IndiaNzym’s Post

Where is that loose nail? This is the question that every urbanite has to make in the very very near future! What I'm alluding reference to is the 14th century poem, "For Want of a Nail, A Kingdom was Lost"! Although it's probably a nursery rhyme now, the message it conveys is about how we need to manage the small things well to ensure that big outcomes are achieved. As well as the risk of losing big, when small but critical aspects are ignored. In today's imminent threat of climate change, that's threatening everything from food security to potable water to clean air to UV radiation, how much can we expect from world leaders and change agents alone? Especially if no one is looking for that one loose nail? Ever stop to think that the 'Loose Nail' could be right under your nose, sitting pretty in your utility rack of 'Home Cleaners'? Think again! #dishwashing #cleaning #dishwasher #kitchen #dishwashingliquid #dishes #washing #clean #dishwash #ecofriendly #dishtowel #detergent #kitchendecor #dishcloth #dishcloths #dishscrubbie #reusable #floorcleaner #dishdoozies #scrubbie #plasticfree #home #detergents #multipurposecleaner #laundry #sustainability #sustainable #climatechange #climateaction #greenbusiness #ecofriendly #environmentalsustainability

Amaranth oil and CO2 extract have a surprisingly high content of squalene. The oil may contain up to 80,000 ppm (8%) squalene with all the amazing properties it brings with. Our organic amaranth CO2 extract contains about 7,5% squalene https://lnkd.in/eMvzyged

What Is Chelation? 🤨 And How Does It Work? 🧐 Chelation refers to a process of encapsulation in which an ion is reacted with another material to form a protective casing. This has the effect of limiting possible negative ionic reactions, thereby maintaining fertiliser in plant-available forms and increasing the pH availability window of many elements – promoting efficient nutrient assimilation. Furthermore, chelates neutralise the charge of ions, allowing plant surface charge gradients to be easily overcome and nutrients to be absorbed with low energy expenditure. If you will, imagine a crab claw (chelate) holding a marble (ion) – the word “chelate” is derived from the Greek “khēlḗ” meaning “claw.” Common chelating molecules include: 🌱 EDTA (Ethylene diamine tetracetic acid) 🌱DTPA (Diethylene triamine pentaecetic acid) 🌱HEEDTA (Hydroxyethyl ethylene diamine triacetic acid) 🌱CDTA (Cyclohexane trans 1, 2 diamino tetracetic acid) 🌱EDDHA (Ethylene bis Alpha-imino-2hydroxyphenyl-acetic acid). These synthetic chelates possess extremely strong binding characteristics, but demonstrate a myriad of negative physiological consequences once inside the plant. They are totally foreign molecules and often require extremely laborious metabolic breakdown from the plant to both cleave the ion from the chelate and expel the foreign substance from its system. Remember that these synthetic molecules have a very high affinity for fertiliser ions, so once liberated from their initial ion, will scavenge the system for a new one to hold – interrupting internal biology. The plant must then expel these synthetic chelates, or else a protracted cycle of chelation and cleaving will take place, significantly stunting growth. Due to the energy-intensive nature of cleaving ions from these compounds, as well as their large size hampering passage through plant pores, uptake is also often slow and inefficient. Adding to the disaster, these synthetic molecules frequently possess inherent phytotoxic properties. You might be wondering why growers bother with synthetic chelates at all. We do too. For more details and to order 👉👉👉 https://lnkd.in/gc3mangc #fertiliser #ruralaustralia #ruralnsw #ruralqld #qldfarming #nswfarming #renovum #renovumag #agriculture #agricultureaustralia #chelator #chelates

