二、年度2個(gè)月布偶貓幼貓喂養(yǎng)方法？?jī)?yōu)質(zhì)答案1：年度2個(gè)月的布偶貓，最好不要喂人吃的食物，以及鹽分重，油脂大的肉類，貓貓需要脂肪、蛋白質(zhì)、及鈣、磷等礦物質(zhì)，建議喂貓糧，為強(qiáng)壯骨骼與肌肉，提供足夠之能量，以供給小貓的成長(zhǎng)與活動(dòng)。同時(shí)，凈利為了保持貓咪身體健康，應(yīng)該保證充足的飲水和適當(dāng)?shù)倪\(yùn)動(dòng)。5.奶制品：同比雖然成年貓不能消化乳糖，但是寵物店里面賣(mài)的一些奶制品還是很受一些貓咪歡迎的。

濕糧類包括貓罐頭、增長(zhǎng)妙鮮包、貓布丁。此外，平高定期帶貓咪去獸醫(yī)那里進(jìn)行身體檢查和預(yù)防接種。

優(yōu)質(zhì)答案3：電氣貓咪喜歡吃的零食有貓罐頭、電氣妙鮮包、貓布丁等，可以當(dāng)做改善貓咪口味的零食，這些零食不僅口感好，而且還可以給貓咪補(bǔ)充部分的營(yíng)養(yǎng)。

飼養(yǎng)方面主要需要注意給布偶貓每月做好驅(qū)蟲(chóng)、預(yù)計(jì)9億元2億元疫苗、體檢等保健工作。傳統(tǒng)的球磨法大多是通過(guò)機(jī)械作用將硅破碎來(lái)降低顆粒尺寸，年度且尺寸也是亞微米，年度Prof.XingguoLi等人[6]為了解決納米硅制備過(guò)程復(fù)雜及上述問(wèn)題，提出了一種反應(yīng)球磨-疏水處理的方法，得到粒徑50nm且分布均勻的納米硅顆粒，且能夠均勻的分散在乙醇等溶劑中，有利于與碳復(fù)合，制備得到的硅碳負(fù)極在電流密度2.1A/g下循環(huán)1000圈后仍能保留1750mAh/g的容量。

凈利放電容量和充電容量分別能達(dá)到1693和1227mAh/g。石墨烯的克容量較高，同比可逆容量約700mAh/g，同比因?yàn)榭梢宰鳛樨?fù)極材料，比石墨類負(fù)極的容量要高得多，其片層間距大于石墨，鋰離子在石墨烯片層間可以擴(kuò)散通暢，有利于提高電池性能。

