Principles of Instrumental Analysis, Sixth Edition
By Skoog, Holler, Crouch
This document contain a list of journal links (page 1) and a list of 120 journal articles (pages
2–12) that can be found at the journal websites. You can access 11 of the articles (in Adobe
Acrobat PDF format) by clicking the article citation highlighted in yellow on pages 2–14.
Journal Links
Analyst Journal of Chromatography A
Analytical and Bioanalytical Chemistry
Analytica Chimica Acta
Analytical Biochemistry
Analytical Chemistry
Journal of Chromatography B
Journal of Mass Spectrometry
Journal of Geophysical Research
Journal of Physical Chemistry A
Applied Spectroscopy
Biochemical Journal
Crystal Growth and Design
Journal of Physics D: Applied Physics
Journal of Radioanalytical and Nuclear
Chemistry
Electroanalysis
Environmental Science and Technology
Journal of Agricultural and Food
Chemistry
Journal of the American Chemical
Society
Magnetic Resonance in Chemistry
Physical Review Letters
Science
Pure and Applied Chemistry
Reviews of Modern Physics
Journal of the American Society for
Mass Spectrometry
Journal of Chemical Education
Journal of Chemical Information and
Computer Sciences
(changed name to Journal of Chemical
Information and Modeling in January, 2005)
Sensors and Actuators B: Chemical
Spectrochimica Acta, Part B: Atomic
Spectroscopy
Talanta
Thermochimica Acta
Today’s Chemist at Work
Trends in Analytical Chemistry
Journal of Chromatographic Science
Journal Articles
Using Digital Object Identifiers
Many citations to journal articles contain digital object identifiers (DOIs), which are useful in locating online bibliographic information and links to the articles. One method for using the DOIs to locate an article is to access the home page of the International DOI Foundation at http://www.doi.org/ , paste or type the DOI of your article into the text box at the bottom on the page, and then click Submit. A second method is to construct the URL yourself by appending the
DOI to http://dx.doi.org/ . For example, the DOI for the article in Chapter 3 is
10.1021/ac60268a018, so the URL for the article is http://dx.doi.org/10.1021/ac60268a018 .
9/19/07

Certain journal publishers, such as the American Chemical Society, permit searching by DOI on their search pages. For more information regarding digital object identifiers, see http://www.doi.org/ .
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Chapter 1
1.
Data domains―an analysis of digital and analog instrumentation systems and components.
Enke, Christie G., Analytical Chemistry (1971), 43(1), 69A–73A, 75A–
76A, 78A, 80A. Publisher: American Chemical Society.
2.
Sensitivity and limit of detection in quantitative spectrometric methods.
Ingle, J. D.,
Jr, Journal of Chemical Education (1974), 51(2), 100–105. Publisher: Division of
Chemical Education of the American Chemical Society.
3.
Limit of detection. A closer look at the IUPAC definition.
Long, Gary L.;
Winefordner, J. D., Analytical Chemistry (1983), 55(7), 712A–714A, 716A, 718A, 720A,
722A, 724A. Publisher: American Chemical Society.
Chapter 2
No references
Chapter 3
1.
Automatic digital readout system for reaction-rate methods.
Cordos, E. M.; Crouch,
S. R.; Malmstadt, H. V., Analytical Chemistry (1968), 40(12), 1812–1818. Publisher:
American Chemical Society. DOI: 10.1021/ac60268a018
Chapter 4
1.
The amazing evolution of computerized instruments . Crouch, S. R.; Atkinson, T. V.,
Analytical Chemistry (2000), 72(17), 596A–603A. Publisher: American Chemical
Society.
Chapter 5
1.
Signal-to-noise enhancement through instrumental techniques. 1. Signals, noise, and
S/N enhancement in the frequency domain.
Hieftje, G. M., Analytical Chemistry
(1972), 44(6), 81A–82A, 84A, 86A–88A. Publisher: American Chemical Society.
2.
Smoothing and differentiation of data by simplified least squares procedures.
Savitzky, Abraham; Golay, Marcel J. E., Analytical Chemistry (1964), 36(8), 1627–1639.
Publisher: American Chemical Society. DOI: 10.1021/ac60214a047
3.
Signal-to-noise ratio enhancement by least-squares polynomial smoothing.
Enke, C.
G.; Nieman, Timothy A., Analytical Chemistry (1976), 48(8), 705A–706A, 708A, 710A,
712A Publisher: American Chemical Society.
2

Chapter 6
1.
Perspectives on the uncertainty principle and quantum reality.
Bartell, Lawrence S.,
Journal of Chemical Education (1985), 62(3), 192–96. Publisher: Division of Chemical
Education of the American Chemical Society.
2.
Accurate measurement of the Planck Constant.
Williams, Edwin R.; Steiner, Richard
L.; Newell, David B.; Olsen, Paul T., Physical Review Letters (1998), 81(12), 2404–
2407. Publisher: American Physical Society. DOI:10.1103/PhysRevLett.81.2404
3.
Least-squares adjustment of the atomic constants, 1952.
DuMond, Jesse W. M.;
Cohen, E. Richard., Reviews of Modern Physics (1953), 25, 691–708.
