Journal of Physical and Chemical Reference Data
Journal Impact IF - Analysis · Trend · Prediction · Ranking


New

Journal Impact IF

2019-2020

3.051

-34.9 %

Journal Impact IF Trend

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Journal of Physical and Chemical Reference Data

The 2019-2020 Journal Impact IF of Journal of Physical and Chemical Reference Data is 3.051, which is just updated in 2020.

Journal of Physical and Chemical Reference Data Impact Factor
Highest IF
4.684
Highest Journal Impact IF

The highest Journal Impact IF of Journal of Physical and Chemical Reference Data is 4.684.

Lowest IF
2.811
Lowest Journal Impact IF

The lowest Journal Impact IF of Journal of Physical and Chemical Reference Data is 2.811.

Total Growth Rate
-3.8%
IF Total Growth Rate

The total growth rate of Journal of Physical and Chemical Reference Data IF is -3.8%.

Annual Growth Rate
-0.4%
IF Annual Growth Rate

The annual growth rate of Journal of Physical and Chemical Reference Data IF is -0.4%.

Journal Impact IF Ranking

Subcategory Quartile Rank Percentile
Physical and Theoretical Chemistry Q1 21/162

Physical and Theoretical Chemistry 87%

General Physics and Astronomy Q1 20/224

General Physics and Astronomy 91%

General Chemistry Q1 50/398

General Chemistry 87%

Journal Impact IF Ranking

· In the Physical and Theoretical Chemistry research field, the Quartile of Journal of Physical and Chemical Reference Data is Q1. Journal of Physical and Chemical Reference Data has been ranked #21 over 162 related journals in the Physical and Theoretical Chemistry research category. The ranking percentile of Journal of Physical and Chemical Reference Data is around 87% in the field of Physical and Theoretical Chemistry.
· In the General Physics and Astronomy research field, the Quartile of Journal of Physical and Chemical Reference Data is Q1. Journal of Physical and Chemical Reference Data has been ranked #20 over 224 related journals in the General Physics and Astronomy research category. The ranking percentile of Journal of Physical and Chemical Reference Data is around 91% in the field of General Physics and Astronomy.
· In the General Chemistry research field, the Quartile of Journal of Physical and Chemical Reference Data is Q1. Journal of Physical and Chemical Reference Data has been ranked #50 over 398 related journals in the General Chemistry research category. The ranking percentile of Journal of Physical and Chemical Reference Data is around 87% in the field of General Chemistry.

Journal of Physical and Chemical Reference Data Impact Factor 2020-2021 Prediction

Journal of Physical and Chemical Reference Data Impact Factor Predition System

Journal of Physical and Chemical Reference Data Impact Factor Prediction System is now online. You can start share your valuable insights with the community.

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Total Publications
960
Total Citations
194326

Annual Publication Volume

Annual Citation Record

International Collaboration Trend

Cited Documents Trend

Journal Impact IF History

Year Journal Impact IF
Year Journal Impact IF
2019-2020 3.051
2018-2019 4.684
2017-2018 3.51
2016-2017 4.204
2015-2016 3.29
2014-2015 2.811
2013-2014 3.108
2012-2013 3.5
2011-2012 3.172
Journal Impact IF History

· The 2019-2020 Journal Impact IF of Journal of Physical and Chemical Reference Data is 3.051
· The 2018-2019 Journal Impact IF of Journal of Physical and Chemical Reference Data is 4.684
· The 2017-2018 Journal Impact IF of Journal of Physical and Chemical Reference Data is 3.51
· The 2016-2017 Journal Impact IF of Journal of Physical and Chemical Reference Data is 4.204
· The 2015-2016 Journal Impact IF of Journal of Physical and Chemical Reference Data is 3.29
· The 2014-2015 Journal Impact IF of Journal of Physical and Chemical Reference Data is 2.811
· The 2013-2014 Journal Impact IF of Journal of Physical and Chemical Reference Data is 3.108
· The 2012-2013 Journal Impact IF of Journal of Physical and Chemical Reference Data is 3.5
· The 2011-2012 Journal Impact IF of Journal of Physical and Chemical Reference Data is 3.172

