What is the main topic of the presentation?

The presentation discusses the quantum properties of phonons, focusing on their angular momentum, magnetic properties, and applications.

Who is the speaker and what are her qualifications?

The speaker is Swathi Chaudhary, who has a BSc from Delhi University, an MSc from IIT Kanpur, and a PhD from Caltech.

What are chiral phonons?

Chiral phonons are phonons that exhibit a circular motion and can carry angular momentum related to the polarization.

How do phonons contribute to magnetic moments?

Phonons can contribute to magnetic moments through mechanisms like orbital-lattice coupling, which allows them to couple with electronic states.

What materials are discussed in relation to phonons?

The discussion touches on various materials with significant phonon behavior, including certain types of magnets and topological materials.

What are the applications of phonon angular momentum?

They can generate effective magnetic fields, enhance thermal transport, and influence electronic transitions.

How can phonon magnetic moments be measured?

Phonon magnetic moments can be measured using techniques such as spectroscopy and monitoring the shifts in energy levels upon external perturbations.

What is the significance of orbital-lattice coupling?

Orbital-lattice coupling is significant because it can lead to unexpectedly large phonon magnetic moments due to the interaction between lattice vibrations and electronic states.

What experimental results were highlighted?

Recent experiments have shown large phonon magnetic moments in certain materials, which correlate with theoretical predictions.

What areas does the research open up for future exploration?

The research suggests avenues for investigating phonons in new materials, exploring their potential applications in next-generation electronics.

QuIC Talk by Swati Chaudhary: Phonons with angular momentum: Magnetic properties and applications

00:52:19

https://www.youtube.com/watch?v=QaFJlnLMhts

Summary

TLDRSwathi Chaudhary, an accomplished researcher, presents on the angular momentum of phonons, exploring their magnetic properties and applications in materials science. She explains how phonons can exhibit angular momentum and contribute to magnetic moments through mechanisms such as orbital-lattice coupling. The talk outlines various materials where these effects can be observed and emphasizes the potential applications of chiral phonons in electronics, thermal transport, and controlling magnetization using ultrafast technologies. Chaudhary provides a comprehensive overview of theoretical models, experimental results, and the implications of her research for future advancements in the field.

Takeaways

🔍 Phonons can exhibit angular momentum and magnetic moments.
💡 Chiral phonons display unique magnetic properties that can be useful in practical applications.
📊 Orbital-lattice coupling explains how phonons can have significant magnetic moments in certain materials.
🌌 The research opens up avenues for new materials and applications in electronics and thermal transport.
🔬 Magnetic properties of phonons can potentially enhance magnetization control in ultrafast technologies.

Timeline

00:00:00 - 00:05:00
Introduction of Swathi Chaudhary as the speaker, highlighting her academic journey and experience in quantum information and her current focus on phonons and their properties.
00:05:00 - 00:10:00
Overview of the presentation on phonon angular momentum, chirality, and its magnetic properties and applications, setting the stage for an in-depth discussion.
00:10:00 - 00:15:00
Explanation of phonon momentum and how it contributes to phenomena such as chirality in phonons, leading to the exploration of their magnetic moments and mechanisms.
00:15:00 - 00:20:00
Introduction to a microscopic model for understanding orbital lattice coupling and its implications for magnetic moments in various materials, along with group theoretic aspects.
00:20:00 - 00:25:00
Definition and significance of angular momentum in photons and phonons, including the derivation of angular momentum from lattice vibrations and potential physical implications.
00:25:00 - 00:30:00
Discussion on circularly polarized phonons and their interactions with magnetic fields, presenting examples and exploring their unique properties in different materials.
00:30:00 - 00:35:00
Investigation of mechanisms behind the emergence of substantial magnetic moments in phonons, comparing classical predictions with experimental observations in various types of magnetic materials.
00:35:00 - 00:40:00
Presentation of a theoretical framework addressing how phonons can couple with electronic states, leading to higher-than-expected magnetic moments observed in experiments.
00:40:00 - 00:45:00
Consideration of potential applications in electronics, thermoelectrics, and advanced materials, outlining the promise of circularly polarized phonons in device technology and thermal transport capabilities.
00:45:00 - 00:52:19
Conclusion summarizing the key findings and future directions for research on phonon angular momentum, highlighting the importance of understanding these materials for practical applications.

Mind Map

Video Q&A

What is the main topic of the presentation?
The presentation discusses the quantum properties of phonons, focusing on their angular momentum, magnetic properties, and applications.
Who is the speaker and what are her qualifications?
The speaker is Swathi Chaudhary, who has a BSc from Delhi University, an MSc from IIT Kanpur, and a PhD from Caltech.
What are chiral phonons?
Chiral phonons are phonons that exhibit a circular motion and can carry angular momentum related to the polarization.
How do phonons contribute to magnetic moments?
Phonons can contribute to magnetic moments through mechanisms like orbital-lattice coupling, which allows them to couple with electronic states.
What materials are discussed in relation to phonons?
The discussion touches on various materials with significant phonon behavior, including certain types of magnets and topological materials.
What are the applications of phonon angular momentum?
They can generate effective magnetic fields, enhance thermal transport, and influence electronic transitions.
How can phonon magnetic moments be measured?
Phonon magnetic moments can be measured using techniques such as spectroscopy and monitoring the shifts in energy levels upon external perturbations.
What is the significance of orbital-lattice coupling?
Orbital-lattice coupling is significant because it can lead to unexpectedly large phonon magnetic moments due to the interaction between lattice vibrations and electronic states.
What experimental results were highlighted?
Recent experiments have shown large phonon magnetic moments in certain materials, which correlate with theoretical predictions.
What areas does the research open up for future exploration?
The research suggests avenues for investigating phonons in new materials, exploring their potential applications in next-generation electronics.

