What Young Athletes Need Besides 10,000 Hours Of Practice

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The 10,000 hour theory has become the American dream for developing athletes. Just work hard enough and your gold medal, Hall of Fame, championship ambitions can come true. It is achievable, measurable and finite.

However, many athletes never quite cross the 10,000 hour finish line, and have used the scapegoat reason, “I just didn’t have enough time to commit to the sport.” Now, recent research suggests that while 10,000 hours of deliberate practice may be necessary to achieve world-class status, it may not be the only ingredient to success.

Celebrating its 20th anniversary this year, a research paper by Florida State professor K. Anders Ericsson, The Role of Deliberate Practice in the Acquisition of Expert Performance, has been cited in the scientific press over one thousand times earning its own HOF credentials.  The gist of it is that Ericsson visited a West Berlin music academy and interviewed violin students and their teachers.  First, he asked the students to estimate the number of structured practice hours they had endured up to age 20.  Then, he asked their teachers to divide the class into good, better and best thirds.  The correlation uncovered showed that the best students had accumulated, on average, over 10,000 hours of practice while the middle group was at about 8,000 hours and the bottom group had not reached 5,000 hours.
After checking this relationship within other groups of skilled experts, Ericsson found similar patterns of 10,000 hours of practice and concluded that innate talent or “what we’re born with” had little to do with becoming an expert in any field, even sports.  With that declaration, the dream (and the practice odometer) was launched.
However, since that landmark 1993 paper, other researchers have been finding exceptions to the rule; some experts were crowned with only 3,000 hours of practice while others still had not reached the mountaintop even though they had doubled the 10,000 hour mark.
David Hambrick, associate professor of psychology at Michigan State, has been searching for the other necessary ingredients for several years.  In 2011, he and his colleague Elizabeth J. Meinz found that deliberate practice among pianists did account for almost half of the variance between experts and novices.  But in their quest to find out what else mattered to make up the other 50% of variance, they found that working memory capacity, the ability to remember a set of objects while engaged in another task, was also a significant determinant of success.
This month, Hambrick and his team released new research that looked at 14 different studies of chess and music students to find other clues to expertise.  Again, they were convinced that deliberate practice alone was not enough.
“The evidence is quite clear,” he writes, “that some people do reach an elite level of performance without copious practice, while other people fail to do so despite copious practice.”
Across those chess and music studies, they found that practice explained about one third of the journey to being world class.  One new factor that did emerge was starting at a young age.  Logically, someone who started training at age 7 versus 12 would have five more years of practice, but Hambrick found that even when total hours of practice were comparable, the student that started at an earlier age became more accomplished.  “This evidence suggests that there may be a critical period for acquiring complex skills just as there may be for acquiring language,” he concluded.
Also, overall intelligence did make a difference, at least for these chess and music students.  Those students with a higher tested IQ, including working memory capacity, were also more likely to end up being experts.
Finally, grit, a determined attitude to succeed, also played a role in creating success.  The term has been made famous by Paul Tough in his book How Children Succeed, based on the research of psychologist Angela Duckworth (see TED talk below).  The desire and passion to get better drives the willingness to spend so many hours practicing a skill.

So, what does all of this mean for the aspiring superstar? That practice, as much as possible, is still a necessary evil to getting better at a sport.  However, it also confirms that different athletes have different qualities and progress through their journey at different paces.  They may need some guidance based on their individual strengths that will help them find the right sport.
“If people are given an accurate assessment of their abilities and the likelihood of achieving certain goals given those abilities,” Hambrick predicted, “they may gravitate toward domains in which they have a realistic chance of becoming an expert through deliberate practice.”

Would You Rather Be A Guitar Hero Or A Golf Legend?

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Gary Marcus
Dan McLaughlin
Despite being a well-respected cognitive psychology professor at New York University, Gary Marcus had a secret ambition; to shred amazing riffs that would make Eric Clapton envious.  The fact that he had been gently told as a child he had no sense of rhythm or tone did not discourage his dream.  With a one year sabbatical from NYU available, he turned himself into a lab experiment of how to teach a middle-aged dog new “licks”.