Publications Cites Dataset

Year Publications Citations
Year Publications Citations
1971 0 8
1972 17 12
1973 23 54
1974 19 107
1975 10 256
1976 17 416
1977 19 433
1978 21 594
1979 28 690
1980 17 775
1981 17 961
1982 17 1081
1983 21 1097
1984 25 1262
1985 22 1415
1986 21 1671
1987 27 1706
1988 19 1755
1989 21 1979
1990 32 2190
1991 27 2485
1992 14 2710
1993 19 2538
1994 18 2867
1995 15 2876
1996 16 2802
1997 19 3283
1998 19 3173
1999 19 3394
2000 21 4146
2001 15 4039
2002 17 4285
2003 19 4386
2004 29 4692
2005 19 5127
2006 31 5007
2007 21 5449
2008 19 5280
2009 17 5731
2010 14 6045
2011 14 6991
2012 19 7918
2013 10 9123
2014 20 9811
2015 34 10104
2016 18 11048
2017 23 11162
2018 18 8971
2019 12 9259
2020 11 9975
2021 0 1187
Publications Cites Dataset

· The Journal of Physical and Chemical Reference Data has published 0 reports and received 8 citations in 1971.
· The Journal of Physical and Chemical Reference Data has published 17 reports and received 12 citations in 1972.
· The Journal of Physical and Chemical Reference Data has published 23 reports and received 54 citations in 1973.
· The Journal of Physical and Chemical Reference Data has published 19 reports and received 107 citations in 1974.
· The Journal of Physical and Chemical Reference Data has published 10 reports and received 256 citations in 1975.
· The Journal of Physical and Chemical Reference Data has published 17 reports and received 416 citations in 1976.
· The Journal of Physical and Chemical Reference Data has published 19 reports and received 433 citations in 1977.
· The Journal of Physical and Chemical Reference Data has published 21 reports and received 594 citations in 1978.
· The Journal of Physical and Chemical Reference Data has published 28 reports and received 690 citations in 1979.
· The Journal of Physical and Chemical Reference Data has published 17 reports and received 775 citations in 1980.
· The Journal of Physical and Chemical Reference Data has published 17 reports and received 961 citations in 1981.
· The Journal of Physical and Chemical Reference Data has published 17 reports and received 1081 citations in 1982.
· The Journal of Physical and Chemical Reference Data has published 21 reports and received 1097 citations in 1983.
· The Journal of Physical and Chemical Reference Data has published 25 reports and received 1262 citations in 1984.
· The Journal of Physical and Chemical Reference Data has published 22 reports and received 1415 citations in 1985.
· The Journal of Physical and Chemical Reference Data has published 21 reports and received 1671 citations in 1986.
· The Journal of Physical and Chemical Reference Data has published 27 reports and received 1706 citations in 1987.
· The Journal of Physical and Chemical Reference Data has published 19 reports and received 1755 citations in 1988.
· The Journal of Physical and Chemical Reference Data has published 21 reports and received 1979 citations in 1989.
· The Journal of Physical and Chemical Reference Data has published 32 reports and received 2190 citations in 1990.
· The Journal of Physical and Chemical Reference Data has published 27 reports and received 2485 citations in 1991.
· The Journal of Physical and Chemical Reference Data has published 14 reports and received 2710 citations in 1992.
· The Journal of Physical and Chemical Reference Data has published 19 reports and received 2538 citations in 1993.
· The Journal of Physical and Chemical Reference Data has published 18 reports and received 2867 citations in 1994.
· The Journal of Physical and Chemical Reference Data has published 15 reports and received 2876 citations in 1995.
· The Journal of Physical and Chemical Reference Data has published 16 reports and received 2802 citations in 1996.
· The Journal of Physical and Chemical Reference Data has published 19 reports and received 3283 citations in 1997.
· The Journal of Physical and Chemical Reference Data has published 19 reports and received 3173 citations in 1998.
· The Journal of Physical and Chemical Reference Data has published 19 reports and received 3394 citations in 1999.
· The Journal of Physical and Chemical Reference Data has published 21 reports and received 4146 citations in 2000.
· The Journal of Physical and Chemical Reference Data has published 15 reports and received 4039 citations in 2001.
· The Journal of Physical and Chemical Reference Data has published 17 reports and received 4285 citations in 2002.
· The Journal of Physical and Chemical Reference Data has published 19 reports and received 4386 citations in 2003.
· The Journal of Physical and Chemical Reference Data has published 29 reports and received 4692 citations in 2004.
· The Journal of Physical and Chemical Reference Data has published 19 reports and received 5127 citations in 2005.
· The Journal of Physical and Chemical Reference Data has published 31 reports and received 5007 citations in 2006.
· The Journal of Physical and Chemical Reference Data has published 21 reports and received 5449 citations in 2007.
· The Journal of Physical and Chemical Reference Data has published 19 reports and received 5280 citations in 2008.
· The Journal of Physical and Chemical Reference Data has published 17 reports and received 5731 citations in 2009.
· The Journal of Physical and Chemical Reference Data has published 14 reports and received 6045 citations in 2010.
· The Journal of Physical and Chemical Reference Data has published 14 reports and received 6991 citations in 2011.
· The Journal of Physical and Chemical Reference Data has published 19 reports and received 7918 citations in 2012.
· The Journal of Physical and Chemical Reference Data has published 10 reports and received 9123 citations in 2013.
· The Journal of Physical and Chemical Reference Data has published 20 reports and received 9811 citations in 2014.
· The Journal of Physical and Chemical Reference Data has published 34 reports and received 10104 citations in 2015.
· The Journal of Physical and Chemical Reference Data has published 18 reports and received 11048 citations in 2016.
· The Journal of Physical and Chemical Reference Data has published 23 reports and received 11162 citations in 2017.
· The Journal of Physical and Chemical Reference Data has published 18 reports and received 8971 citations in 2018.
· The Journal of Physical and Chemical Reference Data has published 12 reports and received 9259 citations in 2019.
· The Journal of Physical and Chemical Reference Data has published 11 reports and received 9975 citations in 2020.
· The Journal of Physical and Chemical Reference Data has published 0 reports and received 1187 citations in 2021.
· The total publications of Journal of Physical and Chemical Reference Data is 960.
· The total citations of Journal of Physical and Chemical Reference Data is 194326.

