나노입자의 기본원리와 응용 2002. 5. 14 나노입자의 기본원리와 응용 전승준...

나노입자의 기본원리와 응용 2002. 5. 14

나노입자의 기본원리와 응용

전승준

( 고려대학교 화학과 )

나노입자의 기본원리와 응용 2002. 5. 14

Macro, Micro, NanoHow small is a nanometer?

나노입자의 기본원리와 응용 2002. 5. 14

나노입자의 기본원리와 응용 2002. 5. 14

3.5 billion years ago The first living cells emerge. Cells house nanoscale biomachines that perform such tasks as manipulating genetic material and supplying energy.

400 B.C. Democritus coins the word "atom," which means "not cleavable" in ancient Greek.

1905 Albert Einstein publishes a paper that estimates the diameter of a sugar molecule as about one nanometer.

1931 Max Knoll and Ernst Ruska develop the electron microscope, which enables subnanometer imaging.

1959 Richard Feynman gives his famed talk "There's Plenty of Room at the Bottom," on the prospects for miniaturization.

1968 Alfred Y. Cho and John Arthur of Bell Laboratories and their colleagues invent molecular-beam epitaxy, a technique that can deposit single atomic layers on a surface.

1974 Norio Taniguchi conceives the word "nanotechnology" to signify machining with tolerances of less than a micron.

History

나노입자의 기본원리와 응용 2002. 5. 14

1981 Gerd Binnig and Heinrich Rohrer create the scanning tunneling microscope, which can image individual atoms.

1985 Robert F. Curl, Jr., Harold W. Kroto and Richard E. Smalley discover buckminsterfullerenes, also known as buckyballs, which measure about a nanometer in diameter.

1986 K. Eric Drexler publishes Engines of Creation, a futuristic book that popularizes nanotechnology.

1989 Donald M. Eigler of IBM writes the letters of his company's name using individual xenon atoms.

1991 Sumio Iijima of NEC in Tsukuba, Japan, discovers carbon nanotubes.

1993 Warren Robinett of the University of North Carolina and R. Stanley Williams of the University of California at Los Angeles devise a virtual-reality system connected to a scanning tunneling microscope that lets the user see and touch atoms.

1998 Cees Dekker's group at the Delft University of Technology in the Netherlands creates a transistor from a carbon nanotube.

1999 James M. Tour, now at Rice University, and Mark A. Reed of Yale University demonstrate that single molecules can act as molecular switches.

2000 The Clinton administration announces the National Nanotechnology Initiative, which provides a big boost in funding and gives the field greater visibility.

2000 Eigler and other researchers devise a quantum mirage. Placing a magnetic atom at one focus of an elliptical ring of atoms creates a mirage of the same atom at another focus, a possible means of transmitting information without wires

나노입자의 기본원리와 응용 2002. 5. 14

Nano Research

나노입자의 기본원리와 응용 2002. 5. 14

Nano Research

Top-Down : Lithography,

Micro-Mechanical Electronic System(MEMS)

IT, Physics approach

Bottom-Up : Molecular engineering

Self-Assembly

Chemistry, Material science approach

나노입자의 기본원리와 응용 2002. 5. 14

Nanochemistry

Materials

Nanoparticle

Nanotube

Supramolecular chemistry(dendrimer, micelle)

Self- Assembly

Nanoporous

나노입자의 기본원리와 응용 2002. 5. 14

Why Nanoparticle?

