In north-western North America, the so-called divergence problem (DP) is expressed in tree ring width (RW) as an unstable temperature signal in recent decades. Maximum latewood density (MXD), from the same region, shows minimal evidence of DP. While MXD is a superior proxy for summer temperatures, there are very few long MXD records from North America. Latewood blue intensity (LWB) measures similar wood properties as MXD, expresses a similar climate response, is much cheaper to generate and thereby could provide the means to profoundly expand the extant network of temperature sensitive tree-ring (TR) chronologies in North America. In this study, LWB is measured from 17 white spruce sites (Picea glauca) in south-western Yukon to test whether LWB is immune to the temporal calibration instabilities observed in RW. A number of detrending methodologies are examined. The strongest calibration results for both RW and LWB are consistently returned using age-dependent spline (ADS) detrending within the signal-free (SF) framework. RW data calibrate best with June–July maximum temperatures (Tmax), explaining up to 28% variance, but all models fail validation and residual analysis. In comparison, LWB calibrates strongly (explaining 43–51% of May–August Tmax) and validates well. The reconstruction extends to 1337 CE, but uncertainties increase substantially before the early 17th century because of low replication. RW-, MXD- and LWB-based summer temperature reconstructions from the Gulf of Alaska, the Wrangell Mountains and Northern Alaska display good agreement at multi-decadal and higher frequencies, but the Yukon LWB reconstruction appears potentially limited in its expression of centennial-scale variation. While LWB improves dendroclimatic calibration, future work must focus on suitably preserved sub-fossil material to increase replication prior to 1650 CE.
AnchukaitisKJBreitenmoserPBriffaKR, et al. (2012) Tree rings and volcanic cooling. Nature Geoscience5(12): 836.
2.
AnchukaitisKJD’ArrigoRDAndreu-HaylesL, et al. (2013) Tree-ring-reconstructed summer temperatures from northwestern North America during the last nine centuries. Journal of Climate26(10): 3001–3012.
3.
AnchukaitisKJWilsonKBriffaU, et al. (2017) Last millennium Northern Hemisphere summer temperatures from tree rings: Part II: Spatially resolved reconstructions. Quaternary Science Reviews163: 1–22.
4.
Andreu-HaylesLD’ArrigoRAnchukaitisKJ, et al. (2011) Varying boreal forest response to Arctic environmental change at the Firth River, Alaska. Environmental Research Letters6(4): 045503.
5.
BjörklundJGunnarsonBESeftigenK, et al. (2015) Using adjusted blue intensity data to attain high-quality summer temperature information: A case study from Central Scandinavia. The Holocene25(3): 547–556.
6.
BjörklundJAGunnarsonBESeftigenK, et al. (2014) Blue intensity and density from northern Fennoscandian tree rings, exploring the potential to improve summer temperature reconstructions with earlywood information. Climate of the past10(2): 877–885.
7.
BriffaKRMelvinTM (2011) A closer look at regional curve standardization of tree-ring records: Justification of the need, a warning of some pitfalls, and suggested improvements in its application. In: HughesMKSwetnamTWDiazHF (eds) Dendroclimatology. Dordrecht: Springer, pp. 113–145.
8.
BriffaKRJonesPDSchweingruberFH, et al. (1996) Tree-ring variables as proxy-climate indicators: Problems with low-frequency signals. In: JouzelJBradleyRSJonesP (eds) Climatic Variations and Forcing Mechanisms of the Last 2000 Years. Berlin: Springer, pp. 9–41.
9.
BriffaKROsbornTJSchweingruberFH, et al. (2002) Tree-ring width and density data around the Northern Hemisphere: Part 1, local and regional climate signals. The Holocene12(6): 737–757.
10.
BuckleyBMHansenKGGriffinKL, et al. (2018) Blue intensity from a tropical conifer’s annual rings for climate reconstruction: An ecophysiological perspective. Dendrochronologia50: 10–22.
11.
BüntgenUFrankDCNievergeltD, et al. (2006) Summer temperature variations in the European Alps, AD 755–2004. Journal of Climate19(21): 5606–5623.
12.
BurasASpytBJaneckaK, et al. (2018) Divergent growth of Norway spruce on Babia Góra Mountain in the western Carpathians. Dendrochronologia50: 33–43.