What is Impact Factor?

The impact factor (IF) or journal impact factor (JIF) of an academic journal is a scientometric index calculated by Clarivate that reflects the yearly average number of citations of articles published in the last two years in a given journal. It is frequently used as a proxy for the relative importance of a journal within its field; journals with higher impact factor values are often deemed to be more important, or carry more intrinsic prestige in their respective fields, than those with lower values.

Journal of Physical and Chemical Reference Data | Academic Accelerator - About the Impact Factor

Impact factor is commonly used to evaluate the relative importance of a journal within its field and to measure the frequency with which the “average article” in a journal has been cited in a particular time period. Journal which publishes more review articles will get highest IFs. Journals with higher IFs believed to be more important than those with lower ones. According to Eugene Garfield “impact simply reflects the ability of the journals and editors to attract the best paper available.” Journal which publishes more review articles will get maximum IFs. The Impact Factor of an academic journal is a scientometric Metric that reflects the yearly average number of citations that recent articles published in a given journal received. It is frequently used as a Metric for the relative importance of a journal within its field; journals with higher Impact Factor are often deemed to be more important than those with lower ones. The Journal of Physical and Chemical Reference Data Impact Factor IF measures the average number of citations received in a particular year (2020) by papers published in the Journal of Physical and Chemical Reference Data during the two preceding years (2018-2019). Note that 2020 Impact Factor are reported in 2021; they cannot be calculated until all of the 2020 publications have been processed by the indexing agency. New journals, which are indexed from their first published issue, will receive an impact factor after two years of indexing; in this case, the citations to the year prior to Volume 1, and the number of articles published in the year prior to Volume 1, are known zero values. Journals that are indexed starting with a volume other than the first volume will not get an impact factor until they have been indexed for three years. Occasionally, Journal Citation Reports assigns an impact factor to new journals with less than two years of indexing, based on partial citation data. The calculation always uses two complete and known years of item counts, but for new titles one of the known counts is zero. Annuals and other irregular publications sometimes publish no items in a particular year, affecting the count. The impact factor relates to a specific time period; it is possible to calculate it for any desired period. In addition to the 2-year Impact Factor, the 3-year Impact Factor, 4-year Impact Factor, 5-year Impact Factor, Real-Time Impact Factor can provide further insights and factors into the impact of Journal of Physical and Chemical Reference Data.

History

The impact factor was devised by Eugene Garfield, the founder of the Institute for Scientific Information (ISI). Impact factors are calculated yearly starting from 1975 for journals listed in the Journal Citation Reports (JCR). ISI was acquired by Thomson Scientific & Healthcare in 1992, and became known as Thomson ISI. In 2018, Thomson ISI was sold to Onex Corporation and Baring Private Equity Asia. They founded a new corporation, Clarivate, which is now the publisher of the JCR.

