Nanocar Race 2017: 4. Wie steuert man ein Nanocar? - TIB AV-Portal

Nanocar Race 2017: 4. Wie steuert man ein Nanocar?

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Zugehöriges Material

Beilstein-Institut zur Förderung der Chemischen Wissenschaften

Drude, Niklas Meier, Tobias

Formale Metadaten

Titel

Nanocar Race 2017: 4. Wie steuert man ein Nanocar?

Serientitel

Teil

4

Anzahl der Teile

163

Autor

Lizenz

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Identifikatoren

10.5446/50306 (DOI)

Herausgeber

Beilstein-Institut zur Förderung der Chemischen Wissenschaften

05jdrrw50 (ROR)

Erscheinungsjahr

Sprache

Inhaltliche Metadaten

Fachgebiet

Biowissenschaften / Biologie Chemie Physik

Genre

Dokumentation/Report

Abstract

Im Frühjahr 2017 findet in Toulouse (Frankreich) das kleinste Autorennen der Welt statt. Molekülgroße Fahrzeuge gehen dort an den Start. Auf einer Rennstrecke, die gerade mal einen Zehntausendstelmillimeter lang ist, konkurrieren sechs Forscherteams aus den USA, Japan, Deutschland, Frankreich Österreich und der Schweiz um den Sieg. Wie aber kann man ein einzelnes Molekül bewegen und dabei auch noch steuern? Das ist gar nicht so einfach, wie Niklas von Tobias erfährt.

Schlagwörter

molecular dynamics

Beilstein TV12 / 163

1

06:41

Wie funktioniert ein Teilchenbeschleuniger?

2

01:31

Nanocar Race 2017: 1. The Smallest Car in the World

3

01:47

Nanocar Race 2017: 1. Die kleinsten Autos der Welt

4

05:23

Wie entdeckt man neue Elemente?

5

02:45

Nanocar Race 2017: 2. Meet the Swiss Nano Dragster

6

02:43

Nanocar Race 2017: 2. Der Swiss Nano Dragster

7

06:34

Der Sternenstaub aus der Supernova

8

04:54

Nanocar Race 2017: 3. The Tools – STM and AFM

9

04:19

Nanocar Race 2017: 3. Wie man ein Nanocar sehen kann

10

04:55

Von der Supernova bis zum Neutronenstern

11

02:47

Nanocar Race 2017: 4. Driving the Nanocar – Manipulation of single molecules

12

03:10

Nanocar Race 2017: 4. Wie steuert man ein Nanocar?

13

04:55

Warum sind wir so schwer wie wir sind?

14

03:26

Nanocar Race 2017: 5. The Track – Preparation of the sample

15

04:08

Nanocar Race 2017: 5. Eine Piste aus Gold

16

04:48

Krebstherapie mit Schwerionen

17

03:20

Nanocar Race 2017: 6. The Environment

18

03:52

Nanocar Race 2017: 6. Eine extreme Umwelt

19

03:25

Nanocar Race 2017: Die Windmühle aus Dresden

20

10:54

Editorial flow chemistry II

21

18:48

Assembling Boron-Doped Polyphenylenes

22

11:32

The application of a monolithic triphenylphosphine reagent for conducting Appel reactions in flow microreactors

23

06:55

Mechanical characterization of carbon nanomembranes from self-assembled monolayers

24

13:32

Binary Pt-Si nanostructures prepared by focused electron-beam-induced deposition

25

12:27

Inductive Heating with Magnetic Materials inside Flow Reactors

26

09:10

Continuous flow photolysis of aryl azides: Preparation of 3H-azepinones

27

04:55

Introducing the Innovative Technology Centre

28

08:05

Continuous gas/liquid–liquid/liquid flow synthesis of 4-fluoropyrazole derivatives by selective direct fluorination

