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Physics版 - Interview with Dr. Xi Yin --- By Fiona Rawsontile, Sept 20
相关主题
这个版怎么很少有讨论真物理的.....这些都是什么级别的杂志?
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抢的就是论文排名Openings in Nanophotonics, Plasmonics and Optical Metamaterials
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相关话题的讨论汇总
话题: dr话题: yin话题: fiona话题: theory话题: gravity
进入Physics版参与讨论
1 (共1页)
P*****s
发帖数: 375
1
A nice interview I just read is being shared with you guys here. :)
[ref]
http://fionarawsontile.blogspot.com/2015/09/interview-with-dr-x
Interview with Dr. Xi Yin
By Fiona Rawsontile, Sept 2015
This interview was inspired by an earlier interview of Dr. Yin I saw on the
Internet, which made me think that we can’t expect someone who normally
writes for entertainment to understand a physicist. To “provoke” a
scientist, we need another scientist. So I volunteered (to myself) and sent
an invitation to Dr. Yin, who was recently promoted to Professor in Physics
at Harvard University at the age of 31. It is a great pleasure for me to
share with you his experience and wisdom.
Fiona: As a faculty member at Harvard, you must have met many outstanding
students and researchers. When you recruit students into your lab, what
personal traits or qualification do you particularly look for? What type of
students is an absolute NO? Can you talk about your mentoring style?
Dr. Yin: Indeed, I have interacted with numerous spectacular talents at
Harvard: students, postdoctoral fellows, faculties. It’s one of the best
things about being at Harvard.
I should clarify a few things. First of all, I’m a theoretical physicist
and I work with pens, papers, chalks, and computers. Sometimes I work with
the Harvard supercomputing cluster, but I do not have a lab, nor would I
need one.
Fiona: You reminded me of a joke I read. “I’m a mathematician. All I need
is paper and a trash basket.” “Too bad you are not a philosopher; then you
wouldn’t need the basket.”
Dr Yin: Second of all, unlike many other institutes, in the physics
department at Harvard each faculty does not recruit students directly from
colleges. Each year an admission committee consisting of around ten
professors handle the applicants to our PhD program, with a loose quota in
each subfield. The admitted students will choose their thesis advisors and/
or labs later on. Typically, experimental physicists require more students
to run their labs. We theorists do not depend on or need students as much.
Our students are more independent in their research. While I’m perfectly
happy to collaborate with my students, they are also free to work on their
own projects and publish on their own, if they wish to.
Initially, students that are interested in working with me will come to talk
to me, often towards the end of their first year or during their second
year in graduate school, and ask for research problems/projects. I would
hand them a number of papers to study, and ask them to come back and report
on what they have learned. If they make progress, we will discuss and they
read more, and at some point we arrive at a concrete and interesting problem
to develop and work on. In a way this is also a selection process. About
half of the students who talk to me will not end up working with me. I
rarely turn away a student. The students would turn away on their own if
they do not find it productive to be working with me.
Fiona: Well, your model sounds like a classic Socrates-type mentorship. I
run a biomedical lab, and have to spend a lot of energy in money raising and
management, including motivating or firing employees.
Dr. Yin: I do not require any specific quality of a student, as long as they
have the basic integrity and are capable of getting the job done. One type
of students I definitely do NOT work with are those who pretend to
understand what they don’t know. It’s perfectly okay to be ignorant about
a subject, but it’s not okay to pretend that you know something and you
really don’t.
I think in reality my selection process puts fairly high demands on the
students. All the students I ended up working with have been terrific. I
work quite closely with my students, we discuss our work nearly daily, and I
try to keep all of my students informed on all topics I’m interested in,
even if they are not actively working on it. I believe the students should
not confine their knowledge into a tiny area of their own research, but
rather they should learn broadly and keep their eyes open on all subjects of
interest.
Fiona: The next question is related to your view of the scientific
environment in China. What do you think is the critical advantage
researchers have in top Chinese institutions, such as funding opportunities,
student availability/quality, or the tenure system? On the other hand, what
is the biggest issue that hinders the progress of their research or
prevents them from being recognized internationally?
Dr. Yin: I’m not as familiar with the scientific environment in China as I
should. I believe there is plenty of funding opportunities at top institutes
in China for fundamental research. A key disadvantage, however, is that it
is difficult for a top institute in China to attract high quality foreign
researchers, especially postdoctoral fellows who contribute in an essential
