Point of clarification: organic matter doesn’t really retain the nutrients but acts as the slowly mineralized pool of nutrients associated with soil quality.
The way you describe it is similar to how a sponge works rather than a storehouse.
You are right, though, in that you don’t need to fertilize trees for the most part. Forest soils are hilariously low in nutrients: TOC is around 1% and N is next to non existent (N is highly labile), while P and K are moderate to high. As a result, forests veg is most competitive in nutrient poor conditions. If you fertilize a disturbed area, you get a pile of weeds and grass that can set back your revegetation timeline because your desirable woody spp now have to out-compete them. This process still happens if you don’t fertilize, but it’s generally less pronounced and allows some woody plants to gain the foothold they need
Well, based on our prior conversations I suspect you know far more about soil science than I do, I only know the basics necessary for arboriculture.
So what you wrote is of course accurate but I understand both to be at play here—leaves break down into humus that chelates minerals and supports fungi that can hold onto nutrients and keep them from leaching away in rain. Leaves also provide a physical barrier that protects soil from physical erosion. But let me know if I got anything wrong.
My overall point was mainly just that you don’t need to replace leaves with fertilizer if you are removing them, but it’s still a good idea to leave them in place for other reasons.
First and foremost, I’m not trying to nitpick - I just really like dirt. It’s embarrassing kinda.
Secondly, being a good soil scientist doesn’t necessarily mean you have a good understanding of plant requirements. Plants are their own can of worms, and their needs vary by species.
Third, the soil carbon and fertility cycle is a terrifying place. There are so many facets of organic matter in the soil it will make your head spin. In some cases OM can be physically protected by other, more recalcitrant OM.
Building up OM can yield more humus and more cation exchange capacity, which does play a role in fertility for secondary and micronutrients.
I really don’t know much about fungi holding onto minerals, but in general, the organic nutrients (like P tied up in ATP) only get released when organisms die, so in that capacity fungi and other biota play a buffering role
Some trees do a bit, I guess? Like, beech trees will release some chemicals to inhibit other plant growth, and iirc their leaves do that as they decompose, as well as the root system itself. But depends on the plant and mostly bunk I believe.
I’m not directly aware of any trees that do that, but it honestly wouldn’t surprise me if that was true for at least one species.
Most trees that drop seeds have methods of getting them away from the parent tree. Maple trees have little helicopter twirlies, oak trees have animals carry them off, some trees grow new ones from their roots called suckers.
I’ll try to look it up later because now I’m curious. I’ll update here if I find anything interesting about trees dropping leaves to prevent new ones growing too close.
I don’t think my arborist textbook said anything about that specifically, but I’ll double check there first.
Not bunk, but not an evolutionary strategy, I imagine. Leaves are dropped because they are too hard to maintain, rather than the benefit the trees get from mulching out competition.
Yes, but again, it don’t think it’s evolutionary strategy, rather than the content of the needles is what is needed, and the acidification is just a knock on effect. Pines in particular are disturbance specialists - they take off after fire, and drop relatively few needles during establishment when competition from grasses and other plants is at the highest. When they get larger they don’t have to worry (,as it were) because you can choke out anything below you just by being big
Point of clarification: organic matter doesn’t really retain the nutrients but acts as the slowly mineralized pool of nutrients associated with soil quality.
The way you describe it is similar to how a sponge works rather than a storehouse.
You are right, though, in that you don’t need to fertilize trees for the most part. Forest soils are hilariously low in nutrients: TOC is around 1% and N is next to non existent (N is highly labile), while P and K are moderate to high. As a result, forests veg is most competitive in nutrient poor conditions. If you fertilize a disturbed area, you get a pile of weeds and grass that can set back your revegetation timeline because your desirable woody spp now have to out-compete them. This process still happens if you don’t fertilize, but it’s generally less pronounced and allows some woody plants to gain the foothold they need
Well, based on our prior conversations I suspect you know far more about soil science than I do, I only know the basics necessary for arboriculture.
So what you wrote is of course accurate but I understand both to be at play here—leaves break down into humus that chelates minerals and supports fungi that can hold onto nutrients and keep them from leaching away in rain. Leaves also provide a physical barrier that protects soil from physical erosion. But let me know if I got anything wrong.
My overall point was mainly just that you don’t need to replace leaves with fertilizer if you are removing them, but it’s still a good idea to leave them in place for other reasons.
First and foremost, I’m not trying to nitpick - I just really like dirt. It’s embarrassing kinda.
Secondly, being a good soil scientist doesn’t necessarily mean you have a good understanding of plant requirements. Plants are their own can of worms, and their needs vary by species.
Third, the soil carbon and fertility cycle is a terrifying place. There are so many facets of organic matter in the soil it will make your head spin. In some cases OM can be physically protected by other, more recalcitrant OM.
Building up OM can yield more humus and more cation exchange capacity, which does play a role in fertility for secondary and micronutrients.
I really don’t know much about fungi holding onto minerals, but in general, the organic nutrients (like P tied up in ATP) only get released when organisms die, so in that capacity fungi and other biota play a buffering role
I read a while ago that trees attempt to reduce competition by dropping their leaves to prevent saplings growing too near. Was that all bunk?
Some trees do a bit, I guess? Like, beech trees will release some chemicals to inhibit other plant growth, and iirc their leaves do that as they decompose, as well as the root system itself. But depends on the plant and mostly bunk I believe.
I’m not directly aware of any trees that do that, but it honestly wouldn’t surprise me if that was true for at least one species.
Most trees that drop seeds have methods of getting them away from the parent tree. Maple trees have little helicopter twirlies, oak trees have animals carry them off, some trees grow new ones from their roots called suckers.
I’ll try to look it up later because now I’m curious. I’ll update here if I find anything interesting about trees dropping leaves to prevent new ones growing too close.
I don’t think my arborist textbook said anything about that specifically, but I’ll double check there first.
Thanks!
Np! I couldn’t find any evidence that any species of tree use their leaves to prevent new ones from growing too close.
The lack of light, water, and nutrients would kill and new saplings all on its own.
That might be an old hypothesis that later got disproven, but most people don’t keep up on forestry sciences so that’s understandable!
Not bunk, but not an evolutionary strategy, I imagine. Leaves are dropped because they are too hard to maintain, rather than the benefit the trees get from mulching out competition.
Depends on the type of tree – pine trees do benefit from the acidification of soil via their dropped needles - it reduces competition.
Yes, but again, it don’t think it’s evolutionary strategy, rather than the content of the needles is what is needed, and the acidification is just a knock on effect. Pines in particular are disturbance specialists - they take off after fire, and drop relatively few needles during establishment when competition from grasses and other plants is at the highest. When they get larger they don’t have to worry (,as it were) because you can choke out anything below you just by being big