29

05:56

A practical microreactor for electrochemistry in flow

30

12:02

The rich history of organo-fluorine chemistry at the University of Durham

31

08:01

Polymerizations in miniemulsion

32

13:51

Charge transport through single molecules

33

11:09

Self-assembly of metal-complex-containing nanoparticles

34

09:04

Formation of precise 2D Au particle arrays via thermally induced dewetting on prepatterned substrates

35

08:52

The Single-Atom Transistor: Perspective for Quantum Electronics at Room Temperature

36

05:11

Magnetic nanostructures based on self-organization

37

08:42

The 'Ulm - Nanotoolbox' and a Demonstration of Superhydrophobicity of a single nanostructure

38

08:25

Colloidal and micellar approaches to prepare nanostructures

39

12:30

Continuous flow α-aminoxylation monitored by in-situ IR spectroscopy

40

10:31

Enyne cyclizations with cationic gold(I) complexes

41

11:25

Nanomechanical sensors for medical applications

42

11:16

From single molecules to dye-sensitized solar cells

43

1:00:53

Perspective on biological chemistry

44

09:47

Chemical lessons from bacteria

45

10:09

Smart carbohydrate chemistry as a means to understand glycocalyx biology

46

08:32

Molecular switches as motors of molecular machines

47

12:51

Mutasynthetic biotransformations

48

09:34

Surface functionalization towards biocompatible medical devices

49

13:43

Iron catalysis for biaryl coupling and ether cleavage reactions

50

14:34

3D-printed millifluidic reactionware for synthesis and analysis

51

09:08

3D-printed reactionware

52

10:22

Organic photochemistry from 1 to 4 eV

53

10:32

Olefin metathesis - ring-opening reaction

54

07:56

Single-molecule fluorescence excitation spectroscopy

55

09:12

Perspective on photochromic compounds

56

01:27

Nanophotonics, nano-optics and nanospectroscopy

57

14:39

Optochemical Genetics

58

48:27

Using light to control molecular and nanomaterials

59

19:25

Perspective on e-science, systems biology and drug discovery

60

05:55

Chemical reactions on conducting surfaces

61

08:22

Expanding the toolbox of cytochrome P450s through enzyme engineering

62

23:05

Perspective on chemistry and biology

63

59:10

Chemistry and biology: alkaloid biosynthesis in plants

64

07:32

Bioprocessing and protein glycosylation analysis

65

07:08

Carbohydrate modeling: a twisted tale

66

04:07

Investigating the role of glycosylation in multiple myeloma

67

04:08

Examining glycosylation changes

68

03:31

Identification of glycosylation abnormalities in galactosaemia

69

07:11

An introduction to immunoglobulin G

70

05:26

Mucin glycoproteins – a complex array of carbohydrate structures

71

04:56

Carbohydrate molecules as a potential means to prevent food poisoning

72

05:08

New elements – Alchemy with the accelerator

73

05:13

How does an accelerator for heavy ions work?

74

04:30

Tumor therapy – Fast ions in the fight against cancer

75

05:07

Creation of elements – supernova in the lab

76

04:00

Neutron stars – a melting pot for atomic nuclei

77

05:27

Antimatter: On the trail of the glueballs

78

11:13

Sugar hydrogels as biosensors

79

17:24

Fabrication of low-cost and large-area complex nanostructures: An overview to the concept

80

12:44

Fabrication of low-cost and large-area complex nanostructures: The fabrication process step by step

81

10:05

Synthesis of DNA with optical functionalities

82

07:20

The world’s smallest switchable magnet and its application in medical diagnostics