DOI:10.1103/RevModPhys.25.691
Chapter 7
1.
A comparison of optical detectors for the visible and ultraviolet.
Grossman, William
E. L., Journal of Chemical Education (1989), 66(8), 697–700. Publisher: Division of
Chemical Education of the American Chemical Society.
2.
Coupled wave theory for thick hologram gratings.
Kogelnik, H.
, The Bell System
Technical Journal (1969) 48, 2909–2947.
Chapter 8
1.
Sample introduction techniques for atomic spectroscopy.
Browner, Richard F.; Boorn,
Andrew W., Analytical Chemistry (1984), 56(7), 875A–876A, 878A, 880A, 883A, 885A,
887A–888A. Publisher: American Chemical Society.
2.
Sample introduction: the Achilles' heel of atomic spectroscopy?
Browner, Richard F.;
Boorn, Andrew W., Analytical Chemistry (1984), 56(7), 786A–788A, 790A, 792A,
794A, 796A, 798A. Publisher: American Chemical Society.
3.
Line broadening mechanisms in the low pressure laser-induced plasma.
Gornushkin,
Igor B.; King, Leslie A.; Smith, Ben W.; Omenetto, Nicolo; Winefordner, James D.,
Spectrochimica Acta Part B: Atomic Spectroscopy (1999), 54B(8), 1207–1217. Publisher:
Elsevier Science B.V. DOI:10.1016/S0584-8547(99)00064-6
Chapter 9
1.
A new background-correction method for atomic absorption spectrometry.
Smith, S.
B., Jr.; Hieftje, G. M., Applied Spectroscopy (1983), 37(5), 419-24. Publisher: Society for
Applied Spectroscopy.
2.
Influence of experimental parameters in electrothermal atomic absorption spectrometry on a priori calculated instrumental detection limits.
Cabon, J. Y.; Le
Bihan, A., Analyst (Cambridge, United Kingdom) (1997), 122(11), 1335–1341.
Publisher: Royal Society of Chemistry. DOI: 10.1039/a701308f
Chapter 10
1.
ICP-AES remains competitive.
Erickson, Britt. Analytical Chemistry (1998), 70(5),
211A–215A. Publisher: American Chemical Society.
2.
Error modeling and confidence interval estimation for inductively coupled plasma calibration curves.
Watters, Robert L., Jr.; Carroll, Raymond J.; Spiegelman, Clifford
H., Analytical Chemistry (1987), 59(13), 1639–43. Publisher: American Chemical
Society. DOI: 10.1021/ac00140a013
3

Chapter 11
1.
The quadrupole mass filter: basic operating concepts.
Miller, Philip E.; Denton, M.
Bonner., Journal of Chemical Education (1986), 63(7), 617–622. Publisher: Division of
Chemical Education of the American Chemical Society.
2.
AB-TOF mass spectrometer for the analysis of ions with extreme high start-up energies.
Lezius, M., Journal of Mass Spectrometry (2002), 37(3), 305–312. Publisher:
John Wiley & Sons Ltd. DOI: 10.1002/jms.286
Chapter 12
1.
X-ray fluorescence spectrometric analysis of geologic materials. Part 1. Principles and instrumentation.
Anzelmo, John A.; Lindsay, James R., Journal of Chemical
Education (1987), 64(8), A181–A185. Publisher: Division of Chemical Education of the
American Chemical Society.
2.
X-ray fluorescence spectrometric analysis of geologic materials. Part 2.
Applications.
Anzelmo, John A.; Lindsay, James R., Journal of Chemical Education
(1987), 64(9), A200, A202–A204. Publisher: Division of Chemical Education of the
American Chemical Society.
3.
Athena Mars rover science investigation.
Squyres, S. W., et al. J. Geophys. Res.
(2003), 108(E12), 8062. Publisher: American Geophysical Union.
DOI:10.1029/2003JE002121.
4.
Refined data of alpha proton x-ray spectrometer analyses of soils and rocks at the
Mars Pathfinder site: implications for surface chemistry.
Brückner, J.; Dreibus, G.;
Rieder, R.; Wänke, H., J. Geophys. Res.
(2003), 108(E12), 8094. Publisher: American
Geophysical Union. DOI:10.1029/2003JE002060.
5.
Chemistry of rocks and soils in Gusev Crater from the alpha particle x-ray spectrometer.
Gellert, R.; Rieder, R.; Anderson, R. C.; Brueckner, J.; Clark, B. C.;
Dreibus, G.; Economou, T.; Klingelhoefer, G.; Lugmair, G. W.; Ming, D. W.; Squyres, S.
W.; d'Uston, C.; Waenke, H.; Yen, A.; Zipfel, J., Science (2004), 305(5685), 829–833.
Publisher: American Association for the Advancement of Science. DOI:
10.1126/science.1099913
6.
Basaltic rocks analyzed by the Spirit rover in Gusev Crater.
McSween, H. Y.;
Arvidson, R. E.; Bell, J. F., III; Blaney, D.; Cabrol, N. A.; Christensen, P. R.; Clark, B.
