14 December 2012

Why Stretching Is Bad For You

Pulling on a muscle for a long time doesn't make it longer, doesn't make it more pliable, and doesn't improve athletic performance. There's lots of scientific literature that shows that stretching before exercise increases the risk of injury, but still there's a lot of emphasis on it in common fitness literature. It's similar to the demonization of saturated fats: once a meme gets firmly implanted in the culture, it's hard to eradicate it. 

I wanted to share this video from Evan Oscer on why conventional stretching is bad.  I think it's worth your time to watch:

Personally, I happen to do yoga as my means of integrating my muscles and nervous system. Yoga is mentioned in this video around the 23 minute mark in a positive light. A lot of people seem to think yoga is glorified stretching, but that's evidence of a bad yoga teacher (there are many, many bad yoga teachers out there). The physical side of yoga, the asana practice, is the integration of:
  1. Breath
  2. Stability
  3. Movement
Stability and breath are both important for reducing muscle apprehension throughout the movement.  Whenever your nervous system is unsure of whether it can support a load at the edge of your range of motion, the interaction between the muscle spindles and the Golgi organ in the tendons causes the muscle to spasm to protect itself. If you want to decrease muscle tightness and improve your range of motion, the thing to work on is improving the stability of the movement while breathing deeply and evenly, _not_ pulling on the muscle harder.The apprehensive reflex is inhibited when the body is convinced, by many repetitions, that the joint is still safe and stable even at the edge of the range of motion. This in turn allows us to be more athletic, more open, and improve our eccentric muscle control so that we can relax when muscle tension is deleterious.

11 December 2012

Thermoelectric Breakthrough, ZT = 2.2

Recently there was a major advance reported in Nature (Biswas et al., 2012), conducted at Northwestern University (NWU), on a new high-temperature thermoelectric material. This particular material is doped and structured Lead Telleride (PbTe) and is used to produce electricity from high-temperature 'waste' heat, otherwise known as a Seebeck generator (as opposed to a Pelletier refrigerator, which is the effect in reverse).

If I may diverge for a moment, Tellurium is an element with a lot of interesting chemistry associated with it. Jim Ibers of Northwestern University wrote an interesting article in Nature Chemistry (2009) about it. It's in the same column as Oxygen and Sulfur on the periodic table, so it shares some aspects the very complicated chemistry that these elements have.  However unlike Oxygen and Suflur, it can also form distended Te-Te bonds, in addition to Te-Te single bonds, so oxidation states in metal Telluride compounds are often indeterminate (which sort of implies that Te-containing compounds can have lots of different phases with very different physical and chemical properties). 

Tellurium ain't exactly common (it's less abundant than gold, but not in as high demand) nor environmentally benign.  Also, thermoelectrics are naturally going to be employed more in high-wear, industrial environments.  Furthermore, there is competition for Tellurium from other industries such as thin-film CdTe photovoltaic manufacturers such as First Solar.

Anyway, back to the thermoelectric!  

The advance improved ZT, which is the figure of merit for the heat efficiency performance, from about 1.7 to 2.2.  ZT governs the Carnot efficiency of  the thermoelectric, and hence dictates how close to entropy-limited performance a thermoelectric material can operate.  These devices are supposed to operate from a heat source at about 750-900 Kelvin (630 - 480 °C) and dump into room temperature.  This is not low-quality heat by any means, as its easily hot enough to make steam, so there's no magic when it comes to thermoelectrics.  They still obey the laws of thermodynamics.

The basic trick here is the governing equation,
ZT = σS2/(κel+κlat)
from which we see that if you decrease the thermal conductivity, κ, you can improve the performance (electrical conductivity is σ). Thermal energy in solids is primarily conducted by phonons, which are quantized lattice vibrations (i.e. sound). Electrons carry some thermal energy as well, but at the temperature we're concerned with, it's precious little. In order to decrease the thermal conductivity, but not overly decrease the electronic conductivity, you need some structures that are phonon-sized (many atoms). Phonons have a large range of possible wavelengths, so in order to inhibit thermal conductivity you want to provide all wavelengths with something to reflect and scatter from.  Hence, the desire is to have a material that is structured/disordered on all potential length scales so there's no window for phonon-driven thermal conductivity to occur in. 

The previous body of research, that improved the ZT up to 1.7 involved nanopatterning the thermoelectric with precipitates about 5 nm in diameter. In comparison the microscale crystallites have a much broader distribution of grain sizes, but average around 1 μm (or 1000 nm).  The histograms in Figure 3 tell the story.
Figure 3 (from Biswas et al., 2012): Micro- (top) and nano-scale (bottom) structures in Sodium-doped Lead/Strontium Telluride.  The low-mag electron micrograph in (a) shows the crystal grains, while in (e) the nano-scale precipitates are seen in high-resolution transmission electron microscope images. 
It is slightly ironic, given the nanotechnology craze, that the group improved the performance first with nanostructures and then when that was insufficient, reverted to the microtechnology to further improve the performance. So the new model is to develop sexy technology first and the simple solution later? Of course there's a fairly big gap between the nano-scale precipitates and the micro-scale crystalline boundaries.  Perhaps something in the range of 50-100 nm could be added to further reduce the thermal conductivity? 

One concern I would pose is whether the nanostructures and microstructures are stable long-term at the given operating temperature.The melting point of PbTe is 924° C, but the constituents melt at much lower temperatures, so there is the potential for annealing over time.