way to the research in my field. It’s no secret that many of the top
talents in Chinese colleges apply to graduate schools in the United States,
leaving a somewhat weak talent pool for graduate schools in China. I am not
familiar with the tenure system in China.
I have observed that there is a huge disparity between faculty members of
different levels in China, in terms of privilege as well as salary. I
believe this is deeply unhealthy and hinders the scientific progress
tremendously. I strongly favor the Israeli academic system (which in my
opinion is better than that of the US), where all faculties have a flat base
salary, with bonus each year based on their productivity and the quality of
their works. Such a system stimulates a collaborative atmosphere and curbs
unhealthy competitions. Professors should never have to worry about their
salaries and administrative duties. They should be able to focus entirely on
research and teaching.
Fiona: A flat base salary model may be difficult to implement in the US
because of the huge variation of living costs in different areas of the
country, but hopefully there are other ways of promoting equity. Anyway, as
a physicist, what would you say is the most important personality for your
success, such as curiosity, vision, imagination, or persistence? (You don’t
have to choose from the list.) Do you have a life-long goal you’d like to
achieve, such as solving a long-existing problem, establishing a new area,
or educating the public?
Dr. Yin: I would say the one personality of mine that benefits my scientific
work is that tendency of being obsessive. When I’m onto a problem, I can
skip meals and sleep and work tireless until I’m satisfied. I would have a
hard time going to sleep, say, when I know that there is a mistake in my
work and I haven’t been able to identify it.
Fiona: Obsessive. You reminded me of what Oscar Wilde said, “Moderation is
a fatal thing. Nothing succeeds like excess.”
Dr. Yin: I do have a few long standing problems in my mind, that I
contemplate from time to time. However, my experience in research is that,
more often than not, ground breaking work originates from attempts of
patching up a tiny hole. I spend most of my time patching up tiny gaps in
our knowledge here and there. It often happens that progress in these little
problems leads to major breakthroughs.
My style of research is probably more known for problem solving than for
establishing a new area of research. I wouldn’t mind doing the latter, but
I don’t seem to be particularly good at it. What I really like to do is to
solve a problem that many people have looked at and thought about but could
not solve. If I happen to invent a new method and open up a new direction of
research while doing so, it would be icing on the cake.
Fiona: So you like String Theory. I’m a biomedical engineer. Could you give
me a reason why I should care about it? About gravity, Einstein said it’s
space-time curvature; quantum mechanics says it’s executed by gravitons (
correct me if I’m wrong). How do you reconcile the two interpretations?
Dr. Yin: Don’t you want to know what is the tiniest, most fundamental
building block of our universe? What lies beyond the standard model of
particle physics? Are quarks and leptons truly fundamental particles or do
they have internal structures?
One may say that such questions are endless and you could always try to
divide things up further and it never ends. While this could have been the
case in the world of particle physics without gravity, it cannot be so in
the world of quantum AND gravity. Here is why. In the quantum world, it
takes energy to probe short distances, or “divide stuff into small pieces”
. The energy it takes is inversely proportional to the size. Roughly
speaking, the energy it takes to probe a certain tiny distance scale is of
order the Planck constant times the speed of light, divided by the distance
scale of question. This is why to make tiny new particles we need huge
particle accelerators, like the Large Hadron Collider. That is all fine, but
in a world with gravity, a large amount of energy cannot stay confined in a
tiny space. This is because energy is mass (according to the famous
equation E=mc^2 you see on T-shirts), and mass gravitates, and when there is
enough mass in a small volume of space, it makes a black hole. To the
outside observer, a black hole is as big as its horizon, and the horizon
size grows with the mass (or energy) of the black hole. Now you see, gravity
does not want you to probe arbitrarily short distances. You might take this
as a hint that perhaps there is a fundamental size after all, beyond which
there is no structure. Well, to understand all of this, you need string
theory. :)
Regarding your question of reconciling the classical description of gravity
as spacetime curvature and the quantum nature of gravitons, it does not
touch the essence of quantum gravity and is in fact well understood within
the framework of quantum field theory. The question is not different in any
essential way from reconciling the description of electromagnetic fields and
photons. The answer is that the notion of “field” (or curvature of
spacetime, in the context of gravity) may be viewed as a classical
approximation of a certain type of quantum states, known as coherent states,
that are superpositions of states involving many photons (or gravitons) in