At about the same time, Dan McLaughlin was growing restless with his career as a commercial photographer in Portland.  However, life as a professional golfer seemed to be the dream destination if only he could find the right path to get there.  

On opposite ends of the country, two guys pursuing different goals but with the same underlying principle; devote a large chunk of dedicated time breaking down and learning complicated skills with the help of experienced coaches.

They had both heard of a theory out there by Florida State psychology professor K. Anders Ericsson that claimed the best performers in a variety of fields had accumulated around 10,000 hours of specific, deliberate practice before they became world-class.  Some took more hours, some less, but on average it provided a rough target to shoot for before expecting magic with a Stratocaster or a five iron.
 While Marcus’ window of full-time learning was limited to one year, McLaughlin estimated he could reach 10,000 hours of structured golf practice in six years or around 2016.  These timeframes seemed to match their respective goals; McLaughlin’s ultimate measure of success would be to actually earn a player’s card on the PGA Tour, while Marcus just wanted to launch a side passion, maybe start a band.

Given his scientific background, Professor Marcus was able to combine his knowledge of learning theory with his quest.  In fact, he documented the entire adventure in his 2012 book, Guitar Zero, which offers a mix of cognitive science, music theory and guitar stories. McLaughlin tracks his progress at his web site, The Dan Plan, (and soon in an upcoming book), where he provides daily updates including the countdown to 10,000 hours (only 6,220 to go!) See their video overviews below.

I recently caught up with both men to compare their methods and their progress:

Gary, are you familiar with Dan McLaughlin’s quest to teach himself golf in 10,000 hours?
Gary Marcus: “I've been meaning to read more about his story; I think he's been more dedicated about logging the specifics of his practice than I have been. But the number of 10,000 hours itself is pretty crude; there are well-documented cases of people becoming chess masters in barely more than 3,000 hours, and others take 25,000. Some depends on genes, but it also depends on how you practice.”

Dan, what about you; did you know of Gary’s journey to be a guitar god?
Dan McLaughlin: “I am familiar with Gary's book although have not personally read it. The writer that I am working with for The Dan Plan's book read Guitar Zero as part of his research and has told me some aspects of his story.  A similarity could be seen in his full-on approach to learning, and perhaps the biggest difference is the time frame.”  

How related is learning the guitar with, say, learning to golf?
Gary: “There are some obvious differences (e.g. great weight on muscle development in golf), but both are complex skills that require extensive neural rewiring. Guitar has its own kind of athleticism, and arguably places greater demands on memory, but in both cases precision is paramount, and one must integrate a great deal of perceptual input in order to perform appropriate motor actions. In both cases, self-discipline is paramount, and some kind of coaching is critical for anyone wishing to be a top performer. Of course, the outfits are better in rock and roll...”

Has your learning progress in golf been pretty linear with gradual improvement every month, or does it go in bursts with plateaus where you stay the same for awhile? 
Dan: “Learning, from what I have experienced, comes in chunks.  This is why putting in time is so crucial, because you never know when the next big learning bump will occur.  Sometimes days will pass where it seems like nothing is being achieved then that will be followed by a period of great momentum.  In the big picture it may be possible to see that learning evens out over time, but when you are in the thick of it the biggest moves always come in bursts.”

Have you had periods where you've gone backwards in your progress?  How do you handle that emotionally?
Dan: “Every time you stretch out your neck to improve the first step is in reverse.  I have yet to make a large change in my swing and immediately see a positive outcome. Rather, when you are in transition, it at first creates errors which are then followed by a slow improvement in consistency and eventually the new move is grooved and the positive results are reaped.  Emotionally, you have to allow for building periods where you know that you will be moving in reverse for a while before you get back to your level and break through to the next.”

Gary: “Learning to cope with failure and to channel into improved performance is an art that any human being ought to develop, no matter what they are learning. Some of that is about setting proper goals, and appreciating progress.”