C.; Crisp, J. A.; Crumpler, L. S.; Des Marais, D. J.; Farmer, J. D.; Gellert, R.; Ghosh, A.;
Gorevan, S.; Graff, T.; Grant, J.; Haskin, L. A.; Herkenhoff, K. E.; Johnson, J. R.; Jolliff,
B. L.; Klingelhoefer, G.; Knudson, A. T.; McLennan, S.; Milam, K. A.; Moersch, J. E.;
Morris, R. V.; Rieder, R.; Ruff, S. W.; de Souza, P. A., Jr.; Squyres, S. W.; Waenke, H.;
Wang, A.; Wyatt, M. B.; Yen, A.; Zipfel, J., Science (2004), 305(5685), 842–845.
Publisher: American Association for the Advancement of Science. DOI:
10.1126/science.3050842
7.
In situ evidence for an ancient aqueous environment at Meridiani Planum, Mars.
Squyres, S. W.; Grotzinger, J. P.; Arvidson, R. E.; Bell, J. F., III; Calvin, W.;
Christensen, P. R.; Clark, B. C.; Crisp, J. A.; Farrand, W. H.; Herkenhoff, K. E.; Johnson,
J. R.; Klingelhoefer, G.; Knoll, A. H.; McLennan, S. M.; McSween, H. Y., Jr.; Morris, R.
V.; Rice, J. W., Jr.; Rieder, R.; Soderblom, L. A., Science (2004), 306(5702), 1709–
1714. Publisher: American Association for the Advancement of Science. DOI:
10.1126/science.1104559
8.
Soils of Eagle Crater and Meridiani Planum at the Opportunity rover landing site.
Soderblom, L. A.; Anderson, R. C.; Arvidson, R. E.; Bell, J. F., III; Cabrol, N. A.;
Calvin, W.; Christensen, P. R.; Clark, B. C.; Economou, T.; Ehlmann, B.; Farrand, W.
4

H.; Fike, D.; Gellert, R.; Glotch, T. D.; Golombek, M. P.; Greeley, R.; Grotzinger, J. P.;
Herkenhoff, K. E.; Jerolmack, D. J.; Johnson, J. R.; Joliff, B.; Klingelhoefer, G.; Knoll,
A. H.; Learner, Z. A.; Li, R.; Malin, M. C.; McLennan, S. M.; McSween, H. Y.; Ming, D.
W.; Morris, R. V.; Rice, J. W., Jr.; Richter, L.; Rider, R.; Rodionov, D.; Schroeder, C.;
Seelos, F. P.; Soderblom, J. M.; Squyres, S. W.; Sullivan, R.; Watters, W. A.; Weitz, C.
M.; Wyatt, M. B.; Yen, A.; Zipfel, J., Science (2004), 306(5702), 1723–1726. Publisher:
American Association for the Advancement of Science. DOI: 10.1126/science.1105127
9.
Jarosite and hematite at Meridiani Planum from Opportunity's Mossbauer
Spectrometer . Klingelhofer, G.; Morris, R. V.; Bernhardt, B.; Schroder, C.; Rodionov,
D. S.; de Souza, P. A., Jr.; Yen, A.; Gellert, R.; Evlanov, E. N.; Zubkov, B.; Foh, J.;
Bonnes, U.; Kankeleit, E.; Gutlich, P.; Ming, D. W.; Renz, F.; Wdowiak, T.; Squyres, S.
W.; Arvidson, R. E., Science (2004), 306(5702), 1740–1745. Publisher: American
Association for the Advancement of Science. DOI: 10.1126/science.1104653
10.
Chemistry of rocks and soils at Meridiani Planum from the alpha particle x-ray spectrometer . Rieder, R.; Gellert, R.; Anderson, R. C.; Bruckner, J.; Clark, B. C.;
Dreibus, G.; Economou, T.; Klingelhofer, G.; Lugmair, G. W.; Ming, D. W.; Squyres, S.
W.; d'Uston, C.; Wanke, H.; Yen, A.; Zipfel, J., Science (2004), 306(5702), 1746–1749.
Publisher: American Association for the Advancement of Science. DOI:
10.1126/science.1104358
11.
Planetary science: the enigma of Martian soil.
Banin, Amos., Science (2005),
309(5736), 888–890. Publisher: American Association for the Advancement of Science.
DOI: 10.1126/science.1112794
12.
Monitoring the Mercury Menace , P. Stockwell, Today’s Chemist at Work , p. 27,
November 2003; Publisher: American Chemical Society.
Chapter 13
1.
Theoretical basis of the Bouguer-Beer law of radiation absorption.
Strong, Frederick
C., Analytical Chemistry (1952), 24, 338–342. Publisher: American Chemical Society.
DOI: 10.1021/ac60062a020
2.
Theoretical basis of the Bouguer-Beer law of radiation absorption.
Strong, F. C.
Analytical Chemistry (1952), 24, 2013. Publisher: American Chemical Society. DOI:
10.1021/ac60072a601
3.
Stray light in UV-VIS spectrophotometers.
Sharpe, M. R., Analytical Chemistry
(1984), 56(2), 339A–340A, 342A, 344A, 348A, 350A, 356A. Publisher: American
Chemical Society.
4.
Theoretical and experimental investigation of factors affecting precision in molecular absorption spectrophotometry.
