have a high-quality feed?

The quality of ruminant feed is directly linked with milk production, animal health, as well as farm performance. As feed costs represent a significant number of the total production costs, it is crucial to ensure feed nutritional values and quality throughout the whole year.
Therefore, the intake of superior quality TMR and silages can help to reduce costs and increase profitability due to the lower amount of feed supplements needed. The most common dairy cattle feed is TMR and silages.

What is TMR?

A TMR or Total Mixed Ration is a method of feeding cows that mixes different ingredients into a single feed formulation with specific nutrient values. TMR usually consist of silages, grains, concentrated feed, vitamins, minerals as well as feed additives. With this feeding method, cows can be fed with a fixed amount of silages and concentrates with balanced nutrient content. TMR is formulated based on several factors including the average milk production and the stages of the cows, for example, heifer and lactation cows have different nutritional requirements.

What is silage?

Silage is a type of chopped fodder that is made of green foliage crops (e.g., maize, sorghum, barley, etc.) or pasture grass. In any case, the entire plant is used for making silage. It is a method used to preserve the pasture in the long-term involving fermentation under anaerobic conditions. This process is known as ensiling. Proper handling and care of the silage is especially important to keep the feed fresh and safe for animal consumption. Silage made under poor conditions could lead to low dry matter, low digestibility (energy) and crude protein, elevated levels of ammonia and high acidity.

Solutions that help to ensure quality feed

Ensuring the optimal nutritional intake for your livestock, particularly in the context of TMR, requires a comprehensive understanding of the nutritional values in your feed. Given the varying nutrient compositions in TMR due to its diverse ingredients, it is essential to perform feed analysis and have accurate data on the nutritional content of grains and ensiled forages incorporated into the TMR.

Moreover, regularly monitoring the nutritional profile of your feed by analysing your feed serves as an important factor in achieving optimal milk production. This approach empowers farmers to create well-balanced feed formulations based on precise information, enabling them to make informed decisions about the supplementation needs of their livestock. For instance, underestimating the dry matter content of TMR can result in overfeeding or underfeeding, adversely impacting the overall health and productivity of the cows. Additionally, variations in nutrient values may arise depending on the seasons, the process of ensiling, as well as the process of mixing. Therefore, precision is critical for formulating a well-balanced ration, which results in promoting performance in cattle. However, feed analysis can be costly and time-consuming. Having a tool on-hand that can simplified the analysis with comparable accuracy is an advantage for the farmers and farm advisors.

With the FeedCares Scanner Solution (based on non-destructive Near Infra-Red Spectroscopy (NIRS) technology) qualitative parameters of feed materials and forage can be quickly determined on-site, without sending the feed sample to the laboratory. This enables the farmers and farm advisors to monitor, optimize, and control the quality of the feed to meet the nutritional requirements of animals. Furthermore, this tool can be used as a monitoring tool to know the optimal stage in which the crop/ grass needs to be cut for silage.

If you want to learn more about the FeedCares Scanner Solution, please send us a message via info@agrocares.com or contact form.

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The importance of soil health

agrocares — Wed, 06 Dec 2023 14:07:48 +0000

Though it is the foundation of life, soil constitutes only a thin layer of material on the surface of our planet. It provides the necessary weathered minerals, organic materials, air, and water, which are the most precious resources for all living creatures. Plants find life in soil, as it provides a rooting medium and nutrient source for plants to grow. Through healthy plants, animals and humans find food to thrive on Earth.

A vital and healthy soil is the base for good crop production and a sustainable future for farming. Therefore, there is a growing awareness of the benefits a healthy soil can deliver and the role of good soil management in delivering them.

What is soil health?

Soil health refers to the ability of the soil to sustainably support plant growth, maintain or enhance water, air quality, and promote biodiversity. Moreover, a healthy soil is a stable living environment which enables all essential biological processes, maintaining a diverse community of soil organisms that help to control plant disease, insect and weed pests form beneficial symbiotic associations with plant roots. It contains a variety of living organisms, so that they can co-exist in a balanced ratio and help to decompose organic matter, recycle essential nutrients, and improve soil structure with a positive impact for soil water and nutrient holding capacity.

Why does soil health matter?

