Science 287, 1022 (2000)Fig. 4Pentacene Crystal FET

Nature 413, 713 (2001)Fig. 4 SAMFET (undiluted)

Science 294, 2138 (2001)Fig. 4 SAMFET (diluted)

Science 290, 963 (2000)Figure 1

Applied Physics Letters 77, 3776 (2000)Figure 2

Synthetic Metals 122, 195 (2001)Figure 2

Physical Review B 58, 12952 (1998)Figure 2, top. Look at top curve.

Physical Review B 63, 245201 (2001)Figure 2, pentacene single crystal

Nature 413, 713 (2001), Fig. 2.

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Nature 413, 713 (2001)Fig. 3. (same paper)Overlap except very close to 0.Note fine structure on -0.4 V curve, andcurrent axis scaled byexactly 2.

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Synthetic Metals 122, 195 (2001)Figure 3, pentacene

Applied Physics Letters 79, 4043 (2001)Figure 2, pentacene, output axis identical (including fine structurenear the tops of the peaks), but different scale on time axis

Thin Solid Films 385, 271 (2001)Figure 5, CdS, scaled by exactly a factor of 2 on output axis.

Nature 410, 189 (2001)Bottom two curves areidentical except for first point.

Science 287, 1022 (2000)Fig. 2 lowerPentacene Crystal FET

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Science 288, 656 (2000)Fig. 1 lowerC60 FET

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Nature 406, 702 (2000)Fig 3Superconductivity in molecular crystals

Advanced Materials 13, 1273 (2001), Fig. 1.Compare noise on OPV4 curve to the tetracence curve on theprevious Nature graph. OPV5 is suspiciously similar to pentacene, but the data are cut off.

Science 288, 2338 (2000) Fig. 2 Phys. Stat. Sol. 226, 257 (2001) Fig. 4

Rxx data are shifted between graphs along the carrier concentration axis

Science 289, 599 (2000), “An Organic Solid State Injection Laser”(a) and (c) insets to Fig. 2, 5 K.(b) and (d) insets to Fig. 5, room temperature.Current densities are also said to be different for all 4 graphs.

(a) (b) (c) (d)

Journal of Applied Physics 79, 6961 (1996). Fig. 1

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Note repeated double-points in both * and ** curves

Solar Energy Materials and Solar Cells 57, 229 (1999). Fig. 1

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Solar Energy Materials and Solar Cells 57, 229 (1999). Fig. 2

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