Rothman, L. D.; Crouch, S. R.; Ingle, J. D.,
Jr., Analytical Chemistry (1975), 47(8), 1226–1233. Publisher: American Chemical
Society. DOI: 10.1021/ac60358a029
5.
Evaluation of precision of quantitative molecular absorption spectrometric measurements.
Ingle, J. D., Jr.; Crouch, S. R., Analytical Chemistry (1972), 44(8),
1375–1386. Publisher: American Chemical Society. DOI: 10.1021/ac60316a010
Chapter 14
1.
Ultraviolet and light absorption spectrometry.
Hargis, L. G.; Howell, J. A.; Sutton, R.
E., Analytical Chemistry (1996), 68(12), 169–183. Publisher: American Chemical
Society. DOI: 10.1021/a19600101
2.
Ultraviolet and absorption light spectrometry.
Howell, J. A.; Sutton, R. E., Analytical
Chemistry (1998), 70(12), 107-118 .
Publisher: American Chemical Society. DOI:
10.1021/a19800040
5

3.
Derivative and wavelength modulation spectrometry.
O'Haver, T. C., Dep. Chem.,,
Analytical Chemistry (1979), 51(1), 91A–92A, 94A, 96A, 99A–100A. Publisher:
American Chemical Society.
4.
Kinetic method that is insensitive to variables affecting rate constants.
Mieling, Glen
E.; Pardue, Harry L., Analytical Chemistry (1978), 50(12), 1611–1618. Publisher:
American Chemical Society. DOI: 10.1021/ac50034a011
5.
A spectrophotometric investigation of the interaction of iodine with aromatic hydrocarbons.
Benesi, H. A.; Hildebrand, J. H.
Journal of the American Chemical
Society (1949), 71, 2703–2707. Publisher: American Chemical Society. DOI:
10.1021/ja01176a030
6.
Polyiodine and polyiodide species in an aqueous solution of iodine + KI. Theoretical and experimental studies.
Calabrese, Vincent T.; Khan, Arshad., Journal of Physical
Chemistry A (2000), 104(6), 1287–1292. Publisher: American Chemical Society. DOI:
10.1021/jp992847r
Chapter 15
1.
Molecular fluorescence measurements with a charge-coupled device detector.
Epperson, Patrick M.; Jalkian, Rafi D.; Denton, M. Bonner., Analytical Chemistry (1989),
61(3), 282–285. Publisher: American Chemical Society. DOI: 10.1021/ac00178a020
2.
Rapid scanning fluorescence spectroscopy.
Johnson, D. W.; Callis, J. B.; Christian, G.
D., Analytical Chemistry (1977), 49(8), 747A–750A, 752A, 754A, 756A–757A.
Publisher: American Chemical Society.
3.
Time-resolved fluorescence spectroscopy for illuminating complex systems.
Bright,
Frank V.; Munson, Chase A., Analytica Chimica Acta (2003), 500(1–2), 71–104.
Publisher: Elsevier Science B.V. DOI:10.1016/S0003-2670(03)00723-2
Chapter 16
1.
Product review: the endearing FTIR spectrophotometer.
Smith, James P.; Hinson-
Smith, Vicki, Analytical Chemistry (2003), 75(1), 37A–40A. Publisher: American
Chemical Society.
2.
Quantitative analysis of trace mixtures of toluene and xylenes by CO2 laser photoacoustic spectrometry.
Zelinger, Z.; Strizik, M.; Kubat, P.; Civis, S. J., Analytica
Chimica Acta (2000), 422(2), 179–185. Publisher: Elsevier Science B.V. DOI:
10.1016/S0003-2670(00)01069-2
Chapter 17
1.
Computer-based structure determination: then and now.
Munk, Morton E., Journal of Chemical Information and Computer Sciences (1998), 38(6), 997-1009. Publisher:
American Chemical Society, Note: The Journal of Chemical Information and
Computer Sciences changed its name to Journal of Chemical Information and
Modeling in January, 2005. DOI : 10.1021/ci980083r
2.
Optical depth profiling by attenuated total reflection Fourier transform infrared spectroscopy: a new approach.
Ekgasit, Sanong; Ishida, Hatsuo., Applied Spectroscopy
(1996), 50(9), 1187–1195. Publisher: Society for Applied Spectroscopy. DOI:
10.1366/0003702963905178
3.
Application of a new quantitative optical depth profiling technique for the diffusion of polymers.
Ekgasit, Sanong; Ishida, Hatsuo., Applied Spectroscopy (1997), 51(4), 461–
465. Publisher: Society for Applied Spectroscopy. DOI: 10.1366/0003702971940594
6

Chapter 18
1.
Specific values of the depolarization ratio in Raman spectroscopy: their origins and significance.
Strommen, Dennis P., Journal of Chemical Education (1992), 69(10), 803–
807. Publisher: Division of Chemical Education of the American Chemical Society]
2.
Raman on the run.
Harris, Cheryl M., Analytical Chemistry (2003), 75(3), 75A–78A.
Publisher: American Chemical Society.
3.
Product review: Raman revisited.
Harris, Cheryl M., Analytical Chemistry (2002),
74(15), 433A–438A. Publisher: American Chemical Society.
4.
