戻る
「早戻しボタン」を押すと検索画面に戻ります。

今後説明を表示しない

[OK]

コーパス検索結果 (left1)

通し番号をクリックするとPubMedの該当ページを表示します
1                                              LED knockdown reduces CDKN1A enhancer induction and acti
2                                              LED light irradiation at 660 nm accelerated palatal woun
3                                              LED-stimulated NO levels were not reduced by inhibition
4                                              LEDs provide a compact, low cost light source and have b
5 hickness increased (+0.064 mm/D, P < 0.001), LED decreased (-0.075 mm/D, P < 0.001), CMRD decreased (
6 d 8 wk of normal food intake combined with 2 LED products/d, followed by a 48-wk period of weight mai
7  was inhibited significantly using 5 J/cm(2) LED light irradiation in vitro.
8 w-dose [LD]), or 20 (high-dose [HD]) J/cm(2) LED light irradiation on the opened palatal wound and we
9  in vitro wound healing with 0 to 20 J/cm(2) LED light irradiation.
10 culture period with 60-second (224 mJ/cm(2)) LED exposure significantly increased cell growth compare
11     The output power successfully lit up 600 LED bulbs by the application of a 0.2 N mechanical force
12                           We also designed a LED based reporting for the presence of EtG in the human
13 as a flexible conductive wire for lighting a LED and a cathode in a fiber-shaped dye-sensitized solar
14 al orders of magnitude higher than that of a LED or thermal light source.
15 hich combines the low spatial coherence of a LED with the high spectral radiance of a laser, could en
16 ervals up to 120 seconds demonstrated that a LED array emitting 653-nm red light stimulated significa
17 ining 7-dehydrocholesterol were exposed to a LED that emitted a peak wavelength at 293, 295, 298 or 3
18 peak wavelength: 518 nm) or an ultraviolet-A LED array (peak wavelength: 375 nm).
19 es were modelled as synchronously activating LED arrays (LED radius: 1 mm; optical power: 10 mW mm(-2
20 onexpensive commercial digital camera and an LED illumination system.
21                The membrane is excited by an LED at 385 nm wavelength and the intensity of the lumine
22 ufficient cortical light penetration from an LED and diffusion of caged GABA to quickly terminate int
23                             We thus mated an LED light source, a dark-field condenser and a 20x objec
24  running a program for 17h that turned on an LED every 60s.
25 trical current and potential for powering an LED for more than 20min.
26                     For in vitro studies, an LED dose (2, 4, 6 J cm(-2))-dependent cytotoxicity was o
27 of an initial 16-wk randomized phase with an LED for 8 wk and 8 wk of normal food intake combined wit
28                            Treatment with an LED showed a trend in favor of clinically important PASI
29 ces, such as photon detector, solar cell and LED.
30 d dosing (n=382) alternating between EED and LED.
31                              ESEM images and LED multispectral imaging confirmed that no damages or a
32 lled as synchronously activating LED arrays (LED radius: 1 mm; optical power: 10 mW mm(-2) ; array de
33 ight signals from incoherent sources such as LEDs through selective suppression of light propagation.
34 mic therapy and artificial white light (AWL) LED photodynamic therapy for the treatment of AKs on the
35 nsitivity and specificity of CellScope-based LED FM was noninferior to conventional LED FM by using a
36 tting diode (LED) made from a blue GaN-based LED and the CQD/NP-GaN shows an increase of extraction e
37                        We simulate GaN-based LED structures that delay the onset of efficiency droop
38  to realize the high performance AlInN-based LEDs and lasers with the desired emission wavelength.
39 ncreased from 54 MHz up to 117 MHz in a blue LED chip under 0.14% compressive strain.
40 We used a small, commercially available blue LED light box, screen size 11.2 x 6.6 cm at approximatel
41                               GaN-based blue LED technology not only resulted in efficient white ligh
42  species, photo-excited with a benchtop blue LED source, can exhibit excited-state reduction potentia
43 ), solvent and light-source (CF lamp or blue LED) play in a variety of Ir-photoredox mediated transfo
44 m/W; four times greater than the parent blue LED.
45  responsible for the development of the blue LED were awarded the 2014 Nobel Prize in Physics.
46  ethers catalyzed by fac-Ir(ppy)3 under blue LED irradiation with subsequent one-pot condensation wit
47 diation of cyclic 2-aryloxyketones with blue LED light in the presence of an Ir(III) complex leads to
48   Fluorescence was excited with cyan or blue LEDs on alternating camera frames, thus providing a 375-
49 substrate as the limiting reagent using blue LEDs and an easily prepared N-xanthylamide.