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Subtitles

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00:00:00
so welcome to the come to this uh
00:00:01
Quantum information and Program start
00:00:03
quick talk so today we have a swathi
00:00:07
swathi Chaudhary as our speaker so
00:00:10
swathi did her BSC from Delhi University
00:00:14
in 2013.
00:00:17
her MSC is from IIT kanpur so yeah she
00:00:20
is wrong
00:00:21
I'll see if it is that in 2015
00:00:25
condensy finished at a PhD from Caltech
00:00:29
in 2021 and she has been a poster joined
00:00:33
me at the University of Texas Austin at
00:00:35
Northeastern University in US
00:00:37
and today's he's talking about
00:00:42
yes who announced with anger momentum
00:00:44
magnetic properties and applications
00:00:49
good afternoon everyone first of all I
00:00:52
would like to thank you to organizers
00:00:54
and Island for inviting me for this room
00:00:57
I'm really grateful for this opportunity
00:00:59
and it feels really good to be here
00:01:01
so today I will talk about phone on
00:01:06
angular momentum about their magnetic
00:01:09
properties and applications
00:01:12
so uh first I will uh try to describe
00:01:15
momentum of phonons then I will talk
00:01:17
about something called chirophonouns and
00:01:19
how they respond to different physical
00:01:21
uh students and then I will talk about
00:01:23
Magnetic Moment of chiroponomes and the
00:01:26
mechanism for this form of chirality and
00:01:28
Magnetic Moment uh then I will present a
00:01:31
microscopic model for orbital lattice
00:01:33
coupling like how this Magnetic Moment
00:01:35
arises from orbital that is covering in
00:01:37
certain cases then we will talk about
00:01:39
different materials where this kind of
00:01:41
latoscopic mechanism can manifest very
00:01:44
briefly I would also touch on group
00:01:46
theoretical aspects of Californians
00:01:47
which would provide us some insight
00:01:49
about what kind of materials these
00:01:51
hormones can occur in and then what
00:01:53
applications
00:01:54
so to start with what is environmental
00:01:58
I'm not going to give you a definition
00:01:59
but
00:02:01
um you'll know
00:02:03
um well we have an answer in this book
00:02:05
so I don't say for me what is angular
00:02:08
momentum it's the second most important
00:02:10
topic in this book and it's the most
00:02:12
difficult topic I think so I think the
00:02:15
first the most important topic is
00:02:17
hormone incarcerative
00:02:19
um
00:02:20
where we know that um angular momentum
00:02:23
is very important for lab course and
00:02:25
nuclei and different kind of
00:02:28
accompanying between different kind of
00:02:30
angular momentum is at the heart of very
00:02:32
exotic phenomenal physics whether it's
00:02:34
high profile splitting fine splitting or
00:02:37
magnetism in multiples
00:02:39
but Magnetic Moment sorry angular
00:02:41
momentum is also important for photons
00:02:46
so we know that photons can carry
00:02:48
something called momentum
00:02:50
which arises from the circular motion of
00:02:53
polarization factors so if you look at
00:02:55
the cross section of this wheel and if
00:02:58
you have like a circle or equalized beam
00:02:59
then the polarization Vector moves in a
00:03:01
closed group and that gives it its
00:03:03
Preamble momentum depending on whether
00:03:05
it's rotating in lab circular manner or
00:03:08
rights of permanent and if you look at
00:03:10
this perception that at any two points
00:03:12
if you assume that the pen is correct
00:03:13
enough then this polarization Vector is
00:03:16
moving in the face like both of them are
00:03:18
normally increase on the other hand it
00:03:21
was realized like about 30 years ago
00:03:23
that angular momentum can also arise
00:03:25
from the spatial distribution of this
00:03:27
so if I take a cross-section of beam and
00:03:30
I look at two different points on this
00:03:32
cross section you can have situation
00:03:34
with cold digestion factor is holding in
00:03:35
the same direction but there's a phase
00:03:38
difference and that gives rise to
00:03:40
orbital angular momentum of photos
00:03:43
similarly it's proposed that phonons can
00:03:47
also have angular momentum for example
00:03:49
you can have circular motion of ions
00:03:51
which can give rise to something similar
00:03:53
to spin ambulance
00:03:55
or you can have a situation where the
00:03:58
lattice displacement and neighboring
00:04:00
atoms has some facingness
00:04:02
it's not exactly similar to OEM beams
00:04:04
because we have a discrete lattice here
00:04:06
we have some rotational symmetries which
00:04:08
kind of restricts the values of L that
00:04:11
are allowed in this case for example if
00:04:12
you have like some C and pole symmetry
00:04:14
like n Fold rotation then you can have
00:04:16
angular momentum zero one two n minus
00:04:19
one
00:04:25
so what is the angular momentum of this
00:04:28
uh like what is the angular momentum of
00:04:30
fall on if I take one circular one
00:04:32
phonon which describes the circular
00:04:35
polarized lattice vibration like the
00:04:37
contest form of that circulator is
00:04:39
vibration what is the format
00:04:42
let's first consider this classical
00:04:44
picture here we have this phonon
00:04:47
displacement which is described by this
00:04:48
you want to do these are like the atoms
00:04:51
in your unit cell and I am going to
00:04:54
focus on your Zone centered hormones
00:04:56
so we can top only in terms of limit
00:04:58
cells let's say we have some no recorded
00:05:00
queue which we can write as Q sine Omega
00:05:02
T cosine Omega in X in y direction
00:05:05
so this um
00:05:07
so this that is vibration would have an
00:05:10
angular momentum Omega Q Square
00:05:12
now assuming classical harmonic
00:05:14
vibration energy for unit cell Omega
00:05:16
Square Q Square then we can get number
00:05:17
of phonons and we can show that this
00:05:19
angular momentum is H quite identical so
00:05:22
we can say like what panta associated
00:05:24
with this circular polarized vibration
00:05:26
has an angular momentum of one Edge
00:05:28
similarly we can also use this Quantum
00:05:30
picture where we express these normal
00:05:32
coordinates in terms of creation and
00:05:34
Annihilation operators and the same
00:05:36
thing for velocity and then also uh we
00:05:40
can write down the circle
00:05:41
and superposition of X and Y motions and
00:05:45
then we can show that the samplement
00:05:46
should be shooting plus minus H bar
00:05:50
so
00:05:51
um now I have showed like this should
00:05:53
carry an argument of plus minus H bar
00:05:56
um
00:05:57
so how do I get these forms
00:05:59
so this Omega comes out of the natural
00:06:03
material characters
00:06:07
so it's the the frequency of the phone
00:06:09
on that we're considering and also like
00:06:11
I am taking only one standard phonons
00:06:13
and for now I am focusing on your
00:06:15
Optical formulas
00:06:19
so it would be like something in the
00:06:21
range of like 10 to 100
00:06:25
so now you can uh get this kind of
00:06:27
motion by uh getting the superposition
00:06:30
of like X and Y bonds like vertical
00:06:33
motion Chronos for example but in most
00:06:35
cases these two superpositions will have
00:06:38
the same energy
00:06:39
but some in in some cases you can get a
00:06:42
scenario where the two phonons naturally
00:06:44
polarized and right Circle and polarized
00:06:46
hormone they get different energy right
00:06:49
there's a speeding of these phonons
00:06:54
when the energies associated with rights
00:06:56
are really polarizing lab circularly
00:06:58