Use

The impact factor is used to compare different journals within a certain field. The Web of Science indexes more than 11,500 science and social science journals. Journal impact factors are often used to evaluate the merit of individual articles and individual researchers. This use of impact factors was summarised by Hoeffel:

Impact Factor is not a perfect tool to measure the quality of articles but there is nothing better and it has the advantage of already being in existence and is, therefore, a good technique for scientific evaluation. Experience has shown that in each specialty the best journals are those in which it is most difficult to have an article accepted, and these are the journals that have a high impact factor. Most of these journals existed long before the impact factor was devised. The use of impact factor as a measure of quality is widespread because it fits well with the opinion we have in each field of the best journals in our specialty....In conclusion, prestigious journals publish papers of high level. Therefore, their impact factor is high, and not the contrary.

Eugene Garfield

In brief, Impact factors may be used by:
  • Authors to decide where to submit an article for publication.
  • Libraries to make collection development decisions
  • Academic departments to assess academic productivity
  • Academic departments to make decisions on promotion and tenure.
As impact factors are a journal-level metric, rather than an article- or individual-level metric, this use is controversial. Garfield agrees with Hoeffel,but warns about the "misuse in evaluating individuals" because there is "a wide variation [of citations] from article to article within a single journal". Other things to consider about Impact Factors:
  • Many journals do not have an impact factor.
  • The impact factor cannot assess the quality of individual articles. Even if citations were evenly distributed among articles, the impact factor would only measure the interests of other researchers in an article, not its importance and usefulness.
  • Only research articles, technical notes and reviews are “citable” items. Editorials, letters, news items and meeting abstracts are “non-citable items”.
  • Only a small percentage of articles are highly cited and they are found in a small subset of journals. This small proportion accounts for a large percentage of citations.
  • Controversial papers, such as those based on fraudulent data, may be highly cited, distorting the impact factor of a journal.
  • Citation bias may exist. For example, English language resources may be favoured. Authors may cite their own work.
Moreover, informed and careful use of these impact data is essential, and should be based on a thorough understanding of the methodology used to generate impact factors. There are controversial aspects of using impact factors:
  • It is not clear whether the number of times a paper is cited measures its actual quality.
  • Some databases that calculate impact factors fail to incorporate publications including textbooks, handbooks and reference books.
  • Certain disciplines have low numbers of journals and usage. Therefore, one should only compare journals or researchers within the same discipline.
  • Review articles normally are cited more often and therefore can skew results.
  • Self-citing may also skew results.
  • Some resources used to calculate impact factors have inadequate international coverage.
  • Editorial policies can artificially inflate an impact factor.
Impact factors have often been used in advancement and tenure decision-making. Many recognize that this is a coarse tool for such important decisions, and that a multitude of factors should be taken into account in these deliberations. When considering the use of the impact factor (IF), keep these aspects in mind:
  • IF analysis is limited to citations from the journals indexed by the Web of Science/Web of Knowledge. Currently, the Web of Science indexes only 8621 journals across the full breadth of the sciences, and just 3121 in the social sciences.
  • A high IF/citation rate says nothing about the quality -- or even, validity -- of the references being cited. Notorious or even retracted articles often attract a lot of attention, hence a high number of citations. The notority related to the first publication on "cold fusion" is one such example.
  • Journals that publish more "review articles" are often found near the top of the rankings. While not known for publishing new, creative findings, these individual articles tend to be heavily cited.
  • The IF measures the average number of citations to articles in the journal -- given this, a small number of highly-cited articles will skew the figure.
  • It takes several years for new journals to be added to the list of titles indexed by the Web of Science/Web of Knowledge, so these newer titles will be under-represented.
  • It's alleged that journal editors have learned to "game" the system, encouraging authors to cite their works previously published in the same journal.
Comparing Journals Across Disciplines? Not a good idea! Using Impact Factors within a given discipline should only be done with great care, as described above. Using impact factor data to compare journals across disciplines is even more problematic. Here are some of the reasons:
  • Disciplines where older literature is still referenced, such as Chemistry and Mathematics, offer challenges to the methodolgy since older citations (older than two years) are not used to calculate the impact factor for a given journal. (Five-year impact factor analysis, which can be calculated using the Journal Citation Index database, helps smooth out this problem only to some degree.)
  • Different disciplines have different practices regarding tendency to cite larger numbers of references. Higher overall citation rates will bump upward impact factor measurements.
  • Where it's common for large numbers of authors to collaborate on a single paper, such as in Physics, the tendency of authors to cite themselves (and in this case, more authors) will result in increased citation rates.