#Jute : A Promising Resource for #BioethanolProduction As the world moves towards #sustainableenergy solutions, #bioethanol has emerged as a viable #alternative to fossil fuels, and jute is playing an increasingly important role in its production. 🌿 Why Jute? Jute, known for its strong, fibrous quality, has high cellulose content, making it an ideal raw material for bioethanol production. The conversion process of jute to bioethanol involves breaking down the cellulose into fermentable sugars, which are then converted into ethanol via fermentation. This makes jute an #ecofriendly, #renewablesource for fuel, especially in regions like #India and #Bangladesh, where jute is abundantly grown. #Benefits of Using Jute for Bioethanol #Sustainability: Jute is #biodegradable and does not contribute to #deforestation, making it a #greeneroption compared to traditional sources like corn or sugarcane. Abundant Availability: #Jute is widely cultivated in countries like India, providing a #reliablesupplychain for #bioethanolproduction. #EconomicImpact: It provides an additional income stream for farmers and helps reduce the dependence on oil imports. #CurrentStatus and Research While the use of jute for bioethanol is still being developed at a larger scale, significant strides have been made in research and pilot projects. India, for example, is investing heavily in bioethanol plants, focusing on #secondgenerationbiofuels that use #nonfoodcrops like jute. This supports the country’s goal of achieving 20% #ethanolblending (E20) with petrol by 2025, up from the current 10% blending (E10). #Bioethanol and #FuelBlending Bioethanol is blended with #gasoline to reduce #greenhousegasemissions and enhance #fuelefficiency. India, the third-largest oil importer, is aggressively working towards achieving higher #ethanolblending targets, significantly reducing its #carbonfootprint. 🌍🚗 #Jutebasedbioethanol could be a game-changer in the #transition to #renewableenergy, providing both #environmental and #economicbenefits for developing nations. 🌱

Palm oil mill effluent (POME) is known for its high organic content, which can easily overwhelm anaerobic lagoons, impacting treatment efficiency and requiring periodic sludge removal. A recent Kampung Pon, Indonesia case highlighted this challenge: a palm oil mill plant faced capacity issues in its lagoon due to accumulated sludge. To tackle this, the plant applied Microbe-Lift, a powerful microbial solution to boost biological degradation in anaerobic lagoons. Microbe-Lift features a diverse consortium of aerobes, facultative anaerobes, strict anaerobes, and photosynthetic bacteria. This unique blend effectively breaks down complex organic matter in POME, enhancing overall treatment efficiency. Additionally, Microbe-Lift helps mitigate odor problems by degrading sulfur compounds responsible for foul smells. By harnessing the strengths of each microbial group, this solution not only improves treatment processes but also addresses odor issues, leading to a cleaner and more efficient operation. #EnvironmentalManagement #Wastewater #PalmOil #WasteTreatment #MicrobialSolutions #SustainablePractices #POME #Bioaugmentation #CleanTech #Remediation

Exposure to Volatile Organic Compounds and Isocyanates. #vocs #volatileorganiccompounds #isocyanates #occupationalhygiene

The interaction between biota and silicate weathering is a fascinating process that involves a series of complex, interrelated mechanisms. Here's a detailed illustration of how these interactions occur: 1.Silicate Weathering Process: -Silicate Rocks: Silicate minerals in rocks like basalt contain elements such as silicon and magnesium. -Weathering Reaction: When silicate minerals react with carbon dioxide (CO2) and water (H2O), they undergo a chemical weathering process. The general reaction can be summarized as follows: \[ \text{2KAlSi}_3\text{O}_8 + \text{11H}_2\text{O} + \text{2CO}_2 \rightarrow \text{Al}_2\text{O}_3 + \text{4K}^+ + \text{8SiO}_2 + \text{4HCO}_3^- \] This reaction releases essential nutrients like potassium (K+), aluminum (Al3+), and silica (SiO2), which become available in the soil. 2.Role of Biota: -Plants: Plant roots secrete organic acids and other exudates that increase soil acidity (lowers pH) and promote the dissolution of silicate minerals. They also enhance soil weathering indirectly through their physical growth and root expansion. -Mycorrhizal Fungi (AM Fungi): Arbuscular mycorrhizal (AM) fungi form symbiotic relationships with plant roots. They secrete organic acids and protons (H+) into the soil, which further promotes silicate weathering. Additionally, AM fungi release hyphal exudates that contribute to the breakdown of minerals. -Microbes: Soil microbes produce organic acids and CO2 during their metabolic processes. They also contribute to soil weathering through their biochemical activities. 3.Influence of Soil Aggregation: -AM Fungal Hyphae: These fungal hyphae can stimulate soil aggregation by binding soil particles together. This aggregation increases the surface area of minerals exposed to weathering processes and enhances the overall weathering rate. 4.Nutrient Uptake: -As silicate minerals weather, geogenic nutrients such as potassium, calcium, magnesium, and other trace elements are released into the soil. These nutrients are then available for uptake by plants, AM fungi, and other soil microbes. 5.Feedback Mechanisms: - The nutrients released through weathering enhance plant growth, which in turn increases root exudation and mycorrhizal colonization. This creates a positive feedback loop that sustains and potentially accelerates the weathering process. In summary, the interaction between biota and silicate weathering involves a synergistic relationship where plants, fungi, and microbes contribute to and benefit from the weathering of silicate minerals, leading to nutrient cycling and soil formation. . . . . . . . . . . . •name :- abhi baraiya •mail I'd :- abhibaraiya94@gimail.com . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . #ai #agri #bio #fertilizer #organic #Microbiallnoculants #agriculture #Innovation #Technology #Future #productivity #automation #food #sustainable #export #import