13.
CampbellRMcCarrollDLoaderNJ, et al. (2007) Blue intensity in Pinus sylvestristree-rings: Developing a new palaeoclimate proxy. The Holocene17(6): 821–828.
14.
CookERBriffaKShiyatovS, et al. (1990) Tree-ring standardisation and growth-trend estimation. In: CookERKairiukstisLA (eds) Methods of Dendrochronology: Applications in the Environmental Sciences. Dordrecht: Kluwer Academic Publishers, pp. 104–123.
15.
CookERBriffaKRJonesPD (1994) Spatial regression methods in dendroclimatology: A review and comparison of two techniques. International Journal of Climatology14(4): 379–402.
16.
CookERBriffaKRMekoDM, et al. (1995) The ‘segment length curse’ in long tree-ring chronology development for palaeoclimatic studies. The Holocene5(2): 229–237.
17.
D’ArrigoRWilsonRAnchukaitisKJ (2013) Volcanic cooling signal in tree ring temperature records for the past millennium. Journal of Geophysical: Research Atmospheres118(16): 9000–9010.
18.
D’ArrigoRWilsonRLiepertB, et al. (2008) On the ‘divergence problem’ in northern forests: A review of the tree-ring evidence and possible causes. Global and Planetary Change60(3-4): 289–305.
19.
DaviNKJacobyGCWilesGC (2003) Boreal temperature variability inferred from maximum latewood density and tree-ring width data, Wrangell Mountain region, Alaska. Quaternary Research60(3): 252–262.
20.
EsperJFrankDBüntgenU, et al. (2007) Long-term drought severity variations in Morocco. Geophysical Research Letters34(17): L17702.
21.
EsperJFrankDCTimonenM, et al. (2012) Orbital forcing of tree-ring data. Nature Climate Change2(12): 862.
22.
EsperJGeorgeSSAnchukaitisK, et al. (2018) Large-scale, millennial-length temperature reconstructions from tree-rings. Dendrochronologia50: 81–90.
23.
FrittsHC (1976) Tree Rings and Climate. San Diego, CA: Academic, p. 567.
24.
FrittsHCMosimannJEBottorffCP (1969) A revised computer program for standardizing tree-ring series. Tree-Ring Bulletin29: 15–20.
25.
FuentesMSaloRBjörklundJ, et al. (2018) A 970-year-long summer temperature reconstruction from Rogen, west-central Sweden, based on blue intensity from tree rings. The Holocene28(2): 254–266.
26.
GennarettiFArseneaultDNicaultA, et al. (2014) Volcano-induced regime shifts in millennial tree-ring chronologies from northeastern North America. Proc Natl Acad Sci U S A111; 10077–10082.
27.
GuilletSCoronaCStoffelM, et al. (2017) Climate response to the Samalas volcanic eruption in 1257 revealed by proxy records. Nature Geoscience10(2): 123.
28.
HarrisIPhilipJOsbornT, et al. (2014) Updated high-resolution grids of monthly climatic observations–the CRU TS3. 10 Dataset. International Journal of Climatology34(3): 623–642.
JacobyGCD’ArrigoRD (1995) Tree ring width and density evidence of climatic and potential forest change in Alaska. Global Biogeochemical Cycles9(2): 227–234.
31.
KaczkaRJSpytBJaneckaK, et al. (2018) Different maximum latewood density and blue intensity measurements techniques reveal similar results. Dendrochronologia49: 94–101.
32.
LuckmanBHWilsonRJS (2005) Summer temperatures in the Canadian Rockies during the last millennium: A revised record. Climate Dynamics24(2–3): 131–144.
33.
McCarrollDPettigrewELuckmanA, et al. (2002) Blue reflectance provides a surrogate for latewood density of high-latitude pine tree rings. Arctic, Antarctic, and Alpine Research34(4): 450–453.
34.
MekoD (1997) Dendroclimatic reconstruction with time varying predictor subsets of tree indices. Journal of Climate10(4): 687–696.
35.
MelvinTMBriffaKR (2008) A ‘signal-free’ approach to dendroclimatic standardisation. Dendrochronologia26(2): 71–86.
36.
MelvinTMBriffaKR (2014) CRUST: Software for the implementation of regional chronology standardisation: Part 1. Signal-free RCS. Dendrochronologia32(1): 7–20.