polarized forms are different so these
00:07:01
phonons are obtained from like e
00:07:03
generator
00:07:05
and then like there can be some internal
00:07:08
mechanism which can be interested
00:07:12
um actually this
00:07:17
is to break in person symmetry or they
00:07:20
can break at the center of your video
00:07:22
John if you break families
00:07:25
recently there has been a lot of
00:07:27
interest in studying this kind of
00:07:28
phonons for example these works both of
00:07:31
these Works have so the first one is the
00:07:33
theory work where they discuss the
00:07:35
angular momentum of very very
00:07:36
correlation so you have a honeycomb
00:07:38
lattice
00:07:40
um and you have some very colors so
00:07:42
these are the hormones which come with
00:07:44
some finite momentum
00:07:46
at high 30 points
00:07:51
that can be different than two and that
00:07:53
would be different
00:07:55
literally in this science work it has
00:07:58
been devastated this kind of hormones
00:08:00
have been demonstrated experiment where
00:08:02
they assist some excitations which are
00:08:05
otherwise stored allowed
00:08:09
so what makes these hormones interesting
00:08:11
is how they respond to different current
00:08:13
quantities
00:08:14
for example the couple to circulatory
00:08:17
polarized light in some materials they
00:08:19
show Circle dipoism they show like
00:08:21
different absorption for right relaxed
00:08:24
life in some cases they show you
00:08:28
[Music]
00:08:35
for me the most interesting part is
00:08:37
their magnetic Behavior
00:08:39
so they coupled with magnetic field and
00:08:42
this coupling is chirality dependent and
00:08:44
they can also Exhibit C van impact
00:08:48
another related process is foreign
00:08:58
cases they can generate a very large
00:09:01
effective magnetic field uh in this
00:09:03
paper it was shown that you can generate
00:09:05
a magnetic field as large as stupid as
00:09:07
the uh by exciting such phonons which is
00:09:10
very high and you can also get like some
00:09:13
other analogs
00:09:16
for example
00:09:18
so today I am going to focus on
00:09:21
magnetophononic processes I would
00:09:23
discuss how strong is discovering and
00:09:25
what is the mechanism behind
00:09:28
Instagram so first of all why should
00:09:30
these circularly polarized hormones
00:09:31
coupled to magnetic field let's consider
00:09:34
a simple classical scenario so I have
00:09:37
some ionic solid where we have different
00:09:40
files with different charges and they
00:09:42
are moving in circular motion
00:09:44
so if they are moving in circular motion
00:09:46
then you would expect them to move like
00:09:48
they have some angular momentum but they
00:09:50
will also have some magnetic mode and
00:09:52
now we can calculate the magnetic
00:09:54
moments of this full phone on by
00:09:56
including like different ions and then
00:09:58
from there we can say that this angular
00:10:01
momentum would be of the order of
00:10:03
nuclear magnetism in fact right some
00:10:05
more disorder but if you choose your
00:10:07
system carefully you can get some
00:10:10
Magnetic Moment as high as seven of
00:10:13
nuclear Magneto and nuclear Magneton is
00:10:16
like 2000 times smaller than Burma
00:10:19
so now if we look at phonology matter of
00:10:21
fact then you would get a very big
00:10:23
display for example even activated Tesla
00:10:26
with seven nuclear magnetism
00:10:31
because 0.002
00:10:35
so on the basis of the simple classical
00:10:36
picture we should expect that the phonon
00:10:40
G Factor would be much smaller
00:10:43
would be smaller than this movement too
00:10:45
so
00:10:46
on the other hand there are some
00:10:48
experimental books so these are some
00:10:49
very old experimental goals for 1970s
00:10:52
and these are on Rare Earth paramagnets
00:10:55
we have this
00:10:56
ethereum 3 positive ion which has one
00:10:58
electron in four effort
00:11:00
and this material shows this kind of
00:11:03
split enforce
00:11:04
enforcements with a Magnetic Moment of
00:11:06
the order of like seven more
00:11:09
and similarly there are like a lot of
00:11:11
materials in this class which show
00:11:14
similar magnetic moments of the order of
00:11:17
format
00:11:19
in fact most recently there has been
00:11:23
some works on some topological materials
00:11:25
where similar kind of Magnetic Moment
00:11:29
has been observed for phonos for example
00:11:31
in this work on Latin calorie which is
00:11:35
insulator once you have enough
00:11:37
doping with the skin then we see that as
00:11:42
we change
00:11:45
this is
00:11:47
and that line shows the condition
00:11:50
the topological and normal
00:11:52
so
00:11:54
in this material like once you go into
00:11:56
this um topological phase you get some
00:12:00
phonons which have a Magnetic Moment
00:12:03
again of the order of government
00:12:05
and similarly this another material
00:12:07
which is atroxima material you can see
00:12:09
this is spreading of left hand and right
00:12:11
and phones again with the Magnetic
00:12:14
Moment of core magnet
00:12:15
so this raises the question where is
00:12:17
this magnetic model coming from if we
00:12:20
expect that on the basis of the simple
00:12:21
classical picture we should get some
00:12:24
Magnetic Moment of the order of nuclear
00:12:26
Avenue but what we are seeing
00:12:27
experimentally it's much higher
00:12:30
so where is this family moment coming
00:12:33
well and so the order of Bohr Magneton
00:12:35
so it kind of indicates that there is
00:12:38
some contribution from electron still
00:12:41
somehow electrons are contributing to
00:12:43
this matter
00:12:45
and in fact many different mechanisms
00:12:47
have been identified to account for this
00:12:50
very large Magnetic Moment performance
00:12:54
so in first case this Magnetic Moment
00:12:56
comes from electronically
00:12:58
which can be explained within the bone
00:13:00
Oppenheimer approximation so you have a
00:13:02
phone on you it is you excite some
00:13:05
lattice vibrations and then your
00:13:07
laparing system forward adiabatically if
00:13:09
your electronic bands have some
00:13:10
non-people topology they accumulate some
00:13:13
orbital magnetization and that continues
00:13:17
and for those paramagnets that I would
00:13:19
I'm showing you in that case it arises
00:13:22
from coupling with electronic side
00:13:23
issues which
00:13:26
and similarly for this drug symmetry it
00:13:29
arises from the company with Cyclone
00:13:31
resonances so you have a drug dispersion
00:13:33
once you apply magnetic field you get
00:13:35
these Lambda labels and non-honors can
00:13:38
couple to the excitations with
00:13:41
the different today I am going to focus
00:13:42
on this electron insidation mechanism
00:13:45
it's a non-edible
00:13:47
open Hardware approximation
00:13:53
so this mechanism operates in these rare
00:13:55
paramagnets where phones support to
00:13:58
crystalline
00:13:59
foreign
00:14:01
we asked whether this mechanism can also
00:14:03
occur in some other materials
00:14:06
for example can it occur in some new
00:14:07
orbital magnets and can it occur in some
00:14:10
other magnets where you have like some
00:14:12
kind of super extreme interactions
00:14:15
and is it possible to estimate this
00:14:18
estimate value of this orbital lattice
00:14:20
coupling estimate the value of this
00:14:22
phonon magnetic movement from a
00:14:24
microscope
00:14:25
so those Works had provided a model but
00:14:27
they did not provide a microscope model
00:14:29
to estimate those
00:14:32
bags so so first I will describe the
00:14:35
model which accounts for this phonon
00:14:37
Magnetic Moment arising from orbital
00:14:39
