Decomposition, Nutrient Cycling & Biogeochemical Cycles

5th Grade Science Quiz: Movement of Matter in Ecosystems 1. Which organisms are responsible for breaking down dead plants and animals into simple nutrients? a) Producers b) Consumers c) Decomposers d) Predators 2. What is the process by which plants use sunlight to make food? a) Respiration b) Decomposition c) Photosynthesis d) Erosion 3. How do animals contribute to the movement of matter in an ecosystem? a) They produce oxygen b) They break down dead organisms c) They release nutrients through waste d) They absorb carbon dioxide 4. What is the primary source of energy for most ecosystems? a) Soil b) Water c) Sunlight d) Air 5. How does matter move through the environment? a) It flows in a straight line b) It cycles through various organisms and the environment c) It remains stationary d) It only moves between plants and animals Answer Key (Always review AI generated answers for accuracy - Math is more likely to be inaccurate.) 1. c) Decomposers 2. c) Photosynthesis 3. c) They release nutrients through waste 4. c) Sunlight 5. b) It cycles through various organisms and the environment

Title (Slide 0): "Digging Deeper: The Truth About Tillage" Subtitle: How turning the soil affects plants, microbes, and the planet Slide 1: What Is Tillage? Tilling the soil means digging, turning, and loosening it using tools or machines. It's a common farming practice to prepare the land before planting. Slide 2: Why Do Farmers Till? Tillage is usually done before planting to: • Soften and aerate the soil • Mix in nutrients • Remove weeds • Bury crop residues for decomposition and fertility Slide 3: Tools Used for Tillage Farmers use tools like: • Ploughs: Cut deep into the soil • Harrows: Break up clumps and smooth the surface Slide 4: Ploughs vs. Harrows • Ploughs: Used first, go deep, lift and flip soil • Harrows: Used after ploughs, work on the surface to break clumps and level the soil Slide 5: Types of Tillage Systems From most to least soil disturbance: • Conventional Tillage: Deep ploughing • Minimum Tillage: Light disturbance • Conservation Tillage: Only disturb seed zone, keep residues on top • Zero Tillage (No-Till): Plant directly into undisturbed soil Slide 6: Problem 1 – Soil Erosion Tillage removes protective cover, exposing soil to wind and rain. Result: topsoil—the most fertile layer—is easily washed or blown away. Slide 7: Problem 2 – Disruption of Soil Life Soil is a living ecosystem! • Worms, fungi, and bacteria help aerate soil and release nutrients • Tillage destroys their habitat, reducing fertility and soil health Slide 8: Problem 3 – Loss of Soil Structure Healthy soil has pores for air, water, and roots. Tillage breaks the sponge-like structure, and soil compacts over time—like flattening it into a pancake. Hard soil = poor plant growth. Slide 9: Problem 4 – Decreased Organic Matter Microbes "eat" organic matter through aerobic respiration (using O₂ and releasing CO₂). Tillage adds oxygen, microbes speed up, and burn through the soil’s “pantry” of organic matter—leaving it empty and poor. Slide 10: Problem 5 – Greenhouse Gas Emissions Faster decomposition = more CO₂ released. Tillage boosts microbial activity, which increases carbon dioxide emissions—contributing to climate change. ✅ Conclusion (Slide 11): 🌱 Tillage: A Double-Edged Tool Tillage can help prepare the soil and control weeds—but it comes at a cost. Over time, repeated tilling can strip away organic matter, destroy soil life, and release greenhouse gases. It's like spending all your savings for quick results—and being left with nothing for the future. The smarter path? Use reduced or no-till methods that protect soil health, keep carbon in the ground, and support long-term farming success.

All animals, most protists, all fungi, and many bacteria are het- erotrophs. Unlike autotrophs, heterotrophs cannot manufacture their own food. Instead, they get energy by eating other organisms or organic wastes. Ecologically speaking, heterotrophs are consumers. They obtain energy by consuming organic molecules made by other organisms. Consumers can be grouped according to the type of food they eat. Herbivores eat producers. An antelope that eats grass is a herbivore. Carnivores eat other consumers. Lions, cobras, and praying mantises are examples of carnivores. Omnivores eat both producers and consumers. The grizzly bear, whose diet ranges from berries to salmon, is an omnivore. Detritivores (dee-TRIET-uh-VAWRZ) are consumers that feed on the “garbage” of an ecosystem. This waste, or detritus, includes organisms that have recently died, fallen leaves, and animal wastes. The vulture shown in Figure 18-8 is a detritivore. Many bacteria and fungi are detritivores that cause decay by breaking down complex molecules into simpler molecules. So, they are specifically called decomposers. Some of the molecules released during decay are absorbed by the decomposers, and some are returned to the soil or water. Decomposers make the nutrients that were contained in detritus available again to the autotrophs in the ecosystem. Thus, the process of decomposition recycles chemical nutrients. Copyright © by Holt, Rinehart and Winston. All rights reserved. 368 CHAPTER 18 ENERGY FLOW When one organism eats another, molecules are metabolized and energy is transferred. As a result, energy flows through an ecosystem, moving from producers to consumers. One way to follow the pattern of energy flow is to group organisms in an ecosystem based on how they obtain energy. An organism’s trophic (TRAHF-ik) level indicates the organism’s position in a sequence of energy transfers. For exam- ple, all producers belong to the first trophic level. Herbivores belong to the second trophic level, and the predators belong to the third level. Most terrestrial ecosystems have only three or four trophic lev- els, whereas marine ecosystems often have more. Food Chains and Food Webs A food chain is a single pathway of feeding relationships among organisms in an ecosystem that results in energy transfer. A food chain may begin with grass, which is a primary producer. The chain may continue with a consumer of grass seeds—a meadow mouse. Next, a carnivorous snake may kill and eat the mouse. A hawk then may eat the snake, as shown in Figure 18-9. The feeding relationships in an ecosystem are usually too com- plex to be represented by a single food chain. Many consumers eat more than one type of food. In addition, more than one species of consumer may feed on the same organism. Many food chains inter- link, and a diagram of the feeding relationships among all the organisms in an ecosystem would resemble a web, as shown in Figure 18-10. For this reason, the interrelated food chains in an ecosystem are called a food web.