Quantum Size(Confinement) effect

Surface Effect

나노입자의 기본원리와 응용 2002. 5. 14

Quantum Size(Confinement) effect

Particle in a box quantum localization energy

2 2 2*

2

1 1 1.7860.248

2Ry

e h

eE E

R m m R

Coulomb EnergySpecial correlation Effect

나노입자의 기본원리와 응용 2002. 5. 14

Absorption

Fluorescence

나노입자의 기본원리와 응용 2002. 5. 14

Metal nano :surface

Semiconductor nano : quantum

Density of state

나노입자의 기본원리와 응용 2002. 5. 14

Band theory

나노입자의 기본원리와 응용 2002. 5. 14

Surface effect

나노입자의 기본원리와 응용 2002. 5. 14

나노입자의 기본원리와 응용 2002. 5. 14

Synthesis 시 고려할 주요 사항

입자 크기 조절

입자 크기의 균일도

입자의 Mophology

나노입자의 기본원리와 응용 2002. 5. 14

Vaporization Chamber 내에서

합성 - C60 합성과 유사

Vacuum Chembar synthesis: 조절 용이

나노입자의 기본원리와 응용 2002. 5. 14

Wet Chemistry 에 의한 합성 : 다량 합성 가능

Inverse micelle method

Capping agent

State of Art 합성 : 물리화학적 합성

나노입자의 기본원리와 응용 2002. 5. 14

나노입자의 기본원리와 응용 2002. 5. 14

Property of Nanoparticle

• Optical : sensor

• Magnetic : storage

• Electrical : electronic device

나노입자의 기본원리와 응용 2002. 5. 14

Nano for SaleThe following sampling of already commercialized applications indicates. Application: CatalystsCompany: ExxonmobilDescription: Zeolites, minerals with pore sizes of less than one nanometer, serve as more efficient catalysts to break down, or crack, large hydrocarbon molecules to form gasoline.

Application: Materials enhancementCompany: Nanophase TechnologiesDescription: Nanocrystalline particles are incorporated into other materials to produce tougher ceramics, transparent sunblocks to block infrared and ultraviolet radiation, and catalysts for environmental uses, among other applications

나노입자의 기본원리와 응용 2002. 5. 14

Application: Data storageCompany: IBMDescription: In the past few years, disk drives have added nanoscale layering-which exploits the giant magnetoresistive effect-to attain highly dense data storage.

Application: Drug deliveryCompany: Gilead SciencesDescription: Lipid spheres, called liposomes, which measure about 100 nanometers in diameter, encase an anticancer drug to treat the AIDS-related Kaposi's sarcoma

Application: Manufacture of raw materialsCompany: Carbon NanotechnologiesDescription: Co-founded by buckyball discoverer Richard E. Smalley, the company has made carbon nanotubes more affordable by exploiting a new manufacturing process

나노입자의 기본원리와 응용 2002. 5. 14

Carbon Nanotube

나노입자의 기본원리와 응용 2002. 5. 14

Nano-rod

나노입자의 기본원리와 응용 2002. 5. 14

Nanostucture

Nanofabrication : comparing the method

Photolithography

Scanning Probe Method

Soft lithography

Bottom-Up Method

나노입자의 기본원리와 응용 2002. 5. 14

나노입자의 기본원리와 응용 2002. 5. 14

Single Molecule

Molecular engineering

Molecular Device -nanoelec

nano wire

nano transistor(switch)

nano diode

nano logic gate

나노입자의 기본원리와 응용 2002. 5. 14

나노입자의 기본원리와 응용 2002. 5. 14

Single molecular detection

• Scanning Tunneling Microscope(STM)

• Atomic Force Microscope(AFM)

• Scanning Probe Microscope(SPM)

• Near-Field Scanning Optical Mocroscopy(NSOM)

Two-Photon application

나노입자의 기본원리와 응용 2002. 5. 14

AFM

나노입자의 기본원리와 응용 2002. 5. 14

TP-NSOM

나노입자의 기본원리와 응용 2002. 5. 14

나노입자의 기본원리와 응용 2002. 5. 14

나노입자의 기본원리와 응용 2002. 5. 14

Famous Group

Nanoparticle A. Alivisatos(UC Berkeley)

M. Bawendi(MIT)

Carbon Nano : R. E. Smally(Rice)

C. Lieber(Harvard) H.Dai(Stanford)

Self-Assembley : G. Whiteside (Harvard)

Molecular Electronics : J. Heath, Stoddard(UCLA)

Soft Lithography : Mirkin (Northwestern)

Single Molecular Spectroscopy : Moener(Stanford)

S. Xie(Harvard), P. Barbara(Texas, Austin)

나노입자의 기본원리와 응용 2002. 5. 14

국내

나노 입자 : 이성훈 ( 광주과기원 ) 현택환 ( 서울대 응용화학부 )

천진우 ( 연세대 )

탄소나노 : 서정쌍 ( 서울대 ) 이영희 ( 성균관대 )

나노구조 : 이해원 ( 한양대 ) 하정숙 ( 고려대 화공 )

이명수 ( 연세대 )

단분자 분광학 : 강태종 ( 대구대 ) 송남웅 ( 표준연 )

자기조립 : 최인성 (KAIST)

초분자 : 김기문 ( 포항공대 )

나노입자의 기본원리와 응용 2002. 5. 14

“What I want to talk about is the problem of manipulating and controlling things on a small scale……What I have demonstrated is that there is room - that you can decrease the size of things in a practical way. I now want to show that there is plenty of room. I will not now discuss how we are going to do it, but only what is possible in principle….We are not doing it simply because we haven’t yet gotten around to it”

Richard Feynman, American Physical Society meeting at Caltech, 1959