lattice coupling so it's a
00:14:41
generalization
00:14:42
of
00:14:44
what so it's a generalization of this
00:14:46
work where this work provided a theory
00:14:49
for this 4f rear back means but they did
00:14:52
not provide a microscopic model
00:14:57
so this is so here are like some minimal
00:14:59
ingredients of this model so we have a
00:15:01
ground state which is W regenerate and
00:15:03
these two states are Thai University
00:15:04
Partners so we have agreement upgrade
00:15:06
and these states are they have some
00:15:08
fixed Android momentum J Alpha and
00:15:11
magnetic and J minus
00:15:14
and then we have some
00:15:16
of other states at a slightly higher
00:15:19
energy which we call side three side
00:15:21
four they are also clever doublets but
00:15:23
but with very different aluminum
00:15:25
population
00:15:27
yeah if you have to go from State one to
00:15:28
state three that would include some
00:15:30
angular momentum Exchange
00:15:33
and now you can have phone also these
00:15:35
are the two phones that I have shown for
00:15:38
um it's either like the two components
00:15:41
of a w degenerate phonon mods you can
00:15:43
think of them as X motion and by motion
00:15:45
for example
00:15:46
so now
00:15:48
we have this electrophone interaction
00:15:51
where these hormones couple these
00:15:53
different states basically what these
00:15:55
phones are doing these phonons are
00:15:56
compension side three side to side four
00:15:58
in this complicated matter and this the
00:16:00
form of this interaction is written by
00:16:03
timing Association
00:16:06
so these interactions can be explained
00:16:08
can be represented by these vertices and
00:16:13
then we can calculate like what they do
00:16:15
the phonon energies while using
00:16:19
case where this is the greens function
00:16:22
Matrix for two modes so we have two
00:16:24
modes that's right we have two
00:16:26
components and if you have to like find
00:16:28
a frequency of these phones you can just
00:16:29
look at the denominator pretty procure
00:16:31
that's a very simplistic thing
00:16:34
now we include the first Corrections
00:16:36
from the these interaction vertices and
00:16:40
that modifies the great function Matrix
00:16:43
and it introduces the cell energy terms
00:16:45
so we have this um of diagonal term
00:16:48
which is uh most important for us so
00:16:51
this soft algorithm basically it splits
00:16:53
up the two phonons so you can think of
00:16:55
this together two by two Matrix where it
00:16:57
was silently earlier now you have the
00:16:59
assumpty maxing of
00:17:01
and also I will show later that these
00:17:05
coupling constants have this problem
00:17:08
now once we uh get these phonons these
00:17:11
functions then we can get one on
00:17:13
energies by solving this equation which
00:17:15
can be done analytically and then to the
00:17:18
first order in magnetic field begins so
00:17:22
this magnetic field enters into picture
00:17:23
because this row is non-zero if you have
00:17:27
Delta one
00:17:37
or if the population of the two levels
00:17:40
in the ground state planning for this
00:17:41
different you can think of damage up and
00:17:43
down so by applying magnetic field you
00:17:46
can change the
00:17:49
in order to get these terms non-zero
00:17:51
will have to Great Value
00:17:55
so this we say that it has two
00:17:56
contributions one arises from the
00:17:59
differences into
00:18:01
um
00:18:01
cases and another arises from the
00:18:04
population difference of two states
00:18:06
within the lower energy uh manifold and
00:18:09
this storm is directly proportional
00:18:12
for a paramagnet it will have like a 10
00:18:14
hyperbolic term it will also have a
00:18:16
temperature dependence
00:18:18
if you want to consider a simple picture
00:18:20
sorry
00:18:22
so you can also think like if you have
00:18:24
the stigma y kind of term the new phonon
00:18:26
modes also get modified earlier you had
00:18:28
X and Y which were your eigenous States
00:18:30
and the system was degenerate right once
00:18:32
you include those interactions you get
00:18:35
these new phonon mods and they are this
00:18:37
kind of superposition which
00:18:39
are priority
00:18:43
now if we want to consider we can
00:18:44
actually visualize this whole
00:18:46
interaction in a very simple way let's
00:18:48
say um if this condition is satisfied
00:18:50
then you can write it down in terms of
00:18:52
this lab cell really polarized phonon
00:18:54
displacement and that's certainly for
00:18:56
them all right
00:18:58
so what I have I have this excitation
00:19:01
electronic excitation on the magnetic
00:19:04
ion which involves a magnetic which
00:19:06
involves a change of angular momentum by
00:19:08
one let's say and then we have a phonon
00:19:10
which also carries an angular moment
00:19:12
so now you can these two uh excitations
00:19:15
will be hybridized it's very very
00:19:16
similar to what you see for exit one
00:19:18
polarity
00:19:20
coupling x01 coupling and you get those
00:19:23
four atoms so so this follow-on uh this
00:19:27
stats are very polarized phone on
00:19:28
couples to this excitation and the
00:19:30
opposite phonon which is time remember
00:19:31
so copy of this phone on it couples with
00:19:34
another excitation which is the time it
00:19:36
was a copy of that explanation both of
00:19:38
them hybridize and that changes the
00:19:40
frequencies of these formats well it
00:19:42
changes the frequencies but they still
00:19:44
remain the same if tan reverse is
00:19:45
symmetry is
00:19:48
you can also visualize this process like
00:19:50
this where I have two halogenables for
00:19:51
phonons and two energy levels citations
00:19:54
and they hybridize it as you can see now
00:19:57
we have two phones whose energies are
00:19:59
different but they are still teacher
00:20:00
rate but once you apply magnetic field
00:20:02
then the speed Generac is lifted for two
00:20:05
reasons one that excitations that I
00:20:09
showed you this Delta one entitled to
00:20:11
their energies become different second
00:20:13
the population for excitation one and
00:20:15
excitation two they also equal to
00:20:18
so as a result of this this decent ratio
00:20:22
of two phonons is lifted and it's lifted
00:20:24
in a way that the new item votes are
00:20:26
right circular polarized and last
00:20:27
circular importance
00:20:29
and this uh displaying is non-zero only
00:20:33
if the level minus WC over F minus F2 is
00:20:36
0 which I mentioned now this is
00:20:39
spreading depends on a lot of factors
00:20:40
first thing which we need for this is
00:20:42
pretty is that these Deltas need to be
00:20:45
closer in energy to phonons and that's a
00:20:49
very um
00:20:50
difficult thing to do like that that's
00:20:52
very material specific thing because
00:20:54
photos depend on material like their
00:20:57
fragment system and materials and
00:20:58
similarities
00:20:59
electronic excitations
00:21:04
and another thing that we need is the
00:21:06
electronic G factor of States because
00:21:08
how much they would be shifted how much
00:21:10
their populations would change with
00:21:11
applied magnetic field would depend on
00:21:13
this camera
00:21:15
and of course language that would decide
00:21:17
the population in that
00:21:21
so another uh there's one more Factor so
00:21:25
all of these things we can measure but
00:21:27
there's one more factor that is
00:21:28
excitations
00:21:33
so here I'm I'm considering an orbital
00:21:37
lattice coupling mechanism so what is
00:21:39
happening like you have a magnetic
00:21:40
material you have a magnetic ion which
00:21:43
is surrounded by some ligands so for