83

11:25

Mbandakamine A, a unique alkaloid from an african liana

84

10:14

Asymmetric organocatalysis in a ball mill

85

09:59

Biological and biologically inspired adhesives

86

06:33

Tetramolecular fluorescence complementation

87

11:51

A chemo-enzymatic approach for site- specific modification of the RNA cap

88

11:31

Olefin metathesis – ring-closing reaction

89

17:35

Enzymatic fluorination: The fluorinase enzyme from Streptomyces cattleya

90

07:04

Enzymatic radiosynthesis of an isotope-labelled halogenated sugar

91

11:01

Photoswitchable monolayers on silicon

92

07:37

Annihilation upconversion in ambient atmosphere

93

08:32

Surface patterning for biological applications

94

05:11

Novel applications of superhydrophilic-superhydrophobic patterned surfaces

95

10:07

Toxic epibatidine was structurally modified to image Alzheimer´s disease

96

08:44

Nanostructured catalysts for chemical energy storage

97

08:59

Mimicking Natural Surface Wettability with 3D Carbon Nanoarchitectures

98

06:15

How lipid membranes meet chip technology

99

13:00

Visible light mediated deoxygenations

100

05:24

Metal-Enhanced Antimicrobial Peptides

101

04:13

Laser rapid prototyping of bioactive materials for medical treatment

102

12:41

Structure Elucidation without NMR

103

10:43

Lithium-Sulfur Battery: From Materials Development to Production at Fraunhofer IWS

104

07:07

Photoswitchable molecules for the next generation devices

105

05:12

How do photoswitches work?

106

06:21

Ultrafast “Hydrogen on Demand”-technology by means of iron-catalysis

107

13:12

A Ru-catalysis based rechargeable H2-battery

108

05:56

From natural to technical branchings: functional analysis as basis for biomimetic transfer

109

10:32

Biomimetic research in the botanic garden of the University of Freiburg

110

05:03

Plant movements as concept generators for biomimetic materials and structures

111

12:14

Natural antibiotics from mushrooms based on metabolic profiling

112

06:58

Medicinal inorganic chemistry

113

04:35

Springtails – promising templates for robust omniphobic and anti-fouling surfaces

114

07:25

Attachment systems of climbing plants: an inspiration for bio-inspired solutions

115

07:26

Bidentate lewis acid catalysis for organic synthesis

116

04:50

Recipe for the preparation of a bidentate Lewis acid catalyst

117

09:56

Femtosecond dynamics of electronic motion in nanostructures

118

06:32

Light-metal interaction on the nanoscale

119

04:37

Anisotropic frictional properties of snake skin

120

06:59

Snake skin as functional biological material – Abrasion properties

121

04:11

Conductive textiles of hard matter by electrospinning

122

09:19

Chemical synthesis of antifeedant – natural products from the coca cola tree

123

06:22

nano.AR – technical applications of biomimetic nanostructures

124

09:55

Taste modifiers – Virtual Screening and Biocatalytic Production with Rationally Opzimized Enzymes

125

05:33

Functional gradients in fibrillar adhesives

126

06:41

Adhesion experiments and analysis of the human pathogen Acanthamoeba castellanii

127

09:03

Chemoenzymatic synthesis of oxygen heterocycles

128

05:53

Investigation of the anthropogenic Gadolinium (Gd) anomaly

129

05:47

Photoswitchable protein kinase Inhibitors for novel anti-cancer applications

130

09:12

Fixation of spin crossover complexes on surfaces

131

08:25

Switchable antifreeze proteins

132

06:03

Ultrafast molecular switches caught in the act

133

04:15

Nanoscale switches for memorizing polymers

134

08:48

Computational chemistry aids the discovery of phytoeffectors

135

06:53

Moving molecules by hand

136

04:20

Chemical imaging of biological tissues

137

05:48

Investigating drug metabolism with electrochemistry / mass spectrometry

138

05:19

Functional Polymers

139

09:42

Superconducting spin-electronics

140

08:31

Direct laser interference patterning

141

09:17

One pot synthesis of a cyclodextrin polyrotaxane and formation of a slide-ring gel

142

09:27

Detecting magnetism on the atomic scale

143

10:08

Continuously manufactured polymersomes by self-assembly using micro-technology

144

04:09

Der kleinste Schalter der Welt

145

07:25

Vom Tensid zur Biomembran

146

06:49

Können Metall-Ionen heilen helfen?