During the entire growing and reproductive period of a crop, soil health has a direct influence on the overall quality of it for several reasons:

1. Nutrient availability: Healthy soils are rich in essential nutrients, such as nitrogen, phosphorus, and potassium, which are essential for plant growth and development. For more information about the role of these nutrients, please check the article section on our website: NPK: What is it and why is it so important? | AgroCares, Why are Calcium and Magnesium important for soil and plant growth? | AgroCares, Why measure Iron and Aluminium in soil? | AgroCares, and more. However, the presence of sufficient total quantities of essential nutrients in a soil does not guarantee the availability of these nutrients to growing plants, because there are other factors such as soil-moisture content, soil temperature, microorganisms, pH, etc., that can limit this access. This article Why measure potential mineralizable N? | AgroCares shows an example of factors that influence N availability for plant uptake. Hence, adequate levels of nutrients alone do not guarantee soil productivity. Productive soil is one that has optimal total environmental conditions for plant growth.

2. Biodiversity: Healthy soils can host a vast diversity of organisms. They all play vital roles in nutrient cycling, decomposition, and soil formation. Furthermore, a diverse soil microbial community can help suppress diseases as beneficial microbes can out-compete pathogenic microbes for resources (or even prey them) giving the soil the inherent capacity to control and suppress pests and diseases. For instance, by symbiotic relationships with the plant. The plant produces food for the microbes, and in return, they protect the plant from stress and feed it by converting and holding nutrients in the soil. Bacteria for instance, break down nutrients and release them to the root zone for the plant. Fungi (e.g., Mycorrhizae) facilitates water and nutrient uptake by the roots and plants to provide sugars, amino acids, and other nutrients. Nematodes (microscopic worms) are predators while others are beneficial, eating pathogenic nematodes and secreting nutrients to the plant. There are many diverse types of soil microbes that help boost the plant's health.

3. Soil structure: Healthy soils present a good arrangement of solids (aggregates) and pore spaces. A “well-structured soil” embodies a vast amount of interconnecting pore spaces that allows the drainage of water, free movement of air and unrestricted growth of roots. This provides the perfect environment for plants to grow in, by anchoring roots and storing nutrients. Soil texture (that refers to the size of mineral particles/solids) is divided into three parts; sand, silt, and clay. This property helps determine the nutrient-supplying ability and the supply of water and air. Moreover, adequate levels of soil organic fraction also benefits soil in many ways, including; improved physical condition, increased water infiltration, improved soil tilth, decreased erosion losses, enhanced nutrient availability, and retention for plants.

4. Water retention: When soils have poor structure, they cannot hold water within the pore spaces, the water hits the compacted layers, and it cannot infiltrate. This leads to more runoff, and therefore, more erosion, flooding, more pollution, and less water held in the soil. However, healthy soils with good levels of organic matter, soil structure and greater porosity, route water more efficiently during floods and retain more for plants. This ability of healthy soils to sustain water for longer periods it is also known as “water holding capacity.”

5. Carbon sequestration: Healthy soils play a vital role in capturing and storing CO2. Soils with higher organic carbon content can support a richer population of microorganisms and contain more nutrients favoring the development of high-quality crops. C/N ratios are also important, as it has a direct impact on residues decomposition and in nutrient cycling in soils. A good C/N ratio is 24:1 is the proper amount of C and N the microorganisms need to sustain their health. Moreover, hummus, a type of organic matter created after the total decomposition of plants and animals, contains many nutrients that improve the health and fertility of soils. Carbon is critical for healthy soil conditions, and humus is roughly 60 percent carbon. Thus, increasing the potential of hummus to act as a sink of carbon. Improving the soil’s ability to capture and retain carbon not only contributes to mitigating and adapting to climate change but makes land more suitable to sustain biodiversity and preserve food security.

A non-renewable resource

Soil plays the utmost role in the lives of all living creatures, yet it is not a renewable resource. Soil regeneration takes more time and effort than soil pollution.

Good soil health benefits productivity, sustainability, and profitability. From monitoring soil and increasing organic matter to planting trees and restoring peatland, there are many things food producers can do to improve soil health. Moreover, since soil is a continuum, it is a matrix in constant change. Different practices (for instance tillage, cover crops, fertilization) affect soil differently, therefore regular monitoring is ideal to know the status and needs of the soil. With AgroCares solution you can start performing soil tests on a regular basis and manage crops and soil more efficiently.

Contact our team to discuss different practices to protect soil and learn more about our SoilCares solution.