00:21:45
example some oxygen ions or chlorine
00:21:47
ions IELTS and once you excite a phonon
00:21:50
which reduces the symmetry of the system
00:21:53
it changes the crystallographic field
00:21:55
around that magnetic
00:21:57
data and that change that introduces
00:21:59
some perturbation to that
00:22:00
crystallographic field and now you can
00:22:02
expand the crystalline to feel in terms
00:22:04
of these states of that magnetic ion and
00:22:07
then you can find these coupling forces
00:22:10
and this is the app which we use because
00:22:13
like these states that I talked about I
00:22:15
said I never characterized by some J and
00:22:17
MJ and this energy is coming from
00:22:19
orbital and this will take your freedom
00:22:21
now if you change if you point out this
00:22:22
crystall active field around this ion
00:22:24
that can compute
00:22:28
first we apply this to this well
00:22:30
established today so prayer or
00:22:32
trihilites which was studied in 1970s
00:22:35
so um this is
00:22:37
cereal trichloride where we have this
00:22:40
serial three positive wine which is
00:22:42
surrounded by nine taurine ions and this
00:22:46
is a Four f orbital system
00:22:49
coupling is very strong
00:22:52
so if I take like one electron in Forum
00:22:54
system
00:22:55
if
00:22:56
then you have all of your F4 bedrooms
00:22:59
have the same energy but once you have
00:23:00
some economic coupling which is very
00:23:02
strong for these materials as you keep
00:23:04
on moving down a periodic table this
00:23:06
will all the company keeps on increasing
00:23:08
so this country has it's going to copy
00:23:10
of the odor finder down
00:23:12
and F electrons are very well shaded so
00:23:14
they don't feel the crystal lactic
00:23:16
fields of bacterial effects that much
00:23:18
for this to feel uh some effect from
00:23:21
Crystal activities in this case you get
00:23:23
these um this distribution once you
00:23:26
apply once you can see the effects of
00:23:28
crystallactive field as perturbation
00:23:30
so the point to note at here is that you
00:23:33
have these electric labels for these low
00:23:36
energy low energy levels of this
00:23:38
material which are characterized by J Pi
00:23:40
by 2 and mg with different values so
00:23:42
they are all coming from the same
00:23:48
engine and next we consider some each
00:23:51
phonons so we can obtain the
00:23:53
displacement for for these columns from
00:23:55
group Theory
00:23:56
and then we uh find out like how they
00:23:59
change this Crystal
00:24:02
and then you write down in terms of
00:24:04
the X and Y equals
00:24:06
so in terms of like position or
00:24:08
coordinates around that same
00:24:10
um
00:24:11
and what it does it basically introduces
00:24:14
coupling between these different
00:24:16
Industries for example when you write
00:24:17
this from cycling don't so these states
00:24:21
for J and M J you can see that they are
00:24:24
coupling like different
00:24:26
different um States
00:24:30
so in this case this vertical formula is
00:24:32
coupling plus minus five by two by plus
00:24:34
minus 3 by 2 which is about 40 mud and
00:24:38
this formula has energy 23rd scales are
00:24:41
battery which is good enough
00:24:43
usually that doesn't happen because like
00:24:45
this exercise
00:24:50
and then we apply this model and study
00:24:53
like all this is feeding off these
00:24:55
phonons changes with magnetic field and
00:24:57
this is what we get we basically see a
00:24:59
splitting of about men you see the
00:25:01
saturation is splitting of about 1.2 mm
00:25:04
and the saturation is coming from this
00:25:06
10 hyperbolic Factor because we had this
00:25:08
low energy manifolded up and down here
00:25:12
and you can see that it Compares quite
00:25:15
well with these results from
00:25:17
1970s their their uh saturation
00:25:20
spreading was 18 scientific reverse and
00:25:22
it was the saturated
00:25:24
as well
00:25:26
we should be looking at the cell 200
00:25:29
this phone one at 200 centimeters
00:25:37
in this case which is characterized by
00:25:40
this kind of motion where these
00:25:43
um chlorine ions are moving out of X by
00:25:46
K like they are moving along c Direction
00:25:47
but there is a relative phase a
00:25:50
different
00:25:51
items similarly we can now apply this
00:25:54
model to other phonons and we see that
00:25:57
there is another phone on E to G which
00:25:59
couples these plus minus five by two and
00:26:02
plus minus one by two and
00:26:04
six other formula and in this case the
00:26:06
combination like this color
00:26:07
superposition gives rise to the circular
00:26:08
motion
00:26:10
so what we see is that there is a
00:26:12
consider
00:26:16
ation which indicates that these phonons
00:26:18
can carry a Magnetic Moment of the order
00:26:19
of four magnet known in this case at 10
00:26:22
Kelvin this first phonon shows uh
00:26:24
Magnetic Moment of three more Magneto
00:26:28
which at least by order of magnitude
00:26:30
Wise It's very uh you know it's a good
00:26:33
argument with the experimental disease I
00:26:36
mean this is a very crude model so I
00:26:38
think we can't expect a very very good
00:26:40
argument but I think it's good enough
00:26:42
now next question we asked like have we
00:26:45
tested this model for the their
00:26:46
paramagnets can we apply this kind of
00:26:49
process into
00:26:53
it so let's first very briefly review
00:26:55
what is different
00:26:58
system that I was showing you it had
00:27:01
like a very strong economic coupling and
00:27:03
eventually Queen excitation was
00:27:04
splitting of these fingers
00:27:07
on the other hand for day lactose
00:27:09
systems you know that crystalline
00:27:10
excitations are very crystallographic
00:27:12
field energies are very high so we see
00:27:14
this is splitting of the orbitals in t2g
00:27:16
EG which is on plot of one so this is
00:27:20
not compatible with Optical phonons
00:27:22
because they are virtually lower than
00:27:25
however there are mechanisms too which
00:27:27
these t2g can spring for them for
00:27:30
example
00:27:31
or some other events
00:27:32
for example you can have some tribal
00:27:34
Distortion in your system that can also
00:27:37
split up these labels further
00:27:42
in fact recently uh
00:27:45
in fact recently
00:27:47
there's a group at Beauty Austin
00:27:49
professor in English who have detected a
00:27:51
very high Magnetic Moment
00:27:55
on point 11 cobal type weight so in this
00:27:58
case Cobalt three positives
00:28:01
forward too positive it has
00:28:04
seven kilometers in its outermost shell
00:28:06
and they have noticed the form of
00:28:09
Magnetic Moment of the order of four
00:28:10
magnetone again and to the best of her
00:28:12
knowledge this is the first such example
00:28:14
community
00:28:17
so now we uh
00:28:19
apply a wall to this setting but before
00:28:22
that I would very quickly talk about
00:28:24
like how animation is
00:28:26
so this Magnetic Moment is measured by
00:28:29
uh to this healthy Resort Planet romance
00:28:32
spectroscopy so you have this course
00:28:34
circular Channel where you sat in the
00:28:36
right Circle that's hormone
00:28:39
polarized phonon and then what they
00:28:41
notice is that this Peak for this phone
00:28:44
when it spins up as you apply magnetic
00:28:48
[Music]
00:28:52
I will talk about that too like why this
00:28:55
one direction is important
00:28:57
and then it indicates that this exchange
00:29:00
of environment which is happening it's
00:29:01
basically going to this excitation this
00:29:04
phone on excitation
00:29:06
so here again the uh so we are proposing
00:29:09
that in this case this mechanism is