FreeFlow Liquid Rapidly digests organic matter, keeps drains cleaner for longer. Learn More: https://lnkd.in/gvy-x-xD . . . . . #NCHAPAC #NCHSINCE1919 #NCHMaintenance #NCHFacilities #Maintenance #facilitymanagement #wastewatermanagement #wastewatertreatment #Bioaugmentation #biologicaltreatment #superchemzyme #nchsuperchemzyme #drainmaintenance #odorcontrol

The relationship of Humic acid and Fulvic acid: Humic acid and fulvic acid are both important components of humic substances and are closely related. 1. Chemical structure and composition： Humic acid: Humic acid is a complex macromolecular organic compound. It has a relatively high molecular weight and a more complex structure. It is composed of aromatic rings and aliphatic chains that are cross - linked through various chemical bonds such as ester bonds and ether bonds. The structure of humic acid makes it less soluble in water under acidic conditions (pH < 2), but it becomes more soluble as the pH increases. Fulvic acid: Fulvic acid is also an organic acid, but it has a lower molecular weight compared to humic acid. It has a more linear and less complex structure. Fulvic acid is highly soluble in water across a wide range of pH values, which allows it to be more mobile and reactive in soil and water environments. 2. Functional characteristics and roles in Soil improvement： Humic acid: It plays a significant role in improving soil structure. By binding soil particles together, it helps to create aggregates, which increases soil porosity and water - holding capacity. It can also adsorb and exchange cations, improving the availability of nutrients such as potassium, calcium, and magnesium to plants. Fulvic acid: Fulvic acid is excellent at chelating metal ions. It can form complexes with micronutrients such as iron, manganese, zinc, and copper, making these nutrients more soluble and available for plant uptake. It also has a role in stimulating root growth and enhancing the activity of beneficial soil microorganisms. 3. Interactions between humic acid and fulvic acid： In the natural environment, humic acid and fulvic acid can interact with each other. For example, fulvic acid can act as a precursor or a building block for the formation of humic acid during the humification process. Additionally, they can work together to enhance the overall beneficial effects on soil and plant health. For instance, fulvic acid's ability to chelate nutrients can complement humic acid's role in nutrient storage and release in the soil, providing a more comprehensive nutrient - management system for plants. 📲 Whatsapp/Wechat: +86 158 9318 0907 📨 Email: doris@khumic.com Zhengzhou Shengda Khumic Biotechnology Co.,Ltd #humicacid #fulvicacid #potassiumfulvate #potassiumhumate #watersoluble #organic #organicfarming #organicfertilizer #organicagriculture #foliarfertilizer #basefertilizer #fulvicacidminerals #OMRI #REACH #soilconditioners #liquidfertilizer #biostimulant #mineralfertilizer #crops #npk #farming #planting #fertilizers #biotechnology #khumic

CALCIUM HYPOCHLORITE 65% GRANULAR Help your pool free of contaminants and prevent buildup of algae and other organic contaminants. Contact Hydro Global (333-0043) for inquiries. #hydroglobalmaldives #poolwaterchemistry #swimmingpoolchemicals #calciumhypochlorite #poolwaterdisinfection