Keynote Address View Full Text


Ontology type: schema:Chapter     


Chapter Info

DATE

1997

AUTHORS

Michael F. Crommie

ABSTRACT

Over the last decade rapid growth has occurred in the variety of scanned probe techniques available.1 The vast array of familiar reciprocal space probes is now joined by a multitude of real space probes. The relatively new ability to observe real space properties of systems at microscopic-length scales has found wide applicability across the physical sciences, from physics and chemistry to biology, with no end in sight. Much of this advancement has been made possible by the ready availability of commercial instruments operating in air, liquid, and vacuum. One can now even purchase high performance combined STM/AFM devices, tailored to a particular application. Despite this rapid advancement, however, there still exists a feeling that the fields of scanned probe microscopy are in their infancy, perhaps with the best yet to come. New techniques continue to be developed, and a new philosophy of experimentation has begun to take shape. Rather than just use scanned probe instruments as passive tools of surface characterization, researchers are increasingly using them to intentionally modify the systems under study. This change brings with it a great many new possibilities. More... »

PAGES

1-3

Book

TITLE

Atomic Force Microscopy/Scanning Tunneling Microscopy 2

ISBN

978-1-4757-9327-7
978-1-4757-9325-3

Identifiers

URI

http://scigraph.springernature.com/pub.10.1007/978-1-4757-9325-3_1

DOI

http://dx.doi.org/10.1007/978-1-4757-9325-3_1

DIMENSIONS

https://app.dimensions.ai/details/publication/pub.1005194207


Indexing Status Check whether this publication has been indexed by Scopus and Web Of Science using the SN Indexing Status Tool
Incoming Citations Browse incoming citations for this publication using opencitations.net

JSON-LD is the canonical representation for SciGraph data.

TIP: You can open this SciGraph record using an external JSON-LD service: JSON-LD Playground Google SDTT

[
  {
    "@context": "https://springernature.github.io/scigraph/jsonld/sgcontext.json", 
    "about": [
      {
        "id": "http://purl.org/au-research/vocabulary/anzsrc-for/2008/02", 
        "inDefinedTermSet": "http://purl.org/au-research/vocabulary/anzsrc-for/2008/", 
        "name": "Physical Sciences", 
        "type": "DefinedTerm"
      }, 
      {
        "id": "http://purl.org/au-research/vocabulary/anzsrc-for/2008/0299", 
        "inDefinedTermSet": "http://purl.org/au-research/vocabulary/anzsrc-for/2008/", 
        "name": "Other Physical Sciences", 
        "type": "DefinedTerm"
      }
    ], 
    "author": [
      {
        "affiliation": {
          "alternateName": "Department of Physics, Boston University, 02215, Boston, MA, USA", 
          "id": "http://www.grid.ac/institutes/grid.189504.1", 
          "name": [
            "Department of Physics, Boston University, 02215, Boston, MA, USA"
          ], 
          "type": "Organization"
        }, 
        "familyName": "Crommie", 
        "givenName": "Michael F.", 
        "id": "sg:person.01046572263.84", 
        "sameAs": [
          "https://app.dimensions.ai/discover/publication?and_facet_researcher=ur.01046572263.84"
        ], 
        "type": "Person"
      }
    ], 
    "datePublished": "1997", 
    "datePublishedReg": "1997-01-01", 