Simultaneous monitoring of protein and (NH4)2SO4 concentrations in aprotinin hanging-drop crystallization using Raman spectroscopy.
Tamagawa, Rosana E.;
Miranda, Everson A.; Berglund, Kris A., Crystal Growth & Design (2002), 2(6), 511–
514. Publisher: American Chemical Society. DOI: 10.1021/cg025544m
5.
The new interfacial ubiquity of surface-enhanced Raman spectroscopy.
Weaver,
Michael J.; Zou, Shouzhong; Chan, Ho Yeung H., Analytical Chemistry (2000), 72(1),
38A–47A. Publisher: American Chemical Society.
Chapter 19
1.
NMR spectroscopy: past and present.
Rabenstein, Dallas L., Analytical Chemistry
(2001), 73(7), 214A–223A. Publisher: American Chemical Society.
2.
Solid-state NMR: no longer the outcast.
Smith, James P., Analytical Chemistry (2002),
74(1), 45A–47A. Publisher: American Chemical Society.
3.
An

1-band-selective,

1-homonuclear decoupled ROESY experiment: application to the assignment of 1H NMR spectra of difficult-to-assign peptide sequences.
Kaerner, Andreas; Rabenstein, Dallas L., Magnetic Resonance in Chemistry (1998),
36(8), 601–607. Publisher: John Wiley & Sons Ltd. DOI: 10.1002/(SICI)1097-
458X(199808)36:8<601::AID-OMR342>3.0.CO;2-C
4.
Better brain imaging with chemometrics.
Witjes, Han; Simonetti, Arjan W.; Buydens,
Lutgarde, Analytical Chemistry (2001), 73(19), 548A–556A. Publisher: American
Chemical Society.
Chapter 20
1.
Mass spectrometry and its use in tandem with laser spectroscopy.
Grant, E. R.;
Cooks, R. G., Science (1990), 250(4977), 61–68. Publisher: American Association for the Advancement of Science. DOI: 10.1126/science.1699276
2.
Electrospray ionization for mass spectrometry of large biomolecules.
Fenn, J. B.;
Mann, M.; Meng, C. K.; Wong, S. F.; Whitehouse, C. M., Science (1989), 246(4926),
64–71. Publisher: American Association for the Advancement of Science. DOI:
10.1126/science.2675315
3.
Ion trap mass spectrometry: a personal perspective.
Stafford, George., Journal of the
American Society for Mass Spectrometry (2002), 13(6), 589-596. Publisher: Elsevier
Science Inc. Publisher: American Society for Mass Spectrometry. DOI:10.1016/S1044-
0305(02)00385-9
4.
A mini-review of mass spectrometry using high-performance FTICR-MS methods.
Heeren, R. M. A.; Kleinnijenhuis, A. J.; McDonnell, L. A.; Mize, T. H., Analytical and
Bioanalytical Chemistry (2004), 378(4), 1048–1058. Publisher: Springer-Verlag. DOI:
10.1007/s00216-003-2446-4
7

5.
Recent trends in mass spectrometer development . Hager, James W., Analytical and
Bioanalytical Chemistry (2004), 378(4), 845–50. Publisher: Springer-Verlag. DOI:
10.1007/s00216-003-2287-1
6.
Chemical ionization mass spectrometry of complex molecules. II. Alkaloids . Fales,
H. M.; Lloyd, H. A.; Milne, G. W., Journal of the American Chemical Society (1970),
92(6), 1590–1597. Publisher: American Chemical Society. DOI: 10.1021/ja00709a028
Chapter 21
1.
Analytical chemistry of surfaces. Part I. General aspects.
Hercules, David M.;
Hercules, Shirley H., Journal of Chemical Education (1984), 61(5), 402–409. Publisher:
Division of Chemical Education of the American Chemical Society.
2.
Electron spectroscopy: Applications for chemical analysis.
Hercules, David M.,
Journal of Chemical Education (2004), 81(12), 1751–1766. Publisher: Division of
Chemical Education of the American Chemical Society.
3.
The development of commercial ESCA instrumentation: a personal perspective.
Kelly, Michael A., Journal of Chemical Education (2004), 81(12), 1726–1733. Publisher:
Division of Chemical Education of the American Chemical Society.
4.
On the surface with Auger electron spectroscopy.
Felton, Michael J., Analytical
Chemistry (2003), 75(11), 269A–271A. Publisher: American Chemical Society.
5.
Functional group imaging by chemical force microscopy.
Frisbie, C. Daniel;
Rozsnyai, Lawrence F.; Noy, Aleksandr; Wrighton, Mark S.; Lieber, Charles M., Science
(1994), 265(5181), 2071–2074. Publisher: American Association for the Advancement of
Science. DOI: 10.1126/science.265.5181.2071
Chapter 22
1.
The dissociation constant of acetic acid from 0 º to 35 º .
Harned, Herbert S.; Ehlers,
Russell W., Journal of the American Chemical Society (1932), 54, 1350–1357. Publisher:
American Chemical Society. DOI: 10.1021/ja01343a013
Chapter 23
1.
Thirty years of ISFETOLOGY. What happened in the past 30 years and what may happen in the next 30 years.
