1. Liu Yang. 2020. Evaluating physiological changes of grass and semishrub species with seasonality for understanding the process of shrub encroachment in semiarid grasslands. Functional Plant Biology. IF=3.1

2. Jing Yang.2021. Inhibitory effects and mechanisms of vanillin on gray mold and black rot of cherry tomatoes. Pesticide Biochemistry and Physiology. IF=3.9

3. Nannan Zhao. 2021. Transcriptome and Co-expression Network Analyses Reveal Differential Gene Expression and Pathways in Response to Severe Drought Stress in Peanut (Arachis hypogaea L.). Frontiers in Genetics. IF=4.6

4. Xiaodong Zheng. 2021. Resveratrol improves the iron defciency adaptation of Malus baccata seedlings by regulating iron absorption. BMC Plant Biology. IF=4.2

5. Zheng Wang.2022. Comparing Efficacy of Different Biostimulants for Hydroponically Grown Lettuce (Lactuca sativa L.). Agronomy. IF=3.40

6. 孙晓莉.贾春燕.田寿乐.文燕.王金平.冉 昆.沈广宁. 2022. 外源甲基乙二醛对干旱胁迫下板栗幼苗的影响．应用生态学报.

7.Zaid Khan.2022.How Biochar Affects Nitrogen Assimilation and Dynamics by Interacting Soil and Plant Enzymatic Activities: Quantitative Assessment of 2 Years Potted Study in a Rapeseed-Soil System..IF=.6.627

8.Ming Gao.2022.Sex-specific physiological and biochemical responses of Litsea cubeba under waterlogging stress.IF=6.028

9.Yi Zhang.2022.Analysis of Lhcb gene family in rapeseed (Brassica napus L.) identifies a novel member “BnLhcb3.4” modulating cold tolerance.IF=6.028

10.Tingting Li.2021.Resveratrol Alleviates the KCl Salinity Stress of Malus hupehensis Rhed.IF=5.754

11.Ali Raza.2022.Mechanistic Insights Into Trehalose-Mediated Cold Stress Tolerance in Rapeseed ( Brassica napus L.) Seedlings.IF=5.754

12.Raza  Ali.2021.Integrated Analysis of Metabolome and Transcriptome Reveals Insights for Cold Tolerance in Rapeseed (Brassica napus L.).IF=5.754

13.Danfeng Tang.2021.Identification of Differentially Expressed Genes and Pathways Involved in Growth and Development of Mesona chinensis Benth Under Red- and Blue-Light Conditions.IF=5.754

14.Feng Xiao.2022.Trade-off between shade tolerance and chemical resistance of invasive Phytolacca americana under different light levels compared with its native and exotic non-invasive congeners.IF=5.545

15.Yan Jia.2021.Effects of root characteristics on panicle formation in japonica rice under low temperature water stress at the reproductive stage.IF=5.224

16.Sun, Zhijuan.2022.Brassinolide alleviates Fe deficiency-induced stress by regulating the Fe absorption mechanism in Malus hupehensis Rehd.IF=4.964

17.Zaid Khan.2021.Compensation of high nitrogen toxicity and nitrogen deficiency with biochar amendment through enhancement of soil fertility and nitrogen use efficiency promoted rice growth and yield.IF=4.745

18.Shifa Xiong.2022.Effects of Drought Stress and Rehydration on Physiological and Biochemical Properties of Four Oak Species in China.IF=4.658

19.Zhao  Nannan.2021.Transcriptome and Co-expression Network Analyses Reveal Differential Gene Expression and Pathways in Response to Severe Drought Stress in Peanut (Arachis hypogaea L.).IF=4.599

20.Zheng Wang.2022.Comparing Efficacy of Different Biostimulants for Hydroponically Grown Lettuce (Lactuca sativa L.).IF=3.949

21.Xiaodong Zheng.2020.Exogenous Strigolactones alleviate KCl stress by regulating photosynthesis, ROS migration and ion transport in Malus hupehensis Rehd.IF=3.72

22.Changchang Shao.2022.Physiological and Biochemical Dynamics of Pinus massoniana Lamb. Seedlings under Extreme Drought Stress and during Recovery.IF=3.282

23.Cheng-zhe ZHOU.2022.Transcriptome and phytochemical analyses reveal the roles of characteristic metabolites in the taste formation of white tea during the withering process.IF=2.848

24.Liu Yang.2020.Evaluating physiological changes of grass and semishrub species with seasonality for understanding the process of shrub encroachment in semiarid grasslands.IF=2.617

