# MIT.nano

Data: 11-01-2025 22:01:05

## Lista de Vídeos

1. [MIT.nano: Innovation](https://www.youtube.com/watch?v=tRQdQWzzUbw)
2. [The rising](https://www.youtube.com/watch?v=-Oc_IK_kFU0)
3. [The big dig](https://www.youtube.com/watch?v=uoqJ4841Q-o)
4. [Ship in a bottle](https://www.youtube.com/watch?v=NPzJjIcVp1A)
5. [Slurry wall](https://www.youtube.com/watch?v=wLPWgT9kgk4)
6. [What comes down](https://www.youtube.com/watch?v=bd4_lYb3vPE)
7. [MIT.nano: Education](https://www.youtube.com/watch?v=B2mqGhT6OG4)
8. [MIT.nano: An Overview](https://www.youtube.com/watch?v=rGnr2ipfY3o)

## Transcrições

### MIT.nano: Innovation
URL: https://www.youtube.com/watch?v=tRQdQWzzUbw

Idioma: en

MIT.nano
in science and engineering you have to
question whether what you're told
or what you see in front of you is what's
really there
there may be something else behind it
that you haven't seen because it's not in your view
but if you dig deeper you maybe you'd find it
my research is driven by
curiosity
if I'm interested in understanding something, I pursue it
the vision is that this nano building
will change the exploration of many things
our basic mission is to advance
knowledge
and the nanoscale is an an important frontier for us
because it's right here, it's right here all
around us
once you can make things so much smaller
it changes the world in ways we can
anticipate
I know my research is going well when
I'm surprised by what I see
that's when we find something new
it's about fundamental discovery
discovery about new types of matter new ways that light, electrons, mechanical forces, interact with matter
every aspect of energy storage, energy
generation, energy transformation comes from the nanoscale
If i look at leaves, they're green because they reflect green light
they don't absorb green light
but leaves absorb is red light and UV
light
so can I take all that green light and convert it into red light?
it turns out you can you, you just need these little things called quantum dots
and they can absorb the light and glow back the red color
so in cloudy climates, you can generate more useful lights
that's a unique way of thinking and
rethinking what is arable land
you can have a great idea in the lab but
that idea is a long way from having real world or industrial impact
the nano center can really help us to bridge the gap
between material development in a
lab and the type of reproducibility
and understanding one will need to prototype a new engineered system
to even think about scaling those materials up to the levels where industry would become interested
seeing in biology has
always been the key to understanding
one picture is not worth a thousand words, it's worth a million words
the ability to construct materials at a nanoscale
it's a very important new tool in cancer
research
you can use them as imaging agents to
tell you when the cell is changing
from being a viable cell, to a dying cell, to a sick cell
and every time you can see something new
you can begin to use that image to
understand the process
and ultimately to take it to treatment
you have to be in an environment that's permissive of crazy thoughts
and crazy directions, which can lead to something really great
all around MIT we already are focused on
nanotechnology
but the way we do it is using the
specific tool sets that can fit inside our present labs
if I had a bigger lab, if I had a more
complex lab,
I could put more complex sets of tools inside it
all of us because
we are from different disciplines will inspire each other
so give me a tool that all of us need to
go to
and you'll start spurring innovation like you have never done before
MIT.nano
Millie Dresselhaus, Phil Sharp, Mike Sipser, Gabriela Schlau-Cohen, Vladimir Bulović, Fickle Brushett

