◆发表论文
以第一或通讯作者身份发表核心期刊以上科技论文70余篇(其中SCI32篇),同时以其他共同作者身份发表论文50余篇。
[1]. Genomic survey sequencing, development and characterization 0f single-and multi-locus genomic ssr markers of Elymus Sibiricus L.[J]. BMC Plant Biology, 2021, 21:3 (通讯)
[2]. Transcriptomic resources for prairie grass (Bromus catharticus): expressed transcripts, tissue-specific genes, and identification and validation of EST-SSR markers[J]. BMC Plant Biology, 2021, 21(4):264. (通讯)
[3]. Comparative and phylogenetic analysis of complete chloroplast genome sequences of two wildrye grasses Elymus sibiricus and E. nutans (Triticeae, Poaceae) [J]. Intl J Agric Biol, 2021, 25(6):1203?1212 (通讯)
[4]. Genetic Diversity and Molecular Characterization of Worldwide Prairie Grass (Bromus catharticus Vahl) Accessions Using SRAP Markers[J]. Agronomy-Basel, 2021, 11:2054. (通讯)
[5]. Insights into soil bacterial and physicochemical properties of annual ryegrass?maize rotation (ARMR) system in southern China [J]. Scientific Reports, 2021, 11:20125. (通讯)
[6]. Genetic variability and structure of an important wild steppe grass Psathyrostachys juncea (Triticeae: Poaceae) germplasm collection from north and central Asia[J]. PeerJ, 2020, 8(3):e9033.(通讯)
[7]. The Complete Chloroplast Genome of Two Important Annual Clover Species, Trifolium alexandrinum and T. resupinatum: Genome Structure, Comparative Analyses and Phylogenetic Relationships with Relatives in Leguminosae[J]. Plants, 2020, 9(4):478.(通讯)
[8]. The Complete Chloroplast Genome Sequencing and Comparative Analysis of Reed Canary Grass (Phalaris arundinacea) and Hardinggrass (P. aquatica)[J]. Plants, 2020, 9 (6):748.(通讯)
[9]. Comparative Physiological and Proteomic Analysis Reveals Different Involvement of Proteins during Artificial Aging of Siberian Wildrye Seeds[J]. Plants 2020, 9, 1370; doi:10.3390/plants9101370. (通讯)
[10]. Genetic Diversity and Population Divergence of a Rare, Endemic Grass (Elymus breviaristatus) in the Southeastern Qinghai-Tibetan Plateau[J]. Sustainability, 2019, 11(20): 5863.(通讯)
[11]. Genetic diversity and structure of Elymus tangutorum accessions from western China as unraveled by AFLP markers[J]. Hereditas, 2019, 156(1): 8.(通讯)
[12]. Revelation of genetic diversity and structure of wild Elymus excelsus (Poaceae: Triticeae) collection from western China by SSR markers[J]. PeerJ, 2019, Doi:10.7717/peerj.8038(通讯)
[13]. AFLP-based genetic diversity of wild orchardgrass germplasm collections from Central Asia and Western China, and the relation to environmental factors. PLoS ONE 2018, 13(4): e0195273. (通讯)
[14]. Genetic Structure and Eco-Geographical Differentiation of Wild Sheep Fescue (Festuca ovina L.) in Xinjiang, Northwest China. Molecules 2017, 22, 1316. (通讯)
[15]. Analysis of Genetic Diversity and Structure Pattern of Indigofera Pseudotinctoria in Karst Habitats of the Wushan Mountains Using AFLP Markers. Molecules 2017, 22, 1734. (通讯作者)
[16]. AFLP assessment of Genetic variability and relationships in an Asian wild germplasm collection of Dactylis glomerata L. Comptes Rendus Biologies,2017,340:145-155. (通讯作者)
[17]. Insight into the genetic variability analysis and cultivar identification of tall fescue by using SSR markers. Hereditas (2016) 153: 9. doi:10.1186/s41065-016-0013-1(通讯作者)
[18]. SSRs transferability and genetic diversity of three allogamous ryegrass species. Comptes Rendus Biologies,2016,39(2):60-67. (通讯作者)
[19]. Phylogenetic analysis of Festuca-Loliumcomplex using SRAP marker. Genetic Resources and Crop Evolution, 2016,63(1):7-18. (共同一作)
[20]. Population genetic variability and structure of Elymus breviaristatus (Poaceae: Triticeae) endemic to Qinghai-Tibetan Plateau inferred from SSR markers,Biochemical Systematics and Ecology,2015,58:247-256.