such a way that they exhibit semi-classical behavior.
Fiona: I still can’t perceive gravity in the same way of an electromagnetic
field and photons. For example, if, for any bizarre reason, a heavy item is
suddenly “born” at a particular point of space, the rest of the universe
would not instantly know its existence, because gravitons have to travel at
speed of light? That is, we cannot be “attracted” by something before we
can “see” it?
Dr. Yin: Firstly, one has to be careful in asking hypothetical questions in
physics, because the laws of physics do not leave much room for
modifications. One could easily arrive at inconsistent and contradictory
conclusions based on faulty assumptions. The conservation of energy and
momentum is essential for a consistent theory of gravity, just as the
conservation of charge is essential in electromagnetism.
It is true that, if the sun explodes for some reason, we would only perceive
the resulting gravitational disturbance eight minutes later, the same
amount of time it takes for light to travel the distance from the sun to the
earth. In this perspective, gravity is not all that different from
electromagnetism, if you substitute charge with mass.
One thing that makes gravity different, however, is that Einstein’s
equations of gravity are nonlinear, whereas Maxwell’s equations of
electromagnetism are linear. This nonlinearity makes the equations of
gravity a whole lot more complicated. However, the nonlinearity of Einstein
’s equations is important only in the presence of strong gravitational
fields, and allows for all sorts of bizarre phenomena such as black holes.
Your question though is really about classical gravity, which to the first
order approximation was understood by Einstein in 1915 (even though it took
decades to verify experimentally various aspects of his theory). The
questions string theorists are tackling are really about quantum gravity,
and effects of quantum gravity are expected to be important only in the
presence of extremely high energy and/or extremely strong gravitational
fields.
Fiona: In our field, theorists often collaborate with experimenters. Does
your study depend on such collaborations? Have you proposed any hypothesis
that you really want to verify experimentally but are unable to do so due to
technological infeasibilities?
Dr. Yin: The short answer is no, and we make up for the lack of experiments
with mathematical rigor.
Physics is the most mature among all subjects of natural science. We have
come to understand the theory so well, to the point that the very logical
and mathematical consistency of the theory itself leaves little room for
adjustments. We are not talking about models of economics where you can
adjust parameters here and there to fit experiments. The laws of physics are
supposed to be absolute. If there is any small violation of the laws of
physics by any experiment, the entire foundation of modern physics could be
shattered and we would have to rethink everything. This has happened a few
times in history, most notably the black body radiation and the constant
speed of light, which shattered Newtonian physics and paved the way to
quantum mechanics and relativity.
Now just because we know the principles doesn’t mean we know what theory is
exactly. For instance, the theory of quantum electrodynamics is based
simply on the principle of quantum mechanics and relativity, but it took
decades and works of thousands of brilliant physicists to understand how to
calculate and make experimental predictions with this theory. Eventually,
the theory was proven to be successful, perhaps more successful than any
other theory in the history of mankind. For instance it successfully
predicted the anomalous magnetic moment of the electron to eleven digits. As
a layman’s analogy, that is better than predicting the exact number of
human population on the earth, to the accuracy of a single person.
In modern theoretical physics, we don’t simply fit models with data or come
up with new hypothesis. We try to understand what the theory is based on
its own mathematical consistency, and its compatibility with basic
principles that we believe to hold absolutely. We are driven not by the need
to explain a certain piece of experimental data, but rather questions like
“what is the cross section of graviton scattering at Planck energy?” and
“what is the state of a black hole at the end of Hawking evaporation?”
There are a number of deep theoretical puzzles that drive us to advance our
understanding of the theory itself.
That is not to say we know for sure that string theory is correct. We would
like to understand how quantum gravity works, and string theory is the only
theory known to mankind that works, and it works beautifully. Over the last
two decades we have learned that the mathematical structure of string theory
is inevitable in the study of quantum field theories, and quantum field
theory is our establish framework that explains all phenomena of particle
physics to date.
I personally think we don’t understand string theory well enough yet to
even attempt a direct comparison with experiments in particle physics and
astrophysics. On the other hand we are learning tremendous fundamental
physics by studying string theory, and it gave us deep insights into other
