ABC D E FG H IJ K L M N O P Q R S T U V W X Y Z
• Shi, Wei and Maginn, Edward J., “Molecular Simulation of Ammonia Absorption in the Ionic Liquid 1-ethyl-3-methylimidazolium bis(trifluoro-methylsulfonyl)imide ([emim] [Tf2N]),” AIChE Journal, 2009, 55, 2414-2421.
American Chemical Society (Journal of the)
• Gurkan, Burcu E.; de la Fuente, Juan C.; Mindrup, Elaine M.; Ficke, Lindsay E.; Goodrich, Brett F.; Price, Erica A.; Schneider, William F.; and Brennecke, Joan F., “Equimolar CO2 Absorption by Anion-functionalized Ionic Liquids,” Journal of the American Chemical Society, 2010132, 2116-2117.
• Sigmon, Ginger; Ling, Jie; Unruh, Daniel K.; Moore-Shay, Laura; Ward, Matthew; Weaver, Brittany; and Burns, Peter C., “Uranyl-Peroxide Interactions Favor Nanocluster Self-assembly,” Journal of the American Chemical Society, 2009, 131 (46), 16648-16649.
• Kongkanand, A.; Tvrdy, K.; Takechi, K.; Kuno, M. K.; and Kamat, P. V., “Quantum Dot Solar Cells: Tuning Photoresponse through Size and Shape Control of CdSe-TiO2 Architecture,” Journal of the American Chemical Society, 2008, 130, 4007-4015.
Angewandte Chemie International Edition
• Wang, Shuao; Alekseev, Evgeny V.; Ling, Jie; Skanthakumar, S.; Soderholm, L.; Depmeier, Wulf; and Albrecht-Schmitt, Thomas E., “Neptunium Diverges Sharply from Uranium and Plutonium in Borate Matrixes: Insights into Actinide Materials Relevant to Nuclear Waste Storage,” Angewandte Chemie International Edition, 2010, 49, 1263-1266.
• Wang, Shuao; Alekseev, Evgeny V.; Diwu, Juan; Casey, William H.; Phillips, Brian L.; Depmeier, Wulf; and Albrecht-Schmitt, Thomas E., “NDTB-1: A Supertetrahedral Cationic Framework that Removes TcO4– from Solution,” Angewandte Chemie International Edition, 2010, 49, 1057-1060.
• Sigmon, Ginger E.; Unruh, Daniel K.; Ling, Jie; Weaver, Brittany; Ward, Matthew; Pressprich, Laura; Simonetti, Antonio; and Burns, Peter C., “Symmetry Versus Minimal Pentagonal Adjacencies in Uranium-based Polyoxometalate Fullerene Topologies,” Angewandte Chemie International Edition, 2009, 48, 2737-2740.
Applied Microbiology and Biotechnology
• Shea, Caitlyn and Nerenberg, Robert, “Performance and Microbial Ecology of Air-Cathode Microbial Fuel Cells with Layered Electrode Assemblies,” Applied Microbiology and Biotechnology, 2010, 86, 5, 1399.
Applied Physical Letters
• Jena, Debdeep; Fang, T.; Zhang, Q.; and Xing, Huili, “Zener Tunneling in Semiconducting Nanotube and Graphene Nanoribbon P-N Junctions,” Applied Physical Letters, 2008, Vol. 93, 11, 112106.
Applied Physics (Journal of the)
• Calderón-Muñoz, Williams R.; Jena, Debdeep; and Sen, Mihir, “Temperature Influence on Hydrodynamic Instabilities in a One-dimensional Electron Flow in Semiconductors,” Journal of Applied Physics, 2010, 107, 7, 074504.
Biological Applications of Microfluidics
• Iannacone, J., Kim, B.-Y., Sweedler, J.V., King, T.L., and Bohn, P.W., “Manipulating Mass Limited Samples Using Hybrid Microfluidic/ Nanofluidic Networks,” Biological Applications of Microfluidics, F.A. Gomez, ed., John Wiley & Sons, New York, 2008, Ch. 23, 451-472.
• Shi, Xiutao; Liu, X. Sherry; Wang, Xiang; Guo, X. Edward; and Niebur, Glen L., “Effects of Trabecular Type and Orientation on Microdamage Susceptibility in Trabecular Bone,” Bone, May 2010, 46 (5), 1260-1266. Also available on http://www.sciencedirect.com/science/issue/4987-2010-999539994-1864684.
• Kinman, W.S.; Neal, C.R.; Davidson; J.P.; and Font, L., (2009), "The Dynamics of Kerguelen Plateau Magma Evolution: New Insights from Major Element, Trace Element, and Sr Isotope Microanalysis of Plagioclase Hosted in Elan Bank Basalts," Chemical Geology, 2009. 264, 247-265.