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The most cultivated crop in the Netherlands: Onion

agrocares — Wed, 08 Nov 2023 07:34:16 +0000

Did you know that onions are the most cultivated crop in The Netherlands? and that it is the most widely cultivated species of the genus Allium worldwide? This crop is an herbaceous bulbous plant that is cultivated for bulb production either as biannual or perennial, depending on the cultivation conditions. Onions are among the most widely adapted vegetable crops that can be grown under a wide range of climates from temperate to tropical. World production is nearly 106 million tons of bulbs on some 5.7 million ha.

Onions are vegetables that thrive in mid climates. The best performance can be obtained without extreme cold or heat and excessive rainfall, but it can also endure temperatures below 0 degrees. For optimum growth, the crop requires a relative humidity of around 70% and a mean daily temperature between 15 and 20°C. In normal conditions, onions grow bulbs in the first season of growth and flowers in the second. During the vegetative stage, onion crops need lower temperatures and shorter daylength. Moreover, for a good crop establishment the right amount of water is beneficial in this stage. However, during the maturity stage and development of the bulb dry, warm weather and longer daylength are needed for a higher yield and quality. The critical daylength to produce the bulb, varies from 11 to 16 hours depending on variety. Therefore, the selection of a proper cultivar that can be adapted to the local climate in terms of daylength requirements, is essential.

While other common crops are planted directly from the seeds, onions can also grow from sets. Onion sets are small onions that look like small bulbs and once they mature, they develop into full size bulbs. This last method is known to have better success rate than direct seed sowing. Onions can be planted in spring or autumn, and they need typically about 100 days of growing to produce decent sized bubs.

The best soil to successfully grow onions is deep, friable loam, with good drainage and moisture-holding capacity and sufficient organic matter content. Compacted soils will strongly affect the development of the bulb. The optimum pH ranges around 6 and 7, but onions can also be grown in medium alkaline soils.

Since onions are heavy feeders, it requires more mineral fertilizers than other vegetables for a bulb and shot growth. Due to its sparse and shallow rooting system, this crop calls for careful management of water and nutrients to ensure an appropriate supply. Nutrients like P, K and some macronutrients are immobile and therefore not easily accessed by the plant while other mobile nutrients like the N is easily reachable.

The demand of nutrients varies along the development of the crop. Therefore, the timing of the application of nutrient is also crucial. For instance, the lack of nitrogen available will severely suppress growth but the excess in late growing season is believed to delay maturity and cause double centres. Or for the case of potassium, where applying it during the development of the bulb, increases it size and quality and low levels makes plants more susceptible to cold.

Consequently, a proper soil monitoring can help the farmer to make better decisions and manage the crop more efficiently. This can be performed by two soil testing solutions provided by AgroCares: Scanner or Lab-in-a-Box.

If you want to learn more about onion cultivation and the best practice recommendation provided by the Scanner & Liab Solutions, please send us a message to info@agrocares.com.

Select your preferred SoilCares license and start scanning now!

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Transforming Carbon Farming with AgroCares Carbon Monitor Solution

agrocares — Fri, 13 Oct 2023 12:11:39 +0000

Carbon sequestration is a critical component of ensuring sustainable soil and water management, promoting biodiversity, fostering greener food supply chains, and enhancing resilience against climate extremes. However, putting carbon farming into practice to achieve that frequently, requires further investments; such as buying new equipment, devoting time and resources to soil analysis followed by strict protocols, or diversifying crops.

As the market leader in organic carbon measurement on-the-spot, AgroCares strives to innovate solutions to support carbon programs and promote sustainable agriculture practices. With this approach, we are now taking centre stage by creating the Carbon Monitor solution for carbon farming in collaboration with NMI. The AgroCares Carbon Monitor Solution provides a comprehensive carbon stock measurement that is revolutionizing how farmers and advisors approach carbon farming.

The Windpark Krammer Project

One of the projects that utilizes the AgroCares Carbon Monitor solution for soil analysis is The Windpark Krammer project, initiated by the Southern Farmer’s Association ZLTO, in Zeeland, the Netherlands. During their pilot carbon initiative that’s been active over 5 years, 15 Dutch farmers, guided by carbon farming experts from ZLTO, aim to sequester 2,750 tonnes of CO2 across 617 hectares. Techniques like cover crops, no tillage, deep-rooted crops, manure management, and optimal pasture practices stimulate plant growth and convert CO2 into biomass, binding carbon to the soil and enhancing resilience to climate extremes.