    "description": "Over the last decade rapid growth has occurred in the variety of scanned probe techniques available.1 The vast array of familiar reciprocal space probes is now joined by a multitude of real space probes. The relatively new ability to observe real space properties of systems at microscopic-length scales has found wide applicability across the physical sciences, from physics and chemistry to biology, with no end in sight. Much of this advancement has been made possible by the ready availability of commercial instruments operating in air, liquid, and vacuum. One can now even purchase high performance combined STM/AFM devices, tailored to a particular application. Despite this rapid advancement, however, there still exists a feeling that the fields of scanned probe microscopy are in their infancy, perhaps with the best yet to come. New techniques continue to be developed, and a new philosophy of experimentation has begun to take shape. Rather than just use scanned probe instruments as passive tools of surface characterization, researchers are increasingly using them to intentionally modify the systems under study. This change brings with it a great many new possibilities.", 
    "editor": [
      {
        "familyName": "Cohen", 
        "givenName": "Samuel H.", 
        "type": "Person"
      }, 
      {
        "familyName": "Lightbody", 
        "givenName": "Marcia L.", 
        "type": "Person"
      }
    ], 
    "genre": "chapter", 
    "id": "sg:pub.10.1007/978-1-4757-9325-3_1", 
    "isAccessibleForFree": false, 
    "isPartOf": {
      "isbn": [
        "978-1-4757-9327-7", 
        "978-1-4757-9325-3"
      ], 
      "name": "Atomic Force Microscopy/Scanning Tunneling Microscopy 2", 
      "type": "Book"
    }, 
    "keywords": [
      "space probes", 
      "real-space probes", 
      "real space properties", 
      "scanned probe microscopy", 
      "probe instrument", 
      "probe microscopy", 
      "microscopic length scale", 
      "AFM device", 
      "probe technique", 
      "surface characterization", 
      "commercial instruments", 
      "new possibilities", 
      "space properties", 
      "ready availability", 
      "physics", 
      "probe", 
      "chemistry", 
      "vacuum", 
      "new technique", 
      "wide applicability", 
      "physical sciences", 
      "liquid", 
      "high performance", 
      "microscopy", 
      "instrument", 
      "characterization", 
      "field", 
      "devices", 
      "vast array", 
      "properties", 
      "new abilities", 
      "array", 
      "particular application", 
      "sight", 
      "technique", 
      "air", 
      "shape", 
      "applications", 
      "system", 
      "possibility", 
      "advancement", 
      "applicability", 
      "rapid advancement", 
      "variety", 
      "scale", 
      "performance", 
      "ability", 
      "biology", 
      "multitude", 
      "science", 
      "study", 
      "growth", 
      "changes", 
      "passive tools", 
      "rapid growth", 
      "tool", 
      "end", 
      "availability", 
      "experimentation", 
      "researchers", 
      "infancy", 
      "new philosophy", 
      "address", 
      "philosophy", 
      "keynote address", 
      "feelings"
    ], 
    "name": "Keynote Address", 
    "pagination": "1-3", 
    "productId": [
      {
        "name": "dimensions_id", 
        "type": "PropertyValue", 
        "value": [
          "pub.1005194207"
        ]
      }, 
      {
        "name": "doi", 
        "type": "PropertyValue", 
        "value": [
          "10.1007/978-1-4757-9325-3_1"
        ]
      }
    ], 
    "publisher": {
      "name": "Springer Nature", 
      "type": "Organisation"
    }, 
    "sameAs": [
      "https://doi.org/10.1007/978-1-4757-9325-3_1", 
      "https://app.dimensions.ai/details/publication/pub.1005194207"
    ], 
    "sdDataset": "chapters", 
    "sdDatePublished": "2022-11-24T21:16", 
    "sdLicense": "https://scigraph.springernature.com/explorer/license/", 
    "sdPublisher": {
      "name": "Springer Nature - SN SciGraph project", 
      "type": "Organization"
    }, 
    "sdSource": "s3://com-springernature-scigraph/baseset/20221124/entities/gbq_results/chapter/chapter_334.jsonl", 
    "type": "Chapter", 
    "url": "https://doi.org/10.1007/978-1-4757-9325-3_1"
  }
]
 