---

### The rising
URL: https://www.youtube.com/watch?v=-Oc_IK_kFU0

Idioma: en

When I hear "nano," I think of small tiny flies that are gonna spy on me or something...
...I don't know, you know...
or they can go inside your body to cure cancer and stuff like that...
(music)
My name is Kevin Burtsell. I'm the raising gang boss. Yup, yup!
Down there, they took care of us.
They covered everything with stone, and when we came in, the anchor bolts were right on the money.
That's like the backbone to the building. It's what the first column is set on.
If those aren't in the right spot, then the building's not gonna come up straight. You know what I mean?
(music)
If you just look up there and see the guy way up there,
you might think that you could do that,
but it takes a special guy to get up on the iron,
because it's a really really dangerous business, ya know,
One hundred percent tie off. I preach it to my guys, 'cause they wanna go home at night.
It's a split second, and you could be going down. You know what I mean?
So you've got to be careful, that's all.
(music)
For the erection part of it,
you just put a couple of bolts in and make it safe and then you move onto the next piece.
Then you have guys come in behind you,
and they bolt up all the iron. They put the right bolts in.
And then after they get it bolted up, the decking gang comes in.
Once they get the deck down, two safety arms go up around the parameter
to keep anybody from walking off the edges and stuff like that.
Then the detail guys come in,
and they detail holes and all the openings for all the pipework and all the elevators, and all that.
They have different bent plate on the iron.
Or they have to put some stuff down in order to keep the concrete from flowing into the hole
once they pour the concrete.
And after those guys come,
the stud guy comes in.
The stud's like a six-inch piece of iron about this big,
and he shoots down thousands of them over all the beams,
and that fastens all the beams to the deck and to the concrete.
And then the rod busters come in,
and then they start putting down all the mesh, and all the rebar,
and then the concrete guys come in,
and then from thereon the carpenters, and everybody else can come in and go to work.
You know what I mean? Hundreds of guys!
So we just keep going up from there, all the way to the top.
(music)
I'm a Local 7 ironworker.
A proud Local 7 ironworker!
I have been for 25 years.
And it's a good local.
A good brotherhood. We take care of each other.
You know, we do a lot of community stuff, and...
Go Local 7 ironworkers!
(music)

---

### The big dig
URL: https://www.youtube.com/watch?v=uoqJ4841Q-o

Transcrição não disponível

---

### Ship in a bottle
URL: https://www.youtube.com/watch?v=NPzJjIcVp1A

Transcrição não disponível

---

### Slurry wall
URL: https://www.youtube.com/watch?v=wLPWgT9kgk4

Transcrição não disponível

---

### What comes down
URL: https://www.youtube.com/watch?v=bd4_lYb3vPE

Transcrição não disponível

---

### MIT.nano: Education
URL: https://www.youtube.com/watch?v=B2mqGhT6OG4

Idioma: en

[Music]
To fully understand something,
you have to use it, play with it, or work with it
with your hands, outside of the classroom.
It is one thing to go college and learn a lot of equations
and to understand it on a theoretical level and to say, "I've seen this."
It is something else entirely to be able to say,
"I've done this."
I think the best environment for learning is
in a lab—building something with my hands,
by myself, trying things out, failing a bunch.
Science isn't about getting everything right the first time.
It's about the struggle.
And that is what I love about MIT.
We need to be training the next generation of scientists
and engineers to tackle the really hard stuff.
And have no fear because these problems need to be solved
and we need to be involved in that.
I am working toward revolutionizing the field of thermo energy harvesting
using carbon-based nano materials.
Using 2D materials
for display technologies and flexible electronics.
I am trying to create a pair of gloves and shoes that I can use to climb up anything.
[Music]
If you look at the great seal of MIT,
it has a man reading a book and it has another man with a sledge hammer.
And the reason is that this urgency of going from theory to practice
is very central to MIT's founding principles.
And so the nano building is very much a continuation
of the spirt and soul of MIT.
[Music]
All the action.
All the important physics and the important engineering that takes place
is going to be happening at the nano scale.
So, you have a big chunk of material and you make it smaller and smaller,
and it behaves, okay, like you expect, like you expect,
until you get down to the nano scale.
Until you get down to this really, really, really, tiny size,
and then they start doing these incredibly different
and surprising things that you didn't expect at all.
If you look into something that is really small,
and you change a little bit of it,
you can change the world.
[Music]
What we see in our students is
they want to solve the problems the world is facing.
And one of our answers is MIT.nano.
Engineering is now starting at the nano scale.
And it wasn't 20 or 30 years ago.
So, we need to put tools in our students hands..
MIT.nano will do that.
[Music]
It used to be, soft-of, a matter of opinion,
but now we know that doing something in real life,
having context for it,
just fundamentally changes learning.
I don't really care what anybody says.
Working problem sets on nano stuff
is not the same as actually building something nano.
We do the classroom learning setting
to facilitate the hands-on learning
that students actually do while they are here.
The most important types of experiences
you can have at MIT
is not in my classroom,
but it's in somebody's laboratory.
That's because the path to discovery
always leads through an experiment.
[Music]
If I had access to the most advanced cleanrooms,
it would just be crazy. Right? You can do so much more.
You can accomplish any project that you can dream of.
Right?
It is not even imaginable. It is one of those things.
Only at MIT.
Like, that is incredible, that I can do that.
[Music]
Students come to us today,
and they want to solve problems.
And MIT.nano maps to that.
To focus on developing and using tools
in a direction, which is very important for the world.
[Music]