Both music and golf have “rules” or foundational elements that need to be learned.  How do our brains wire themselves to follow these principles?
Gary: “Music is a special case in that there is a lot of formal knowledge (about music theory) that can be taught, both demand a lot of unconscious knowledge, too. I'm not a golfer, but I wonder whether there are (aside from the formal rules of the game) mathematical principles in golf that are analogous to the principles of harmony and voice leading. Then again, lots of people make beautiful music without any formal understanding of those  rules. (And as in any creative endeavor, the best artists have a good sense of when it is effective to break the rules.)”

In Guitar Zero, you explain that learning a new skill is often spread across multiple areas of the brain. Yet sometimes we hear that specific brain regions are responsible for specific tasks.  Can you help us understand the difference?
Gary: “I think of the brain as being made up of many subcomponents, whereas I think of most things that we know as depending on choosing that right combination of those components for a particular job. Individual bits of brain tissue often do pretty precise things, but do those same things in the service of many different computations.  So-called “muscle memory” is really in the brain, distributed across areas such as somatosensory cortex and the basal ganglia; you don't learn anything unless you've rewired the brain.”

Can there be a transference of guitar skill to a related task like playing a violin?
Gary: “For sure, though I am told that the bow is a whole other dimension. But lots of things about rhythm and pitch and motion and perception transfer reasonably well. Look at people like Prince, Stevie Wonder, Paul McCartney, etc who play loads of instruments well.”

Do you think a person’s genes play a role in being a talented performer?  Are some people just "born with it"?  
Dan: “If your genetics are somewhere in the norm of the bell curve I do not think that genes play a role in being a great golfer.  There are certain limiting factors such as bone structure limiting range of motion or fused joints, but outside of the extremes we are all capable of being great at this sport.  If there was a genetic advantage then there would be a prototype golfer and from what I see golf champions come in all shapes and sizes.”

Gary: You have to have the genes to be Jimi Hendrix, but all you have to do enjoy yourself is to be sufficiently dedicated, and to allow yourself to enjoy the journey, rather than fixating on the destination.

Gary and Dan, thanks so much for your time and we hope to see you on stage and on the leaderboard!

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Aaron Rodgers, Working Memory and 10,000 Hours Of Practice

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Aaron Rodgers Assuming the Packers’ quarterback does not have super-human vision or a time machine, these comments must refer to his ability to recognize opposing defensive formations, adjust quickly to their movements and pick out an open receiver.  It is a skill that all young players would like to have and their coaches would like to teach.
Of course, the ongoing debate in the sports world is if great perceptual awareness and quick decision making are gifts you’re born with or ones you can develop with practice.  The extreme ends of that continuum seem illogical, that a player can excel with no practice or that anyone who practices enough can be a superstar.  Instead, the discussion has turned to the gray area in between looking for the right combination and the direction of causation between the two.
At the center of the debate for the last 20 years, Florida State psychology professor K. Anders Ericsson has held to a theory that enough deliberate practice, described as a focused activity meant to improve a specific skill, can make up for or even circumvent the lack of general, innate abilities.  His research has shown that about 10,000 hours of practice is the minimum required to rise to an expert level of most knowledge domains, including sports.
Now, in a new study published in Current Directions of Psychological Science, psychologists David Z. Hambrick of Michigan State University and Elizabeth J. Meinz of Southern Illinois University Edwardsville examined this interplay between basic abilities, like working memory capacity, and acquired knowledge learned through practice.  “We have been especially interested in the question of whether various forms of domain knowledge moderate the impact of basic cognitive abilities on performance,” the authors wrote.
Working memory is used in complex tasks that require holding information in the mind while also trying to reason or comprehend the environment.  Think of Rodgers remembering the pass routes of all of his receivers while processing the movements of eleven defenders around him.
Hambrick and Meinz wanted to find out if the working memory of domain experts, like Rodgers, has as much as an impact on their performance as their years of deliberate practice and learned knowledge of their specialized world.  Previous research has shown that a person’s working memory capacity is strongly correlated with abstract reasoning, problem solving, decision making, language comprehension, and complex learning.

After a great Aaron Rodgers performance, you will usually hear at least one of two phrases uttered by post-game football analysts, “he has a great ability to see the field,” or “the game has really slowed down for him.”






