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@ARTICLE{Chen:903667,
      author       = {Chen, Chenglong and Li, Shaopeng and Notten, Peter H. L.
                      and Zhang, Yuehua and Hao, Qingli and Zhang, Xiaogang and
                      Lei, Wu},
      title        = {3{D} {P}rinted {L}ithium-{M}etal {F}ull {B}atteries {B}ased
                      on a {H}igh-{P}erformance {T}hree-{D}imensional {A}node
                      {C}urrent {C}ollector},
      journal      = {ACS applied materials $\&$ interfaces},
      volume       = {13},
      number       = {21},
      issn         = {1944-8244},
      address      = {Washington, DC},
      publisher    = {Soc.},
      reportid     = {FZJ-2021-05316},
      pages        = {24785 - 24794},
      year         = {2021},
      abstract     = {A three-dimensional (3D) printing method has been developed
                      for preparing a lithium anode base on 3D-structured copper
                      mesh current collectors. Through in situ observations and
                      computer simulations, the deposition behavior and mechanism
                      of lithium ions in the 3D copper mesh current collector are
                      clarified. Benefiting from the characteristics that the
                      large pores can transport electrolyte and provide space for
                      dendrite growth, and the small holes guide the deposition of
                      dendrites, the 3D Cu mesh anode exhibits excellent
                      deposition and stripping capability (50 mAh cm–2),
                      high-rate capability (50 mA cm–2), and a long-term stable
                      cycle (1000 h). A full lithium battery with a LiFePO4
                      cathode based on this anode exhibits a good cycle life.
                      Moreover, a 3D fully printed lithium–sulfur battery with a
                      3D printed high-load sulfur cathode can easily charge mobile
                      phones and light up 51 LED indicators, which indicates the
                      great potential for the practicability of lithium-metal
                      batteries with the characteristic of high energy densities.
                      Most importantly, this unique and simple strategy is also
                      able to solve the dendrite problem of other secondary metal
                      batteries. Furthermore, this method has great potential in
                      the continuous mass production of electrodes.},
      cin          = {IEK-9},
      ddc          = {600},
      cid          = {I:(DE-Juel1)IEK-9-20110218},
      pnm          = {1232 - Power-based Fuels and Chemicals (POF4-123)},
      pid          = {G:(DE-HGF)POF4-1232},
      typ          = {PUB:(DE-HGF)16},
      pubmed       = {pmid:34013732},
      UT           = {WOS:000659315800041},
      doi          = {10.1021/acsami.1c03997},
      url          = {https://juser.fz-juelich.de/record/903667},
}