Nanoscale Temperature Distributions Measured by Scanning Joule Expansion Microscopy. Majumdar, A. & Varesi, J. Journal of Heat Transfer, 120:297-305, May 1, 1998, 1998. ![Nanoscale Temperature Distributions Measured by Scanning Joule Expansion Microscopy [link]](https://bibbase.org/img/filetypes/link.svg "link")
Paper abstract bibtex This paper introduces scanning Joule expansion microscopy (SJEM), which is a new thermal imaging technique with lateral resolution in the range of 10–50 nm. Based on the atomic force microscope (AFM), SJEM measures the thermal expansion of Joule-heated elements with a vertical resolution of 1 pm, and provides an expansion map of the scanned sample. Sunmicron metal interconnect lines as well as 50-nm-sized single grains of an indium tin oxide resistor were images using SJEM. Since the local expansion signal is a convolution of local material properties, sample height, and as temperature rise, extraction of the thermal image requires deconvolution. This was experimentally achieved by coating the sample with a uniformly thick polymer film, resulting in direct measurement of the sample temperature distribution. A detailed thermal analysis of the metal wire and the substrate showed that the predicted temperature distribution was in good agreement with the measurements of the polymer-coated sample. However, the frequency response of the expansion signal agreed with theoretical predictions only below 30 KHZ, suggesting that contilever dynamics may play a significant role at higher frequencies. The major advantage of SJEM over previously developed submicron thermal imaging techniques is that it eliminates the need to nanofabricate specialized probes and requires only a standard AFM and simple electronics.
@article {827,
title = {Nanoscale Temperature Distributions Measured by Scanning Joule Expansion Microscopy},
journal = {Journal of Heat Transfer},
volume = {120},
year = {1998},
month = {May 1, 1998},
pages = {297-305},
abstract = {This paper introduces scanning Joule expansion microscopy (SJEM), which is a new thermal imaging technique with lateral resolution in the range of 10{\textendash}50 nm. Based on the atomic force microscope (AFM), SJEM measures the thermal expansion of Joule-heated elements with a vertical resolution of 1 pm, and provides an expansion map of the scanned sample. Sunmicron metal interconnect lines as well as 50-nm-sized single grains of an indium tin oxide resistor were images using SJEM. Since the local expansion signal is a convolution of local material properties, sample height, and as temperature rise, extraction of the thermal image requires deconvolution. This was experimentally achieved by coating the sample with a uniformly thick polymer film, resulting in direct measurement of the sample temperature distribution. A detailed thermal analysis of the metal wire and the substrate showed that the predicted temperature distribution was in good agreement with the measurements of the polymer-coated sample. However, the frequency response of the expansion signal agreed with theoretical predictions only below 30 KHZ, suggesting that contilever dynamics may play a significant role at higher frequencies. The major advantage of SJEM over previously developed submicron thermal imaging techniques is that it eliminates the need to nanofabricate specialized probes and requires only a standard AFM and simple electronics.},
isbn = {0022-1481},
url = {http://dx.doi.org/10.1115/1.2824245},
author = {Majumdar, A. and Varesi, J.}
}
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Based on the atomic force microscope (AFM), SJEM measures the thermal expansion of Joule-heated elements with a vertical resolution of 1 pm, and provides an expansion map of the scanned sample. Sunmicron metal interconnect lines as well as 50-nm-sized single grains of an indium tin oxide resistor were images using SJEM. Since the local expansion signal is a convolution of local material properties, sample height, and as temperature rise, extraction of the thermal image requires deconvolution. This was experimentally achieved by coating the sample with a uniformly thick polymer film, resulting in direct measurement of the sample temperature distribution. A detailed thermal analysis of the metal wire and the substrate showed that the predicted temperature distribution was in good agreement with the measurements of the polymer-coated sample. However, the frequency response of the expansion signal agreed with theoretical predictions only below 30 KHZ, suggesting that contilever dynamics may play a significant role at higher frequencies. The major advantage of SJEM over previously developed submicron thermal imaging techniques is that it eliminates the need to nanofabricate specialized probes and requires only a standard AFM and simple electronics.","isbn":"0022-1481","url":"http://dx.doi.org/10.1115/1.2824245","author":[{"propositions":[],"lastnames":["Majumdar"],"firstnames":["A."],"suffixes":[]},{"propositions":[],"lastnames":["Varesi"],"firstnames":["J."],"suffixes":[]}],"bibtex":"@article {827,\n\ttitle = {Nanoscale Temperature Distributions Measured by Scanning Joule Expansion Microscopy},\n\tjournal = {Journal of Heat Transfer},\n\tvolume = {120},\n\tyear = {1998},\n\tmonth = {May 1, 1998},\n\tpages = {297-305},\n\tabstract = {This paper introduces scanning Joule expansion microscopy (SJEM), which is a new thermal imaging technique with lateral resolution in the range of 10{\\textendash}50 nm. Based on the atomic force microscope (AFM), SJEM measures the thermal expansion of Joule-heated elements with a vertical resolution of 1 pm, and provides an expansion map of the scanned sample. Sunmicron metal interconnect lines as well as 50-nm-sized single grains of an indium tin oxide resistor were images using SJEM. Since the local expansion signal is a convolution of local material properties, sample height, and as temperature rise, extraction of the thermal image requires deconvolution. This was experimentally achieved by coating the sample with a uniformly thick polymer film, resulting in direct measurement of the sample temperature distribution. A detailed thermal analysis of the metal wire and the substrate showed that the predicted temperature distribution was in good agreement with the measurements of the polymer-coated sample. However, the frequency response of the expansion signal agreed with theoretical predictions only below 30 KHZ, suggesting that contilever dynamics may play a significant role at higher frequencies. The major advantage of SJEM over previously developed submicron thermal imaging techniques is that it eliminates the need to nanofabricate specialized probes and requires only a standard AFM and simple electronics.},\n\tisbn = {0022-1481},\n\turl = {http://dx.doi.org/10.1115/1.2824245},\n\tauthor = {Majumdar, A. and Varesi, J.}\n}\n","author_short":["Majumdar, A.","Varesi, J."],"key":"827","id":"827","bibbaseid":"majumdar-varesi-nanoscaletemperaturedistributionsmeasuredbyscanningjouleexpansionmicroscopy-1998","role":"author","urls":{"Paper":"http://dx.doi.org/10.1115/1.2824245"},"metadata":{"authorlinks":{"majumdar, a":"https://web.stanford.edu/group/magiclab/publications.html"}},"downloads":0},"bibtype":"article","biburl":"https://web.stanford.edu/group/magiclab/Biblio-Bibtex.bib","creationDate":"2019-06-17T06:21:29.659Z","downloads":0,"keywords":[],"search_terms":["nanoscale","temperature","distributions","measured","scanning","joule","expansion","microscopy","majumdar","varesi"],"title":"Nanoscale Temperature Distributions Measured by Scanning Joule Expansion Microscopy","year":1998,"dataSources":["gdJGyArc3xb5ekC5e","fmwcugs5KZsQWukEh"]}