147

03:31

Nanocar Race 2017: The "Windmill" of the TU Dresden

148

03:39

Moleküle für den Bau von Rechenmaschinen

149

03:17

Molecules as gears and switches

150

02:58

Drähte auf atomarer Ebene

151

03:20

Building atomic wires

152

02:56

Acene - Molekulare Drähte generiert auf der Oberfläche

153

02:49

Acenes - On-surface generation of molecular wires

154

05:48

Photochemie: An und Aus mit Licht

155

06:23

Photochemie: Ungleiche Gleichgewichte

156

05:03

Photochemie: Ein chemisches Chamäleon

157

06:51

Photochemie: Underground-Minigolf

158

05:29

Photochemistry: Light turns On and Off

159

05:50

Photochemistry: What is a photon?

160

05:34

Photochemistry: Unequal equilibria

161

05:37

Photochemie: Was ist ein Photon?

162

04:21

Photochemistry: A chemical chameleon

163

06:33

Photochemistry: Underground-Minigolf

Automatisches Abspielen

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GezeitenstromSubstrat <Boden>SpanbarkeitTiermodellComputeranimationChemisches Experiment

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Computeranimation

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Substrat <Boden>StockfischFruchtmarkBesprechung/Interview

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WursthülleToll-like-RezeptorenBesprechung/Interview

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Gangart <Erzlagerstätte>NahrungsergänzungsmittelRäuchernSingle electron transferSystemische Therapie <Pharmakologie>WildbachElektronische ZigaretteMolekülElektron <Legierung>PrimärelementDiagramm

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Chemischer ProzessLevomethadonElektrolytische DissoziationZellteilungBesprechung/Interview

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Transkript: Englisch(automatisch erzeugt)

00:03

In the next video we will see a model, a STM, so a very fine microscope, and this is all of this machine. All of your models are here in this camera, this is our STM. Ok, so you can't see directly, where are you going to build it?

00:20

The building that we are going to see is a computer, we can use our handsets and build it. Ok, so what are you going to see now? So here you can see one nano-autos of the object. That's a lot of fun, right? So here you can see a nano-car.

00:40

Ok, and how do you get one of these molecules? Do you need one of these? Or how do you do it? The only thing we need is the ring. But we need it? Yes, we need it. Ok, so we need it in a very small way. How do you get one of these? We need it in a small way, but then we need it in contact with the molecule and we need it in contact with the molecule.

01:01

And what we need is that we need to position the nano-car and then fold our nano-car. Can you position it in a small way? Yes, I can position it in a small way. Here you can see the box. You can position it in a small way.

01:20

You can position it in a small way. So I can position it in a small way. Yes, that's why we need an anti-microscopy method and position it in the same way. Ok, but why does the nano-car position it in the same way? The nano-car position is in contact with the molecule.

01:42

It has a nitric energy. At the same time, we position the molecule in contact with the molecule. And then I can position it in a small way. And then I can position it in a small way. This way the energy will emerge. And when the molecule is in contact with the molecule, it can get an electron from the molecule in the opposite direction.

02:02

And you can see the surface. We have a battery that goes out of the way. And the energy in the battery goes out of the way. And we have a molecule that goes out of the way. So in this moment, when the energy is in contact with the molecule, the nano-car is in contact with the molecule. Do you have the build-up?

02:21

Is that the cost? No, that's our rent-track. And then we fold it. You can see the video. We fold the car up. Ah, there you have it. Now we can see what the rent-track is. What's not really possible. What happened in the nano-car race?

02:42

When the rent-track is in contact with the molecule, we can see the rent-track. But we have a wider fan. Ah, okay, you have a wider fan. Good. In this video, we saw how a small object like a nano-car can be used. In the next video, we will see how the rent-track can be used.

03:00

I hope to see you in the next video. See you next time.