IEEE Electron Device Letters
• Zhang, Q., Fang, T., Xing, H., Seabaugh, A., and Jena, D., “Graphene Nanoribbon Tunnel Transistors,” IEEE Electron Device Letters, 2008, 29, 11, 1340-1343.
Industrial & Engineering Chemistry Research
• Simoni, Luke D.; Ficke, Lindsay E.; Lambert, Caitlin A.; Stadtherr, Mark A.; and Brennecke, Joan F., “Measurement and Prediction of Vapor-Liquid Equilibrium of Aqueous 1-Ethyl-3-methylimidazolium-based Ionic Liquid Systems,” submitted to Industrial & Engineering Chemistry Research, 2010, 49 (8), 3893-3901.
• Simoni, Luke D.; Chapeaux, Alexandre; Brennecke, Joan F.; and Stadtherr, Mark A., “Asymmetric Framework for Predicting Liquid — Liquid Equilibrium of Ionic Liquid — Mixed-Solvent Systems. 2. Prediction of Ternary Systems,” Industrial & Engineering Chemistry Research, 2009, 48, 7257-7265.
JOM (The Member Journal of the Minerals, Metals & Materials Society)
• Roeder, Ryan K., “A Paradigm for the Integration of Biology in Materials Science and Engineering Materials Science and Biomedical Materials,” JOM, 2010, 62, 7, 49-56.
Nanoelectronics and Optoelectronics (Journal of)
• Orlov, A., Imre, A., Csaba, G., Ji, L., Porod, W., and Bernstein, G.H., “Magnetic Quantum-dot Cellular Automata: Recent Developments and Prospects,” Journal of Nanoelectronics and Optoelectronics,
2008, 3, 1-14.
• Shannon, M.A.; Bohn, P.W.; Elimelech, M.; Georgiadis, J.G.; Marinas, B.J.; and Mayes, A.M., "Science and Technology for Water Purification in the Coming Decades," Nature (London, United Kingdom), 2008, 452 (7185), 301-310.
Physical Chemistry C (Journal of)
• Kamat, P. V, “Quantum Dot Solar Cells: Semiconductor Nanocrystals as Light Harvesters,” Journal of Physical Chemistry C, 2008, 112, 18737-18753.
Physics Condensed Matter (Journal of)
• Maginn, Edward J., “Molecular Simulation of Ionic Liquids: Current Status and Future Opportunities,” Journal of Physics Condensed Matter, 2009, 21, 1-16.
• Simon, John; Protasenko, Vladimir; Lian, Chuanxin; Xing, Huili; and Jena, Debdeep, “Reports Polarization-induced Hole Doping in Wide-band-gap Unixial Semiconductor Heterostructures,” Science, 2010, 327, 5961, 60-64.
Water Environment Research
• Downing, Leon S.; Bibby, Kyle J.; Esposito, Kathleen; Fascianella, Tom; Tsuchihashi, Ryujiro; and Nerenberg, Robert, “Nitrogen Removal from Wastewater Using a Hybrid Membrane-biofilm Process: Pilot-scale Studies,” Water Environment Research, 2010, 82, 3, 195-201.
Research Paper Guidelines
Behrooz Parhami: 2007/06/20 || E-mail: parhami at ece.ucsb.edu || Other contact info at: Bottom of this page
Go up to: B. Parhami's course syllabi or his home page
The following is a suggested format for your course-related research or term paper. The general guidelines are followed by sample title pages.
Page 1 Title page should contain all of the following (see the sample title pages below):
Title of paper: max 20 words (make it short, yet descriptive); avoid abbreviations
Name of author
Telephone number(s) and e-mail address for quick contact in case of questions
"Research Paper for ECE x", where x is the course number (252B, 254B, etc.)
Quarter and year (e.g., "Winter 2020")
Body of abstract (summary of contributions and/or results; approx. 1 line per page)
"Keywords:" followed by 5 to 10 keywords and key phrases describing the content
Pages 2–k "1. INTRODUCTION"
Give background on the topic (provide context and include references on prior work), justify your interest in the topic, prepare the readers for what they will find in later sections, and summarize (in a few sentences) your main findings and/or contributions. This section must be kept short. If it exceeds, say, 3 pages, you may wish to break it up by including an additional section that covers the necessary details for one or more of the above aspects. Use a descriptive title such as "2. REVIEW OF PRIOR WORK" or "2. NOTABLE APPLICATIONS OF ... " for this section.