Back in 2002, Professor Hambrick tested this relationship using a baseball domain.  Participants were first tested on their overall baseball acumen and then completed a complex-scan task to test their working memory capacity.  Complex-scan tests combine information storing with information processing.  An example would be reading a series of sentences aloud while also remembering the last word of each sentence.
After the baseline tests, the volunteers listened to radio broadcasts of baseball games and were asked to remember the major events of the game and specific information about the players.  As expected, those who had a higher baseball IQ did better on the recall test.  However, working memory capacity also had a strong correlation with success. As Hambrick concluded, “Working-memory capacity was as important as a predictor of memory performance at high levels of domain knowledge as it was at low levels.”
In the current study, the domain shifted to piano playing while the results were similar.  Fifty-seven pianists with a wide range of lifetime deliberate practice hours, from 260 to over 31,000, were first given a complex-scan test to measure their working memory limits.  Then, they were given a musical piece that they had never seen before and asked to play it with no practice, called sight-reading.
As the authors reported, “Not surprisingly, we found that deliberate practice was a powerful predictor of sight-reading performance. In fact, it accounted for nearly 50% of the variance. However, we also found that working-memory capacity was a positive predictor of performance above and beyond deliberate practice.”
So, at least in the case of working memory, an ingrained ability does have some importance alongside the hours of practice.  Moreover, deliberate practice that also increases your working memory capacity should yield even better results.  Focused training on improving both the storage and processing of information seems to be the key to better performance.
Of course, for most football analysts, saying a quarterback can now “see the field better” is a little easier than saying “activation of domain knowledge by the familiar context did not reduce the effect of working memory capacity on performance.”

Do Young Athletes Need Practice Or Genetics? A Conversation With Peter Vint

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Recently, while I was taking up my normal Saturday position on a youth soccer game sideline, I overheard a conversation between two parents as they watched the players warm-up. “I just love watching James play soccer.  He’s just one of those natural talents.” “I agree. Even though his parents never played growing up, he just seems to have inherited all the right genes to be a top player.” 

It’s a common belief among parents and some coaches that kids either have “it” or they don’t.  Of course, some skills can be gained from practice, but the talent theory of player development and team selection seems to favor the opinion that athletic skill is “hard-wired”, unable to progress much beyond the natural limit.

Now, several books are out to prove this theory incorrect, with titles such as “The Talent Code: Greatness Isn’t Born, Its Grown”, “Talent Is Overrated”, and “The Genius in All of Us: Why Everything You've Been Told About Genetics, Talent, and IQ Is Wrong.” The common thread through all of the research studies quoted by the authors is the mantra that practice makes perfect. More specifically, about 10,000 hours of highly structured practice is required to reach elite performance levels.

Is athletic success that black or white? Instead, is there a combination of talent and tenacity that is required to reach the top? I put these questions to an expert who spends most of his waking hours trying to find the answer.

Peter Vint
Peter Vint is the High Performance Director for the United States Olympic Committee. His responsibilities include leading and coordinating the efforts of sport science and medical professionals focused on the Olympic sports of swimming, track and field, shooting, equestrian, weightlifting, and golf as well as the Pan Am sports of bowling and water skiing.

His team is responsible for conceptualizing, developing, and implementing successful and sustainable applied sport science programs with a focus on maximizing athlete development, performance, and longevity.

Recently, Peter was kind enough to endure my endless questions on this topic. Here is a synopsis of our conversation:

Dan Peterson: Peter, what makes a great athlete? Is it raw, inherited talent or years of dedicated practice?

Peter Vint: The question of what makes an athlete great is very complex.  The extent to which performance is influenced by genetic predisposition or the expression of these traits through extensive hard work and practice is not at all a black and white issue. Human performance is always nuanced and complicated and multivariate. That said, if forced to give an opinion, I would absolutely fall on the nurture/deliberate practice side of this issue than on the nature/"giftedness" side.

But, whether you subscribe to the narratives in The Talent Code, Talent is Overrated, Bounce, Outliers, Genius in All of Us, etc. or not, a great number of the cited references in these books are solid and substantial. Be sure to review the footnotes and bibliographies.