00:29:11
arising from this orbital status
00:29:13
so in order to understand that let's
00:29:15
first look at what is the structure of
00:29:18
this material
00:29:20
s
00:29:21
many positive ion since uh if it's okay
00:29:24
to engage of oxygen ions which is
00:29:26
slightly dysphorically struggling
00:29:28
distorted which means that the Symmetry
00:29:30
side symmetry is reduced to threefold
00:29:33
rotation
00:29:34
and there is a considerable coupling so
00:29:38
um we cannot like read any of them as
00:29:40
for Innovations but what we see like
00:29:43
once we take into account this uh spin
00:29:45
or the coupling and criminal Distortion
00:29:46
and this kind of things have been used
00:29:48
like this electronic energy diagram as
00:29:51
each one it is
00:29:53
so um we are going to focus on these two
00:29:56
low identity states which can get Rise
00:29:59
by mg plus minus one by two
00:30:02
oh
00:30:03
I mean technically they cannot be
00:30:05
characterized by fixed J but
00:30:06
predominantly this lower manifold is and
00:30:09
the upper one is
00:30:15
so now what happens uh now we have
00:30:18
easily phonons here which have energies
00:30:21
around 20 and maybe so 26 are maybe 23
00:30:24
are maybe this excitation has energy
00:30:26
going to take everything which is again
00:30:28
putting it in close proximity uh like
00:30:31
these two energies are to close
00:30:32
proximity so it's highly visible that
00:30:34
this kind of effect might happen
00:30:37
but this material is very different than
00:30:39
what I was talking about earlier because
00:30:42
that was a 4X system I had only one
00:30:44
electron and it was a parabang rate
00:30:49
however in this material there are two
00:30:52
differences first is that these two
00:30:54
states these two energy manifolds that
00:30:56
are important for my model they are
00:30:58
coming from different J values
00:31:00
the second there is soft magnetic phase
00:31:02
transmission so once you fall below 38
00:31:04
Kelvin what happens is you get this
00:31:06
antiviromagnetic
00:31:08
it is
00:31:16
foreign
00:31:18
which means that from exchange
00:31:20
interactions you will get some magnetic
00:31:23
field even if you are not applying any
00:31:24
external magnetic field you will get
00:31:25
some in-plane magnetism
00:31:29
so it hybridizes I'm sorry so it opens
00:31:32
up a gap in these two states that I I
00:31:34
will show you earlier in these two
00:31:36
states and it hybridizes it them in a
00:31:39
way that the angular momentum alone Z
00:31:41
Direction comes out
00:31:42
the phonon carries angular moment
00:31:46
s but once you start applying back when
00:31:48
you feel you can change the eigenous
00:31:50
state so these states such that they
00:31:53
gain some annual fundam which makes this
00:31:55
process which makes this mechanism
00:31:57
physical
00:31:59
however the temperature dependence would
00:32:01
be very different earlier we had that 10
00:32:04
hyperbolic kind of dependence but here
00:32:07
um it would be very different depending
00:32:09
on the magnetic system
00:32:12
so first we calculate the splitting for
00:32:14
T greater than t n which is the
00:32:16
paramagnetic case and here again we
00:32:19
find we apply the same microscopic model
00:32:22
and then we find that magnetic movement
00:32:24
is
00:32:25
0.1 and 0.
00:32:28
but next we stay temperature friends and
00:32:31
for temperature Trends I am going to
00:32:32
focus on living one of those four
00:32:34
numbers that is 33 I mean
00:32:36
um
00:32:38
so then we include this in plane
00:32:40
magnetic field and we take into account
00:32:42
the identities like how these eigen
00:32:44
states are changing with this applied
00:32:45
magnetic field and this applied magnetic
00:32:47
field is itself a function of
00:32:49
temperature because it depends on
00:32:50
magnetic ordering as you keep on going
00:32:52
below a new temperature keeps on
00:32:54
increasing so you can already see that
00:32:56
there is some saturation in this formula
00:32:59
moment which is indicative of this in
00:33:01
plane external magnetic field
00:33:04
and these are experiment these are the
00:33:07
values measured from experiment so um
00:33:10
our Theory matches well for order of
00:33:13
magnitude like we say 0.15 uh for family
00:33:16
node and the trend is very similar
00:33:18
however it doesn't accumulative well
00:33:20
comparatively it could be because like
00:33:23
our model is to approve this microscopic
00:33:25
model for lack of component coupling is
00:33:27
not giving us the right order to
00:33:30
by changing this
00:33:33
orbitalized swiveling and we formed a
00:33:35
reasonably good fit if we use some value
00:33:36
which is twice then that we obtained
00:33:38
from our microscopic model
00:33:41
so um so this orbital access coupling
00:33:43
model can also be applied to some Data
00:33:46
Systems that's one of our main countries
00:33:50
now very briefly you might ask like
00:33:52
where else should I look for this kind
00:33:54
of phonons I think good care can provide
00:33:57
us some insight so what was common in
00:33:59
these
00:34:00
two different materials was like we had
00:34:02
some WD General phonons
00:34:04
it surely presented by these irreducible
00:34:06
representations EGU and then your time
00:34:09
was a breaking um
00:34:12
yeah then once you break time it was
00:34:14
intimidate these um irreducible
00:34:16
representations should break into two
00:34:18
one Dimensions uh you don't have to go
00:34:21
through the details of all those terms
00:34:22
but you can think of this thing like
00:34:24
that so you have let's say p x and P Y
00:34:26
orbitals Let's ignore PC for one moment
00:34:28
and you apply some magnetic field your
00:34:30
break time is symmetry so your new eigen
00:34:33
States become P X Plus y b y and p x
00:34:35
minus i t y so the same thing can be
00:34:38
reflected in these irreducible
00:34:40
representations which you can read from
00:34:42
character tables
00:34:45
and now the possibilities of your system
00:34:47
should be such that they should allow an
00:34:48
exit back because the angular momentum
00:34:50
that we are looking at is
00:34:53
so if you look at the character tables
00:34:55
then an axial Vector like the Z
00:34:58
component of this axis Vector should
00:35:00
occur in this previous which means that
00:35:03
it should not be affected by any
00:35:05
component of your symmetry right if you
00:35:07
do any of those symmetry operations you
00:35:09
should be Studio at the same exercise
00:35:11
for example that is the case for C3 and
00:35:14
for c3h where you have in
00:35:17
where your mirror plane is perpendicular
00:35:19
rotation access
00:35:22
um
00:35:22
I think I'm a good thing to do so it
00:35:24
reactants your um
00:35:27
mirror play you're you're basically your
00:35:29
rotation exercising your rear plane so
00:35:31
it doesn't change the accelerator to
00:35:34
change the ID batteries that's
00:35:36
perpendicular to the potential access
00:35:38
and on the basis of this kind of
00:35:40
symmetry analysis uh we made this list
00:35:43
of magnetic Point groups so this
00:35:45
information about error display
00:35:47
representations can be obtained from
00:35:52
server and we found these magnetic Point
00:35:55
groups which can allow for this kind of
00:35:58
drone centered kind of forms and in fact
00:36:00
this example of cobalt diet made that as
00:36:02
its discussing it was in this case
00:36:04
for example you can also have a
00:36:06
situation like this yesterday you have
00:36:07
some C3 symmetry which allows this kind
00:36:10
of axle vector then you also have let's
00:36:13
say some twofold rotation which Maps it