Pages (k+1)–l Body of the paper (10-20 pp. is considered reasonable) should consist of sections dealing with various aspects of the investigation as appropriate; e.g., theory, applications, design issues, tradeoffs, evaluation, experiments, comparisons with other methods or approaches. Don't be afraid to compare, criticize, and generally leave your personal mark on the paper. There is no general rule, except that subdivisions must be coherent and of reasonable length. Avoid the extremes of single-paragraph and 10-page sections. For very long sections, consider dividing up or moving some details to an appendix. If you present performance or speed-up comparisons for your ECE 254B research paper, then make sure to read:
Crowl, L.A., "How to Measure, Present, and Compare Parallel Performance", IEEE Parallel & Distributed Technology (now IEEE Concurrency), Vol. 2, No. 1, pp. 9-25, Spring 1994.
Pages (l+1)–m "q. CONCLUSION"
Give a brief summary (in a few sentences) of what has been presented and/or accomplished. Emphasize the advantages and disadvantages of the proposed approach, technique, or design. Discuss possible extensions of the work and any interesting/open problem that you can envisage. Like the INTRODUCTION, this section must be fairly short.
Pages (m+1)–n "REFERENCES"
Provide complete bibliographic information for each reference (see any paper in IEEE Trans. Computers for examples). As a rule of thumb, citing 5-20 references is reasonable; review or survey-type papers tend to have much more extensive bibliographies and original contributions breaking new ground may have fewer references. However, don't take this rule too seriously.
Figures/Tables If possible, include each figure or table close to where it is first referenced in the text. Figures and tables must be numbered and have descriptive captions. Elements of figures (boxes, curves, axes) and tables (columns and/or rows) must be clearly labeled, with units shown where appropriate. Do not copy/paste figures or tables from books, journals, or conference papers.
Special Notes I will keep all submitted papers and will return to you my comments on a separate sheet or in an e-mail message. Please make a copy for yourself before submitting. Plagiarism, in any form (outright copying or failure to properly credit ideas), will not be tolerated and will result in a failing grade.
There are many good references to help you with research methodology and technical writing. The following book, which covers writing techniques, research methods, refereeing, and oral presentations is particularly recommended.
Zobel, J., Writing for Computer Science, Springer, 2nd ed., 2004. [T11.Z62 2004]
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Sample title page #1 for a research paper:
A Procedure for Writing A-Level Research Papers
in Computer Arithmetic
A. Mark Earner
(987) 654-3210 Office
(123) 456-7890 Home
Research Paper for ECE 252B
The importance of earning good grades in graduate and upper-level undergraduate courses is well-recognized in academic circles. Although many instructors assign course grades in a seemingly random fashion, numerous studies have shown that the quality of a student’s work does in fact affect the final course grade. In this paper, I present a detailed procedure for submitting successful (A-level) papers in the field of computer arithmetic. The procedure starts with the important step of selecting the paper topic and continues with finding relevant references, taking notes, doing the actual research, organizing the material, writing the paper, and going through the appeals process if the final grade turns out to be unsatisfactory. Experimental results were obtained by asking 80 students to apply the procedure in producing their term papers for ECE 252B over a period of four years. Some 75% of these students earned grades of A+ or A, 15% ended up with A–, and the remaining 10% failed the course because the instructor discovered that they had copied papers published many years ago in certain obscure conferences.Keywords: Cheating, Course grades, Grade-point average, Graduate courses, How-to guide, Research paper, Student performance evaluation, Term paper.
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Sample title page #2 for a research paper:
The VLSI Approach to Computational Complexity*
Ann X. Student
(987) 654-3210 Office
(123) 456-7890 Home
Research Paper for ECE 254B
Advanced Computer Architecture: Parallel Processing
The rapid advances of VLSI and the trend toward the decrease of the geometrical feature size, through the submicron and the subnano to the subpico, and beyond, have dramatically reduced the cost of VLSI circuitry. As a result, many traditionally unsolvable problems can now (or will in the near future) be easily implemented using VLSI technology. In recent years, the cost of VLSI components has decreased exponentially. Hence, the application of an exponential number of processors does not cause any cost increase, and the application of only a polynomial number of processors leads to substantial cost savings. A system having an exponential number of processors will be able to solve many NP-complete problems in polynomial time. Furthermore, plotting processor costs as a function of time reveals that the cost of VLSI processors will soon become negative. Undoubtedly, this trend will create a competition for solving the same problem with more processors. We conclude that with the rapid advances of VLSI technology anything is possible and that the worth of a research paper is directly proportional to the number of processors in the system being proposed.
Keywords: Computational complexity, Concurrency, Massive parallelism, Negative-cost elements, NP-complete problems, Parallel processing, VLSI.
* Copied, with some modifications, from a piece of the same title by Danny Cohen,
in VLSI Systems and Computations, Computer Science Press, 1981, pp. 124-125.
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