The Problem of Global warming is a very big problem on the Existence of Human, animals, and Plants and there is a big question of how it will be reduced on the Earth? For Control of Global warming and Reduction of Green House Effect, we should be changing our lifestyle or changing the way we do things. Here is some important facts and factors of Global warming in the present situation of the globe.

Concept of Global warming

I’ll try to start out by looking at the carbon cycle, which is really one of the core issues in the debate. It has to try to with what controls the greenhouse emission level within the atmosphere. We know the greenhouse emission could be a powerful gas. It has a linear molecular structure, but it can flap and it can vibrate in such a way to absorb and emit infrared radiation. So it’s a powerful greenhouse gas.

Fig1.Heating of Earth Atmosphere due to Global warming

It’s in part controlled by anthropogenic processes, so it’s at the center of the whole debate. You have to know this. You have to understand that after you burn one thing like coal, the chemical reaction looks like that, carbon plus oxygen. You oxidize the carbon to make greenhouse emission, and that’s a gas that goes into the atmosphere. This comes from the atmosphere, and this would become from some buried deposit of coal. If you are burning gas, which is CH4, you combine that with oxygen and you get two by-products, water vapor, and carbon dioxide.

The vapor we have a tendency to just about neglect, because it goes into the atmosphere as water vapor, but then instantly, it becomes part of the normal hydrologic cycle. And if you bear in mind early within the course, we have a tendency to computed the common continuance for vapor.

So in alternative words, it’s cycled back in rain to the earth’s surface or the ocean very, very quickly, and so it really plays no role in the greenhouse effect. Let me be careful. Water vapor is additionally a fully powerful gas. And because there’s so much of it, it’s actually in a sense the strongest of all the greenhouse gases. But it is controlled by the natural system. It doesn’t matter how much we add into it.

The level isn’t progressing to the amendment for that reason. It’s progressing to be controlled by the own, the internal processes within the atmosphere. Nothing we will liquidate adding vapor goes to possess any influence on dynamic the number of vapor within the atmosphere.

So it is vital to understand that vapor is one product, but in terms of what that does to climate, that particular piece is negligible in the sense that I have just described. Propane is another form of gas. It may be burned for warmth, and the reaction–the stoichiometry is a little bit different.

Role of Co2 On Global warming

The CO2 stays in the atmosphere, influencing climate. The vapor quickly gets cycled into the natural hydrologic system. Another thing that’s going on, we’ve talked about calcium carbonate in this course a couple of times because that excess calcium that we found in the Quinnipiac River that wasn’t there in ocean water, we argued goes into making calcium carbonate in the oceans, shells, limestones, and so on.

There’s a ton of that around within the earth’s climate system. If we tend to take a touch little bit of that and warmth it, we can separate it into the material that’s used to make cement, but that releases CO2 as well. So there’s another source of CO2. It’s not quite as powerful as these. I’m progressing to show you some numbers for a minute. But that’s another vital input of dioxide, is the making of cement from natural calcium carbonate that was precipitated in the oceans by either living or non-living processes.

Burning of fossil fuels

When you burn fossil fuels then, you’re putting carbon dioxide in the atmosphere. And that comes from carbon that is been held on within the earth, typically for 60 or 100 million years. Remember in the Cretaceous Period, way back when the dinosaurs were alive, that’s when a lot of forests were being the earth was very warm during that period of time.

You had tropical forests nearly every place on the continents. Those trees would eventually fall. And the productivity was so high, instead of their rotting and putting that CO2 back in the atmosphere, they would be covered over by another and then another and another.

So you finished up sequestering all of that carbon down within the crust of the planet wherever it has been sitting there for sixty or100 million years. And currently, we suddenly pull it back out and burning it and swing it back to the atmosphere. And within the oceans, too, you had algae growing, phytoplankton, that would sink to the bottom of the ocean, and instead of rotting and returning to the ocean system, they would get covered over.

And today you have all of these oil deposits beneath the ocean bottom. And then we tend to dig those up and that we burn those, too. So each on the land and within the oceans, we tend to ar removing ancient, very ancient fossil carbon and burning it to put it back in the atmosphere.

Now the natural, the modern biosphere is active in this as well. For example, trees take away heaps of carbonic acid gas throughout the summer season once they are growing and use that to create their woody biomass.

Remember, the trunk of a tree is regarding 1/5or one quarter carbon. Well, where did that carbon come from? It didn’t come from the soil. From the soil, the tree is getting water and it’s getting nutrients, like nitrogens and phosphorus, but almost all of the carbon to build a tree trunk is coming from the atmosphere.

