Giant barocaloric effect in all-
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-metal Heusler shape memory alloys

Aznar, Araceli; Gràcia-Condal, Adrià; Planes, Antoni; Lloveras, Pol; Barrio, Marı́a; Tamarit, J. Ll.; Xiong, Wenxin; Cong, Daoyong; Popescu, Cătălin; Mañosa, Lluı́s

doi:10.1103/physrevmaterials.3.044406

Cited by 70 publications

(37 citation statements)

References 38 publications

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“…2A and Fig. 2B for CnH2n+2 (n=14, 16 and 18) along with those reported for existing BC materials 10,[13][14][15][16][17]20,21,[29][30][31][32][33][34][35][36][37][38][39] . Here, the isothermal entropy change in references is mainly obtained by indirect method or quasi-direct method 6 .…”

supporting

confidence: 76%

Colossal and Reversible Barocaloric Effect in Phase Change Materials n-Alkanes

Lin¹,

Tong²,

Tao³

et al. 2021

Preprint

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The emergent cooling technologies based on the caloric effect provide a green alternative to the conventional vapor-compression one which brings about the serious environment problem. However, the existing caloric materials are much inferior to their traditional counterparts in cooling performance. Here we report the colossal barocaloric effect in liquid-solid-transition materials, i.e. n-alkanes. Their excellent cooling performance is superior to those for existing caloric materials and comparable to those of traditional refrigerants. Theoretical calculations suggest the liquid state n-alkanes has huge configuration entropy characterized by large dispersion of bond lengths. Appling pressure significantly reduces the configuration entropy and eventually induces the liquid-solid-transition, leading to the colossal barocaloric effect. This work provides promising refrigerants for caloric cooling technology, and opens a new avenue for exploring colossal barocaloric materials.

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supporting

confidence: 76%

Colossal and Reversible Barocaloric Effect in Phase Change Materials n-Alkanes

Lin¹,

Tong²,

Tao³

et al. 2021

Preprint

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“…(b)Reversible adiabatic temperature changes upon 0 → ~1 kbar pressure increase as a function of temperature. Literature data taken from: PG:[12]; C60:[13];[TPrA][Mn(dca)3]:[44]; [(CH3)4N]Mn[N3]3:[45]; MnCoGeB0.03 (asterisk):[46]; (MiNiSi)0.60(FeCoGe)0.40 (diamond) and (MiNiSi)0.61(FeCoGe)0.39 (triangle):[47]; Ni50Mn31.5Ti18.5 (circle):[48].…”

mentioning

confidence: 99%

Reversible colossal barocaloric effects near room temperature in 1-X-adamantane (X=Cl, Br) plastic crystals

Aznar

Négrier

Planes

et al. 2021

Applied Materials Today

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Plastic crystals undergo phase transitions with unusually large volume and entropy changes related to strong molecular orientational disordering. These features have led to a resurgent interest in these materials because recently they have shown great potential in solid-state cooling applications driven by pressure. Here we demonstrate that two plastic crystals derived from adamantane -1-Br-adamantane and 1-Cl-adamantane-undergo colossal reversible barocaloric effects under moderate pressure changes in a wide temperature span near room temperature thanks to a relatively small hysteresis and very high sensitivity of the transition temperature to pressure. In particular, 1-Cl-adamantane displays an optimal operational temperature range covering from ~40 K below and up to room temperature, and under a pressure change of 1 kbar this compound outperforms any other barocaloric material known so far. Our work gives strong support to plastic crystals as best candidates for barocaloric cooling. We also provide insight into the physical origin of the entropy changes through the analysis of the disorder on the involved phases.

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“…合适成分的该系列合金马氏体相变既属于热弹性相变, 又属于铁磁性相变, 因此既可以被温度或应力诱导, 也可以被磁场驱动. 在温度、磁场等外界因素的激励下, 合金可以发生铁磁奥氏体和弱磁马氏体之间的马氏体相变(或逆马氏体相变), 晶体结构转变和磁性相变强烈耦合, 因此, 相变附近表现出很大的磁热效应 [2][3][4] , 同时也具有很大的机械热效应 ( 弹热、压热 ) 、巨磁电阻、磁致应变、交换偏置、动力学囚禁等物理效应 [2][3][4][10][11][12][13][14][15][16][17][18][19][20][21][22][23] , 从而在固态制冷、磁激励、人工智能等前沿和新兴领域都极具应用前景.…”

Section: 在众多一级磁相变材料中 Ni-mn基heusler合金unclassified

“…人们在对Ni-Mn基FSMAs研究的过程中, 通过多种途径调控实现铁磁/弱磁性马氏体相变, 比如过渡/ 主族元素取代 [2][3][4][8][9][10]14,15,[18][19][20][21][22][23] 、热处理 [11] 、改变快淬速度 [13] 、间隙位原子掺杂 [16,17] 等. 人们也提出各种机制解释马氏体相变调控的物理机理, 比如应力弛豫 [11] 、反位缺陷 [11] 、Mn-Mn间距 [2] 、价电子浓度 [8] 、第二相析出 [11,13] 等.…”

Section: 在众多一级磁相变材料中 Ni-mn基heusler合金unclassified

“…人们也提出各种机制解释马氏体相变调控的物理机理, 比如应力弛豫 [11] 、反位缺陷 [11] 、Mn-Mn间距 [2] 、价电子浓度 [8] 、第二相析出 [11,13] 等. 比如, 2009年, Liu等人 [11] 发现2 h [14,15,18,19] 、弹热效应 [17,21] 、压热效应 [16,20] 、磁电阻 [14,15,19] 、磁致应变 [14,15] 、交换偏置 [22] 等, 从而引起人们的广泛重视和研究. 然而目前对此类合金研究得还不够充分, 且相关研究大多都集中在富Ni基all-d Ni-Co-Mn-Ti体系的块材 [14][15][16][17]20,21] 、薄膜 [22] 、条带 [18,19,23] .…”

Section: 在众多一级磁相变材料中 Ni-mn基heusler合金unclassified

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