[21]. Identification of the Valid Reference Genes for Quantitative RT-PCR in Annual Ryegrass (Lolium multiflorum) under Salt Stress. Molecules 2015, 20(3), 4833-4847. (共一)
[22]. Molecular insights into the genetic diversity of Hemarthria compressa germplasm collections native to southwest China. Molecules 2014, 19(12), 21541-21559. (通讯)
[23]. Genetic relationships between Lolium (Poaceae) species revealed by RAPD markers. Genetics and Molecular Research,2013, 12 (3): 3246- 3255. (一作)
[24]. RAPD analysis of genetic diversity and population structure of Elymus sibiricus (Poaceae) native to the southeastern Qinghai-Tibet Plateau, China. Genetics and Molecular Research,2012,11(3):2708-2718. (一作)
[25]. Assessment of Genetic Diversity of Siberian wildrye (Elymus sibiricus L.) Using Gliadin Markers. Molecules, 2012. 17(4):4424-4434 (一作)
[26]. Assessing genetic diversity of Elymus sibiricus (Poaceae: Triticeae) populations from Qinghai-Tibet Plateau by ISSR markers. Biochemical Systematics and Ecology, 2008, 36: 514-522. (一作)
中文cscd论文60余篇
[1]陈仕勇,马啸,齐晓芳,张新全.披碱草属物种AFLP体系优化[J].四川农业大学学报,2010,28(4):467-470.
[2]桂世昌,杨峰,张宝艺,张新全,黄琳凯,马啸.水分胁迫下扁穗牛鞭草根系保护酶活性变化[J].草业学报,2010,19(5):278-282.
[3]汪霞,马啸,张新全,周凯,马迎梅.四种不同钠盐胁迫对多花黑麦草种子萌发的影响[J].中国草地学报,2014(4):44-51.
[4]蒋林峰,张新全,黄琳凯,马啸,罗登,张宗瑜,蒙芬.中国鸭茅主栽品种DNA指纹图谱构建[J].植物遗传资源学报,2014,15(3):604-614.
[5]顾晓燕,郭智慧,张新全,刘新,周朝杰,马啸.短芒披碱草SRAP-PCR体系的建立和优化[J].中国农学通报,2014,30(30):259-264.
[6]罗永聪,马啸,张新全.利用SSR技术构建多花黑麦草品种指纹图谱[J].农业生物技术学报,2013,21(7):799-810.
[7]罗永聪,马啸,张新全.利用SSR标记分析一年生黑麦草遗传多样性的取样策略[J].草业科学,2013,30(3):376-382.
[8]凌瑶,张新全,陈仕勇,刘伟,马啸.野生狗牙根种质资源SRAP与SSR的遗传多样性[J].中国农业科学,2012,45(10):2040-2051.
[9]杨文轩,马啸,张新全,黄琳凯,苗佳敏.多花黑麦草品种间杂交F_2代分子标记遗传分析[J].草业学报,2012,21(4):125-133.
[10]陈永霞,张新全,杨春华,马啸,黄琳凯,刘影.扁穗牛鞭草新品种选育及栽培技术[J].中国草地学报,2012,34(3):109-112.
[11]李州,彭燕,张婧源,马啸.白三叶种质资源形态变异与地理起源的关系[J].草业科学,2012,29(11):1706-1714.
[12]许文志,张新全,黄琳凯,马啸.柳枝稷种子愈伤组织诱导及分化[J].草业科学,2012,29(1):45-50.
[13]周凯,陈仕勇,马啸,张新全.鹅观草属系统演化研究进展[J].草业科学,2012,29(9):1457-1461.
[14]陈仕勇,马啸,张新全,武小龙.野生新麦草种质醇溶蛋白遗传变异分析[J].草业学报,2011,20(4):311-315.
[15]陈永霞,张新全,谢文刚,马啸,刘影.利用EST-SSR标记分析西南扁穗牛鞭草种质的遗传多样性[J].草业学报,2011,20(6):245-253.
[16]苗佳敏,张新全,陈智华,钟金城,陈仕勇,马啸,白史且.青藏高原和新疆地区垂穗披碱草种质的SRAP及RAPD分析[J].草地学报,2011,19(2):306-316.
[17]凌瑶,张新全,初秀娟,马啸,刘伟.狗牙根新品种(系)在西南区的区域适应性研究[J].西南农业学报,2011,24(6):2349-2354.
[18]凌瑶,张新全,齐晓芳,周莹洁,刘伟,马啸,陈仕勇.西南五省区及非洲野生狗牙根种质基于SRAP标记的遗传多样性分析[J].草业学报,2010,19(2):196-203.