25.Chen, Siting.2022.Overexpression of the intertidal seagrass J protein ZjDjB1 enhances tolerance to chilling injury.IF=2.496

26.Chen, Siting.2022.Overexpression of Zostera japonica 14-3-3 gene ZjGRF1 enhances the resistance of transgenic Arabidopsis to copper stress.IF=2.742

27.Chen, Siting.2022.Overexpression of the intertidal seagrass 14-3-3 gene ZjGRF1 enhances the tolerance of transgenic Arabidopsis to salt and osmotic stress.IF=2.496

28.Cheng Zhang.2022.A Comprehensive Investigation of Macro-Composition and Volatile Compounds in Spring-Picked and Autumn-Picked White Tea.IF=5.561

29.Sizhou Chen.2022.Hyperspectral machine-learning model for screening tea germplasm resources with drought tolerance.IF=6.627

30.Xiao Yang.2022.Pre-harvest Nitrogen Limitation and Continuous Lighting Improve the Quality and Flavor of Lettuce (Lactuca sativa L.) under Hydroponic Conditions in Greenhouse.IF=5.895

31.Hang  Yang.2023.Artemisia baimaensis allelopathy has a negative effect on the establishment of Elymus nutans artificial grassland in natural grassland.IF=2.734

32.Liu, Yun-Shan.2023.Asymmetric inter-specific competition between invasive Phytolacca americana and its native congener.IF=1.99

33.Liu B. S.2023.Effects of Light Intensity on Morphological Structure and Physiological Characteristics of Gleditsia sinensis Seedlings.IF=1.419

34.Chen Siting.2023.Overexpression of Zostera japonica J protein gene ZjDjB1 in Arabidopsis enhanced the tolerance to lead stress.IF=2.742

35.Chongxi Liu.2023.Integrated Physiological, Transcriptomic, and Metabolomic Analysis Reveals the Mechanism of Guvermectin Promoting Seed Germination in Direct-Seeded Rice under Chilling Stress.IF=5.895

36.Honglang Duan.2023.Root relative water content is a potential signal for impending mortality of a subtropical conifer during extreme drought stress.IF=7.3

37.Xiao Han.2023.Transcriptome Revealed the Effect of Shading on the Photosynthetic Pigment and Photosynthesis of Overwintering Tea Leaves.IF=3.7

38.Tang Danfeng.2023.Integrating LC-MS and HS-GC-MS for the metabolite characterization of the Chinese medicinal plant Platostoma palustre under different processing methods.IF=6.59

39.Ziyan Liang.2023.Contrasting Responses and Phytoremediation Potential of Two Poplar Species to Combined Strontium and Diesel Oil Stress.IF=4.658

40.Zhijuan Sun.2023.Melatonin enhances KCl salinity tolerance by maintaining K+ homeostasis in Malus hupehensis.IF=13.8

41.Ying Liang.2023.Interactive effects of light quality and nitrate supply on growth and metabolic processes in two lettuce cultivars (Lactuca sativa L.).IF=5.7

42.Hao Chen.2023.Enhancing the Adaptability of Tea Plants (Camellia sinensis L.) to High-Temperature Stress with Small Peptides and Biosurfactants.IF=4.5

43.Meng Yang.2023.Transcriptomic Response to Drought Stress in Populus davidiana Dode.IF=2.9

1、问：官网上试剂盒规格标注的“24样”、“48样”、“96样”是什么意思呢？

     答：“24样”、“48样”、“96样”是试剂盒规格，我们定义了试剂盒可以测多少样，对于试剂盒需要的试剂量都给足的。

          “24样”、“48样”、“96样”规格的试剂盒，可以检测24个样、48个样、96个样；即分别得到24个、48个、96个数据。

2、问：官网上试剂盒检测方法中"可见分光法/紫外分光法"与“微板法”是什么区别？

     答：分光法：指使用紫外可见分光光度计检测，若无紫外可见光分光度计，订购时务必咨询公司技术。公司分光法试剂盒采用的比色皿规格是：光径：1cm,容积：1mL, 狭缝宽3mm;

           微板法：指使用全波段连续酶标仪检测；若无全波段酶标仪，订购指标时务必咨询公司技术， 本公司微板法试剂盒内送96孔普通酶标板，客户无需另外购买耗材。

3、问：分光法试剂盒与微板法试剂盒是否能通用？

     答：公司针对用户实验室具备的实验仪器条件，做了两个体系的试剂盒。两种体系试剂盒检测指标的原理一样，结果可以通用，但是不同体系的试剂盒不可以相互混匀！