Pros and Cons of the Impact Factor

Pros:

  • A vetted, established metric for measuring journal impact within a discipline.
  • Designed to eliminate bias based on journal size and frequency.
Cons:
  • Individual articles makes an uneven contribution to overall Impact Factor.
  • Impact Factor does not account for certain things, things like context (postive or negative citaion) and intentionality (self-citation).
  • The metric is proprietary to and bound by the contents of the Thomson Reuters database.
  • Citations, on which the Impact Factor is based, count for less than 1% of an article's overall use.

Criticism

Numerous critiques have been made regarding the use of impact factors. A 2007 study noted that the most fundamental flaw is that impact factors present the mean of data that are not normally distributed, and suggested that it would be more appropriate to present the median of these data. There is also a more general debate on the validity of the impact factor as a measure of journal importance and the effect of policies that editors may adopt to boost their impact factor (perhaps to the detriment of readers and writers). Other criticism focuses on the effect of the impact factor on behavior of scholars, editors and other stakeholders. Others have made more general criticisms, arguing that emphasis on impact factor results from negative influence of neoliberal policies on academia claiming that what is needed is not just replacement of the impact factor with more sophisticated metrics for science publications but also discussion on the social value of research assessment and the growing precariousness of scientific careers in higher education.
Experts stress that there are limitations in using impact factors to evaluate a scholar's work. There are many reasons cited for not relying on impact factor alone to evaluate the output of a particular individual. Among these are the following:

  • A single factor is not sufficient for evaluating an author's work.
  • Journal values are meaningless unless compared within the same discipline. Impact factors vary among disciplines.
  • The impact factor was originally devised to show the impact of a specific journal, not a specific scholar. The quality and impact of the author's work may extend beyond the impact of a particular journal.
According to Jim Testa, a researcher for ThomsonReuters Scientific, the most widespread misuse of the Impact Factor is to evaluate the work of an individual author (instead of a journal). "To say that because a researcher is publishing in a certain journal, he or she is more influential or deserves more credit is not necessarily true. There are many other variables to consider." (interview 6/26/2008 in Thomson Reuters blog entry)

Journal of Physical and Chemical Reference Data
Journal Profile

About

The Journal of Physical and Chemical Reference Data (JPCRD) is published by AIP Publishing for the U.S. Department of Commerce National Institute of Standards and Technology (NIST). The journal provides critically evaluated physical and chemical property data, fully documented as to the original sources and the criteria used for evaluation, preferably with uncertainty analysis. Critical reviews may also be included if they document a reference database, review the data situation in a field, review reference-quality measurement techniques, or review data evaluation methods. The Journal of Physical and Chemical Reference Data is a quarterly peer-reviewed scientific journal published by AIP Publishing on behalf of the National Institute of Standards and Technology. The objective of the journal is to provide critically evaluated physical and chemical property data, fully documented as to the original sources and the criteria used for evaluation, preferably with uncertainty analysis. The editors-in-chief are Donald R. Burgess, Jr, and Allan H. Harvey.

Highly Cited Keywords

ISSN
0047-2689
ISSN

The ISSN of Journal of Physical and Chemical Reference Data is 0047-2689 . An ISSN is an 8-digit code used to identify newspapers, journals, magazines and periodicals of all kinds and on all media–print and electronic.

ISSN (Online)
1529-7845
ISSN (Online)

The ISSN (Online) of Journal of Physical and Chemical Reference Data is 1529-7845 . An ISSN is an 8-digit code used to identify newspapers, journals, magazines and periodicals of all kinds and on all media–print and electronic.

Publisher
American Institute of Physics
Publisher

Journal of Physical and Chemical Reference Data is published by American Institute of Physics .

Publication Frequency
Bimonthly
Publication Frequency

Journal of Physical and Chemical Reference Data publishes reports Bimonthly .

Coverage
1972 - Present
Coverage

The Publication History of Journal of Physical and Chemical Reference Data covers 1972 - Present .

Open Access
NO
Open Access

Journal of Physical and Chemical Reference Data is Subscription-based (non-OA) Journal. Publishers own the rights to the articles in their journals. Anyone who wants to read the articles should pay by individual or institution to access the articles. Anyone who wants to use the articles in any way must obtain permission from the publishers.