50 (C^N)2] complexes upon irradiation with blue LEDs at room temperature with evolution of methane.
51 m tetrafluoroborate and irradiated with blue LEDs in the presence of the photoredox catalyst Ru(bpy)3
52 illumination of the Ni(IV) complex with blue LEDs results in rapid formation of the cyclic C-C produc
53 at can be activated upon irradiation by blue-LED lamps, we can achieve the coupling of a range of pri
54 s a copper catalyst in combination with blue-LED irradiation to achieve the decarboxylative coupling
55 ns, Auger recombination greatly impacts both LED efficiency and the onset of efficiency roll-off at h
56 prove power conversion efficiencies for both LEDs and solar cells.
57  an ICER of $45 (95% CrI 25-74), followed by LED fluorescence microscopy with an ICER of $29 (6-59).
58 y of electronic devices such as solar cells, LEDs, sensors, and possible future bioelectronic ones.
59  this paper first reports a compact confocal LED epifluorescence sensor using a light stop with an ar
60 e and demonstrate microscopically controlled LED emission.
61 were similar with CellScope and conventional LED FM (34% versus 32%, respectively; P = 0.32), and agr
62 based LED FM was noninferior to conventional LED FM by using a preselected margin of inferiority of 1
63 ation (CO formation); however, conventional (LED) light sources produce water splitting exclusively.
64                       Compared with same-day LED fluorescence microscopy and Xpert full rollout, targ
65                                     Same-day LED fluorescence microscopy is the next most effective s
66 elf-healing of conductivity, custom-designed LEDs with complex micropatterns, and foldable stretchabl
67 f-healing of conductivity, customer-designed LEDs with complex micro-patterns, and foldable stretchab
68 e very promising for light-emitting devices (LEDs) due to their high color purity, low nonradiative r
69 diameter (CMRD) or lens equatorial diameter (LED).
70 tervention group received a low-energy diet (LED) (800-1000 kcal/d) for 8 weeks to induce weight loss
71 ted to a control group or a low-energy diet (LED) group.
72                   A formula low-energy diet (LED) reduces weight effectively in obese patients with k
73                                      Dimming LEDs by 50% or manipulating their spectra to reduce ecol
74 de, employing a 470 nm light emitting diode (LED) and a microfiber optic USB spectrometer.
75 ing an interchangeable light emitting diode (LED) and a photodiode.
76 a using either a green light-emitting diode (LED) array (peak wavelength: 518 nm) or an ultraviolet-A
77  on a ultraviolet (UV) light-emitting diode (LED) array oven, and provides precisely controlled "in-c
78 pillar heterostructure light-emitting diode (LED) arrays for white light emissions are achieved and t
79 ifferent wavelength of light-emitting diode (LED) at 250mumol.m(-2).s(-1) of photon flux density on r
80               A violet light-emitting diode (LED) excitation source and color imaging with either a d
81 using a CCD camera and light emitting diode (LED) excitation source, to measure GFP expression.
82 tigated the effects of light-emitting diode (LED) exposure on dental pulp cells (DPCs).
83           Conventional light-emitting diode (LED) fluorescence microscopy (FM) and mycobacterial cult
84 s of Xpert MTB/RIF and light-emitting diode (LED) fluorescence microscopy in Tanzania.
85 rated to power a 2.2 V light emitting diode (LED) for 1 min.
86 example a conventional light-emitting diode (LED) is driven with a 500-muA peak current (600-C discha
87 rst time, a sub-250 nm light-emitting diode (LED) is investigated as a light source for optical detec
88 y near-infrared 740 nm light-emitting diode (LED) lamps with bright upconversion luminescence is desi
89 evaluate the effect of light-emitting diode (LED) light irradiation on the donor wound site of the fr
90 a near-infrared 860 nm light emitting diode (LED) light source and a wedge depolarizer to create a ph
91 ation of supplementary light-emitting diode (LED) lighting within a greenhouse for cultivation of red
92              The white-light-emitting diode (LED) made from a blue GaN-based LED and the CQD/NP-GaN s
93 m(2) with either green light-emitting diode (LED) or ultraviolet-A (UV-A) irradiation.
94     Light from a white light emitting diode (LED) source is dispersed onto a digital micromirror arra
95 recombination layer in light-emitting diode (LED) structures.