[19]张婧源,彭燕,罗燕,马啸.不同产地白三叶种质遗传多样性的SRAP分析[J].草业学报,2010,19(5):130-138.
[20]罗燕,白史且,彭燕,张玉,马啸.菊苣种质资源遗传多样性的SRAP研究[J].草业学报,2010,19(5):139-147.
[21]陈永霞,张新全,马啸,谢文刚.扁穗牛鞭草种质资源的RAPD分析[J].西南农业学报,2010,23(3):866-871.
[22]孙铭,符开欣,范彦,张新全,张成林,郭志慧,汪霞,马啸.15份多花黑麦草优良引进种质的表型变异分析[J].植物遗传资源学报,2016,17(4):655-662.
[23]张成林,郭志慧,张新全,白史且,张昌兵,李平,马啸.利用SSR标记对垂穗披碱草和老芒麦进行物种鉴定和遗传变异分析[J].植物遗传资源学报,2016,17(3):416-422.
[24]陈仕勇,马啸,张昌兵,陈智华,李世丹,郑经红.川西北牧区7个披碱草属新品系遗传变异分析[J].西南农业学报,2016,29(11):2549-2553.
[25]陈仕勇,马啸,张新全,朱永群.青藏高原垂穗披碱草种质麦角病抗性的初步研究[J].西南农业学报,2016,29(2):302-306.
[26]陈仕勇,陈智华,周青平,李世丹,马啸,张新全.青藏高原垂穗披碱草种质资源形态多样性分析[J].中国草地学报,2016(1):27-33.
[27]刘欢,马啸,张新全,张瑞珍,陈诚,唐露,杨忠富.多花黑麦草品种DUS测试数量性状分级分析[J].植物遗传资源学报,2016,17(5):846-853.
[28]刘欢,马啸,张新全,陈诚,唐露,杨忠富,齐晓.多花黑麦草农艺性状变异及产量通径分析[J].草业科学,2016,33(10):2071-2081.
[29]陈仕勇,马啸,张新全,陈智华,周凯.不同来源SSR和EST-SSR在披碱草属和鹅观草属物种中的通用性分析[J].草业学报,2016(2):132-140.
[30]黄婷,马啸,张新全,张新跃,张瑞珍,符开欣.多花黑麦草DUS测定中SSR标记品种鉴定比较分析[J].中国农业科学,2015,48(2):381-389.
[31]郭志慧,张新全,马啸,周朝杰,汪霞,黄琳凯,闫艳红,程亚娟,顾晓燕,刘新.基于ISAP标记分析西南扁穗牛鞭草无性系种质遗传多样性和亲缘关系[J].草地学报,2015,23(1):156-166.
[32]顾晓燕,郭志慧,张新全,周凯,周朝杰,符开欣,刘新,马啸.短芒披碱草异位保护群体的表型多样性研究[J].草业学报,2015,24(5):141-152.
[33]马啸,周朝杰,张成林,孙铭,郭志慧,王小利,张建波.扁穗雀麦种质资源形态和农艺性状变异的初步分析[J].草地学报,2015,23(5):1048-1056.
[34]蒋林峰,张新全,黄琳凯,马啸,严德飞,胡强,付玉凤.鸭茅品种的SCoT遗传变异分析[J].草业学报,2014,23(1):229-238.
[35]顾晓燕,郭志慧,张新全,周永红,白史且,张昌兵,蒋忠荣,刘新,周朝杰,马啸.老芒麦种质资源遗传多样性的SRAP分析[J].草业学报,2014,23(1):205-216.
[36]陈永霞,张新全,谢文刚,马啸.基于表型性状和SRAP标记的西南区野生扁穗牛鞭草遗传多样性分析[J].西南农业学报,2014,27(6):2680-2686.
[37]白玲,马啸,白史且,张玉,李达旭,柳茜,傅平.菊苣种子丰产栽培模型分析[J].草地学报,2014,22(4):897-902.
[38]王绍飞,黄琳凯,张新全,马啸,张萌.长江2号多花黑麦草主要形态性状的回交改良分析[J].草地学报,2014,22(4):907-910.
[39]王绍飞,黄琳凯,张新全,马啸.连续混合选择下多花黑麦草杂交群体的SSR多样性变化[J].草业学报,2014,23(5):345-351.
[40]季杨,张新全,彭燕,梁小玉,黄琳凯,马啸,马迎梅.干旱胁迫对鸭茅根、叶保护酶活性、渗透物质含量及膜质过氧化作用的影响[J].草业学报,2014,23(3):144-151.
[41]王绍飞,罗永聪,张新全,黄琳凯,马啸,刘恋.14个多花黑麦草品种(系)在川西南地区生产性能综合评价[J].草业学报,2014,23(6):87-94.