Publication Fee
Publication Fee

There is no publication fee for submiting manuscript to Journal of Physical and Chemical Reference Data. Journal of Physical and Chemical Reference Data is Subscription-based (non-OA) Journal. Publishers own the rights to the articles in their journals. Anyone who wants to read the articles should pay by individual or institution to access the articles.

Language
English
Language

The language of Journal of Physical and Chemical Reference Data is English .

Country/Region
United States
Country/Region

The publisher of Journal of Physical and Chemical Reference Data is American Institute of Physics , which locates in United States .

Selected Articles

Full Title Authors
Full Title Authors
Reference Correlation for the Thermal Conductivity of Ammonia from the Triple-Point Temperature to 680 K and Pressures up to 80 MPa S.A. Monogenidou · Marc J. Assael · Marcia L. Huber · Marcia L. Huber
Update: Reference Correlation for the Viscosity of Ethane [J. Phys. Chem. Ref. Data 44, 043101 (2015)] Sebastian Herrmann · Robert Hellmann · Eckhard Vogel · Eckhard Vogel
Temperature Dependence of Mineral Solubility in Water. Part 2. Alkaline and Alkaline Earth Bromides Boris S. Krumgalz · Boris S. Krumgalz
Editorial: Review Articles Welcome in JPCRD Allan H. Harvey · R Donald BurgessJr. · R Donald BurgessJr.
Reference Data for the Density, Viscosity, and Surface Tension of Liquid Al–Zn, Ag–Sn, Bi–Sn, Cu–Sn, and Sn–Zn Eutectic Alloys Alexandra Dobosz · Tomasz Gancarz · Tomasz Gancarz
New Formulation for the Viscosity of n-Butane Sebastian Herrmann · Eckhard Vogel · Eckhard Vogel
Reference Correlation for the Viscosity of Ammonia from the Triple Point to 725 K and up to 50 MPa S.A. Monogenidou · Marc J. Assael · Marcia L. Huber · Marcia L. Huber
Reference Values and Reference Correlations for the Thermal Conductivity and Viscosity of Fluids Marc J. Assael · Agni E. Kalyva · S.A. Monogenidou · Marcia L. Huber · Richard A. Perkins · Daniel G. Friend · Eric F. May · Eric F. May
Energy Levels of Core-Excited 1s2l2l′ States in Lithium-Like Ions: Argon to Uranium V. A. Yerokhin · A. Surzhykov · A. Surzhykov
Reference Correlation for the Thermal Conductivity of n-Hexadecane from the Triple Point to 700 K and up to 50 MPa S.A. Monogenidou · Marc J. Assael · Marcia L. Huber · Marcia L. Huber
Elastic Constants, Bulk Modulus, and Compressibility of H2O Ice Ih for the Temperature Range 50 K–273 K J. J. Neumeier · J. J. Neumeier
Reference Correlation of the Viscosity of n-Hexadecane from the Triple Point to 673 K and up to 425 MPa Xianyang Meng · Y. K. Sun · F. L. Cao · Jiangtao Wu · Velisa Vesovic · Velisa Vesovic
A Relativistic Complex Optical Potential Calculation for Electron–Beryllium Scattering: Recommended Cross Sections R P McEachran · F. Blanco · G. García · M. J. Brunger · M. J. Brunger
Reference Correlations for the Thermal Conductivity of 13 Inorganic Molten Salts Ch. D. Chliatzou · M. J. Assael · K. D. Antoniadis · Marcia L. Huber · W. A. Wakeham · W. A. Wakeham
Reference Correlations for the Thermal Conductivity of n-Hexadecane from the Triple Point to 700 K and up to 50 MPa S.A. Monogenidou · Marc J. Assael · Marcia L. Huber · Marcia L. Huber
Thermodynamic Properties of the Glycine + H2O System Darren Rowland · Darren Rowland
On the Melting Curve of Sulfur Hexafluoride Allan H. Harvey · Allan H. Harvey
Reference Correlation for the Viscosity of Carbon Dioxide Arno R. Laesecke · Chris D. Muzny · Chris D. Muzny