00:36:15
to negative open cells so you cannot get
00:36:17
n you cannot get an ample momentum in
00:36:20
this case so you cannot get a car
00:36:22
formula in this case however if you have
00:36:24
a set of beer C2 is broken but C2 times
00:36:27
time which is preserved and he can have
00:36:29
the same signal the sexual opposite
00:36:32
that's for example the case for this um
00:36:35
magnetic Point group
00:36:37
now uh what are some other situations
00:36:40
where this kind of orbital lattice
00:36:42
coupling mechanism can arise
00:36:46
so for example I think this mechanism
00:36:48
can also arrive in 40 magnets and
00:36:51
lithium trichloride might be a good
00:36:53
candidate it has reasonable spin orbit
00:36:55
coupling so it's been orbit coupling is
00:36:56
usually higher for 4D and 5A in
00:36:59
comparison between
00:37:03
and it has some low energy excitations
00:37:06
which are at about 100 mbv and some
00:37:08
Optical Corners which are responsive
00:37:09
yeah I mean the scales are not matching
00:37:11
very well so the fact would we support
00:37:13
the curve but I think it should
00:37:15
be stronger than incredible so we
00:37:17
haven't done that calculate
00:37:19
and another question we can ask like
00:37:20
right now is breaking tablets in
00:37:22
Symmetry by applying magnetic field but
00:37:24
what about if you have a ferromagnet if
00:37:25
your magnetic order is such that you get
00:37:27
some magnetic fields reduction
00:37:30
symmetry in a manner
00:37:43
um I don't know any such examples at
00:37:44
this point but there's this paper for
00:37:46
World chromium iodide where they have
00:37:48
this kind of ferromagnetic setup uh but
00:37:50
they explain this Magnetic Moment from
00:37:53
the basis of coupling with that loss
00:37:55
another scenario you can imagine is
00:37:58
fluke engineering
00:37:59
so you apply a circularly polarized
00:38:01
light that breaks familiarity of your
00:38:04
system and that uh gives you chiral
00:38:07
forms for example that can occur in
00:38:09
graphene so circularly polarized driven
00:38:11
graphene circular polarized like ribbon
00:38:13
graphene is very well studied both
00:38:14
theoretically and experimentally and
00:38:16
it's known that
00:38:23
so we can ask like what would happen
00:38:25
like if you couple phonons to these
00:38:27
stroke events these new bands which have
00:38:29
some finite qualification and this is
00:38:31
One Direction which I am pursuing with
00:38:33
Professor Takashi Oka from University of
00:38:35
Tokyo and my postdoc advisor Grandfield
00:38:41
so having talked about all these
00:38:42
mechanisms now let me very briefly talk
00:38:46
about applications
00:38:47
so we have these current hormones where
00:38:50
we have this kind of circular vibrations
00:38:52
now what to do with that
00:38:54
they also respond very strongly to
00:38:55
magnetic field
00:38:58
so first thing that we can do with them
00:39:01
so I think I put that reference earlier
00:39:03
is that they can generate a very large
00:39:05
effective magnetic field uh I think the
00:39:08
microscopic model that I applied for for
00:39:11
Magnetic Moment would also explain this
00:39:13
giant effective magnetic field in those
00:39:15
papers it was described on a very
00:39:16
phenomenological basis like uh they had
00:39:18
used a very different analysis so one
00:39:21
thing like if you can generate this kind
00:39:22
of giant effective magnetic field by
00:39:25
applying an external laser it means that
00:39:27
you can basically control the
00:39:29
magnetization on an ultra Fast Times
00:39:31
case which is very important for its
00:39:33
Electronics so you can control the
00:39:34
magnetization of your system at Ultra
00:39:36
first time skills and that can have some
00:39:38
major implications for information
00:39:40
processing
00:39:41
and as I mentioned earlier in that paper
00:39:43
it was shown that you can achieve very
00:39:45
high magnetic fields which can help you
00:39:47
to study phase transitions at very high
00:39:49
magnetic field in some materials and
00:39:52
then you can also use that effective
00:39:53
magnetic field to control the magnitude
00:39:59
similarly another aspect of these chiral
00:40:01
phonons is
00:40:03
um
00:40:03
in some cases they are also connected to
00:40:07
non-trivial phonon band topology that is
00:40:10
one thing and they can also exhibit this
00:40:13
thermal Roll Effect
00:40:15
um I think there are two contributions
00:40:17
in this case one comes from the
00:40:19
non-trivial topology of these phonos and
00:40:22
one from these chiral properties based
00:40:25
on phonon algorithm momentum so now you
00:40:27
can have much more efficient thermal
00:40:29
transport with these chiropodons and
00:40:32
this kind of chiral phonon based thermal
00:40:35
transport has been shown in cup rates in
00:40:37
this paper
00:40:38
um
00:40:41
another implication that you can have is
00:40:43
into the optoelectronics
00:40:45
so you can have cardio phone assisted
00:40:47
transition there are certain transitions
00:40:49
in some materials which are forbidden
00:40:52
due to angular momentum conservation
00:40:54
like you have like much higher angular
00:40:56
momentum you need much higher angular
00:40:57
momentum for those transitions but if
00:41:00
you can like have some chiral phone on
00:41:02
assistive transition where some angular
00:41:04
momentum is provided by the carophonal
00:41:06
then those transitions can be allowed or
00:41:09
it can have some important implications
00:41:10
for exit on phonon coupling as well
00:41:13
so I discussed like the energy is like
00:41:16
how this phonons even effect manifests
00:41:17
but there is also another aspect of
00:41:19
these guidelines that is this Capital
00:41:22
processes so how do they scatter because
00:41:24
they carry angular momentum so their
00:41:26
scattering would be much more restricted
00:41:28
which makes them very long-lived and it
00:41:31
can have some very interesting
00:41:33
consequences for spin relaxation and
00:41:36
scattering uh another thing that this
00:41:40
model can do in our case like if we
00:41:43
apply this model and we study some kind
00:41:44
of phonons and there's splitting in
00:41:46
magnetic field that can also serve as a
00:41:48
pro for orbital lattice coupling or in
00:41:51
some cases a pro for electronic band
00:41:53
temperature
00:41:54
with this I would like to conclude I
00:41:57
think I still have time but
00:42:00
um so I provided a microscopic model for
00:42:03
phonon magnetic movement which was based
00:42:05
on orbital lattice coupling and then we
00:42:08
provided some estimates of magnetic
00:42:10
movements in different classes of
00:42:11
materials and we also
00:42:13
predict some new materials where this
00:42:16
kind of effects can occur and some new
00:42:17
mechanisms for example this flowkey
00:42:19
engineered thing
00:42:21
however there are a lot of aspects of
00:42:23
these car reformers which haven't been
00:42:25
installed it yet because this area is
00:42:26
very new for example the model that had
00:42:30
considered was a molecular model so I
00:42:31
just looked at the unit cell and I
00:42:33
treated that whole system as a molecule
00:42:35
but now you can also have like ignorant
00:42:38
bands like you have these uh bands in
00:42:40
your system and you might ask like how
00:42:42
do electrons couple do those magnetic
00:42:45
eyes which are those magnetic degrees of
00:42:47
freedom which are moved around
00:42:49
uh similarly they can also couple to
00:42:51
some other excitations in the system
00:42:52
like magnets and I've looked I looked at
00:42:56
only at this whole centered phonons but