I mentioned in another context that I did a project down on a tiny low island within the Caribbean last spring. And we were flying AN craft around the island. One of the sensors we had on the airplane was a carbon dioxide sensor so we could measure how much carbon dioxide was in the atmosphere upstream of the island, over the island, and downstream of the island.

The island was forested. It’s the island of Dominica, one of the few Caribbean islands that still has its original forest. And once we flew downstream of the island, across the wake of the island, we tend to found a small deficit in carbonic acid gas. In different words, the air that had returned from upstream and ignored the island’s forests had lost a touch little bit of CO2 to those trees, and that we found that deficit downwind. Now, this has been well known. You can live this in millions of different ways that.

But this is often yet one more thanks to persuading yourself that the forests square measure actively removing CO2 from the atmosphere all the time that they are growing. But then, they recycle some of that. For example, the fabric in leaves that falls to earth at now of year then rots and respires over the winter season to place that small little bit of carbon back in.

Now it still has its woody biomass, that is most of it, however, a touch bit goes into the atmosphere, which provides that small little bit of wiggle within the Keeling curve that you just were learning in some time Series research laboratory. So I want to emphasize that the biosphere is a very active player in this carbon cycle. Certainly in the long term, but then on the modern timescales as well.

Does the carbon that is sequestered within the wood, when, like, the wood from the tree roots, is that additionally, is that rereleased within the atmosphere?

That’s right. So if a tree, if a contemporary tree these days will fall then you watch it over some years, it rots and sort of disappears into the world. That carbon ends up back in the atmosphere. A little bit is also left within the soil as organic carbon, on the other hand over an extended amount of your time, perhaps 10 or twenty years, that too can go back to the atmosphere. So there square measure few places on earth, however, wherever you are obtaining this sequestration, wherever you are obtaining things falling on prime of it quicker than it will rot. But I’d say, for example, in most of these New England forests, most of the ancient tree material is going back into the atmosphere.

Well, in fact, that is one in every of downsides|the issues} with this idea of determination the Global warming problem by planting millions of trees. Because what that may knock off the short run, indeed, it will draw extra CO2 from the atmosphere and store it in the biomass of the tree.

But a typical tree of the species you’re familiar with, both conifers and deciduous, typically have lifetimes of 60to 80 to 100 years. And then {they can|they’re going to|they’ll} fall and therefore they’ll rot and the material will return. So it is a temporary fix, perhaps, to reducing carbon dioxide buildup in the atmosphere, but by no means is it permanent because of the short turnover time of trees in the forest.

Production of Co2

If you would like to grasp what the mass of the CO2 is, be sure to include the mass of the two oxygens that are on the carbon dioxide. This is simply the carbon within the CO2. For example, let’s look at how it interacts with terrestrial production, the one I’ve just been talking about, of trees and other biomass on the continents.

So about 60 gigatons per year are put in and about 62 is taken out every year. So it’s a very dynamic reservoir. The difference, however, is rather small. There’s associate excess going from the atmosphere into the region of concerning 2 or 3 gigatons annually. It’s this massive exchange, the sixty and therefore the sixty that is liable for that wiggle within the Keeling curve. And it’s the annual difference, that two or three units, that’s responsible for that trend the Keeling curve. I’ll show you that Keeling curve in an exceedingly moment. You’ve seen it before, but that’s a central part of our argument. The oceans are somewhat similar, so there’s biological activity taking place in the oceans. We’ve talked about that.

We’ve seen that it’s confined to sure components of the ocean wherever you’ll get nutrients developing into the euphotic zone. The numbers square measure even larger than for the terrestrial biomass, but they too have a similar characteristic. Large instantaneous cycling, but over a year, only about two gigatons, and going in the same direction, going from the atmosphere into the ocean.

There’s the cement production, about 6.5. And there are some other things here. This is one to look at. The amount of fossil fuel reserves still in the crust of the earth is 4,000 units of gigatons. So you’ll imagine if you burn the remainder of that, what that would do to that number. It would be four,760, unless, you probably should take into account this removal as well.

So there’s this rapid cycling that’s taking place. But in a way it’s kind of irrelevant because it cancels itself out at the end of the year. So i am not progressing to place an excellent deal of stock during this range. It is a residence time. It is computed within the correct means, however the fluxes we’re exploitation square measure balanced over the course of a year. And so, the numbers isn’t of nice use. On the long term, I’ll take 760 and divide it by one of those imbalances.

Now again, I’ve used the imbalance for simply the terrestrial biomass. Maybe I might have modified that to four by adding up 2 here and 2 there. But you’ll see what that may do to the numbers pretty simply. I’ve just used two gigatons per year here. And I got 380 years. Now, this is a more useful number because this is actually how long a carbon dioxide molecule is likely to stay in the atmosphere before it’s returned into one of the biosphere sinks.