Lanthanide Ionization Energies and the Sub-Shell Break. Part 1. The Second Ionization Energies David A. Johnson · Peter G. Nelson · Peter G. Nelson
Lanthanide Ionization Energies and the Sub-Shell Break. Part 2. The Third and Fourth Ionization Energies David A. Johnson · Peter G. Nelson · Peter G. Nelson
Estimation of Solvation Quantities from Experimental Thermodynamic Data: Development of the Comprehensive CompSol Databank for Pure and Mixed Solutes Edouard Moine · Romain Privat · Baptiste Sirjean · Jean-Noël Jaubert · Jean-Noël Jaubert
Cross Sections for Electron Collisions with Acetylene Mi-Young Song · Jung-Sik Yoon · Hyuck Cho · Grzegorz P. Karwasz · Viatcheslav Kokoouline · Yoshiharu Nakamura · Jonathan Tennyson · Jonathan Tennyson
Electron Collisions with Hydrogen Fluoride Yukikazu Itikawa · Yukikazu Itikawa
Phase Transition Enthalpy Measurements of Organic and Organometallic Compounds and Ionic Liquids. Sublimation, Vaporization and Fusion Enthalpies From 1880 to 2015. Part 2. C11-C192 William E. Acree · James S. Chickos · James S. Chickos
ランタニドイオン化エネルギーおよびサブシェル破壊 第1部 第2イオン化エネルギー A. Koutian · Marc J. Assael · Marcia L. Huber · Richard A. Perkins · Richard A. Perkins
Reference Correlation of the Thermal Conductivity of Cyclohexane from the Triple Point to 640 K and up to 175 MPa A. Koutian · Marc J. Assael · Marcia L. Huber · Richard A. Perkins · Richard A. Perkins
Cross Sections for Electron Collisions with NF3 Mi-Young Song · Jung-Sik Yoon · Hyuck Cho · Grzegorz P. Karwasz · Viatcheslav Kokoouline · Yoshiharu Nakamura · James R. Hamilton · Jonathan Tennyson · Jonathan Tennyson
IUPAC-NIST溶解度データシリーズ 89 アルカリ金属硝酸塩 第2部 硝酸ナトリウム Eysseltova Jitka · Zbranek Vladimir · Skripkin Mikhail Yurievich · Sawada Kiyoshi · Tepavitcharova Stefka · Tepavitcharova Stefka
Erratum:Calculation of Physicochemical Properties for Short- and Medium-Chain Chlorinated Paraffins[J. Phys. Chem. Ref. Data 42(2), 023103 (2013)] Juliane Glüge · Christian Bogdal · Martin Scheringer · Andreas M. Buser · Konrad Hungerbühler · Konrad Hungerbühler
Cross Sections for Electron Collisions with Ammonia Yukikazu Itikawa · Yukikazu Itikawa
Reference Correlations for the Thermal Conductivity of Liquid Bismuth, Cobalt, Germanium, and Silicon Marc J. Assael · Konstantinos D. Antoniadis · W. A. Wakeham · Marcia L. Huber · Hiroyuki Fukuyama · Hiroyuki Fukuyama
有機および有機金属化合物およびイオン液体の相転移エンタルピー測定 1880年から2015年の昇華,気化,および融解エンタルピー 第2部 C11-C192 Acree William · S Chickos James · S Chickos James
Critical Evaluation of Thermodynamic Properties for Halobenzoic Acids Through Consistency Analyses for Results from Experiment and Computational Chemistry Robert D. Chirico · Andrei F. Kazakov · Ala Bazyleva · Vladimir Diky · Kenneth G. Kroenlein · Vladimir N. Emel’yanenko · Sergey P. Verevkin · Sergey P. Verevkin
Recommended Ideal-Gas Thermochemical Functions for Heavy Water and its Substituent Isotopologues Irén Simkoacute · Tibor Furtenbacher · Jan Hruby · Nikolai F. Zobov · Oleg L. Polyansky · Jonathan Tennyson · Robert R. Gamache · Tamás Szidarovszky · Nóra Dénes · Attila G. Cśaszár · Attila G. Cśaszár
Correlations for the Viscosity and Thermal Conductivity of Ethyl Fluoride (R161) Ch. M. Tsolakidou · Marc J. Assael · Marcia L. Huber · Richard A. Perkins · Richard A. Perkins
Positron Scattering from Molecules: An Experimental Cross Section Compilation for Positron Transport Studies and Benchmarking Theory M. J. Brunger · Stephen Buckman · Kuru Ratnavelu · Kuru Ratnavelu