96 ser, laser diode (LD), light emitting diode (LED), super luminescent light emitting diode (sLED) and
97 sensitive and low-cost light emitting diode (LED)-based epifluorescence sensor module for qPCR sensor
98   A simple inexpensive light-emitting diode (LED)-based fluorescence detector for detection in capill
99 s optional modules for light-emitting diode (LED)-based fluorescence microscopy and optogenetic stimu
100 mice followed by local light-emitting diode (LED)-based illumination, either of the thalamus or the p
101 y to light an external light-emitting diode (LED).
102 r on a commercial blue light-emitting diode (LED).
103 ned and manufactured a light-emitting diode (LED)/PIT device and validated the technical feasibility,
104  or electrically [in a light-emitting diode (LED)].
105 ht source used a green light-emitting diode (LED; lambda(center) = 520 nm), and the light traveled th
106 uipped with a pair of light emitting diodes (LED) was studied in lab synthetic solutions for on-site
107 nt in fullerene-based light emitting diodes (LED).
108 deep ultraviolet (UV) light emitting diodes (LEDs) and lasers.
109 o the device based on light emitting diodes (LEDs) and smart phones.
110                       Light-emitting diodes (LEDs) are a potential new resource in food production li
111 insically stretchable light-emitting diodes (LEDs) are demonstrated using organometal-halide-perovski
112 ighting technologies, light emitting diodes (LEDs) are gradually replacing conventional lighting sour
113                 White light-emitting diodes (LEDs) are rapidly replacing conventional outdoor lightin
114 lity ultraviolet (UV) light-emitting diodes (LEDs) at 308 nm were achieved using high density (2.5 x
115        Development of light-emitting diodes (LEDs) based on colloidal quantum dots is driven by attra
116 fully functional blue light-emitting diodes (LEDs) by growing LED stacks on reused graphene/SiC subst
117 emission intensity of light-emitting diodes (LEDs) by utilizing the piezo-polarization charges create
118  first application of light-emitting diodes (LEDs) for ultraviolet photodissociation (UVPD) mass spec
119                       Light emitting diodes (LEDs) have been developed to emit ultraviolet radiation.
120 and for high-power lighting-emitting diodes (LEDs) is currently increasing.
121           We describe light-emitting diodes (LEDs) made by stacking metallic graphene, insulating hex
122 oduced by solid-state light-emitting diodes (LEDs) on carotenoid content and composition changes in B
123 ances achievable with light-emitting diodes (LEDs) operated on battery power.
124 ficiency of AlGaN DUV light-emitting diodes (LEDs) remains very low because the extraction of DUV pho
125 e FA-perovskite-based light-emitting diodes (LEDs) with high efficiency are reported.
126 orene-free perovskite light-emitting diodes (LEDs) with low turn-on voltages, higher luminance and sh
127 gth downconversion in light-emitting diodes (LEDs), and optical biosensing schemes.
128 ppropriately selected light emitting diodes (LEDs), are visualized and automatically analyzed by a so
129 as thermal sources or light emitting diodes (LEDs), provide relatively low power per independent spat
130 ation sources such as light emitting diodes (LEDs), these reporters need to be excited at wavelengths
131 icroscale, injectable light-emitting diodes (LEDs), with the ability to operate at wavelengths rangin
132  or increasingly, the light-emitting diodes (LEDs).
133 mitted by an array of light-emitting diodes (LEDs).
134 ctrical connection of light-emitting diodes (LEDs).
135 ays to 6 weeks 6 days; late extended dosing (LED; n=274) every 7 weeks to 8 weeks 5 days; variable ex
136 e present an elegant approach based on a DUV LED having multiple mesa stripes whose inclined sidewall
137           The sidewall-emission-enhanced DUV LED breaks through the fundamental limitations caused by
138 the extraction of DUV photons from AlGaN DUV LEDs, and hence to provide promising routes for maximizi
139            The system employed a UV-emitting LED for low-power, pulsed excitation and an intensified
140 s known about the efficiency of UVB emitting LEDs tuned to different wavelengths for producing vitami
141 rogress in piezo-phototronic-effect-enhanced LEDs is reviewed; following their development from singl
142  illumination simply provided by an external LED illumination device.
143 y the phones camera using the embedded flash LED as the illumination source.
144  and fit conditions of the lungs by flashing LEDs of different colors.
145      Our finding may pave the foundation for LED communities to further establish reliable junction-t
146 ations involving ChR2-RED and ChR2-RED+ (for LED arrays with density >/= 2.30 cm(-2) ), suggesting th
147 ptical nonlinearities, light extraction from LEDs and coupling to and from subwavelength waveguides.