Download the RDF metadata as:  json-ld nt turtle xml License info

HOW TO GET THIS DATA PROGRAMMATICALLY:

JSON-LD is a popular format for linked data which is fully compatible with JSON.

curl -H 'Accept: application/ld+json' 'https://scigraph.springernature.com/pub.10.1007/978-1-4757-9325-3_1'

N-Triples is a line-based linked data format ideal for batch operations.

curl -H 'Accept: application/n-triples' 'https://scigraph.springernature.com/pub.10.1007/978-1-4757-9325-3_1'

Turtle is a human-readable linked data format.

curl -H 'Accept: text/turtle' 'https://scigraph.springernature.com/pub.10.1007/978-1-4757-9325-3_1'

RDF/XML is a standard XML format for linked data.

curl -H 'Accept: application/rdf+xml' 'https://scigraph.springernature.com/pub.10.1007/978-1-4757-9325-3_1'


 

This table displays all metadata directly associated to this object as RDF triples.

130 TRIPLES      22 PREDICATES      91 URIs      84 LITERALS      7 BLANK NODES

Subject Predicate Object
1 sg:pub.10.1007/978-1-4757-9325-3_1 schema:about anzsrc-for:02
2 anzsrc-for:0299
3 schema:author Nb7f0dd1971d24c6e8d287fb8da851036
4 schema:datePublished 1997
5 schema:datePublishedReg 1997-01-01
6 schema:description Over the last decade rapid growth has occurred in the variety of scanned probe techniques available.1 The vast array of familiar reciprocal space probes is now joined by a multitude of real space probes. The relatively new ability to observe real space properties of systems at microscopic-length scales has found wide applicability across the physical sciences, from physics and chemistry to biology, with no end in sight. Much of this advancement has been made possible by the ready availability of commercial instruments operating in air, liquid, and vacuum. One can now even purchase high performance combined STM/AFM devices, tailored to a particular application. Despite this rapid advancement, however, there still exists a feeling that the fields of scanned probe microscopy are in their infancy, perhaps with the best yet to come. New techniques continue to be developed, and a new philosophy of experimentation has begun to take shape. Rather than just use scanned probe instruments as passive tools of surface characterization, researchers are increasingly using them to intentionally modify the systems under study. This change brings with it a great many new possibilities.
7 schema:editor N3d9b08c9513246549137534f84478ee9
8 schema:genre chapter
9 schema:isAccessibleForFree false
10 schema:isPartOf N9fdecb69832547e38a17110f57e34b0c
11 schema:keywords AFM device
12 ability
13 address
14 advancement
15 air
16 applicability
17 applications
18 array
19 availability
20 biology
21 changes
22 characterization
23 chemistry
24 commercial instruments
25 devices
26 end
27 experimentation
28 feelings
29 field
30 growth
31 high performance
32 infancy
33 instrument
34 keynote address
35 liquid
36 microscopic length scale
37 microscopy
38 multitude
39 new abilities
40 new philosophy
41 new possibilities
42 new technique
43 particular application
44 passive tools
45 performance
46 philosophy
47 physical sciences
48 physics
49 possibility
50 probe
51 probe instrument
52 probe microscopy
53 probe technique
54 properties
55 rapid advancement
56 rapid growth
57 ready availability
58 real space properties
59 real-space probes
60 researchers
61 scale
62 scanned probe microscopy
63 science
64 shape
65 sight
66 space probes
67 space properties
68 study
69 surface characterization
70 system
71 technique
72 tool
73 vacuum
74 variety
75 vast array
76 wide applicability
77 schema:name Keynote Address
78 schema:pagination 1-3
79 schema:productId N25e5048aaf4f4c9aa424a592c73e5205
80 Nb2cac01d9b1f4f11862b9736512d73b3
81 schema:publisher N99c087c383a34884b21efdeb4f965631
82 schema:sameAs https://app.dimensions.ai/details/publication/pub.1005194207
83 https://doi.org/10.1007/978-1-4757-9325-3_1
84 schema:sdDatePublished 2022-11-24T21:16
85 schema:sdLicense https://scigraph.springernature.com/explorer/license/
86 schema:sdPublisher Nad9577be3afe4e7d9ada0a7a4ab6c3c7
87 schema:url https://doi.org/10.1007/978-1-4757-9325-3_1
88 sgo:license sg:explorer/license/
89 sgo:sdDataset chapters
90 rdf:type schema:Chapter
91 N25e5048aaf4f4c9aa424a592c73e5205 schema:name dimensions_id
92 schema:value pub.1005194207
93 rdf:type schema:PropertyValue
94 N3d9b08c9513246549137534f84478ee9 rdf:first Nf354504b9a274ab08ee21269c8ae05bf
95 rdf:rest N7580981e4c23428dbd2085c3c6e5534e
96 N7580981e4c23428dbd2085c3c6e5534e rdf:first Nb47c1a27840248abb5b1dbe84922e6bd
97 rdf:rest rdf:nil
98 N99c087c383a34884b21efdeb4f965631 schema:name Springer Nature
99 rdf:type schema:Organisation
100 N9fdecb69832547e38a17110f57e34b0c schema:isbn 978-1-4757-9325-3
101 978-1-4757-9327-7
102 schema:name Atomic Force Microscopy/Scanning Tunneling Microscopy 2
103 rdf:type schema:Book
104 Nad9577be3afe4e7d9ada0a7a4ab6c3c7 schema:name Springer Nature - SN SciGraph project
105 rdf:type schema:Organization
106 Nb2cac01d9b1f4f11862b9736512d73b3 schema:name doi
107 schema:value 10.1007/978-1-4757-9325-3_1
108 rdf:type schema:PropertyValue
109 Nb47c1a27840248abb5b1dbe84922e6bd schema:familyName Lightbody
110 schema:givenName Marcia L.
111 rdf:type schema:Person
112 Nb7f0dd1971d24c6e8d287fb8da851036 rdf:first sg:person.01046572263.84
113 rdf:rest rdf:nil
114 Nf354504b9a274ab08ee21269c8ae05bf schema:familyName Cohen
115 schema:givenName Samuel H.
116 rdf:type schema:Person
117 anzsrc-for:02 schema:inDefinedTermSet anzsrc-for:
118 schema:name Physical Sciences
119 rdf:type schema:DefinedTerm
120 anzsrc-for:0299 schema:inDefinedTermSet anzsrc-for:
121 schema:name Other Physical Sciences
122 rdf:type schema:DefinedTerm
123 sg:person.01046572263.84 schema:affiliation grid-institutes:grid.189504.1
124 schema:familyName Crommie
125 schema:givenName Michael F.
126 schema:sameAs https://app.dimensions.ai/discover/publication?and_facet_researcher=ur.01046572263.84
127 rdf:type schema:Person
128 grid-institutes:grid.189504.1 schema:alternateName Department of Physics, Boston University, 02215, Boston, MA, USA
129 schema:name Department of Physics, Boston University, 02215, Boston, MA, USA
130 rdf:type schema:Organization
 




Preview window. Press ESC to close (or click here)


...