Bergveld, P., Sensors and Actuators B: Chemical (2003),
B88(1), 1–20. Publisher: Elsevier Science B.V. DOI:10.1016/S0925-4005(02)00301-5
2.
Light-addressable potentiometric sensor for biochemical systems.
Hafeman, Dean G.;
Parce, J. Wallace; McConnell, Harden M., Science (1988), 240(4856), 1182–1185.
Publisher: American Association for the Advancement of Science. DOI:
10.1126/science.3375810
3.
Microfabricated potentiometric electrodes and their in vivo applications.
Lindner,
Erno; Buck, Richard P., Analytical Chemistry (2000), 72(9), 336A–345A. Publisher:
American Chemical Society.
4.
Recommendations for nomenclature of ion-selective electrodes.
Buck, Richard P.;
Lindner, Erno., Pure and Applied Chemistry (1994), 66(12), 2527–2536. Publisher:
Blackwell.
5.
Measurement of pH. Definition, standards, and procedures: (IUPAC
Recommendations 2002).
Buck, R. P.; Rondinini, S.; Covington, A. K.; Baucke, F. G.
K.; Brett, C. M. A.; Camoes, M. F.; Milton, M. J. T.; Mussini, T.; Naumann, R.; Pratt, K.
W.; Spitzer, P.; Wilson, G. S., Pure and Applied Chemistry (2002), 74(11), 2169–2200.
Publisher: International Union of Pure and Applied Chemistry.
8

6.
A practical guide to pH measurement in fresh-waters. Davison, W., Trends in
Analytical Chemistry (1990), 9(3), 80–83. Publisher: Elsevier Science B.V.
DOI:10.1016/0165-9936(90)87084-Y
7.
Direct potentiometric information on total ionic concentrations.
Ceresa, Alan;
Pretsch, Ernoe; Bakker, Eric., Analytical Chemistry (2000), 72(9), 2050–2054. Publisher:
American Chemical Society. DOI:10.1021/ac991092h
Chapter 24
1.
Determination of oxygen to uranium ratio in irradiated uranium dioxide by controlled potential coulometry.
Sarkar, S. R.; Une, K.; Tominaga, Y., Journal of
Radioanalytical and Nuclear Chemistry (1997), 220(2), 155–159. Publisher: Elsevier
Science S.A. DOI:10.1007/BF02034849
2.
Determination of multiple redox-active compounds by high-performance liquid chromatography with coulometric multi-electrode array system.
Yao, Jeffrey K.;
Cheng, Pu., Journal of Chromatography B: Analytical Technologies in the Biomedical and Life Sciences (2004), 810(1), 93–100. Publisher: Elsevier B.V.
DOI:10.1016/j.jchromb.2004.07.021
3.
The application of coulometry for total antioxidant capacity determination of human blood.
Ziyatdinova, Guzel K.; Budnikov, Herman C.; Pogorel'tzev, Valery I.;
Ganeev, Talgat S., Talanta (2006), 68(3), 800–805. Publisher: Elsevier B.V.
DOI:10.1016/j.talanta.2005.06.010
4.
Low parts per billion determination of sulfide by coulometric argentometry.
Pierce,
David T.; Applebee, Michelle S.; Lacher, Craig; Bessie, Jerry., Environmental Science and Technology (1998), 32(11), 1734–1737. Publisher: American Chemical Society.
DOI:10.1021/es970924v
Chapter 25
1.
Electrochemical Sensors.
Bakker, Eric; Qin, Yu., Analytical Chemistry (2006), 78(12),
3965–3983. Publisher: American Chemical Society. DOI:10.1021/ac060637m
2.
Electrochemical multianalyte immunoassays using an array-based sensor.
Wilson,
Michael S.; Nie, Weiyan., Analytical Chemistry (2006), 78(8), 2507–2513. Publisher:
American Chemical Society. DOI:10.1021/ac0518452
3.
Chemically modified electrodes: recommended terminology and definitions.
Durst,
R. A.; Baumner, A. J.; Murray, R. W.; Buck, R. P.; Andrieux, C. P., Pure and Applied
Chemistry (1997), 69(6), 1317–1323. Publisher: Blackwell.
4.
Cyclic voltammetry.
Kissinger, Peter T.; Heineman, William R., Journal of Chemical
Education (1983), 60(9), 702–706. Journal written in English. CAN 99:138916 AN
1983:538916 [Division of Chemical Education of the American Chemical Society]
5.
Cyclic voltammetry.
Evans, Dennis H.; O'Connell, Kathleen M.; Petersen, Ralph A.;
Kelly, Michael J., Journal of Chemical Education (1983), 60(4), 290–293. Publisher:
Division of Chemical Education of the American Chemical Society.
6.
Psychoanalytical electrochemistry: dopamine and behavior.
Venton, B. Jill;
Wightman, R. Mark., Analytical Chemistry (2003), 75(19), 414A–421A. Publisher:
American Chemical Society.
7.
Microelectrodes. Definitions, characterization, and applications: (technical report).
Stulik, Karel; Amatore, Christian; Holub, Karel; Marecek, Vladimir; Kutner,
Wlodzimierz., Pure and Applied Chemistry (2000), 72(8), 1483–1492. Publisher:
International Union of Pure and Applied Chemistry.