148 ushrooms," internally illuminated by a green LED emitting light similar to the bioluminescence, attra
149 engal concentrations under ambient and green LED irradiation, and (2) for the 0.1% rose bengal in the
150 individually addressable red, blue and green LED triplets placed in 15 vertical strips hanging 0.1 m
151  darkness; red light (R); combined red-green LED (RG) lights; and combined red-green-violet LED (RGV)
152 blue light-emitting diodes (LEDs) by growing LED stacks on reused graphene/SiC substrates followed by
153             Longer pulse duration and higher LED array density were associated with increased optogen
154     Among p53-induced lncRNAs, we identified LED and demonstrate that its suppression attenuates p53
155 ation of the cardiac surfaces (via implanted LED arrays) to elicit light-induced activations.
156          A current obstacle towards improved LED performance is an incomplete understanding of the ro
157  The changes per diopter of accommodation in LED, CMRD, and ciliary muscle thickness were not related
158 terials for much improved optical control in LEDs, solar cells, and also toward applications as optic
159 electronic and mechanical devices, including LED, photodiode, pumps, and electronic boards, can be us
160 me attractive through the use of inexpensive LED light sources and common UV-vis spectrometers, as we
161       Here we describe a novel, inexpensive, LED powered, waveguide based TIRF system that could be u
162                      An 880 nm near infrared LED was irradiated perpendicular to the surface of groun
163 (UV-NIL), that is pumped with a pulsed InGaN LED is demonstrated.
164 robes, pumping systems, microscale inorganic LEDs, wireless-control electronics, and power supplies.
165  the USB port of which drives the integrated LED used for excitation, allows for autonomous operation
166 imed to determine the effect of intermittent LED compared with daily meal replacements on weight-loss
167 e of daily meal replacements or intermittent LED resulted in weight-loss maintenance for 3 y.
168 artphone as light intensity detector and its LED flash light as an optical source.
169 rs and open areas that can accommodate lamps/LEDs and wiring.
170 MOS-compatible techniques to realize lasers, LED, and photodetectors.
171 uid-stored boar semen to different red light LED regimens on sperm quality and reproductive performan
172 the control group (n = 19) in locating a lit LED that she viewed through the eye contralateral to the
173 t includes a high-resolution USB microscope, LED cold light illumination, and miniaturized 3D printed
174 n direction, we also demonstrate microscopic LED beam splitting through the selective choice of polar
175 ted sound-indication devices and a miniature LED backpack to visualize and record the nocturnal phono
176 nts known as saccades allow simple modulated LEDs to be observed at very high rates.
177 ions, but also improved infrared nanocrystal-LEDs and photon-upconversion technology.
178 ethod of fabricating the multishell nanotube LED microarrays with controlled emission colors has pote
179 mission from the entire area of the nanotube LED arrays was achieved via the formation of MQWs with u
180  effectively guide the selection of the next LED structure to be examined based upon its expected eff
181 junction with an exceptionally low-power NIR LED light irradiation (10 mW cm(-2) ), these nanoparticl
182                                   The 293 nm LED was best suited for evaluating its effectiveness for
183 uble bond can be isomerized by light (365 nm LED) during the reaction leading to a characteristic fin
184                                     A 650 nm LED at five different incident angles is used to illumin
185 clusion, data analysis indicated that 653-nm LED irradiation promoted DPC responses relevant to tissu
186 ties upon irradiation with red light (660 nm LED).
187 e optoelectronic setup consists of an 880 nm LED connected to the U-shaped probe driven by a sine wav
188 ng from blue 455/470 nm and green 505/530 nm LEDs was applied (16-h; PPFD-30 mumol m(-2)s(-1)).
189 ion of the effects of 520-, 595-, and 622-nm LEDs supplemental to the standard set of LEDs.
190 s with standard 447-, 638-, 665-, and 731-nm LEDs was used in the experiments.
191 n be driven by a blue (lambda(max) = 472 nm) LED light source using [Ru(bpy)(3)]Cl(2) (bpy = 2,2'-bip
192                     The benefit of the novel LED-excited UCNPs is demonstrated by imaging of breast c
193 xperiments were performed: (1) evaluation of LED irradiance levels of 545, 440, 330, 220, and 110 mum
194 achieved and the light emission intensity of LED array is enhanced by 120% under -0.05% compressive s
195 ts with knee osteoarthritis, but the role of LED in long-term weight-loss maintenance is unclear.We a
196 hypermethylation analysis shows silencing of LED in human tumours.
