Annealing free, clean graphene transfer using alternative polymer scaffolds

Wood, Joshua D.; Doidge, Gregory P.; Carrion, Enrique; Koepke, Justin; Kaitz, Joshua A.; Datye, Isha; Behnam, Ashkan; Hewaparakrama, Jayan; Aruin, Basil; Chen, Yaofeng; Dong, Hefei; Haasch, Richard T.; Lyding, Joseph W.; Pop, Eric

doi:10.1088/0957-4484/26/5/055302

Cited by 130 publications

(128 citation statements)

References 54 publications

(120 reference statements)

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“…Nonetheless it has been reported that some PMMA residues still remain on the surface after thermal annealing, resulting in scattering and defects . In the absence of improved (i.e., low residue) graphene transfer techniques using PMMA or other polymers, the other option for wafer‐scale residue removal is wet‐chemical cleaning typically using organic solvents such as acetone, chloroform, etc . A major issue is that the presence and distribution of these polymer residues heavily depends on experimental conditions, the quality of graphene, etc., and therefore varies significantly from one process to another.…”

Section: Summary Of Test Results Of Electrical Characterization On Gfmentioning

confidence: 99%

Cleaning Transferred Graphene for Optimization of Device Performance

Xiao

Wan

Durkan

2019

Adv Materials Inter

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Section: Summary Of Test Results Of Electrical Characterization On Gfmentioning

confidence: 99%

Cleaning Transferred Graphene for Optimization of Device Performance

Xiao

Wan

Durkan

2019

Adv Materials Inter

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“…The two most widespread methods to synthesize 2D materials applied to RS devices are chemical vapor deposition (CVD) and liquid-phase exfoliation. [89][90][91] A solution commonly employed is to synthesize the 2D material on the most suitable substrates (metallic foils for graphene [80] and h-BN [85][86][87] and SiO 2 or sapphire for 2D transition metal dichalcogenides (TMDs) [81][82][83] ) and transfer it on the desired sample using different methods, [92][93][94] being the wet transfer with the assistance of a polymer scaffold the most used by the RS community. The problem is that the temperature used for the growth is typically >700 °C, which prevents growing the 2D material on wafers with existing integrated circuits due to diffusion problems; the maximum temperature allowed for complementary metal-oxidesemiconductor (CMOS) back-end of line integration is typically 450 °C.…”

Section: Fabrication Rs Cells Based On 2d Materialsmentioning

confidence: 99%

“…[7] CVD can be used to grow high quality graphene, [80] molybdenum disulfide (MoS 2 ), [81] molybdenum diselenide (MoSe 2 ), [82] tungsten disulfide (WS 2 ), [83] tungsten selenide (WSe 2 ), [84] and hexagonal boron nitride (h-BN), [85][86][87] among many others. [94] However, three main issues need to be taken into account: i) if the 2D layered material is too thin (e.g., monolayer) and the top electrodes are very large (>10 4 µm 2 ), [95] the 2D material below the TE is likely to contain cracks (see Figure 3a). [88] Recently, thermally assisted conversion of metallic films at CMOS back-end compatible temperatures has been demonstrated to yield promising layered films, such as platinum diselenide (PtSe 2 ).…”

Section: Fabrication Rs Cells Based On 2d Materialsmentioning

confidence: 99%

Recommended Methods to Study Resistive Switching Devices

Lanza

Wong

Pop

et al. 2018

Adv Elect Materials

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494

434

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Resistive switching (RS) is an interesting property shown by some materials systems that, especially during the last decade, has gained a lot of interest for the fabrication of electronic devices, with electronic nonvolatile memories being those that have received the most attention. The presence and quality of the RS phenomenon in a materials system can be studied using different prototype cells, performing different experiments, displaying different figures of merit, and developing different computational analyses. Therefore, the real usefulness and impact of the findings presented in each study for the RS technology will be also different. This manuscript describes the most recommendable methodologies for the fabrication, characterization, and simulation of RS devices, as well as the proper methods to display the data obtained. The idea is to help the scientific community to evaluate the real usefulness and impact of an RS study for the development of RS technology.

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“…14 Recently, an alternative polymer scaffolds have been used instead of PMMA, which do not require an additional annealing after the polymers are dissolved. 15 However, some of the copper etchants, such as ammonium persulfate, can promote a crosslinking in polymers, resulting in a high concentration of residues on the graphene layer. 16 Alternatively, the direct transfer method is based on an adhesion between a Gr/substrate stack and a flexible perforated carbon membrane induced by capillary forces of a drying solvent such as IPA.…”

Section: Introductionmentioning

confidence: 99%

Toward clean suspended CVD graphene

et al. 2016

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The application of suspended graphene as electron transparent supporting media in electron microscopy, vacuum electronics, and micromechanical devices requires the least destructive and maximally clean transfer from their original growth substrate to the target of interest. Here, we use thermally evaporated anthracene films as the sacrificial layer for graphene transfer onto an arbitrary substrate. We show that clean suspended graphene can be achieved via desorbing the anthracene layer at temperatures in the 100 °C to 150 °C range, followed by two sequential annealing steps for the final cleaning, using Pt catalyst and activated carbon. The cleanliness of the suspended graphene membranes was analyzed employing the high surface sensitivity of low energy scanning electron microscopy and x-ray photoelectron spectroscopy. A quantitative comparison with two other commonly used transfer methods revealed the superiority of the anthracene approach to obtain larger area of clean, suspended CVD graphene. Our graphene transfer method based on anthracene paves the way for integrating cleaner graphene in various types of complex devices, including the ones that are heat and humidity sensitive.

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Annealing free, clean graphene transfer using alternative polymer scaffolds

Cited by 130 publications

References 54 publications

Cleaning Transferred Graphene for Optimization of Device Performance

Cleaning Transferred Graphene for Optimization of Device Performance

Recommended Methods to Study Resistive Switching Devices

Toward clean suspended CVD graphene

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