IUPAC-NIST Solubility Data Series. 104. Lithium Sulfate and its Double Salts in Aqueous Solutions Julia Sohr · Wolfgang Voigt · Dewen Zeng · Dewen Zeng
ランタニドイオン化エネルギーおよびサブシェル破壊 第2部 第3および第4イオン化エネルギー A Johnson David · G Nelson Peter · G Nelson Peter
Reference Correlations for the Viscosity and Thermal Conductivity of n-Undecane Marc J. Assael · T.B. Papalas · Marcia L. Huber · Marcia L. Huber
Reference Correlations of the Thermal Conductivity of Ethylene and Propylene | NIST A. Koutian · Marc J. Assael · Marcia L. Huber · Richard A. Perkins · Richard A. Perkins
Equation of State for the Lennard-Jones Fluid Monika Thol · Gábor Rutkai · Andreas M. Köster · Rolf Lustig · Roland Span · Jadran Vrabec · Jadran Vrabec
Vibration–rotation spectroscopic database on acetylene, X ˜ 1 Σ g + (12C2H2) Badr Amyay · André Fayt · Michel Herman · J. Vander Auwera · J. Vander Auwera
Recommended Correlations for the Surface Tension of Aliphatic, Carboxylic, and Polyfunctional Organic Acids A. Mulero · I. Cachadiña · E. L. Sanjuán · E. L. Sanjuán
Erratum:Surface Tension of Alcohols. Data Selection and Recommended Correlations[J. Phys. Chem. Ref. Data 44, 033104 (2015)] A. Mulero · I. Cachadiña · E. L. Sanjuán · E. L. Sanjuán
Reference Correlation of the Viscosity of meta-Xylene from 273 to 673 K and up to 200 MPa F. L. Cao · Xianyang Meng · Jiangtao Wu · Velisa Vesovic · Velisa Vesovic
Reference Correlation of the Thermal Conductivity of Carbon Dioxide from the Triple Point to 1100 K and up to 200 MPa Marcia L. Huber · E.A. Sykioti · Marc J. Assael · Richard A. Perkins · Richard A. Perkins
IUPAC-NIST Solubility Data Series. 101. Alcohols + Hydrocarbons + Water Part 3. C1–C3 Alcohols + Aromatic Hydrocarbons Paweł Oracz · Marian Góral · Barbara Wiśniewska-Gocłowska · David G. Shaw · Andrzej Mączyński · Andrzej Mączyński
Reference Correlations of the Thermal Conductivity of Ethene and Propene Marc J. Assael · A. Koutian · Marcia L. Huber · Richard A. Perkins · Richard A. Perkins
Cross sections for electron collisions with nitric oxide Yukikazu Itikawa · Yukikazu Itikawa
High-quality Thermodynamic Data on the Stability Changes of Proteins Upon Single-site Mutations Fabrizio Pucci · Raphaël Bourgeas · Marianne Rooman · Marianne Rooman
Phase Transition Enthalpy Measurements of Organic and Organometallic Compounds. Sublimation, Vaporization and Fusion Enthalpies From 1880 to 2015. Part 1. C1 − C10 William E. Acree · James S. Chickos · James S. Chickos
Definitive Ideal-Gas Thermochemical Functions of the H216O Molecule Tibor Furtenbacher · Tamás Szidarovszky · Jan Hrubý · Aleksandra A. Kyuberis · Nikolai F. Zobov · Oleg L. Polyansky · Jonathan Tennyson · Attila G. Császár · Attila G. Császár
元素1≦Z≦92から100GPaのゼロ-ケルビン圧縮等温線 A Young David · Cynn Hyunchae · Soderlind Per · Landa Alexander · Landa Alexander
ラジウム(Ra IおよびRa II)の分光データの比較 U. Dammalapati · Klaus-Peter Jungmann · Lorenz Willmann · Lorenz Willmann
IUPAC-NIST溶解度データシリーズ 101 アルコール+炭化水素+水 第2部 炭素数1~3のアルコール+脂肪族炭化水素 Oracz Pawel · Goral Marian · Wisniewska-Goclowska Barbara · G Shaw David · Maczynski Andrzej · Maczynski Andrzej
New Formulation for the Viscosity of Propane Eckhard Vogel · Sebastian Herrmann · Sebastian Herrmann
Compilation of Spectroscopic Data of Radium (Ra I and Ra II) U. Dammalapati · Klaus-Peter Jungmann · Lorenz Willmann · Lorenz Willmann
Zero-Kelvin Compression Isotherms of the Elements 1 ≤ Z ≤ 92 to 100 GPa David A. Young · Hyunchae Cynn · Per Soderlind · Alexander Landa · Alexander Landa