197                      One prominent target of LED was located at an enhancer region within CDKN1A gene
198  behavior of FO-TEG, lighting of an array of LEDs is demonstrated using artificial vibration and huma
199 promise for reducing the ecological costs of LEDs, but the abundances of two otherwise common species
200     A fundamental challenge in the design of LEDs is to maximise electro-luminescence efficiency at h
201 sing method to enhance the light emission of LEDs based on piezoelectric semiconductors through apply
202 ronment and human health, the flexibility of LEDs has been advocated as a means of mitigating the eco
203 -nm LEDs supplemental to the standard set of LEDs.
204 ces using arrays consisting of electrodes or LEDs (for optogenetic activation of conventional narrow-
205 chieved in fermentation assisted with orange LED light (8.28UA490nm), white light (8.26UA490nm) and u
206 ture utilization in inorganic and/or organic LED applications.
207 f value as the emissive component of organic LEDs (OLEDs).
208  the in vitro and in vivo performance of our LED device.
209 cy of a device based on a 635 nm high-output LED powered by three AA disposable alkaline batteries, t
210 he other hand, it is found that overstressed LEDs show irreversibly degraded device performance, poss
211 e the spatially resolved CTE of the packaged LED device, which offers significant advantages over tra
212 derive the instantaneous CTE of the packaged LED under different injected currents.
213                                 A perovskite LED with a perovskite film treated under optimum thermal
214     Here, using pure CH3 NH3 PbI3 perovskite LEDs with an external quantum efficiency (EQE) of 5.9% a
215                   The stretchable perovskite LEDs are mechanically robust and can be reversibly stret
216 -dependent characteristics of the perovskite LEDs and the cross-sectional elemental depth profile, it
217 generation), emissive materials (plasmonics, LEDs, biolabelling), sensors (electrochemical, biochemic
218 nergy down-conversion phosphors in polarized LEDs.
219  epifluorescence microscopy under high power LED illumination, followed by serial image section decon
220 odular design includes a separate high power LED source, detector head, designed in the epifluorescen
221  an InGaN-based (lambda = 450 nm) high-power LED encapsulated in polystyrene resin.
222 n of an elastomer-mounted extreme high-power LED lamp and a swimming soft robot.
223                                 A high-power LED was used as source for the monochromatic UV light en
224 er fabrication compatible with mass-produced LEDs.
225 -contact chromophore pumping from a proximal LED, and markedly reduced gain thresholds.
226                  The unencapsulated white QD-LED has a long lifetime of 96 h at its initial luminance
227  report a simply solution-processed white QD-LED using a hybrid ZnO@TiO(2) as electron injection laye
228  In this study, QD light-emitting diodes (QD-LEDs) fabricated with electrophoretically deposited film
229  White quantum dot light-emitting diodes (QD-LEDs) have been a promising candidate for high-efficienc
230 pproach to achieve high-performance white QD-LEDs and also other optoelectronic devices.
231     We show that the performance of white QD-LEDs can be adjusted by controlling the driving force fo
232 ed wall, the effective bandgaps of nano-ring LEDs can be precisely tuned by reducing the strain insid
233 ials, and their suitability as energy-saving LED lighting phosphors is assessed.
234                       Equipped with a simple LED excitation source and a colored plastic gel filter,
235 erformance was evaluated through a simulated LED light source and the bioluminescence produced by the
236       Lastly, NMR spectroscopy using in situ LED-irradiated samples was utilized to monitor the kinet
237              Using a miniature spectrometer, LED light source, and optical fibers on a rotating bench
238 our knowledge, a normalized and standardized LED device has not been explicitly described or develope
239 lex micro-patterns, and foldable stretchable LEDs are demonstrated.
240 plex micropatterns, and foldable stretchable LEDs are demonstrated.
241 ceeds all reported intrinsically stretchable LEDs based on electroluminescent polymers.
242                              The stretchable LEDs consist of poly(ethylene oxide)-modified poly(3,4-e
243 of a greater positive effect of supplemental LED components on the vitamin C and tocopherol contents
244 nding and eRNA expression analyses show that LED associates with and activates strong enhancers.