9

8.
Measurement of ultrasmall volumes using anodic stripping voltammetry.
Vandaveer,
Walter R., IV; Fritsch, Ingrid., Analytical Chemistry (2002), 74(14), 3575–3578.
Publisher: American Chemical Society. DOI:10.1021/ac011036s
Chapter 26
1.
Nomenclature for chromatography.
Ettre, L. S., Pure and Applied Chemistry (1993),
65(4), 819–872. Publisher: International Union of Pure and Applied Chemistry.
2.
A new form of chromatogram employing two liquid phases. I. A theory of chromatography. II. Application to the microdetermination of the higher monoamino acids in proteins.
Martin, A. J. P.; Synge, R. L. M. Biochemical Journal
(1941), 35, 1358–1368. Publisher: Portland Press on behalf of the Biochemical Society.
3.
Equations for calculation of chromatographic figures of merit for ideal and skewed peaks.
Foley, Joe P.; Dorsey, John G., Analytical Chemistry (1983), 55(4), 730–737.
Publisher: American Chemical Society. DOI:10.1021/ac00255a033
4.
Peak dispersion and mobile phase velocity in liquid chromatography: the pertinent relationship for porous silica.
Katz, E.; Ogan, K. L.; Scott, R. P. W., Journal of
Chromatography (1983), 270, 51–75. Publisher: Elsevier. DOI:10.1016/S0021-
9673(01)96351-4
Chapter 27
1.
Gas-liquid partition chromatography. A technique of the analysis of volatile minerals.
James, A. T.; Martin, A. J. P., Analyst (1952), 77, 915–932. Publisher: Royal
Society of Chemistry, London. DOI:10.1039/AN9527700915
2.
Method of characterization for gas chromatographic separation of liquids.
Rohrschneider, L., Journal of Chromatography (1966), 22(1), 6–22. Publisher: Elsevier.
Article written in German. DOI:10.1016/S0021-9673(01)97064-5
3.
Column selectivity programming and fast temperature programming for high-speed
GC analysis of purgeable organic compounds.
Smith, Heather; Sacks, Richard D.,
Analytical Chemistry (1998), 70(23), 4960–4966. Publisher: American Chemical Society.
DOI:10.1021/ac980463b
4.
High-speed gas chromatography.
Sacks, Richard; Smith, Heather; Nowak, Mark.,
Analytical Chemistry (1998), 70(1), 29A–37A. Publisher: American Chemical Society.
5.
Cinnamaldehyde content in foods determined by gas chromatography-mass spectrometry.
Friedman, Mendel; Kozukue, Nobuyuki; Harden, Leslie A., Journal of
Agricultural and Food Chemistry (2000), 48(11), 5702–5709. Publisher: American
Chemical Society. DOI:10.1021/jf000585g
Chapter 28
1.
Retention mechanisms of bonded-phase liquid chromatography.
Dorsey, John G.;
Cooper, William T., Analytical Chemistry (1994), 66(17), 857A–867A. Publisher:
American Chemical Society.
2.
Temperature dependence of retention in reversed-phase liquid chromatography. 1.
Stationary-phase considerations.
Cole, Lynn A.; Dorsey, John G., Analytical Chemistry
(1992), 64(13), 1317–1323. Publisher: American Chemical Society.
3.
Temperature dependence of retention in reversed-phase liquid chromatography. 2.
Mobile-phase considerations.
Cole, Lynn A.; Dorsey, John G.; Dill, Ken A., Analytical
Chemistry (1992), 64(13), 1324–1327. Publisher: American Chemical Society.
4.
Optimization of solvent strength and selectivity for reversed-phase liquid chromatography using an interactive mixture-design statistical technique.
Glajch,
10

Joseph L.; Kirkland, J. J.; Squire, Karen M.; Minor, James M., Journal of
Chromatography (1980), 199, 57–79. Publisher: Elsevier. DOI:10.1016/S0021-
9673(01)91361-5
Chapter 29
1.
Supercritical fluid chromatography, pressurized liquid extraction, and supercritical fluid extraction.
Henry, Matthew C.; Yonker, Clement R., Analytical Chemistry (2006),
78(12), 3909–3915. Publisher: American Chemical Society. DOI:10.1021/ac0605703
2.
Advances in environmental SFE.
McNally, Mary Ellen P., Analytical Chemistry
(1995), 67(9), 308A–315A. Publisher: American Chemical Society.
3.
Effect of ionic additives on the elution of sodium aryl sulfonates in supercritical fluid chromatography.
Zheng, J.; Taylor, L. T.; Pinkston, J. David; Mangels, M. L.,
Journal of Chromatography A (2005), 1082(2), 220–229. Publisher: Elsevier B.V.
DOI:10.1016/j.chroma.2005.04.086
Chapter 30
1.
Capillary electrophoresis.
Ewing, Andrew G.; Wallingford, Ross A.; Olefirowicz,
Teresa M., Analytical Chemistry (1989), 61(4), 292A–294A, 296A, 298A, 300A–303A.
Publisher: American Chemical Society.
2.
Capillary array electrophoresis DNA sequencing.