DP:  Most of the books you reference go back to the research of K. Anders Ericsson of Florida State University, known as the “expert on experts.”  His theory states that an individual needs at least 10 years and 10,000 hours of deliberate practice in their chosen sport or skill to become world-class.  Some authors take this literally and suggest that is all that is needed.  Do you agree?

PV:  First, it’s important to recognize that the 10 year/10,000 hr rule is more of a general guideline than an absolute standard. Ericsson is very clear on this but perhaps owing to the simplicity of the message, it is quite possible that the general public has interpreted this in a more absolute sense. That said, I do think that Ericsson’s work is being somewhat oversimplified in that he, and others in this field, realize that there are obvious and necessary interactions between genetic predisposition, "deliberate practice", and even "opportunity" or circumstance. To what extent this has actually happened I cannot say. I can point to several examples in the popular media where authors have captured these complexities nicely (e.g., Malcolm Gladwell’s Outliers, Matthew Syed’s Bounce, and David Shenk’s The Genius in All of Us).

It is likely that athletes like Lebron James, Shaquille O'Neill, and Kevin Durant would never have become an Olympic gymnast or Triple Crown winning jockey - regardless of how hard or how deeply they practiced. But, how many athletes with a relatively similar genetic makeup to guys like Lebron, Shaq, and KD have NOT become superstars? A lot. And, to flip the coin, how many superstars arise from relative obscurity or against all odds? A lot. Even when we do become aware of "young geniuses", closer inspection often yields interested and engaged and supportive parents and an environment that encourages and supports "effort" - and not "the gift" (see Carol Dweck’s “Mindset” for an exceptional treatment of this topic). Michael Jordan, Wayne Gretzky, and Tiger Woods come to mind.

My feeling in reading a broad body of literature related to human performance is that, in general (and there are notable exceptions to this), there is likely a minimal set of physical traits or genetic makeup which facilitates achievement to a particular level of success. Note that this may not be an absolute necessity (think, Mugsy Bogues). However, I believe the great differentiator in human performance is not genetic predisposition. but rather the expression of the gene pool which is itself now clearly related to the extent to which the individual accumulates hours of "deliberate practice".

I see another common misinterpretation in the 10 year/10,000 hr rule. The literature is clear in this but the general public’s understanding often misses the distinction in that this is not simply accumulated hours of practice, but accumulated hours of DELIBERATE practice. Dan Coyle's introduction in "The Talent Code", "The girl who did a month's practice in 6-minutes" is, in my opinion, perhaps the most insightful example of this distinction I’ve ever read.

DP: So, do genetics play any role in sports success?

PV: My short answer is yes, to varying extents, they do. But, as before, I do not believe that genetics are necessarily an absolute limiter of exceptional performances. "Skill" is developed, not from basic physical or cognitive attributes or from some magical quality ("a gift"), but from sustained, effortful, and effective practice complemented with meaningful, well-timed, and actionable feedback.

Skill itself is a complex process and almost always involves many different types or classes of skill: motor skill (the physical actions involved with "doing something"), mental skills, and perceptual skills. The extent to which these various types of skills are called into play will depend on the overall task being executed.

For example, a pilot controlling an automated aircraft may need only nominal motor skill to press a button, but will require substantial mental and perceptual skill to understand what happens when the automation switches from one mode to another. On the other hand, a basketball player will require extensive motor skill in executing a drive to the basket but will, though to a lesser extent, also involve perceptual and mental skills. Good examples of the world's best players in sport (especially team sports) seem to have exceptionally well developed perceptual skills which allow them to "see the field" better than others and "know where players will be before they even arrive".

So, physical ability (height, strength, speed, coordination) and the specific genetic code which tends to manifest it, may or may not play a significant role in the execution of the skill, depending on what the skill actually requires. The same is true of genetic predisposition, which may either enhance or impair the development of mental and perceptual skill.