So when we’re trying to predict the future of carbon dioxide concentrations in the atmosphere, we have to realize that it stays there for quite a long period of time in spite of those fluxes back and forth between the atmosphere and therefore the part.

Economica Data on Geen House Effect and Global Warming

So from economic data, we can get a pretty good handle on the carbon dioxide emissions that have taken place in past years. And here you see various curves. The black is that the total, where all the others have been summed up. The two largest freelance sources are coal, in the green, and petroleum, in the dark blue. Each of these is concerning six billion metric loads of carbon each year.

Fig4. Effects_of_global_warming

So this is not accumulated. This is what’s emitted each year. And of course, that number has been growing since the beginning of the Industrial Revolution, where we began to use fossil fuels for steam engines and then for electricity generation and transportation and so on.

Natural gas is growing rapidly now. Cement production is lower but still growing. And a tiny low quantity is that the gas flaring that you simply see in a number of these oils fields and gas fields, just burning off excess gas. So it’s rising very rapidly. No sign in the least of any decrease during this. There have been some temporary for example, in the 1970sthere was a kind of an oil crisis, and you see a tiny little bit of a dip there. But typically it’s simply a curve that is rising terribly, very steeply.

And this is often the speed at that we tend to ar golf shot CO2 into the atmosphere. This is not the accumulated amount.

So we’ve been monitoring carbon dioxide concentration. There’s an annual oscillation that has to do with the mostly the Northern Hemisphere biomass drawing carbon dioxide in the summer and releasing it in the winter. And then on high of that, you have a trend, which you can see from the smoothed line here.

And that slope has been increasing. And in fact, the rise therein slope is as a result of this, the rate at which we’ve been putting CO2 into the atmosphere has been increasing. So that rate of amendment of greenhouse gas concentration has been increasing furthermore.

And the increase kicked off at regarding zero.5 components per million amendments annually and is currently regarding thrice that quantity of increase annually. Up on top of is that the expected amendment from emissions if all the CO2 we’re setting up, particularly that, remained in the atmosphere, and it’s about twice what we’re actually finding as for the increase every year in the atmosphere.

So here’s what we’ve learned from this. The biomass is taking in regarding 1/2 that further that we tend to are emitting into the atmosphere. That’s rather remarkable. The reason looks to be that greenhouse gas is in several places around the earth and also the ocean a limiting amount for chemical action.

What Happens when Co2 level is incresed

So that once you increase the concentration of CO2, you increase the speed at that plants grow. It’s called CO2 fertilization. So as CO2 has inflated, the plants have tried to require a number of that excess back out. They take about half of it out. There’s some speculation regarding whether or not they can still be ready to cast off [*fr1], as a result of they have different nutrients furthermore.

They need phosphorus and atomic number 7, they have water if they’re planting growing on the land. And it would be that as these different ingredients become limiting, the biosphere will no longer be able to do this for us, and these numbers could creep up.

As this one will increase, these would possibly truly advance eventually to become additionally capable the quantity that we’re setting up per annum. Questions on that? So it’s fascinating to seem at this from a historical perspective as a result of what we’re doing now’s thus uncommon and then speedy.

So if we tend to return 10000 years, this roughly covers the Holocene. Here is greenhouse gas concentration in components per million by volume. And in fact, the Keeling curve is that the very little red half here, it’s just that little part. Before that point, we tend to get that information from the ice cores, the microscopic vesicles, the microscopic bubbles within the ice cores offer the United States the info before that point.

But it had been pretty flat through the Holocene, with a value of about 270 or 280 or 290 parts per million. And then in the Industrial Revolution, on this timescale, it shoots up almost vertically. If you blow that up, blow that point proportion, and show it here going back to 1800, it had been slow initially then has become additional and additional speedy, as we have a tendency to mentioned within the previous few diagrams as a result of the speed of dioxide emissions has increased thus powerfully.

We can return even more in geological time. And you’ve seen this kind of thing before. This is an associate degree ice core showing dioxide concentrations. Here we have a tendency to ar within the Holocene, right regarding here, with preindustrial levels around 270 or 280. But just prior to that, 15,000, 20,000 years ago at the end of last Ice Age, the values were down regarding 200hundred, and so oscillated around those lower levels for a minimum of four hundred,000 years.

It’s onerous to place this recent knowledge even on an identical scale as a result of it plots as virtually a vertical line. So the rate at that we’re golf stroke carbon dioxide in and dynamic region composition is much over something one may diagnose from previous geological eras. There’s another piece to the present argument that I realize reasonably attention-grabbing. It has to try to with the isotopes of carbon.

