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Posted Feb 11, 2019
By Hanny Allston.
Is running really as simple as we make it out to be? The motion of pulling on your shoes and stepping out a door anywhere makes it appear simple. Once out the door we take one step forward, push strongly, move our other leg forward… and away we go. As we warm-up, we begin to exert a little more effort and our speed gets faster and faster. Simple! But is it really the case? Research shows that the answer is a loud and definitive NO.
As I open my eyes more and more to the world of running I am continually amazed by how complicated the sport is. The actualactof running and how each individual sequence of limb movements come together to carry us smoothly forwards is more attuned to ballet dancing than it is to anything else. Where we place our feet, the landing point, the subtle shifting of our weight and the counterbalances we put in place are all unconscious things that keep us in a state of running harmony. Further to this, the ground isn’t always flat nor the surface we are running on smooth. And what happens if you need to accelerate or decelerate? Go uphill or downhill? Or even crash through the bush with a map in our hand?!
In this article we explore the science behind running propulsion and discuss some amazing research recently released on flat, uphill and downhill running. During the article I will also try to highlight some important running technique tips that might help to make you faster and more efficient.
To run across flat terrain we need to utilise energy to move us forward. There are two types of energy at our disposal; the energy that we hold within our bodies, stored as glycogen or fat (protein can be used but is the least preferred source of fuel); and gravity, our free energy source. When we run on flat surfaces, the energy that we need to put in is directly proportional to the amount of forces opposing us.
Propulsive Force = Braking Force
The greatest opposing force that we have is the braking forces we generate when our foot hits the ground. There are other opposing forces such as wind resistance and how much lateral movement we get from our running style, but where are foot strikes makes a considerable difference.
Studies have shown that if our foot lands directly under our centre of mass, then we have a lower braking force than if it lands out in front of us. Further to this, if our torso is gently pressing forward and giving us the appearance of a lean then we are more likely to have our feet landing under our centre of gravity. In this position we are also tapping into the energy of gravity that will help us to move forward, thus reducing the amount of energy we have to put in.
Interestingly, the metabolic energy we have to put into running on the flat falls into three different categories:
Therefore, to run fast on the flat we want to:
Sadly, the ground isn’t always flat and on almost every run you will encounter a hill. So what happens now?
When we run uphill it becomes much harder to get our feet under our body. We also tend to want to slouch which makes us feel heavy. Despite this and contrary to what we might think, our braking forces actually reduce by approximately 40%. This is due to the fact that our foot strikes the ground with less force than when we run on the flat. In fact, by the time we are running on a nine percent gradient, the impact forces are almost negligible. However, the reason hill running is so tough is that the parallel propulsion we have to apply has to increase dramatically to overcome gravity. For example, on a nine percent gradient, parallel forces have to increase by almost 75%. That is a lot of extra energy!
Therefore, to run faster up hill we need to:
We are always grateful when we get to the top of a hill and begin the descent. However, often by the time we are half way down the hill our quads are burning and our knees complaining. Sometimes we can even be surprised by how much energy we feel like we are using up.
When we run downhill our braking forces are dramatically greater than our propulsive forces.
Braking Force > Propulsive Force
In fact, by the time we hurtle down a nine percent gradient, our braking forces have increased by a whopping 108%! Therefore, even though we have gravity and momentum in our favour, our bodies still have to absorb a huge amount of shock from the impact of downhill running and at the same time apply some energy to overcome these forces.
Further to this, in downhill running our muscles are eccentrically contracting to brake us (ie. while under tension the muscles are lengthening) and yet we still have to provide some concentric contraction to create propulsion (I.e. the muscles shorten whilst generating a force). This strange mix of muscle contractions to overcome the huge braking forces guarantees that downhill running is actually quite energy intensive. Research also shows that landing on stiff legs when running downhill also causes the braking forces to increase further.
Therefore, to run fast downhill we need to:
As you can see, behind every step that we take when we hit the roads or trails, is an intricate series of energy ‘ins & outs’. The alterations in surfaces and slopes change the way our muscles need to respond. Sometimes they will be contracting strongly to propel us forward and other times they will be eccentrically contracting to slow us down. Sometimes gravity will be working in our favour, and sometimes completely against us. Therefore, it is important to begin thinking about the way you catch, create and utilise the energy that you have available to you – and perhaps turn the struggle home, into a strong finish!