Participating farmers are rewarded by Zeeuwind and Deltawind, the owners of Windpark Krammer, for their contributions to climate neutrality. This project stands out for three main reasons:

The compensation happens within the farmers’ local environment
It strengthens the connection between the energy transition and circular agriculture.
Carbon farmers are driven by a commitment to sustainable soil management, with financial compensation serving as recognition. The Windpark Krammer project demonstrates the profitability of nature restoration, validating carbon farming as a sustainable business model.

Recommendations and insights from the project, including those derived from the AgroCares Carbon Monitor solution, are shared with the Netherlands Ministry of Agriculture, Nature and Food Quality and the European Commission. The European Union recognizes carbon farming's potential and includes it in the common agricultural policy (CAP).

Looking ahead, the future of carbon farming is driven by data and technology. Through advanced modelling, satellite imaging, and remote sensing and sensor technologies, farmers and agricultural advisors can make informed decisions and effectively monitor carbon farming practices and pave the way for a sustainable agricultural landscape.

To learn more about how AgroCares Carbon Monitor solution is revolutionizing soil analysis and empowering carbon farming initiatives, visit http://agrocares.com/carbon/ . Together, we can create a greener and more resilient future for agriculture and the planet.

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Paving the Way for Measurable Corporate Sustainability

agrocares.com — Wed, 13 Sep 2023 14:23:42 +0000

In the context of unprecedented climate change it is increasingly crucial for industries to take proactive steps towards reducing greenhouse gas emissions and their carbon footprint. In the food and beverage sector, a significant portion of emissions occur indirectly throughout the value chain (scope 3 emissions). To offset these emissions, carbon farming practices are gaining traction as an effective solution. Carbon farming involves the implementation of sustainable agricultural techniques that sequester carbon dioxide from the atmosphere and store it in soil, vegetation, or other organic matter. Let's explore how multinational food and beverage companies are embracing carbon farming to offset their Scope 3 emissions.

Food and Beverage Companies Embrace Insetting

Companies in the food and beverage industry have a unique opportunity to lead the way as they can work with the farmers in their supply chain to remove atmospheric carbon and store it in their agricultural soil. Instead of purchasing carbon credits from external compensation projects (offsetting), companies such as Nestlé, Danone and many others, have set scope 3 emission reduction targets of 30-50% by 2030, and started to collaborate with the farmers they source raw materials from to reach those targets. Financially supporting and incentivizing them to implement sustainable farming practices such as no-till farming, agroforestry, or composting, not only sequesters carbon, but also increases soil health, water retention, and biodiversity. Farmers benefit in the long run from higher yields, whilst multinationals can account for the carbon stored in the soils.

The Importance of Accurate Data and AgroCares Carbon Monitor Solution:

By focusing on a clear insetting strategy, agricultural companies contribute to mitigating climate change and benefit from more productive and resilient farming systems. To effectively account for these efforts, it is indispensable to have accurate and reliable data to measure and monitor the Soil Organic Carbon (SOC) content in the farms' soils over time. This is where AgroCares' Carbon Monitor solution comes into play. Powered by the scientifically proven SoilCASTOR methodology, our technology enables companies to analyze soil samples efficiently and provides accurate carbon stocks in tons per hectare. Utilizing AgroCares Carbon Monitor Solution, agricultural companies can monitor the effectiveness of their regenerative initiatives in an affordable and quick manner and make informed decisions on how to optimize carbon sequestration efforts.

Explore the power of AgroCares' Carbon Monitor solution by visiting our page at http://agrocares.com/carbon/ and discover how our solution empowers agricultural companies to efficiently measure, monitor, report and verify the effectiveness of regenerative initiatives.

Reference

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Why soil carbon monitoring is important for sustainable agriculture and climate resilience?

agrocares.com — Wed, 23 Aug 2023 09:20:39 +0000

Why soil carbon monitoring is important for sustainable agriculture and climate resilience?