為了實(shí)現(xiàn)大批量生產(chǎn)，增長(zhǎng)Prof.YiCui等人[7]采用化學(xué)氣相沉積法（CVD），將天然石墨放在900℃的爐中，通以硅烷和乙炔，制備得到Si-C復(fù)合材料。參考文獻(xiàn)：平高1.JinhyukLee,DaniilA.Kitchaev,Deok-HwangKwonetal.ReversibleMn2+/Mn4+doubleredoxinlithium-excesscathodematerials.Nature,2018,556:185-190.2.YuxuanZuo,BiaoLi,NingJiangetal.Ahigh-capacityO2-typeLi-richcathodematerialwithasingle-LayerLi2MnO3superstructure.Mater.?2018,30:1707255.3.BiaoLi,NingJiang,WeifengHuangetal.Thermodynamicactivationofchargetransferinanionic?redoxprocessforLi-ionbatteries.?Adv.Funct.Mater.?2018,?28:1704864.4.JunLiu,PeterKopold,PeterA.vanAkenetal.Nanotechnology:Asustainableroutefromreedplantstoasiliconanodeforlithium-ionbatteries.Angew.Chem.Int.Ed.,2015,54:9632-9636.5.LinqiZong,YanJin,ChangLiuetal.PreciseperforationandscalableproductionofSiparticlesfromlow-gradesourcesforhigh-performancelithiumionbatteryanodes.NanoLett.,2016,16:7210-7215.6.ZhiliangLiu,XinghuaChang,TengWang?etal.Silica-DerivedHydrophobicColloidalNano-SiforLithium-IonBatteries.ACSNano,?2017,11:6065-6073.7.Min-seongKo,SujongChae,JiyoungMaetal.Scalablesynthesisiofsilicon-nanolayer-embeddedgraphiteforhigh-energylithium-ionbatteries.NatureEnergy,2016,1:16113.8.WeiLuo,DengkeShen,RenyuanZhangetal.GermaniumNano-GrainsDecorationonCarbonShell:BoostingLithium-StoragePropertiesofSiliconNanoparticles.Adv.Funct.Mater.,?2016,26:7800-7806.9.ZaileiZhang,ZhongLinWang?XianmaoLu?etal.MultishelledSi@CuMicroparticlesSupportedon3DCuCurrentCollectorsforStableandBinder-freeAnodesofLithium-IonBatteries.ACSNano,?2018,12:3587.10.ShitongWang,WeiQuan,ZhiZhuetal.Lithiumtitanatehydrateswithsuperfastandstablecyclinginlithiumionbatteries.NatureCommunications,2017,8:627.11.XianjunZhu,YanwuZhu,ShanthiMuralietal.Nanostructuredreducedgrapheneoxide/Fe2O3compositeasahighperformanceanodematerialforlithiumionbatteries.ACSNano.,2011,5:3333-3338.12.ZhongshuaiWu,WencaiRen,LiXuetal.Dopedgraphenesheetsasanodematerialswithsuperhighrateandlargecapacityforlithimionbatteries.ACSNano.,2011,5:5463-5471.13.JiantieXu,YiLin,JohnW.Connelletal.Nigrogen-dopedholeygrapheneasanodeforlithium-ionbatterieswithhighvolumetricenergydensityandlongcyclelife.Small,2015,11:6179-6185.14.XingxingLiang,YingYang,XinJinetal.Polyethyleneoxide-coatedelectrospunpolyimidefibrousseparatorforhigh-performancelithium-ionbattery.JournalofMaterialsScienceTechnology,2015.15.LiyunCao,PingAn,ZhanweiXuetal.Performanceevaluationofelectrospunpolyimidenon-wovenseparatorsforhighpowerlithium-ionbatteries.JournalofElectroanalyticalChemistry,2016,767:34-39.16.Chun-ErLin,JunWang,MingyongZhouetal.Poly(m-phenyleneisophthalamide)(PMIA):Apotentialpolymerforbreakingthroughtheselectivity-permeabilitytrade-offforultrafiltrationmembranes.JournalofMembraneScience,2016,15:72-78.17.Yeon-SuOh,GwanYeongJung,Jeong-HoonKimetal.Janus-faced,dual-conductive/chemicallyactivebatteryseparatormembranes.AdvancedFunctionalMaterials,2016,26:7074-7083.18.HengLi,DabeiWu,JinWu?etal.Flexible,High-WettabilityandFire-ResistantSeparatorsBasedonHydroxyapatiteNanowiresforAdvancedLithium-IonBatteries.Adv.Mater.,?2017,29:170354.19.Tae-wooKwon,YouKyeongJeong,ErhanDenizetal.Dynamiccross-linkingofpolymericbindersbasedonhost-guestinteractionsforsiliconanodesinlithiumionbatteries.ACSNano.,2015,9:11317-11324.20.SunghunChoi,Tae-wooKwon,AliCoskunetal.Highlyelasticbindersintegratingpolyrotaxanesforsiliconmicroparticleanodesinlithiumionbatteries.Science,?2017,357:279-283.21.HailongLyu,YunchaoLi,CharlJ.Jaftaetal.Bis(trimethylsilyl)2-fluoromalonatederivativesaselectrolyteadditivesforhighvoltagelithiumionbatteries.JournalofPowerSources,2019,412:527-535.22.NiloofarEhteshami,AitorEguia-Barrio,IratxedeMeatzaetal.Adiponitrile-basedelectrolytesforhighvoltage,graphite-basedLi-ionbattery.JournalofPowerSources,2018,397:52-58.—本文完—往期鋰電回顧：平高BryanMccloskey、夏定國(guó)、郭玉國(guó)等在富鋰錳基材料方向的最新進(jìn)展?鋰電方向既省錢(qián)又提升文章檔次的方法還不掌握起來(lái)？?攻略：用于緩解鋰電池負(fù)極材料的體積膨脹效應(yīng)的六種不同中空結(jié)構(gòu)的制備方法?實(shí)驗(yàn)理論解釋的好幫手鋰電領(lǐng)域常用模擬計(jì)算方法大起底。