37.
MelvinTMBriffaKRNicolussiK, et al. (2007) Time-varying-response smoothing. Dendrochronologia25(1): 65–69.
38.
PetersonTCEasterlingDRKarlTR, et al. (1998) Homogeneity adjustments of in situ atmospheric climate data: A review. International Journal of Climatology: A Journal of the Royal Meteorological Society18(13): 1493–1517.
39.
PorterTJPisaricMF (2011) Temperature-growth divergence in white spruce forests of Old Crow Flats, Yukon Territory, and adjacent regions of northwestern North America. Global Change Biology17(11): 3418–3430.
40.
RydvalMDruckenbrodDLSvobodaM, et al. (2018) Influence of sampling and disturbance history on climatic sensitivity of temperature-limited conifers. The Holocene28(10): 1574–1587.
41.
RydvalMGunnarsonBELoaderNJ, et al. (2017a) Spatial reconstruction of Scottish summer temperatures from tree rings. International Journal of Climatology37(3): 1540–1556.
42.
RydvalMLarssonLÅMcGlynnL, et al. (2014) Blue intensity for dendroclimatology: Should we have the blues? Experiments from Scotland. Dendrochronologia32(3): 191–204.
43.
RydvalMLoaderNJGunnarsonBE, et al. (2017b) Reconstructing 800 years of summer temperatures in Scotland from tree rings. Climate Dynamics49(9–10): 2951–2974.
44.
SchneiderLSmerdonJEBüntgenU, et al. (2015) Revising midlatitude summer temperatures back to AD 600 based on a wood density network. Geophysical Research Letters42(11): 4556–4562.
45.
SchweingruberFHBriffaKR (1996) Tree-ring density networks for climate reconstruction. In: JouzelJBradleyRSJonesP (eds) Climatic Variations and Forcing Mechanisms of the Last 2000 Years. Berlin: Springer, pp. 43–66.
46.
SiglMWinstrupMMcConnellJR, et al. (2015) Timing and climate forcing of volcanic eruptions for the past 2,500 years. Nature523(7562): 543.
47.
StoffelMKhodriMCoronaC, et al. (2015) Estimates of volcanic-induced cooling in the Northern Hemisphere over the past 1,500 years. Nature Geoscience8(10): 784.
48.
SullivanPFPattisonRRBrownleeAH, et al. (2016) Effect of tree-ring detrending method on apparent growth trends of black and white spruce in interior Alaska. Environmental Research Letters11(11): 114007.
49.
WigleyTMBriffaKRJonesPD (1984) On the average value of correlated time series, with applications in dendroclimatology and hydrometeorology. Journal of Climate and Applied Meteorology23(2): 201–213.
50.
WilesGCD’ArrigoRDBarclayD, et al. (2014) Surface air temperature variability reconstructed with tree rings for the Gulf of Alaska over the past 1200 years. The Holocene24(2): 198–208.
51.
WilsonREllingW (2004) Temporal instability in tree-growth/climate response in the Lower Bavarian Forest region: Implications for dendroclimatic reconstruction. Trees18(1): 19–28.
52.
WilsonRAnchukaitisKBriffaK, et al. (2016) Last millennium Northern Hemisphere summer temperatures from tree rings: Part I: The long term context. Quaternary Science Reviews134: 1–18.
53.
WilsonRD’ArrigoRAndreu-HaylesL, et al. (2017) Experiments based on blue intensity for reconstructing North Pacific temperatures along the Gulf of Alaska. Climate of the past13(8): 1007–1022.
54.
WilsonRRaoRRydvalM, et al. (2014) Blue Intensity for dendroclimatology: The BC blues: A case study from British Columbia, Canada. The Holocene24(11): 1428–1438.
55.
WilsonRJLuckmanBH (2003) Dendroclimatic reconstruction of maximum summer temperatures from upper treeline sites in Interior British Columbia, Canada. The Holocene13(6): 851–861.
56.
YoungblutDLuckmanB (2008) Maximum June–Julytemperatures in the southwest Yukon over the last 300 years reconstructed from tree rings. Dendrochronologia25(3): 153–166.
Supplementary Material
Please find the following supplemental material available below.
For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.
For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.