As we delve into the world of agriculture and its interaction with the climate crisis, an important perspective unfolds. Agriculture is both subject to adverse impacts of climate as well as a significant contributor to greenhouse gas (GHG) emissions. This dynamic provides a platform for constructive action driven by scientific exploration, data analysis, and a commitment to a more sustainable future. The facts are striking. Between 2000 and 2020, global on-farm emissions, which are connected to the production of crops and livestock, increased by 13% and reached a total of 7.4 gigatons of carbon dioxide equivalent (Gt CO2 eq). In 2019, agriculture and other land-use activities accounted for 22% of the world's total greenhouse gas (GHG) emissions. Notably, a significant portion of these emissions comes from methane produced during enteric fermentation, manure management, and rice cultivation.

Interestingly, a 2017 study estimated that with these farm management practices in place, global croplands have the potential to store an additional 1.85 Gt CO2 each year, as much as the global transportation sector emits annually. These figures communicate that in the world of agriculture and environmental care, the soil takes centre stage. It has a big impact on three important things: making soil healthier, tackling climate challenges, and improving crop growth. By keeping an eye on the carbon in the soil, we can enhance how soil works, reduce climate effects, and cultivate better plants.

At the same moment, the world's soils contain a larger amount of carbon than the combined total of carbon in its vegetation and atmosphere. Therefore, soil plays a vital role in the carbon cycle by storing organic carbon through the decomposition of plant matter and microbial activity.

There is a significant interest in increasing carbon content in soil due to its potential for mitigating climate change. A promising approach to do this is implementing regenerative farming practices, such as zero or reduced tillage, intercropping, introducing trees (agroforestry) and cover crops, crop rotation, etc. It is important that these practices are continuously maintained in order to retain the added carbon in the soil (permanence). For sequestered carbon to be eligible for trading in carbon markets, it has to be shown that the practices have been adopted actively and are additional to the business-as-usual scenario (additionality according to Oldfield et. al., 2021). Moreover, it is also important that the implementation of regenerative agricultural practices on one field does not result in the release of carbon, e.g., through deforestation, on another field nearby (leakage).

Soil carbon monitoring is a necessary step to enable sustainable agriculture and climate mitigation because it can ascertain the status and changes in soil carbon (additionality and permanence). These benefits demonstrate the effectiveness of soil carbon monitoring as a valuable practice that should be on the agenda of policymakers and land managers. Active participation in monitoring carbon levels in soils is essential for collectively mitigating the impacts of climate change. This approach offers the benefit of enhancing soil properties and fostering the overall health, resilience, and productivity of agroecosystems.

AgroCares provides a rapid and cost-effective way to measure soil organic carbon content. It addresses the concern of potential workload over time associated with measuring organic matter for carbon. AgroCares offers an opportunity to regularly conduct carbon monitor tests, measuring and remeasuring, which leads to consistent results regarding overall carbon level changes at the farm level. Furthermore, the peer-reviewed SoilCASTOR methodology incorporated in the Carbon Monitor Solution not only determines optimal sampling spots for rapid soil scanning but also computes carbon stocks in t/ha.

If you want to learn more about our Carbon Monitor Solution, please send us a message at info@agrocares.com or get in touch via our form.

Reference

Funderburg, E. (2020). The role of organic matter in soil. Stockfarm, 10(9), 31-33.
E. Oldfield et al., “Agricultural soil carbon credits: Making sense of protocols for carbon sequestration and net greenhouse gas removals” (Environmental Defense Fund, 2021)
Smith, P., Soussana, J. F., Angers, D., Schipper, L., Chenu, C., Rasse, D. P., ... & Klumpp, K. (2020). How to measure, report and verify soil carbon change to realize the potential of soil carbon sequestration for atmospheric greenhouse gas removal. Global Change Biology, 26(1), 219-241.
Paustian, K., Collier, S., Baldock, J., Burgess, R., Creque, J., DeLonge, M., ... & Jahn, M. (2019). Quantifying carbon for agricultural soil management: from the current status toward a global soil information system. Carbon Management, 10(6), 567-587.
Paustian, K., Lehmann, J., Ogle, S., Reay, D., Robertson, G. P., & Smith, P. (2016). Climate-smart soils. Nature, 532(7597), 49-57.
Dhakal, S., Minx, J. C., Toth, F. L., Abdel-Aziz, A., Figueroa, M. J., Hubacek, K., ... & Diga, G. M. (2022). Emissions trends and drivers. In Climate Change 2022: Mitigation of Climate Change. IPCC: Intergovernmental Panel on Climate Change.
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Zomer, R. J., Bossio, D. A., Sommer, R., & Verchot, L. V. (2017). Global sequestration potential of increased organic carbon in cropland soils. Scientific Reports, 7(1), 1-8.