Carbon, like H and O that we have a tendency to spoke regarding earlier within the week, return as a primary part and so numerous heavier isotopes. And most carbon is Carbon twelve, however, there is a Carbon thirteen furthermore. It’s a stable isotope of carbon. And the buried fuel happens to be depleted in Carbon thirteen relative to the traditional Carbon twelve.

So when we dig up this fossil fuel and burn it, we’re now putting a lot of the dominantly we’re putting in the Carbon 12 into the atmosphere, which takes whatever fraction we started with, Carbon 13 to Carbon 12in the atmosphere, and making the overall carbon in the atmosphere lighter, because we’re mixing in more of the light carbon from the fossil fuel burning.

So some would argue, how do we know that new carbon dioxide in the atmosphere is coming from the burning of fossil fuels?

Well, one argument would have been, well we’re putting twice that much in the atmosphere. It is smart that a minimum of 1/2 that will stick around. It’s a pretty powerful argument. But maybe this is even a more powerful argument because that carbon we’re putting it has a certain isotopic signature. And currently, we have a tendency to see that signature disclosure within the region carbon.

So it’s another argument for the case that the burning of fossil fuels is what’s leading to that increase in carbon dioxide in the atmosphere.

A Questions arise here that is, Do we know why it’s depleted in the heavier isotope?

Yeah, it’s to try to with the plants that originally took in this carbon. So once a plant grows, as I mentioned, it takes carbon in from the atmosphere to build its biomass. It truly prefers the sunshine atom over the serious atom. So once those plants, way back, 100 million years ago, were growing their biomass, they were doing it preferentially out of Carbon 12.

And then once they got buried, that left behind loads of the Carbon thirteen within the atmosphere. They buried loads of the Carbon twelve.Now we’re reversing that, golf stroke the Carbon twelve back within the atmosphere. So it’s to try to to it however plants attract carbon dioxide into their leaves and so use that to make their biomass.

So let’s conclude, then, our brief discussion of the carbon cycle. Fossil fuel burning is quickly returning to the atmosphere carbon keep for immeasurable years in crustal reservoirs. About 1/2 the emitted carbon dioxide stays within the atmosphere, and we estimate it’ll stay there for at least a few hundred years, given the cycling rate between the biosphere and the atmosphere.

The carbon dioxide emission rate has increased with time since the start of the Commercial Revolution. And the current carbon dioxide concentration, which is approximately 395 parts per million by volume, is the highest in several million years.

Compare to past Global Atmosphere

Let me be careful of what I say here. If you return means earlier, say 50, 60, 100million years agone, you will find periods within the earth’s history wherever the dioxide concentration within the atmosphere was truly much higher than it is even today. So I don’t want to make a blanket statement saying that it’s as high as it’s ever been. So instead I have said, it is the highest it’s been in several million years. But again, this is the kind of an argument that arises. Someone can say, well, yes, we’re putting a great deal of carbon dioxide within the atmosphere, but it hasn’t by any means reached an unprecedented level. There are periods within the ancient earth history wherever dioxide concentrations are abundant on top of this.

So it all depends on what you would like to use for your reference timeframe on what quite a press release you create during this regard. So be terribly careful that to not overdraw the distinctiveness of this dioxide concentration. It’s probably safe to say there’s never been a time in Earth’s history where the CO2 is increasing as rapidly as it is today, where the rate has been as large.

Fig5. Heat production During Global Warming

But in terms of absolutely the quantity, the record we’re setting now could be solely the record for the previous couple of million years, not for–certainly not for all of Earth’s history. So we have got a handful minutes to start the ensuing section, that is that the epoch as a reference period of time. And I wished you to remember of those explicit typically mentioned dates. The retreat of the last massive ice sheets was occurring around eleven,000 years before the gift.

That’s right when the ice was in the process of melting back. There was a heat amount that followed that referred to as the epoch Optimum concerning seven to eight thousand years agone. That comes into the argument once one is making an attempt to search out whether or not this heated climate is exclusive even within the epoch. In alternative words, is our current climate cooler or warmer than this so-called Holocene Optimum?

Conclusion

You see speedy warming starting up of the last glacial epoch. Then you see this climatical optimum, what I referred to as the epoch Optimum, right here. And then it cooled off a little bit. And then there are some wiggles near the end that we’ll talk about in just a minute.

So in the arguments, we see that such a rapid rise in the last 20 or 30 years. So, we’re out of time today, but we’ll recover it now by doing some works on it that will find in my next article.

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