Novel Rewritable, Non‐volatile Memory Devices Based on Thermally and Dimensionally Stable Polyimide Thin Films

Hahm, Suk Gyu; Choi, Seungchel; Hong, Sang Hyun; Lee, Taek Joon; Park, Samdae; Kim, Dong-Min; Kwon, Won Sang; Kim, Kyung‐Tae; Kim, Ohyun; Ree, Moonhor

doi:10.1002/adfm.200800758

Cited by 171 publications

(91 citation statements)

References 32 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…[5,6] Because all of the devices were fabricated by using the same method under controlled conditions, the thicknesses of thin films of NIT n CzNO 2 (n = 0, 1, 2) were very consistentw ith each other (ca. 80 nm;s ee the Supporting Information, Figure S5).…”

Section: Performance Of the Memory Devicesmentioning

confidence: 99%

See 1 more Smart Citation

Inserting Thienyl Linkers into Conjugated Molecules for Efficient Multilevel Electronic Memory: A New Understanding of Charge‐Trapping in Organic Materials

et al. 2016

Chemistry An Asian Journal

View full text Add to dashboard Cite

The practical application of organic memory devices requires low power consumption and reliable device quality. Herein, we report that inserting thienyl units into D-π-A molecules can improve these parameters by tuning the texture of the film. Theoretical calculations revealed that introducing thienyl π bridges increased the planarity of the molecular backbone and extended the D-A conjugation. Thus, molecules with more thienyl spacers showed improved stacking and orientation in the film state relative to the substrates. The corresponding sandwiched memory devices showed enhanced ternary memory behavior, with lower threshold voltages and better repeatability. The conductive switching and variation in the performance of the memory devices were interpreted by using an extended-charge-trapping mechanism. Our study suggests that judicious molecular engineering can facilitate control of the orientation of the crystallite in the solid state to achieve superior multilevel memory performance.

show abstract

Section: Performance Of the Memory Devicesmentioning

confidence: 99%

“…[1c, 5,6] These requirements become more challenging for multilevel RRAMs, because the writing/reading voltagew indows for each level must be separated within an arrow range.…”

Section: Introductionmentioning

confidence: 99%

Inserting Thienyl Linkers into Conjugated Molecules for Efficient Multilevel Electronic Memory: A New Understanding of Charge‐Trapping in Organic Materials

et al. 2016

Chemistry An Asian Journal

View full text Add to dashboard Cite

show abstract

“…[1][2][3][4] Among the various types of organic memory devices, a considerable number of studies have been devoted to nonvolatile memory systems that include organic-resistive-switching diode memory and organic fieldeffect transistor (OFET) memory. [5][6][7][8][9][10][11][12][13][14][15][16][17] The organic-resistive-switching diode memory devices consist of organic-resistive layers between two electrodes, which typically act as either electrically insulating components or electrically conducting components under appropriate voltage conditions. [5][6][7][8][9][10] However, the organic-resistiveswitching diode memory devices require transistors for addressing signals in two-dimensional memory arrays because they do not possess third electrodes for signal addressing.…”

Section: Introductionmentioning

confidence: 99%

Organic nonvolatile memory transistors with self-doped polymer energy well structures

Nam

Hahm

et al. 2013

NPG Asia Mater

Self Cite

View full text Add to dashboard Cite

Developing organic nonvolatile memory devices with a writing/reading/erasing logic function in actual array structures is extremely important for realizing low-cost lightweight/flexible plastic electronic systems. Here, we demonstrate that organic field-effect transistors (OFETs) with a polymer energy well structure (PEW-OFET) exhibit excellent nonvolatile memory performances. The PEW structure is created by sandwiching a self-doped poly(o-anthranilic acid) (SD-PARA) nanolayer (high dielectric constant, k ¼ 14) between two low-dielectric polymer layers (k ¼ 2-4). The primary idea behind this concept is the rapid storage and retrieval of charge carriers in the PEW layer during operation due to the high k feature of the SD-PARA nanolayer, which aids the rapid transport of charge carriers inside, whereas the stored charges are safely trapped due to the two low k layers. The results indicate that the PEW-OFET memory devices exhibit outstanding retention characteristics upon continuous reading up to 2000 s after writing, whereas their excellent writing/reading/erasing/reading cyclability is demonstrated in a test with 43000 cycles. Therefore, the present simple yet cost-effective PEW-OFET concept is expected to significantly contribute to the development of low-cost plastic memory array devices because all processes can be inexpensively performed at low temperatures and additional logic transistors are unnecessary.

show abstract

“…[16][17][18][19] Thus far, numerous electrical memory polymers composed either of fully π-conjugated backbones [17][18][19][21][22][23][24][25] or of nonconjugated backbones bearing only electron-donor units or both electron-donor and -acceptor units as parts of the backbone and/or side groups have been reported. [18][19][20][26][27][28][29] In particular, the majority of the nonconjugated polymers have been synthesized with carbazole, triphenylamine, fluorine and their derivatives. [18][19][20][26][27][28][29] Moreover, they are known to mainly exhibit p-type electrical memory characteristics.…”

Section: Introductionmentioning

confidence: 99%

“…[18][19][20][26][27][28][29] In particular, the majority of the nonconjugated polymers have been synthesized with carbazole, triphenylamine, fluorine and their derivatives. [18][19][20][26][27][28][29] Moreover, they are known to mainly exhibit p-type electrical memory characteristics. In contrast, n-type memory polymers have rarely been reported.…”

Section: Introductionmentioning

confidence: 99%

High-performance triazole-containing brush polymers via azide–alkyne click chemistry: a new functional polymer platform for electrical memory devices

Song

Lee

et al. 2015

NPG Asia Mater

Self Cite

View full text Add to dashboard Cite

Two series of well-defined brush polymers bearing a triazole moiety on each bristle were prepared from the click chemistry reactions of a poly(glycidyl azide) (PG) and a poly(4-azidomethylstyrene) (PS) with alkyne derivatives. The thin-film morphologies and properties, especially electrical memory performances, of these triazole-containing brush polymers were investigated in detail. The brush polymers with a triazole ring substituted with an alkyl or alkylenylphenyl group in the bristle exhibited only dielectric characteristics. By contrast, the other brush polymers bearing a triazole ring substituted with phenyl or its derivatives with a longer π-conjugation length in the bristle demonstrated excellent unipolar permanent memory behaviors with low power consumption, high ON/OFF current ratios and high stability and reliability under ambient air conditions. Furthermore, their memory type could be tuned to p-or n-type by the incorporation of an electron-donating or -accepting group into the phenyl unit linked to the triazole moiety. Overall, this study presents the first demonstration of the azide-alkyne click chemistry synthesis of triazole moieties with substituent(s) that exhibit a resonance effect; this approach is a very powerful synthetic route to develop electrical memory polymers suitable for the low-cost mass production of high-performance, polarity-free programmable memory devices.

show abstract

Novel Rewritable, Non‐volatile Memory Devices Based on Thermally and Dimensionally Stable Polyimide Thin Films

Cited by 171 publications

References 32 publications

Inserting Thienyl Linkers into Conjugated Molecules for Efficient Multilevel Electronic Memory: A New Understanding of Charge‐Trapping in Organic Materials

Inserting Thienyl Linkers into Conjugated Molecules for Efficient Multilevel Electronic Memory: A New Understanding of Charge‐Trapping in Organic Materials

Organic nonvolatile memory transistors with self-doped polymer energy well structures

High-performance triazole-containing brush polymers via azide–alkyne click chemistry: a new functional polymer platform for electrical memory devices

Contact Info

Product

Resources

About