Kheterpal, Indu; Mathies, Richard
A., Analytical Chemistry (1999), 71(1), 31A–37A. Publisher: American Chemical
Society.
3.
Microfabricated 384-lane capillary array electrophoresis bioanalyzer for ultrahighthroughput genetic analysis.
Emrich, Charles A.; Tian, Huijun; Medintz, Igor L.;
Mathies, Richard A., Analytical Chemistry (2002), 74(19), 5076–5083. Publisher:
American Chemical Society. DOI:10.1021/ac020236g
4.
Electrokinetic separations with micellar solutions and open-tubular capillaries.
Terabe, Shigeru; Otsuka, Koji; Ichikawa, Kunimichi; Tsuchiya, Akihiro; Ando, Teiichi.,
Analytical Chemistry (1984), 56(1), 111–113. Publisher: American Chemical Society.
DOI:10.1021/ac00265a031
5.
Micellar electrokinetic chromatography.
Terabe, Shigeru., Analytical Chemistry
(2004), 76(13), 240A–246A. Publisher: American Chemical Society.
6.
Measuring colloidal and macromolecular properties by FFF.
Giddings, J. Calvin.,
Analytical Chemistry (1995), 67(19), 592A–598A. Publisher: American Chemical
Society.
7.
Distribution of zeptomole-abundant doxorubicin metabolites in subcellular fractions by capillary electrophoresis with laser-induced fluorescence detection.
Anderson,
Adrian B.; Ciriacks, Chanda M.; Fuller, Kathryn M.; Arriaga, Edgar A., Analytical
Chemistry (2003), 75(1), 8–15. Publisher: American Chemical Society.
DOI:10.1021/ac020426r
Chapter 31
1.
Thermal analysis.
Vyazovkin, Sergey., Analytical Chemistry (2006), 78(12), 3875–
3886. Publisher: American Chemical Society. DOI:10.1021/ac0605546
2.
Micro-thermal analysis: techniques and applications.
Pollock, H. M.; Hammiche, A.,
Journal of Physics D: Applied Physics (2001), 34(9), R23–R53. Publisher: Institute of
Physics Publishing. DOI:10.1088/0022-3727/34/9/201
3.
The use of micro-thermal analysis as a means of in situ characterization of a pharmaceutical tablet coat.
Royall, Paul G.; Craig, Duncan Q. M.; Grandy, David B.,
11

Thermochimica Acta (2001), 380(2), 165–173. Publisher: Elsevier Science B.V.
DOI:10.1016/S0040-6031(01)00667-0
4.
New method of purity determination by means of calorimetric differential thermal analysis.
Staub, Heiner; Perron, Werner, Analytical Chemistry (1974), 46(1), 128–130.
Publisher: American Chemical Society. DOI:10.1021/ac60337a039
Chapter 32
No references
Chapter 33
1.
Rapid analysis of discrete samples: the use of nonsegmented, continuous flow.
Stewart, Kent K.; Beecher, Gary R.; Hare, P. E., Analytical Biochemistry (1976), 70(1),
167–73. Publisher: Elsevier. DOI:10.1016/S0003-2697(76)80058-9
2.
Flow injection analyses. I. New concept of fast continuous flow analysis.
Ruzicka, J.;
Hansen, E. H., Analytica Chimica Acta (1975), 78(1), 145–57. Publisher: Elsevier.
DOI:10.1016/S0003-2670(01)84761-9
3.
Control of dispersion and variation of reaction coil length in flow injection analyzers by flow reversals.
Betteridge, D.; Oates, P. B.; Wade, Adrian P., Analytical Chemistry
(1987), 59(8), 1236–1238. Publisher: American Chemical Society.
DOI:10.1021/ac00135a036
4.
Sequential injection: a new concept for chemical sensors, process analysis and laboratory assays.
Ruzicka, Jaromir; Marshall, Graham D., Analytica Chimica Acta
(1990), 237(2), 329–43. Publisher: Elsevier. DOI:10.1016/S0003-2670(00)83937-9
5.
Where is analytical laboratory robotics going?
Luque de Castro, M. D.; Torres,
P., Trends in Analytical Chemistry (1995), 14(10), 492–496. Publisher: Elsevier.
DOI:10.1016/0165-9936(95)90810-A
6.
Glucose biosensors: 40 years of advances and challenges.
Wang, Joseph.,
Electroanalysis (2001), 13(12), 983–988. Publisher: Wiley-VCH Verlag GmbH.
7.
Biocatalytic carbon paste sensors based on a mediator pasting liquid.
Lawrence,
Nathan S.; Deo, Randhir P.; Wang, Joseph., Analytical Chemistry (2004), 76(13), 3735–
3739. Publisher: American Chemical Society. DOI:10.1021/ac049943v
Chapter 34
1.
Particle size determination by quasielastic light scattering.
McConnell, Michael L.,
Analytical Chemistry (1981), 53(8), 1007A–1008A, 1010A, 1016A, 1018A. Publisher:
American Chemical Society.
2.
Particle-size determination by centrifugal pipet sedimentation.
Kamack, H. J.,
Analytical Chemistry (1951), 23, 844–850. Publisher: American Chemical Society.
DOI:10.1021/ac60054a006
12