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Organic Matter: Key for sustainable agriculture

agrocares.com — Tue, 08 Aug 2023 15:14:37 +0000

The growth in human population has had an important impact on soil and the services and resources it can provide. The consequences of human activities on soil resources resulted in the loss of biodiversity, accelerated erosion, desertification, compaction, nutrient depletion, and loss of soil organic matter (SOM), which is primarily made up of carbon (58%). Considerable losses of soil carbon occurred around the world due to land use and changes in land cover, for instance trough deforestation, crop-grass rotations, peatlands drainage, etc., resulting in a cumulative loss of 133 Gt of carbon.

What are the benefits of Organic Matter?

Healthy soils are crucial for sustainable food production and organic matter plays a vital role in achieving this. Organic matter can be considered one of the most essential components for promoting healthy soils and a stable high amount of it presents many benefits for an agricultural soil. These benefits can be categorised into physical, chemical, and biological.

Physical benefits include enhancing aggregate stability, improving water infiltration and soil aeration (reducing runoff), improving water holding capacity, etc.

Chemical benefits include increasing the soil’s cation exchange capacity (CEC), improving the ability of soil to resist pH change, also known as buffering capacity, accelerating the decomposition of soil minerals over time, making the nutrients in the minerals available for plant uptake, etc.

Biological benefits include providing food for the living organisms in the soil, enhancing soil microbial biodiversity and activity, which can help in the suppression of diseases and pests, enhancing pore space through the actions of soil microorganisms, increasing infiltration, and reducing runoff.

How to measure the effect of regenerative farming practices on soil organic matter?

Considering all the benefits organic matter has on soil health and crop production, increasing organic matter is an important management practice to address by the producer to improve a farm’s profitability and sustainability. As SOM is key in sustaining food production and the total global food demand is expected to increase by 35% to 56% by 2050, it is essential that we learn how to practice a more "nature-inclusive" agriculture. The type of farming will determine if the soil stores or emits carbon. Regenerative agriculture, for instance, is an integrated approach that focuses (among other things) on minimizing soil disturbance, enhancing biodiversity, use of cover crops, incorporation of crop rotation, and storing carbon in the form of SOM to help mitigate the effects of climate change. These practices have the potential to increase crop yields as well as lead to a more efficient use of the farmers’ resources in the long term, while also mitigating climate change by removing CO₂ from the atmosphere. To understand the potential of the soil to store carbon as a successful climate mitigation approach, it is indispensable to estimate and monitor soil organic carbon accurately. This requires consistent sampling over time, which enables the creation of long-term records for each field.

With the AgroCares’ soil testing solutions, the farmer or advisor can monitor macro nutrients, including SOM. In less than 10 minutes, they not only receive a soil test but also a recommendation on how to increase organic matter in the soil. Similarly, carbon stocks in t/ha can also be measured and monitored for the entire farm.

If you want to learn more about the AgroCares Scanner, please send us a message to info@agrocares.com or get in touch via our form.

Reference

Evanylo, G. K., & McGuinn, R. (2000). Agricultural management practices and soil quality: measuring, assessing, and comparing laboratory and field test kit indicators of soil quality attributes.
Global Soil Partnership. (2017). Global Soil Organic Carbon Map–Leaflet.
Lefèvre, C., Rekik, F., Alcantara, V., & Wiese, L. (2017). Soil organic carbon: the hidden potential. Food and Agriculture Organization of the United Nations (FAO).
Natural Resources Conservation Service (USDA). Healthy soils are high in organic matter.
Sanderman, J., Hengl, T., & Fiske, G. J. (2017). Soil carbon debt of 12,000 years of human land use. Proceedings of the National Academy of Sciences, 114(36), 9575-9580.
Van Dijk, M., Morley, T., Rau, M. L., & Saghai, Y. (2021). A meta-analysis of projected global food demand and population at risk of hunger for the period 2010–2050. Nature Food, 2(7), 494-501.
Van der Voort, T. S., Verweij, S., Fujita, Y., & Ros, G. H. (2023). Enabling soil carbon farming: presentation of a robust, affordable, and scalable method for soil carbon stock assessment. Agronomy for Sustainable Development, 43(1), 22.

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