00:43:00
what about finite K followers like would
00:43:03
they have similar uh Z manufact
00:43:06
and another possible applications would
00:43:09
be uh like what happens to like phone
00:43:10
online widths do we see any changes in
00:43:13
phone online widths with magnetic field
00:43:15
and because we believe that angular
00:43:17
momentum conservation uh should restrict
00:43:20
the scattering and the it should narrow
00:43:21
the language but this is something we
00:43:23
haven't studied yet and it would also
00:43:26
provide if it changes like if we can
00:43:28
control it with magnetic field then it
00:43:30
will also provide us a mechanism to uh
00:43:32
tune scattering rates by airplane
00:43:36
with this I would like to uh thank my
00:43:39
collaborators my advisor Gregory feed
00:43:41
from Northeastern University Boston and
00:43:44
my other collaborators from UT Austin
00:43:46
talent and University of Tokyo oh thank
00:43:49
you for your attention
00:44:24
but that's how you started feeling
00:44:26
louder
00:44:29
in the system
00:44:30
is there any timing with universal
00:44:32
symmetry in the system
00:44:35
so in this case there was no emergency
00:44:40
for the examples that I discussed but
00:44:43
you can have a situation where you don't
00:44:45
like where you have inversion
00:44:46
symmetrical broken
00:44:48
oh sorry there was inversion submit in
00:44:49
these systems inversion symmetry was not
00:44:51
broken but you can have a set of your
00:44:52
inversion symmetry is broken in that
00:44:54
case you will get calculus but you will
00:44:56
get it at some high symmetry points so
00:44:58
basically you will get title phone one
00:45:00
at one k point and you will get a
00:45:01
carophone on it another K point but
00:45:03
their chirality would be opposing they
00:45:04
for the overall burial Zone overall
00:45:07
chirality would feel
00:45:09
but you can have like at a particular
00:45:11
moment momentum you can have some kind
00:45:13
of phone on with the finite card LED
00:45:18
and that's the case for graphene
00:45:39
sort of
00:45:43
strongly affected yeah I tried this
00:45:46
scattering mechanism would be kind of
00:45:49
suppressed like if you have these um
00:45:53
so I think first thing is that would
00:45:55
depend a lot on the material
00:45:58
um
00:45:59
so if you can like design your system in
00:46:02
a way that now your phone on modes are
00:46:06
chiral
00:46:07
like if you let's say apply some
00:46:08
medicine magnetic field or some other
00:46:10
time it was limited breaking mechanism
00:46:11
then I believe that would increase
00:46:15
electrical conductivity because that
00:46:17
would decrease the scattered events and
00:46:20
that should increase
00:46:21
electronic connectivity yeah
00:46:31
yeah so that uh so for the scattering
00:46:33
part that I haven't done
00:46:37
right right
00:46:40
by a very large extent
00:46:43
um
00:46:45
so I don't have much idea about like I
00:46:49
haven't Quantified that thing but I
00:46:51
think there should be a considerable
00:46:52
effect in fact in that Cupid paper that
00:46:55
I was showing so for electrical and
00:46:58
thermal conductivity you have this white
00:46:59
man friends low so they showed that it's
00:47:02
violated very strongly in Cube rates and
00:47:05
they have attributed that effect to
00:47:06
carry phones I mean they have
00:47:08
experimentalism but theory-wise uh in
00:47:10
that paper they haven't Quantified it so
00:47:12
I don't think there is a mechanism like
00:47:14
there is any work at this point which
00:47:16
has considered this kind of
00:47:25
spiral phonons have a large magnetic
00:47:28
movement right so and your model is that
00:47:32
it is sort of coming because of the
00:47:34
hybridization with the electronic States
00:47:36
right right so is it possible that one
00:47:39
is measuring a part of the electronic
00:47:41
Magnetic Moment itself rather than
00:47:48
right right that's a very good question
00:47:51
yeah actually that's what I think what's
00:47:53
going on because what you are seeing is
00:47:56
note of your phone on but it's an ad
00:47:57
mixture
00:47:58
uh but the thing is like that add
00:48:00
mixture would be very small like the
00:48:04
like the sorry the electronic excitation
00:48:07
percentage would be very small in fact
00:48:09
in some of my other like I haven't
00:48:11
presented those with results but we had
00:48:12
tried to quantify it and it was about 10
00:48:15
I think for this eg2 phone on like the
00:48:17
mixing was about 10 because it's
00:48:19
slightly far from resonance so it's not
00:48:22
like the hybridization is not very
00:48:24
strong but there is definitely a very uh
00:48:27
small like there's definitely this part
00:48:29
for electronic excitation and now
00:48:31
electronic excitation has some bore
00:48:32
magnet on like Magnetic Moment of core
00:48:34
magnet oil so it's it's possible that
00:48:37
this 0.1 bore magnetone that you're
00:48:39
seeing is coming from that glycolic
00:48:41
excitation
00:48:43
state that you are measuring right
00:48:54
because we are quite far away from this
00:48:58
a level coursing point
00:49:00
the temperature should
00:49:03
determine the difference between the two
00:49:05
right
00:49:06
should probably die out no but actually
00:49:09
the energy
00:49:15
those States come very close to the
00:49:17
Colony
00:49:20
because they perhaps have a similar
00:49:21
temperature
00:49:23
also like even for the electronic
00:49:25
excitations like their energy also move
00:49:27
with magnetic field
00:49:28
the hybridization amount also changes
00:49:33
yeah but that's um I think
00:49:46
which
00:49:48
means
00:49:49
yeah but like whatever phononic part you
00:49:51
will get like it will have like some
00:49:52
circular motion as you say so I think
00:49:54
it's okay
00:50:01
yeah yeah
00:50:05
so and line with how do they measure if
00:50:09
at all of the circular kind of thing
00:50:11
measurement
00:50:18
I think they did that so we are still
00:50:20
working out the theory for this language
00:50:22
actually okay
00:50:23
[Music]
00:50:26
yeah I think they just I mean
00:50:28
experimentally they just measure it from
00:50:30
here full of half Max
00:50:33
yeah
00:50:38
sure yeah but we are as to um
00:50:42
so how does one actually measure a
00:50:45
foreign
00:50:47
ah even let's say Optical novel now
00:50:51
I don't know
00:50:53
one is uh definitely Robin experiments
00:50:57
like you can do that okay
00:50:59
and I think now I want to see the
00:51:01
distinction if any
00:51:03
between the magnitude
00:51:06
for the one which are twisted
00:51:09
also I think their temperature
00:51:11
dependence is very different very
00:51:13
performance because I'm forgetting the
00:51:15
name of that thing but you have this and
00:51:17
harmonic Decay like if you take an
00:51:18
optical hormone it decays into two um
00:51:21
acoustic phonons and then you get a very
00:51:24
peculiar structure from there for
00:51:26
language and you do that fit into
00:51:28
temperature and then you can say that
00:51:29
okay
00:51:31
and in some cases there can also be like
00:51:33
some asymmetry but I think it's so it's
00:51:37
more related to like electrophone on
00:51:39
coupling like you can have this fanu
00:51:40
shape kind of thing
00:51:43
that can also be there and then I think
00:51:45
that then you can distinguish like
00:51:47
contributions from black medical
00:51:48
citation yeah but in this case I think
00:51:51
it's a good question like if you can
00:51:52
somehow uh separate the two
00:51:54
contributions experimentally like what
00:51:57
is the phononic part and what is
00:51:58
electronics
00:52:14
[Applause]