245 ennas into the metal electrode, we show that LED emission from randomly polarized QD sources can be p
246                   Moreover, it is shown that LED (lambda = 395 nm) is an efficient light energy sourc
247                                          The LED based unit displayed the diseased, critical, and fit
248                                          The LED junction temperature at different injected currents
249                                          The LED-based sensor was able to reliably distinguish betwee
250                           Interestingly, the LED clearly shows a sub-bandgap emission at 1.7 V (bandg
251 ous high-definition digital recording of the LED coordinates provides automatic tracking of the femal
252 racteristics and photobiologic safety of the LED device, multiple optical measurements were performed
253 ences in PASI and DLQI, also in favor of the LED group, were -2.0 (95% CI, 4.1 to -0.1; P = .06) and
254 the combination of time and intensity of the LED source.
255 used for connecting the detector head to the LED excitation source and the photodetector module.
256 lenses, one of which was integrated with the LED, were used to increase light throughput through the
257                                          The LEDs are sandwiched in-between a stretchable top and bot
258                                         This LED was found to be 2.4 times more efficient in producin
259 ials on a large circular platform, either to LED-cued goal locations or as a spatial sequence from me
260  than 365 nm, where high-powered ultraviolet LEDs are available.
261 n producing time-resolved fluorescence under LED-excitation.
262 types resembling those of plants grown under LEDs reported previously.
263 ogenetics-based defibrillation therapy using LED arrays.
264 s from 60 individual reaction chambers using LEDs and phototransistors.
265 -RPA or RT-PCR assays can be monitored using LEDs and a smartphone camera.
266 ggest that while management strategies using LEDs can be an effective means of reducing the number of
267                             A 260 nm deep UV LED-based absorption detector with low detection limits
268 ass filters and UV light-emitting diodes (UV LEDs) isolated wavelengths in approximate 10 nm interval
269 he exposure conditions with ultraviolet (UV) LEDs were systematically investigated in the wavelength
270 lly optimized sensor head equipped with a UV-LED light source and optical fiber bundles for efficient
271 ng this high quality AlN template: a deep UV-LED device fabricated and showed a strong single sharp e
272 llowing for further re-growth of the deep UV-LED device.
273 ficiency (EQE) of about 0.03%, for a deep UV-LED grown on Si substrate.
274  a deep-ultraviolet light-emitting diode (UV-LED) device using this AlN/patterned Si.
275 nm deep ultraviolet-light-emitting diode (UV-LED) is employed within an on-capillary photometric dete
276              The increased UV exposure by UV-LEDs may be readily implemented in existing food product
277 cted to study the potential of using deep UV-LEDs as the light source in photometric detection for ev
278 tion focused on fundamental properties of UV-LEDs, in particular, emission spectra, radiometric power
279 ls discussed herein are marked by use of UVA LEDs (365 nm), which have reduced the reaction times and
280 D (RG) lights; and combined red-green-violet LED (RGV) lights during the night.
281  1 ppm to monomers) and a low energy visible LED as the light source (1-4.8 W, lambda(max) = 435 nm).
282 hosphors-free white light-emitting-diodes (w-LEDs) using Ba2V2O7 or Sr2V2O7 quantum dots that directl
283 pplication in white light emitting diodes (w-LEDs).
284 ed that such quantum dots can be efficient w-LEDs for solid state lighting.
285 ction system which includes multi-wavelength LEDs capable of exciting many fluorophores in multiple w
286 well-faceted GaN/InGaN multiple quantum well LEDs compared to non-faceted structures.
287     The objective was to investigate whether LED Blue Light (LBL) induces changes in phenolics and et
288 ery and an optical detector based on a white LED and two photodiodes with interference filters.
289                                      A white LED is used as the common optical excitation source for
290         The accessory consists of four white LED lights fixed to the lens of a commercial DSLR camera
291 that had been acclimated to night-time white LED lighting conditions for 16 days and individuals that
292 s' behavioural responses to night-time white LED lighting were performed on individuals that had been
293 he reverse rainbow photocathodes under white LED light illumination.
294                                        White LEDs both increased the total abundance and changed the
295 ing this catalyst and irradiating with white LEDs resulted in the production of polymers with targete
296 illary electrophoresis system was built with LED induced fluorescence detection and a credit card siz
297 r the intermittent treatment (IN) group with LED for 5 wk every 4 mo for 3 y or to daily meal replace
298  dots with their emissive performance within LEDs.
299                              After the 16-wk LED-only period, the mean weight loss was -15.0 kg (95%
300 the control group received the same 8 + 8-wk LED intervention, and all patients were then followed fo

WebLSDに未収録の専門用語(用法)は "新規対訳" から投稿できます。
 
Page Top