fields as well, such as nuclear physics, condensed matter physics, and even
fluid dynamics.
That being said, I am interested (as a side project) in aspects of fluid
dynamics that involves turbulence, and the possibility of applying quantum
field theory to understand the universality of turbulence. In this case
experimental data would be helpful, but really what we need is computer
simulations (which could be called experiments by the theoretical physicists
’ standard).
Fiona: Truth is objective, but the pursuing of it, which we call scientific
activity, is imprinted with human characters. Is there someone who had a
significant influence on your professional life, without whom you might have
become a different individual?
Dr. Yin: There are a few people that have made significant impact on my
research career. One of them is my PhD advisor Andy Strominger. He has the
inimitable skill of reaching deep conclusions with the simplest possible
calculation, and he has a terrific taste in telling the good physics from
the bad ones.
Another person that shaped my approach to research is Davide Gaiotto, with
whom I had collaborated extensively while he was a postdoctoral fellow at
Harvard. He is now a faculty at Perimeter Institute and one of the stars of
my field. One thing I learned from him is that, when you don’t know where
to start in trying to solve a problem, don’t look around. Go to the
blackboard, start writing down equations. You are probably wrong initially,
but little by little you will correct them, until when things click.
Fiona: The academic system in the U.S. is generally reasonable and
functioning, albeit not perfect. What aspects would you like to see change,
including, but not limited to, job recruitment, peer reviewing, tenure, etc.?
Dr. Yin: The academic system in the US is quite tough on the young people,
partially due to the publish-or-perish culture. Junior researchers are often
forced to work on topics in which they can be productive in terms of
publications, and are discouraged from taking risks on truly original and
unexplored research directions.
In my field there are extremely few faculty jobs compared to the number of
PhDs awarded each year. (Fiona sighed. “Dare I say this is the case for a
lot of majors now!”) Many tremendously talented physicists spend years
working as postdocs, which is quite difficult for those who have families
especially kids, due to the constant need for relocations. And still, in the
end most of them are forced to leave academia due to the lack of faculty
position openings.
I would say the peer reviewing system in my field is acceptable but very,
very far from perfect. In certain fields such as mathematics, research
papers are put to great scrutiny before publication. Proofs are checked line
by line. This is possible only when people don’t write many papers.
Physicists tend to write a lot more papers than mathematicians. It is
difficult and impractical for every physics paper to be inspected and
verified line by line before its publication. The peer review system does
little more than filtering out crackpots. In my field, the quality of a
research paper is not judged based on the journal on which it is published,
but rather through a reputation that is built based on seminars, private
discussions, and follow-up works. Most of the time, the truly important and
original papers do become known to the community, and that’s what matters
in the end.
I think I’ve made a number of complaints here, with no immediate solutions
to offer. I enjoy working in the field of string theory, particularly
because in our community people are open with sharing ideas (often before
publication) and most of us value the progress in our field more than the
assignment of credits on a piece of publication.
Fiona: Has your Chinese background (cultural, educational) influenced your
career, in either positive or negative ways? Do you have particular advice
for Asian scientists who strive in the Western academia?
Dr. Yin: I think my ethnic background has had zero influence on my career. I
feel completely comfortable living and working in the US, as well as during
my extended visits to India, Israel, and Japan. I never feel tied to a
certain place. I think Asian students tend to focus too much on course work
and do not spend enough time socializing and live a balanced life. I’m an
introvert myself, but I can be social when I need to be. I see many
successful Asian scientists in the US, and I don't think they need any
advice from me. Go vote, that’s my only advice to Asians in this country.:)
Fiona: All right. Thank you so much, Dr. Yin, for taking the time to offer
us your invaluable insights. Is there anything else you would like to share
with us that hasn’t been covered by the above topics?
Dr. Yin: The other day I receive an email which was practically a dating/
marriage proposal. While flattered, I would like to clarify that I have been
happily married for 10 years and my daughter is 7 years old and she loves
AC/DC. I enjoy rock climbing so if anyone goes to Rumney, NH I’d gladly
join and partner up.
-end-
P**********l
发帖数: 310
2
一个外国人,反复问尹西对中国的看法。尹西很谨慎,一个劲说“我不知道”。最后来
了个“I think my ethnic background has had zero influence on my career”。难
道尹西教授不知道这里ethnic background是浮点数,再尚未明确最小浮点数取值的时
候,不能随便说zero?我觉得尹西是谨慎过头了,但是现在媒体普遍捕风捉影抓中国间
谍,尹西这种做纯理论的,也不得不防呀。