---

### MIT.nano: An Overview
URL: https://www.youtube.com/watch?v=rGnr2ipfY3o

Idioma: en

 
Today we spend 1.3% of
the world's electricity
running cloud computing.
Projection is that we'll need
a thousand times more cloud
computing in about
10 years from today.
That's 1,300% of the
world's electricity.
Starting in 2002, cancer
began to kill more people
every year than AIDS,
malaria, and TB combined,
and that's only gotten worse.
Even here in the US it's
approaching the number one
killer, higher than
cardiovascular disease.
I like to say water is sort
of the one energy problem
that could kill you.
Two billion people
in the world today
do not have regular access
to clean drinking water.
Within the next
couple of decades
that's expected to go
up to four billion.
MIT is a place where we
think about solving problems
in our society today, and
we have a responsibility
to actually come
up with solutions
and to show that science,
engineering, and technology can
actually provide solutions.
Nanoscale happens to
be the operative unit.
If we can control it, we
can build the world we want.
 
It's a natural platform
for innovation and thinking
about growing and transforming
nonbiological materials
but giving them some of the
best properties of biology.
You think about in
the periodic table,
it's as if you've
given that whole table
a completely new dimension.
Over the past couple of
decades, the equipment
and the experimental techniques
at micro and nanoscales
have evolved.
I can't even--
[LAUGHS]
I can't even tell you
how much they've evolved.
We can see things now
that we couldn't have even
imagined looking
at 20 years ago.
 
Our present facilities are twice
as busy than any other research
lab in the world.
Opening MIT Nano will enable
us to fulfill our desire
to be even more productive.
Innovation occurs when
you get unusual pairings
or unusual collaborations.
It's about sharing ideas,
it's about working together
to push the boundaries
of what's possible.
It's about what we can do as a
community to make a difference.
Having a fabrication
facility right
at the heart of
the campus really
tells us that we are here to
prototype and make things.
The way discoveries happen is
that engineers actually tinker.
We like to play,
we like to invent.
And so we might have
one idea in mind
and discover something
completely different
that has another application.
MIT Nano will house the most
complex set of nano technology
tools ever assembled in
a single place, tools
that none of the
individual faculty
can afford because they're
too expensive to maintain.
But as a group of
2,000 users, we
can certainly maintain
it as a central facility.
When you get access to those
state of the art tools,
you really start thinking big.
You have this spiral of
technology development,
fundamental science,
technology development that
can start a real
snowball effect.
This is the time to build
this building because this
is the time when the
technology is really
going to leap forward.
What we do is really on the
edge of science and fiction.
And if you make one
more step, if we
can make this particle
a little bit more
magnetic or a little bit bigger,
a little bit smaller, then
maybe we will be
able to really change
the way we interact with
human nervous systems.
We can envision a future
where a large fraction, maybe
as much as 20% or
30% of our chemicals
actually come now from biology
as opposed to from petroleum.
One of the dreams
at MIT is to design
what would be the first
interplanetary small satellite
to explore the moon or
explore Mars or an asteroid.
That would be unheard of.
MIT attracts people
who see their mission
to be beyond academic pursuits.
Mind and hand
symbolizes what we do.
MIT Nano epitomizes
MIT's mission.
We think about ideas, we
reduced them to practice,
and then we give them
to the world outside.
 

---