Le microplastiche Le microplastiche rappresentano il 20% delle 8 milioni di tonnellate di plastica che finiscono negli oceani ogni anno le più comuni sono le microfibre provenienti per la maggior parte da capi di abbigliamento sintetici l'università di Newcastle ha studiato per oltre 50 anni le acque del Mare del Nord facendo luce sull'impatto del cambiamento dei microrganismi dei livelli di nutrienti e del riscaldamento globale ma ora i ricercatori stanno utilizzando i campioni d'acqua raccolti per analizzare una crescente invisibile minaccia che sta colpendo i nostri oceani: le microfibre di plastica. Alla radice del problema c'è l'industria tessile. che produce più di 40 milioni di tonnellate di prodotti sintetici l'anno. La grande maggioranza sono vestiti, realizzati in poliestere, un materiale che ha molti benefici, viene utilizzato per lo sport e l'attività all'aperto, si asciuga bene, è economico, ma la sua resistenza rende difficile la sua decomposizione. Ecco cosa succede ogni volta che indossiamo un capo realizzato con fibre sintetiche. Cosa ti fa pensare la parola poliestere? Agli abiti degli anni settanta? Alle camicie inamidate? Una volta era così, oggigiorno lo indossano tutti.” I pantaloncini per yoga, maglioni di lana, l’intimo” sono fatti tutti con fibre sintetiche come Il poliestere più poliestere vuol dire maggiore richiesta per i materiali che lo producono, ma non servono nuovi materiali, alcune aziende producono in poliestere da materiali usati come le bottiglie di plastica. Ogni giorno si consumano miliardi di bottiglie di plastica, e questo è il problema. Certo la soluzione sarebbe usare meno plastica, ma mentre si cerca di diluire il consumo di plastica alcune aziende trasformano le bottiglie in oggetti che ci piacciono. Bevete, gettate la bottiglia, fatela riciclare, tagliatela, tessetela, indossatela, lavatela, indossatela di nuovo, lavatela di nuovo, sembra la soluzione perfetta No? Ma se ci pensiamo meglio in questo comportamento si nascondono molti problemi: Il primo è che la gente potrebbe usare più plastica usa e getta, pensando che venga riciclata continuamente. Ma c'è un altro problema, un micro problema, che si somma a tutti gli altri: ogni volta che si lavano le fibre sintetiche, sia che si ricavano da bottiglie riciclate o da materiali nuovi dei minuscoli pezzetti di plastica le microfibre finiscono nello scarico dell’acqua, quindi dopo centinaia di migliaia di lavaggi i nostri capi si disintegrano. Più vecchi sono peggio è. Il problema maggiore è che queste fibre sono così piccole che non sempre vengono filtrate negli impianti, finendo nei fiumi, nei laghi, nell'oceano, una volta nell'oceano agiscono come spugne risucchiando gli altri agenti inquinanti, sono come delle piccole bombe tossiche, cariche di olio per motori, pesticidi, sostanze chimiche industriali, che finiscono nello stomaco dei pesci e quindi nei nostri. Si stima che ce ne siano 1,4 milioni di trilioni negli oceani cioè 200 milioni di microfibre a persona. Questo è l'altro lato della medaglia, di quella che sembravano soluzione al problema, sarebbe il caso che queste aziende ripartano da zero, perché se è vero che possiamo lavare meno i nostri vestiti o evitare di comprare abiti sintetici non possiamo risolvere il problema senza di loro, se vogliamo che la questione diventi una priorità di queste aziende, dobbiamo farci sentire, troviamo una soluzione reale per rendere i nostri vestiti sicuri per l'ambiente sicuri per gli oceani e sicuri per noi.

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