In the context of sport, well-matched physical abilities are often very advantageous. That said, those same physical attributes, without an ability to properly coordinate body actions or to properly execute the action at the appropriate time or to adequately control them under pressure or in unusual circumstances, more often than not, will lead to poorer performances. Pointing again to examples like Wayne Gretzky or Magic Johnson, these were not the biggest, fastest, or strongest athletes in their sport. Their exceptional performances came from exceptional development of all facets of the skills they were required to execute in the environments they worked in. This did not happen magically but through hard work, vast and varied experiences, and a level of physical ability that allowed them to execute.  To quote Wayne Gretzky, “I wasn't naturally gifted in terms of size and speed; everything I did in hockey I worked for. ..The highest compliment that you can pay me is to say that I work hard every day…

DP:  Peter, thank you very much for your insight.


See also: Brains Over Brawn In Sports and Winning Olympic Gold With Sport Science

Tiger's Brain Is Bigger Than Ours

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As Tiger Woods heads to Sawgrass for The Players Championship this weekend, mortal golfers wonder what's inside his head that keeps him winning. Well, chances are his brain actually has more gray matter than the average weekend duffer.

Researchers at the University of Zurich have found that expert golfers have a higher volume of the gray-colored, closely packed neuron cell bodies that are known to be involved with muscle control. The good news is that, like Tiger, golfers who start young and commit to years of practice can also grow their brains while their handicaps shrink.

Executing a good golf swing consistently is one of the hardest sport skills to master. Coordinating all of the moving body parts with the right timing requires a brain that has learned from many trial and error repetitions.

In fact, past studies have shown that the number of hours spent practicing is directly related to a golfer's handicap (a calculated number that represents recent playing ability).

Magic number
K. Anders Ericsson, a Florida State professor and the "expert on experts," has spent more than 25 years studying what it takes to become elite in any field, including sports.

The magic number that keeps recurring in Ericsson's studies is 10,000 hours of deliberate practice. If someone is willing to dedicate this amount of structured time on any skill, he has the potential to rise to the top.

Some critics argue that practice is good, but we all start with different levels of innate abilities that put some at an early advantage (i.e. the boy who is six feet tall in fourth grade) While that may be true, Ericsson does not want the rest of us to use that as an excuse. "The traditional assumption is that people come into a professional domain, have similar experiences, and the only thing that's different is their innate abilities," he said in an interview with Fast Company. "There's little evidence to support this. With the exception of some sports, no characteristic of the brain or body constrains an individual from reaching an expert level."

So, what happens to the brain after all of that practice?

In the new study, a team led by neuropsychologist Lutz Jäncke compared the brain images of 40 men divided into four groups based on their experience as golfers. They recruited ten professional golfers (with handicaps of 0), ten advanced golfers (handicaps between 1 and 14), ten average golfers (handicaps between 15 and 36) and ten volunteers who had never played golf (not even mini-golf!).
Interviews revealed the "practice makes perfect" correlation between hours of practice and lower handicaps.

Brain scans (functional Magnetic Resonance Imaging (fMRI) showed that, indeed, there were structural differences, but not in the linear pattern they imagined. While significant differences existed in total volume of gray matter between the pros and the non-players, there was little difference between the pro and the advanced groups or between the average and non-players groups.

When the researchers combined the pros and the advanced golfers into one group called "expert," and the average and non-players into a second group called "novice," a clear dividing line emerged, showing that practice produces a noticeable step up in the brain's gray matter. This jump comes somewhere between 800-3,000 practice hours.

The results were detailed last month in the online journal PLoS ONE.

Step 1: Grow the brain
Another interesting twist is that the pros reported practicing five to eight times more than the advanced group, while the advanced group practiced only twice as much as the average group.

Yet the big jump in gray matter came after golfers achieved a skill level below a 15 handicap, moving from average to advanced. This is consistent with another study in 2008 that measured gray matter volume in students learning to juggle three balls. After learning to juggle for the first time, their gray matter increased. However, once that initial concept was learned, more advanced juggling tricks did not grow more brain cells.

It's been a long time since Tiger's handicap was 15, so clearly the additional years of practice were necessary to reach the top.  And, all of that gray has produced a lot of green.

Please visit my other sports science stories at LiveScience.com