[42]熊毅,熊艳丽,杨晓鹏,赵文达,雷雄,余青青,马啸,张新全.外源褪黑素对盐胁迫下老化燕麦种子萌发及幼苗的影响[J].中国草地学报,2020,42(1):7-14.
[43]杨建,雷雄,陈煜坤,刘伟,董志晓,熊毅,熊艳丽,马啸.多花黑麦草与饲用燕麦引进品种在成都平原的生产性能评价[J].草业科学,2020,37(6):1124-1132.
[44]雷雄,游明鸿,白史且,陈丽丽,邓培华,熊毅,熊艳丽,余青青,马啸,杨建,张昌兵.川西北高原50份燕麦种质农艺性状遗传多样性分析及综合评价[J].草业学报,2020,29(7):131-142.
[45]杨晓鹏,李平,董臣飞,马啸,苟文龙.多花黑麦草+燕麦混播草地地上生物量和营养品质动态研究[J].草地学报,2020,28(1):149-158.
[46]苟文龙,李平,马啸,张瑞珍,董臣飞,李达旭,白史且,师尚礼.混播比例和刈割茬次对一年生禾豆混播草地根系形态、土壤养分的影响[J].草原与草坪,2020,40(4):1-7.
[47]熊艳丽,熊毅,赵文达,杨晓鹏,雷雄,余青青,马啸,张新全.外源褪黑素对NaCl胁迫下扁穗雀麦种子萌发及幼苗的影响[J].草业科学,2019,36(8):2042-2049.
[48]伍文丹,雷雄,赵文达,杨晓鹏,熊毅,熊艳丽,张新全,马啸.饲草型高羊茅引进品种的表型变异分析[J].草业科学,2019,36(10):2622-2630.
[49]苟文龙,李平,张建波,王婷,马啸,周俗,白史且,师尚礼.多花黑麦草+箭筈豌豆混播草地地上生物量和营养品质动态研究[J].草地学报,2019,27(2):473-481.
[50]赵文达,杨晓鹏,孙铭,张成林,伍文丹,马啸,张新全.不同扁穗雀麦种质苗期抗旱性鉴定与评价[J].草业科学,2018,35(11):2664-2671.
[51]杨晓鹏,赵文达,孙铭,朱连发,张成林,伍文丹,马啸,张新全.多花黑麦草引进种质与产草量相关形态性状的变异分析[J].中国草地学报,2018,40(6):39-46.
[52]孙铭,雷雄,张新全,张成林,伍文丹,赵文达,杨晓鹏,马啸.扁穗雀麦优良品系数量性状的变异分析及遗传参数评估[J].草业学报,2018,27(1):131-141.
[53]陈仕勇,马啸,张新全,陈智华,周青平.基于SSR标记的小麦族St、H、Y基因组六倍体物种遗传变异及种间亲缘关系研究[J].草业学报,2018,27(9):142-151.
[54]蒋林峰,黄琳凯,李发玉,尹权为,曾兵,谢文刚,马啸,张宗瑜,张新全.鸭茅重要种质DUS测试及农艺性状评价筛选[J].草地学报,2017,25(2):351-360.
[55]张成林,杨晓鹏,赵文达,张新全,孙铭,汪霞,伍文丹,熊毅,马啸.鸭茅野生种质遗传多样性的AFLP分析[J].西北植物学报,2017,37(9):1711-1719.
[56]刘欢,张新全,马啸,张瑞珍,何光武,潘玲,金梦雅.基于荧光检测技术的多花黑麦草EST-SSR指纹图谱的构建[J].中国农业科学,2017,50(3):437-450.
[57]符开欣,刘新,张新全,张建波,苟文龙,张成林,孙铭,马啸.六份川西北短芒披碱草种质萌发期抗旱性评价[J].中国草地学报,2017,39(2):41-47.
[58]刘新,符开欣,郭志慧,张新全,白史且,李达旭,张昌兵,张成林,孙铭,马啸.6份川西北短芒披碱草种质苗期的抗旱性综合评价[J].草业科学,2017,34(1):101-111.
[59]郭志慧,杨红宇,张成林,孙铭,符开欣,张新全,马啸.利用形态性状以及SSR标记鉴定4个川西北老芒麦品种(系[J].草业科学,2016,33(9):1718-1727.
[60]蒋林峰,姚超,谢文刚,黄林凯,张宗瑜,马啸,严德飞,张新全.鸭茅品种(系)表型分析及隶属函数综合评价[J].草地学报,2016,24(4):859-867.