the
sent
Physics

【在 P*****s 的大作中提到】
: A nice interview I just read is being shared with you guys here. :)
: [ref]
: http://fionarawsontile.blogspot.com/2015/09/interview-with-dr-x
: Interview with Dr. Xi Yin
: By Fiona Rawsontile, Sept 2015
: This interview was inspired by an earlier interview of Dr. Yin I saw on the
: Internet, which made me think that we can’t expect someone who normally
: writes for entertainment to understand a physicist. To “provoke” a
: scientist, we need another scientist. So I volunteered (to myself) and sent
: an invitation to Dr. Yin, who was recently promoted to Professor in Physics

h********0
发帖数: 12056
3
你太多虑了。 在乎那些社会垃圾想什么说什么没意思,做自己想做的事。
高妹这个采访是目前最好的, 有些评论者就是随便瞎说。
尹西是毫无疑问非常出色, 他对自己有很好的定位,
用别人操什么心。

【在 P**********l 的大作中提到】
: 一个外国人,反复问尹西对中国的看法。尹西很谨慎,一个劲说“我不知道”。最后来
: 了个“I think my ethnic background has had zero influence on my career”。难
: 道尹西教授不知道这里ethnic background是浮点数,再尚未明确最小浮点数取值的时
: 候,不能随便说zero?我觉得尹西是谨慎过头了,但是现在媒体普遍捕风捉影抓中国间
: 谍,尹西这种做纯理论的,也不得不防呀。
:
: the
: sent
: Physics

M**a
发帖数: 4
4
采访者是faculty版的Highly,中国人

【在 P**********l 的大作中提到】
: 一个外国人,反复问尹西对中国的看法。尹西很谨慎,一个劲说“我不知道”。最后来
: 了个“I think my ethnic background has had zero influence on my career”。难
: 道尹西教授不知道这里ethnic background是浮点数,再尚未明确最小浮点数取值的时
: 候,不能随便说zero?我觉得尹西是谨慎过头了,但是现在媒体普遍捕风捉影抓中国间
: 谍,尹西这种做纯理论的,也不得不防呀。
:
: the
: sent
: Physics

q*d
发帖数: 22178
5
哪纯英文的名字咋回事,
嫁给老外了?

后来
。难
的时
国间

【在 M**a 的大作中提到】
: 采访者是faculty版的Highly,中国人
s********l
发帖数: 439
6
据说是她写小说用的笔名

【在 q*d 的大作中提到】
: 哪纯英文的名字咋回事,
: 嫁给老外了?
:
: 后来
: 。难
: 的时
: 国间

s*******n
发帖数: 1474
7
著名的高妹教授,同时还是科幻小说作家,全英文的写了好几部了
amazon有售
笔名菲欧那

【在 q*d 的大作中提到】
: 哪纯英文的名字咋回事,
: 嫁给老外了?
:
: 后来
: 。难
: 的时
: 国间

1 (共1页)
进入Physics版参与讨论
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引力场的速度超过光速么Opening Positions in Nanophotonics, Plasmonics and Optical Metamaterials
抢的就是论文排名Openings in Nanophotonics, Plasmonics and Optical Metamaterials
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话题: dr话题: yin话题: fiona话题: theory话题: gravity